CN1469720A - Radioactive emission detector with position tracking system and application in therapeutical system and treatment process - Google Patents

Abstract

a system for calculating a position of a radioactivity emitting source in a system-of-coordinates, the system comprising (a) a radioactive emission detector; (b) a position tracking system being connected to and/or communicating with the radioactive emission detector; and (c) a data processor being designed and configured for receiving data inputs from the position tracking system and from the radioactive emission detector and for calculating the position of the radioactivity emitting source in the system-of-coordinates.

Description

The radioactive emission detector and the application in medical system and medical procedure thereof of being furnished with positioning control system

FIELD OF THE INVENTION and background

The present invention relates to be furnished with the radioactive emission detector of positioning control system.Particularly, the present invention relates on function the surgical instrument that the minimum with the above-mentioned radioactive emission detector of being furnished with positioning control system and imaging of medical instrument and/or guided bone enters integrates.In the position of body imaging part, calculate the radiopharmaceutic position of concentrating in the body so the present invention is applicable to, for example, can utilize this information to carry out the surgical operation that an effective minimum enters.The invention further relates to a kind of surgical instrument of being furnished with positioning control system and radioactive emission detector, be used for during excision and/or biopsy process, carrying out location, accurate original place, this surgical instrument and further feature collaborative work of the present invention.

The use of the surgery operating technology that minimum enters has significantly changed the method and the effect of operation.The cutting of for the position that can see operation bodily tissue and organ being carried out in conventional " open surgery " process can cause very big blunt wound and lose blood.According to the method, the exposure of interior tissue and organ has also greatly increased the danger of infecting.Wound is lost blood and is infected the time that all can prolong recovery, has increased the complication odds, and needs a nursing of more strengthening and monitoring group.This open surgery can produce more pain and feel bad, higher surgery cost and the danger of bigger side effect.

Form a sharp contrast with it, the operation that minimum enters is injury-free to the limit of the resistance naturally ability that infects by fully safeguarding human body, produces very little blunt wound or the risk of infection with minimum of losing blood.The operation that minimum enters is compared with conventional open surgery, recovers sooner, can not produce what complication.At all surgery medical domains, the operation that minimum enters, for example Laparoscopic, endoscopic or cystoscopic surgical operation has substituted the surgical operations that enter more.Owing to, make the easier operation of the doctor who undergos surgery such as the technological progress in fields such as fibre optics, microtool making, imaging and material science, have cost efficiency higher be used for the instrument that minimum enters operation.Yet, still there are a lot of technology barriers, limited curative effect, increased the minimum difficulty that enters operation, along with the development of complicated imaging technique, overcome wherein some obstacle.As following further detailed description, the present invention provides further advantage in this respect.

Radionuclide imaging is one of radioactivity most important application aspect medical science.The purpose of radionuclide imaging is that a patient is used the radioactive marker substance, for example after the radiopharmaceutical, obtains medicine at the intravital distribution image of people.Radiopharmaceutic example comprises monoclonal antibody or other medicaments, for example, utilizes radiosiotope, as ^99MTechnetium, ⁶⁷Gallium, ²⁰¹Thallium, ¹¹¹Indium, ¹²³Iodine, ¹²⁵Iodine and ¹⁸The thrombin of fluorine labelling or fluorine-based deoxyglucose can come medication by oral or intravenous injection.Radiopharmaceutical is concentrated on tumor region, tumor or other disease, for example the active part of inflammation is compared with the tissue of tumor vicinity, and is more and faster to the picked-up of this medicine.After this, adopt radioactive emission detector, normally enter intravital detector or gammacamera (face content as follows), locate the position of this zone of action.Another application is in emergency room or operating room, uses radiopharmaceutical, detects clot as the ACUTECT of NycomedAmersham, detects the thrombosis that forms recently in the vein blood vessel or the blood clotting in heart or the arteriae cerebri.Other application comprises that use such as the medicine of radioactivity anti-drag coagulated protein antibody carries out the radiological imaging of myocardial infarction, uses radiolabeled molecule (also being become molecular imaging) to carry out the radiological imaging of particular cell types, or the like.

The external radiation detector that utilization is placed on the external diverse location of patient write down that radiopharmaceutic radioactive radiation obtains tumor or other body structure is inner and around radiopharmaceutic distribution image.For such application, first-selected usually radiation is the gamma-rays radiation, and its radiation is greatly in the 20-511KeV energy range.When detector contacts with tissue, also can carry out β ray and positron and detect.

Attempt the first time of radioactivity " imaging " is in the later stage forties 20th century.One group of radioactivity seeker is placed on the matrix of measurement point around the patient head.Perhaps, adopt a single detector on each point of matrix, to measure respectively.

In later stage the 1950's, Ben Cassen has proposed rectilinear scanner, makes this technology obtain major progress.Utilize this instrument, in the zone of being paid close attention to, detector is scanned with a predetermined pattern.

Nineteen fifty-three Hal Anger has described first gammacamera of can a time being had a few on the recording picture.What Anger used is a detector that comprises NaI (T1) screen and an x-ray film.In later stage the 1950's, Anger has substituted the pad screen with a photomultiplier tube assembly.In " the nuclear medicine detector device " of New York Academic publishing house publication in 1967, Halo.Anger shows the 19th chapter of " radioisotope camera is at Hine GJ " the Anger photographing unit is introduced.Anger has also described a kind of like this radioactivity seeker assembly in the U.S. Patent No. 2,776,377 of nineteen fifty-seven issue.

People's such as Carroll U.S. Patent No. 4,959,547 has been described a probe that is used for drawing or providing the radioactivity image in patient's body.This probe comprises that a radioactivity seeker and one are used to adjust the adjusting device of lonizing radiation by the solid angle of detector, and this solid angle is a continually varying.Construct this probe so that only make the lonizing radiation in the solid angle arrive detector.During the ray that arrives by near mobile probe radioactive source and sensing detection, solid angle is adjusted to minimum from maximum, probe can be positioned at the radioactive source place.Probe can be used for the pointwise image of determining radioactive position and radioactive source being provided or is used to draw these visual data.

People's such as Carroll U.S. Patent No. 5,246,005 has been described a kind of radioactivity seeker or probe, uses useful signal to detect the emission signal of tissue on statistics.The output of radioactivity seeker is series of pulses, and a predetermined amount of time is counted.By at least two count ranges of the definition of the circuit in the instrument, and comprise the count range of determining the input counting.For each count range, produce one with all other audio signals of audio signal phase region that produces at other count range.On statistics, can select to make between the meansigma methods of the meansigma methods of each count range and contiguous lower or higher count range to differ 1,2 or 3 standard deviation.For each count range, can change the parameter of audio signal, as frequency, tone, repetitive rate and/or intensity, provide other signal of signal phase region with other count range.

The U.S. Patent No. 5,475,933 of Olson has been described a system that is used to detect photo emissions, and wherein detector is used for obtaining the electrical quantity signal, and this signal has the corresponding amplitude of energy with detected photo emissions and other signal generation incidents.In an energy window, use two comparator networks, when a signal amplitude based on incident is equal to or greater than a threshold value, defines a kind of function and produce an output L; Surpass one upward in limited time when this signal amplitude is increased to, produce an output H.Utilize a discriminator circuit,, under the situation of not exporting H, obtain an incident output, improve reliability and accuracy according to the output L that exists in response to the L and the H of these outputs.This discriminator circuit be one have three stable states asynchronous, in proper order, the discriminator circuit of dominant mode.

People's such as Madden United States Patent (USP) 5,694,219 and 6,135,955 have described a kind of system and method, being used for carrying out diagnostic detection for it provides a kind of structure of radiological imaging medicament to patient is intravital, can be to make body structure produce the radiotracer of gamma-rays, the relevant discrete photon continuum of characteristic X-ray and Compton as the radiological imaging medicament.This system comprises a radioactivity receiving system, for example, and portable probe or photographing unit, a coherent signal processor and an analyzer.In order to receive the gamma-rays that sends by structure and characteristic X-ray and, the radioactivity receiving system to be positioned at and health and structure position adjacent in order to provide a processed electrical signals to represent.This processed electrical signals comprises the first of the characteristic X-ray that expression receives and the gamma-ray second portion that expression receives.Signal processor moves the signal corresponding to the discrete photon in Compton of the signal of telecommunication in all-round gamma-rays and the characteristic X-ray scope.The Allocation Analysis device, so that use the X ray part of the signal of handling selectively, the near-field information of structure is provided, use the X ray part and the gamma-rays part of the signal of handling selectively, the near field and the far-field information of structure are provided, selectively use the gamma-rays part of the signal of handling, the expansion field information of structure is provided.

People's such as Thurston U.S. Patent No. 5,732,704 have described a kind of method that is used to discern a sentinel node of the one group of local nodes that is positioned at the lymph basin place relevant with tumor tissues, and radiopharmaceutical is injected in the tumor tissues position in this basin.Radiopharmaceutical moves towards the basin that comprises sentinel node along lymphatic vessel.Move one along conduit and have the crystalline portable probe of preposition radioactivity seeker, the magnitude pattern reading of doctor's observed count rate determines when probe and catheter alignment simultaneously.When the counting rate of probe significantly increases, conclude that promptly this zone comprises sentinel node.Along operative incision, utilize a voice output movable relevant to handle probe with probe, along with the increase of displacement, increase the threshold value of counting rate, till the doctor can't hear acoustical signal up to reaching threshold value.When probe moves to this point, detector will be adjacent with sentinel node, it can be cut off then.

People's such as Thurston U.S. Patent No. 5,857,463 has further described the localized instrument that is used to follow the tracks of the sentinel node that intralymphatic radiopharmaceutical and radiopharmaceutical concentrated.Use less, straight, a portable probe that has two hand switches.For tracing process,, wherein determine to comprise radiopharmaceutic catheter position by observing the figure reading with the mode mobile detector of a fluctuation.When near sentinel node regional, the switch of being handled on the probe apparatus by the doctor carries out the noise elimination operation, up to definite residing zone of minor node.

People's such as Kramer U.S. Patent No. 5,916,167 and the patent 5,987 of Thurston, 350 pairs of surgical operation probes are described, and wherein one can be used in combination with a wield handle and cable assembly by thermally-sterilized and reusable detector parts.This reusable detector parts and a detector crystal and relevant accessory work together together with the preamplifier parts.

The U.S. Patent No. 5,928,150 of Call has been described a system, utilizes a hand-held detector to detect and is injected into Endolymphangial radiopharmaceutic radiation.When being used to locate sentinel node, the supplementary features that provide comprise and are used to handle the function that the useful photon event pulse is determined count rate level signals.System comprises a counting rate function based on scope and adjustable threshold trait.The threshold value amplifying circuit produces full-scale audition and vision output after one.

People's such as Raylman United States Patent (USP) 5,932,879 and 6,076,009 has described the system that takes when a surgical operation carries out, and is used for detecting according to qualifications the β ray on the gamma-rays that sends from radiopharmaceutical.This system has the ionic silicon charged particle detector of injection, is used for producing signal according to the beta-particle that receives.A preamplifier is positioned near the detector wave filter and amplifies this signal.Detector is connected on the processing unit, is used for carrying out signal and amplifies and filtering.

A system that is used to detect with the located irradiation source has been described, the lymph that is specially adapted to take when surgical operation carries out (ILM) process of drawing in people's such as Bouton the United States Patent (USP) 6,144,876.The visual consciousness that also has of the existing audible of scanheads that this system adopts is exported.The signal processing method that unsteady window by setting up a useful photon event count or dynamic window are analyzed can be realized a desirable stability in the reading of system.The window that should float is defined between a top edge and the lower limb.The value of these window edges is to change according to the counting total value that compiled in analysis.In a word, between top edge and the lower limb at a distance of a value that is about four standard deviation numbers.

For calculate these count values and, gather these count values by successive 50 milliseconds short sweep spacing, the count value section that is produced is placed in the binary sequence in the circular buffering memorizer.When counting and surpass its top edge or be lower than its lower limb, unsteady window changes.To each sweep spacing, produce a meansigma methods about the report of the window edge calculating of intersection, be used for obtaining average counter rate signal successively.The perception output device that is produced has desirable stability, particularly when the probe detection device is in situation in the physical dimension that faces a radioactive source.

United States Patent (USP) 5,846,513 have introduced a system, are used for detecting and destroy the active tumour tissue in the organism.This system configuration is for together to use with the radiopharmaceutical of a tumor-localizing.This system comprises that one can be removed instrument via the tumor that skin injects, as transurethral resectoscope.The radiological measuring detector comprises a pin and a handle of releasably fixing this pin with a radiation sensor element.This pin is configured to insert patient body and to be movable to doubt by a little skin inlet be the different position of tumor, detects the radioactivity indication of the cancerous tissue that is embodied.Then, can remove detector, insert tumor by this inlet and remove instrument, destroy and/or remove cancerous tissue.This instrument not only destroys the tissue of labelling, and it is removed in organism, so that can carry out the radioactivity chemical examination to it, confirms that the tissue that is eliminated is cancerous tissue or health tissues.A collimator and detector together can be used, establish the ken of detector.

In case the major limitation of this system is to enter in the body, scan capability just is restricted to along the circuit translation that enters.

A kind ofly be used for gamma-ray effective collimator and must have several mm thick, therefore an effective energetic gamma rays collimator can not be used for accurate surgical instrument, as the surgical stitch pin.On the other hand, because the β ray makes it be absorbed by major part through the chemical reaction after the about 0.2-3mm of biological tissue.Like this, United States Patent (USP) 5,846, the system of describing in 513 can not effectively use high energy gamma to detect, because lost directivity to a great extent, nor can effectively utilize the β ray, because too require near emission source, and tissue has limited the motor-driven degree of instrument.

The processing of soft tissue organs needs visual (imaging) technology, as computerized X-ray axial tomogram (CT), fluorescence imaging (XRF imaging), NMR (Nuclear Magnetic Resonance)-imaging (MRI), optics endoscopy, mammography or ultrasound wave, distinguish the border and the shape of soft tissue or mass.In these years, medical imaging has become the necessary part of early stage inspection, diagnosis and the treatment of cancer and other disease.In some cases, medical imaging is the first step that prevents the cancer diffusion by earlier detection, and under the susceptible condition of institute, medical imaging can make to cure or eliminate cancer by treatment subsequently becomes possibility.

Assessment has or not neoplasm metastasis or morbidity to become the main decision factor of whether cancer patient having been carried out effective treatment.The tumor patient that studies show that about 30% new diagnosis shows detectable clinically transfer.Among these patients all the other 70% do not have clinical metastasis really, and making an appointment with half is can only treat by local tumor to cure.But some during these shift shifts, even early stage primary tumo(u)r, can not show with above-mentioned imaging tool.And, usually the most important part that will carry out the tumor of biopsy excision or surgical excision is active, i.e. Sheng Chang part, and only utilize conventional imaging this special part of tumor and other parts and/or adjacent affected the organizing mutually that do not have can not be distinguished.

In order to locate this movable part, method commonly used is to utilize the radioactive label material that is commonly referred to radiopharmaceutical agent to come this part of labelling, oral or intravenous administration, medicine concentrates on such zone, because the movable part of tumor will be higher than the picked-up of medicine and faster than the tumor tissues that closes on.So, adopt a radioactive emission detector, use the detector of an introduction-type usually, come the position in disposition activity zone.

Medical imaging is generally used for setting up computer model, for example, allow the doctor to import accurate ray when the treatment cancer, and the design minimum enters or the surgical operation of otch.In addition, also to be used at intra-operative be that the surgeon of operating room indicates the intravital target area of patient to Image-forming instrument.For example, localized radiation source of insertion that this therapy can comprise biopsy, be considered to plesioradiotherapy is directly treated near carninomatosis (so that prevent the radiation damage source of disease tissue), to the position of suffering from cancer inject chemotherapeutic agents or remove suffer from cancer or other sick body.

The purpose of all these therapies is accurately to differentiate the target area as much as possible, so that obtain more accurate test alive result, the result of activated part of tumor preferably, perhaps intactly remove on the one hand such tumor, on the other hand to around the affected tissue that do not have produce minimum damage.

But, on the prior art level, can't reach this purpose, because the Image-forming instrument of most conventional, the position and the outward appearance that show source of disease as fluoroscopy, CT, MRI, mammography or ultrasound wave, this source of disease makes tissue change with respect to surrounding tissue, but active part on inactive mass and the pathology can not be made a distinction.

On the other hand, the radioactive emission detector of prior art and/or test alive probe are suitable for distinguishing the position of radiant, but consider to also have certain defective from the angle of being convenient in entering patient's body to remove under the minimum prerequisite or to destroy detected trouble cancerous tissue.

Instrument combination provided by the invention can reduce the error allowance of tumor-localizing.In addition, can be in the single pass of the Image-forming instrument that shows organ or tumor, the position of the active part of additional tumor, and can during surgical intervention, make surgical technique and tools according to ill regional activity, can carry out more accurate and controlled surgical intervention like this, reduce the problems referred to above to greatest extent.

These and other aspect of the present invention is described in further detail below, and for doctor and patient provide more reliable targeting, and can produces and enter more for a short time and the surgical intervention of littler damage and littler mistaken diagnosis probability.

Summary of the invention

A feature of the present invention has provided a system, is used for calculating a radiation source in the position of a coordinate system, and this system comprises: (a) radioactive emission detector; (b) positioning control system links to each other with radioactive emission detector and/or communicates with; (c) data processor, design and configuration are used for receiving the data input from positioning control system and radioactive emission detector, and calculate the position of radioactive radiation source in coordinate system.

Another feature of the present invention has provided a system, is used for calculating a radioactive radiation source in the position of a coordinate system, and this system comprises: (a) at least two radioactive emission detectors; (b) positioning control system links to each other with these two radioactive emission detectors and/or communicate with at least; (c) data processor, design and configuration are used for receiving the data input from positioning control system and this at least two radioactive emission detectors, and calculate the position of radioactive radiation source in coordinate system.

Another feature of the present invention has provided a method, be used for determining a radioactive radiation source in the position of a coordinate system, the step that this method comprises has: a radioactive emission detector that links to each other or communicate with a positioning control system (a) is provided; (b) monitor the radioactivity of sending from radioactive radiation source, simultaneously, the position of monitoring radioactive emission detector in coordinate system determined the position of radioactive radiation source in coordinate system thus.

Another feature of the present invention has provided a method, be used for determining a radioactive radiation source in the position of a coordinate system, the step that this system comprises has: the radioactive emission detector that (a) provides at least one and a positioning control system to link to each other or communicate with; (b) monitoring simultaneously, is monitored this position of at least one radioactive emission detector in coordinate system from the radioactivity that radioactive radiation source sends, and determines the position of radioactive radiation source in coordinate system thus.

Another feature of the present invention has provided a system, is used for calculating a radiation source in the position of one first coordinate system, and further this position is projected in one second coordinate system, and this system comprises: (a) radioactive emission detector; (b) positioning control system links to each other with radioactive emission detector and/or communicates with; (c) data processor, design and configuration are used for (i) from positioning control system and the input of radioactive emission detector reception data; (ii) calculate the position of radioactive radiation source in first coordinate system; (iii) the position with radioactive radiation source projects in second coordinate system.

Another feature of the present invention has provided a system, be used for calculating the position of a radiation source at one first coordinate system, and further this position is projected in one second coordinate system, this system comprises: (a) at least two radioactive emission detectors; (b) positioning control system links to each other with these two radioactive emission detectors and/or communicate with at least; (c) data processor, design and configuration are used for (i) from positioning control system and the input of at least two radioactive emission detectors reception data; (ii) calculate the position of radioactive radiation source in first coordinate system; (iii) the position with radioactive radiation source projects in second coordinate system.

Another feature of the present invention has provided a kind of method, be used for calculating the position of a radioactive radiation source at first coordinate system, and this position projected on one second coordinate system, the step that this method comprises has: a radioactive emission detector that links to each other or communicate with a position tracker (a) is provided; (b) monitor the radioactivity of sending from radioactive radiation source, simultaneously, the position of monitoring radioactive emission detector in first coordinate system determined the position of this radioactive radiation source in first coordinate system thus, and this position is projected on second coordinate system.

Another feature of the present invention has provided a kind of method, be used for calculating the position of a radioactive radiation source at first coordinate system, and this position projected on one second coordinate system, the step that this method comprises has: the radioactive emission detector that (a) provides at least one and a positioning control system to link to each other or communicate with; (b) monitor the radioactivity of sending from radioactive radiation source, simultaneously, monitor this position of at least one radioactive emission detector in first coordinate system, determine the position of this radioactive radiation source in first coordinate system thus, and this position is projected on second coordinate system.

Another supplementary features of the present invention have provided a system, be used to calculate the position of the radiopharmaceutical picked-up part of patient's human organ and human organ, this system comprises (a) two dimension (projection or cross section) or three-dimensional (consequtive cross section) Image-forming instrument, link to each other with a primary importance tracking system and/or communicate with, be used for calculating the position of human organ in one first coordinate system; (b) radioactive emission detector links to each other with a second position tracking system and/or communicates with, and is used for following the tracks of the position of the radiopharmaceutical picked-up part of human organ at one second coordinate system; (c) at least one data processor, design and configuration are used for receiving the data input from three-dimensional imaging instrument, radioactive emission detector, primary importance tracking system and second position tracking system, and calculate the position of radiopharmaceutical picked-up part in a common coordinate system system of human organ and human organ.

Another supplementary features of the present invention have provided a kind of method, be used to calculate the position of the radiopharmaceutical picked-up part of patient's human organ and human organ, the step that this method comprises has (a) that a two dimension or three-dimensional imaging instrument are provided, link to each other with a primary importance tracking system and/or communicate with, and calculate the position of human organ in one first coordinate system; (b) provide a radioactive emission detector, link to each other with a second position tracking system and/or communicate with, follow the tracks of the position of radiopharmaceutical picked-up part in one second coordinate system of human organ; (c) from three-dimensional imaging instrument, radioactive emission detector, primary importance tracking system and second position tracking system, receive the data input, and calculate the position of radiopharmaceutical picked-up part in a common coordinate system system of human organ and human organ.

Another supplementary features of the present invention have provided a system, be used for carrying out an individual Medicine and Surgery operation in the radiopharmaceutical picked-up part of a patient's body organ, this system comprises: (a) radioactive emission detector, link to each other with the primary importance tracking system and/or communicate with, be used for following the tracks of the position of radiopharmaceutical picked-up part in first coordinate system of organ; (b) surgical instrument links to each other with a second position tracking system and/or communicates with, and is used for following the tracks of the position of surgical instrument in one second coordinate system; (c) at least one data processor, design and configuration are used for receiving the data input from primary importance tracking system, radioactive emission detector and second position tracking system, and calculate the position of radiopharmaceutical picked-up part in a common coordinate system system of surgical instrument and organ.

Another supplementary features of the present invention have provided a kind of method, be used for carrying out an individual Medicine and Surgery operation in the radiopharmaceutical picked-up part of a patient's body organ, the step that this method comprises has: a radioactive emission detector (a) is provided, link to each other with the primary importance tracking system and/or communicate with, follow the tracks of the position of radiopharmaceutical picked-up part in first coordinate system of organ.(b) provide a kind of surgical instrument, link to each other with second position tracking system and/or communicate with, in carrying out inside and outside section operation process, follow the tracks of the position of surgical instrument in second coordinate system; (c) from above-mentioned primary importance tracking system, radioactive emission detector and second position tracking system, receive the data input, and in carrying out inside and outside section operation process, calculate the position of radiopharmaceutical picked-up part in a common coordinate system system of surgical instrument and organ.

Further feature according to the preferred embodiments of the invention that describe below, second coordinate system is united as common coordinate system, therefore, the position of radioactive radiation ingestion of medicines part in first coordinate system with organ projects in second coordinate system.

According to the further feature of described preferred embodiment, first coordinate system as common coordinate system system, therefore, is projected to the position of radioactive radiation ingestion of medicines part in second coordinate system of organ in first coordinate system.

According to the further feature of described preferred embodiment, second coordinate system, first coordinate system and common coordinate system system are independent coordinate systems.

Further feature according to described preferred embodiment, first coordinate system, second coordinate system and common coordinate system system be an independently coordinate system, so surgical instrument in second coordinate system the position and the position of radiopharmaceutical picked-up part in first coordinate system of organ all be projected on the common coordinate system system.

According to the further feature of described preferred embodiment, primary importance tracking system and second position tracking system are independent positioning control systems.

According to the further feature of described preferred embodiment, image display is used for the visually collaborative position that shows the radiopharmaceutical picked-up part of surgical instrument and organ.

Further feature according to described preferred embodiment, radioactive emission detector is from comprising a low-angle radioactive emission detector, wide angle radioactive emission detector, a plurality of independent low-angle radioactive emission detector and the radioactivity seeker of a space sensitive, as what select in the gammacamera that adopts in the nuclear imaging.

Further feature according to described preferred embodiment, first and second positioning control systems can comprise, but be not limited to, joint arm positioning control system, positioning control system based on accelerometer, one are based on potentiometric positioning control system, a positioning control system based on sound wave, a positioning control system based on radio frequency, a positioning control system and the combination based on the positioning control system of optics (as optical encoder) based on magnetic field.

Further feature according to described preferred embodiment, surgery instrument can comprise, but be not limited to the combination of laser probe, cardiac catheter, cardiovascular plastic catheter, splanchnoscopy probe, biopsy needle, ultrasound probe, optical fiber scope, suction tube, laparoscopy probe, temperature probe and suction probe.

According to the further feature of described preferred embodiment, radiopharmaceutical agent can include, but are not limited to, ¹³¹I, ⁶⁷Ga (can use gallium citrate), ^99MTc contain methoxyl group the isobutyl group isonitrile, ²⁰¹TICI, ¹⁸The fluorine-based deoxyglucose of F-, ¹²⁵The I-Fibrinogen and ¹¹¹In-octreotide or the like.

According to the further feature of described preferred embodiment, two dimension or three-dimensional imaging instrument link to each other with one the 3rd positioning control system and/or communicate with, and are used for calculating the position of an organ in a system of 3 axes.

Further feature according to described preferred embodiment, receive the data input from two dimension or three-dimensional imaging instrument and the 3rd positioning control system, be used for calculating the radiopharmaceutical picked-up part of surgical instrument, organ and organ position at a common coordinate system system.

According to the further feature of described preferred embodiment, primary importance tracking system, second position tracking system and the 3rd positioning control system are independent positioning control systems.

According to the further feature of described preferred embodiment, the position of the radiopharmaceutical of surgical instrument, organ picked-up part and organ utilizes a visible display device to work in coordination with demonstration.

According to the further feature of described preferred embodiment, first, second and the 3rd positioning control system all be independently from a joint arm positioning control system, positioning control system, one based on accelerometer based on potentiometric positioning control system, positioning control system, positioning control system based on radio frequency based on sound wave, one based on selecting the positioning control system in magnetic field and the positioning control system based on optics (as optical encoder).

Further feature according to described preferred embodiment, second coordinate system is as public coordinate system, and position and organ the position in system of 3 axes of radiopharmaceutical picked-up part in first coordinate system with organ projects in this second coordinate system thus.

Further feature according to described preferred embodiment, first coordinate system projects to position and organ the position in system of 3 axes of surgical instrument in second coordinate system in this first coordinate system thus as public coordinate system.

Further feature according to described preferred embodiment, system of 3 axes is as public coordinate system, thus position and the organ of surgical instrument in second coordinate system absorbed the position of radiopharmaceutic part in first coordinate system and projects in this system of 3 axes.

According to the further feature of described preferred embodiment, unify common coordinate system system of second coordinate system, first coordinate system, three-coordinate is an independent coordinate system.

Further feature according to described preferred embodiment, second coordinate system, first coordinate system and common coordinate system system are an independently coordinate system, therefore the position of surgical instrument in second coordinate system, position and organ the position in three coordinate system of radiopharmaceutical picked-up part in first coordinate system of organ all are projected on the common coordinate system system.

According to another feature of the present invention, a system is provided, be used for producing the two dimension or the 3-D view of the radioactive radiation source of health, this system comprises (a) radioactive emission detector; (b) positioning control system that links to each other and/or communicate with radioactive emission detector; (c) data processor, design and configuration are used for receiving the data input from positioning control system and radioactive emission detector, produce the two dimension or the 3-D view of radioactive radiation source.

According to another feature of the present invention, a kind of method is provided, be used for producing the two dimension or the 3-D view of the radioactive radiation source of health, the step that this method comprises has: (a) utilize a radioactive emission detector that health is scanned; (b) utilize a positioning control system that links to each other with radioactive emission detector and/or communicate with to come piece to decide the position of radioactive emission detector in a two dimension or three-dimensional coordinate system; (c) date processing is carried out in the input from positioning control system and radioactive emission detector, produce the two dimension or the 3-D view of radioactive radiation source.

According to another feature of the present invention, a system is provided, carry out an individual Medicine and Surgery operation in the radiopharmaceutical picked-up part of a patient's body organ, this system comprises a surgical instrument, link to each other with a positioning control system and/or communicate with, be used for following the tracks of the position of surgery instrument in a coordinate system, surgery instrument comprises a coupled radioactive emission detector, is used for monitoring on the spot radiopharmaceutical.Radioactive emission detector is preferably to β ray and/or positron radiation-sensitive.Also can be to low-yield (10-30KeV) or gamma-rays sensitivity.Surgical instrument preferably includes a device for cutting tissue and/or a tissues sampled device, as aspirator.

According to an additional features of the present invention, a system is provided, be used for calculating the position of a radioactive radiation source at a coordinate system, this system comprises that (a) one design and structure are used for entering the surgical instrument of patient body, this surgery instrument comprise one coupled or be integrated in wherein radioactive emission detector; (b) positioning control system links to each other with surgical instrument or communicates with; (c) data processor, design and configuration are used for receiving the data input from positioning control system with from radioactive emission detector, calculate the position of radioactive radiation source in coordinate system.

According to another feature of the present invention, a system is provided, be used for calculating the position of a radioactive radiation source at one first coordinate system, and it is projected in one second coordinate system, this system comprises that (a) one design and structure are used for entering the surgical instrument of patient body, this surgery instrument comprise one coupled or be integrated in wherein radioactive emission detector; (b) positioning control system links to each other with surgical instrument or communicates with; (c) data processor, design and configuration are used for (i) from positioning control system and reception data input from radioactive emission detector; (ii) calculate the position of radioactive radiation source in first coordinate system; (iii) calculate surgical instrument in first coordinate system the position and (iv) the position of radioactive radiation source and surgical instrument is projected in second coordinate system.

According to another feature of the present invention, a kind of method is provided, be used for calculating the position of a radioactive radiation source at one first coordinate system, and it is projected in one second coordinate system, the step that this method comprises has: (a) provide a design and structure to be used for entering the surgical instrument of patient body, this surgery instrument comprise one coupled or be integrated in wherein radioactive emission detector, this surgical instrument links to each other with a positioning control system or communicates with; (b) monitor the radioactivity of from radioactive radiation source, sending, monitor the position of radioactive emission detector in first coordinate system simultaneously, determine radioactive radiation source and the position of surgical instrument in first coordinate system thus, and the position of radioactive radiation source is projected to second coordinate system.

According to another feature of the present invention, a system is provided, be used to calculate the position of patient's body organ and the radiopharmaceutical picked-up position partly of organ, this system comprises (a) two dimension or three-dimensional imaging instrument, link to each other with a primary importance tracking system and/or communicate with, and calculate the position of human organ in one first coordinate system; (b) one is designed and makes up the surgical instrument that is used for entering patient body, this surgical instrument comprise one coupled or be integrated in wherein radioactive emission detector, surgical instrument links to each other with a second position tracking system and/or communicates with, and follows the tracks of the position of radiopharmaceutical picked-up part in one second coordinate system of human organ; (c) at least one data processor, design and configuration are used for receiving the data input from three-dimensional imaging instrument, primary importance tracking system, radioactive emission detector and second position tracking system, and calculate the radiopharmaceutical picked-up part and the position of surgical instrument in a common coordinate system system of human organ, human organ.

According to another feature of the present invention, a kind of method is provided, be used to calculate the position of patient's body organ and the radiopharmaceutical picked-up position partly of organ, the step that this method comprises has (a) that a two dimension or three-dimensional imaging instrument are provided, link to each other with a primary importance tracking system and/or communicate with, and calculate the position of human organ in one first coordinate system; (b) provide a design and structure to be used for entering the surgical instrument of patient body, this surgical instrument comprise one coupled or be integrated in wherein radioactive emission detector, surgical instrument links to each other with a second position tracking system and/or communicates with, and follows the tracks of the position of radiopharmaceutical picked-up part in one second coordinate system of human organ; (c) from two dimension or three-dimensional imaging instrument, primary importance tracking system, radioactive emission detector and second position tracking system, receive the data input, and calculate the radiopharmaceutical picked-up part and the position of surgical instrument in a common coordinate system system of human organ, human organ.

The present invention is the generation for the one dimension that improves and describe in detail radioactive radiation source, two dimension or 3-D view.Particularly, the present invention attempts to provide a kind of improved method and system, is used to carry out imaging and to intravital target area boot diagnostic of patient and therapeutic equipments, particularly utilizes a nuclear radiation detector with positioning control system.

In one aspect of the invention, a radiation probe is installed in a collimator, and is connected to a positioning control system.When probe when a two dimension or three dimensions move around checked patient, image data is also drawn the image of the radiation mode of sending in patient's body.An advantage of two dimension or 3-D scanning is to carry out better radiation source location by the direction search of a larger amt, realizes better safety and accuracy.

The present invention can draw near the figure of the regional and uncertain region of radiation source.A kind of implementation method is to utilize the feedback system of statistical analysis to determine the border of a uncertain region, instructs the medical worker to carry out additional scanning in these uncertain zones, improves precision, reduces error, makes the border minimum of uncertain region thus.

The present invention by provide one itself and/or be integrated into radioactive emission detector in the surgical instrument that links to each other with a positioning control system or communicate with, and use it in the system and method for multiple medical imaging and/or medical procedures, successfully overcome the shortcoming of existing configuration.

The present invention has many other purposes in therapeutic scope, for example still be not limited to: the cryotherapy and the location radiation excision of implanting short distance seed source, ultrasonic-microwave radio frequency.

Realize that method and system of the present invention comprises manually or automatically or both are in conjunction with carrying out or finishing selected task and step.In addition, the instrument and equipment of the preferred embodiment of the method according to this invention and system, selected step can or run on software in the system of any firmware or it makes up and realizes by hardware.For example, as hardware, the selected step of the present invention may be embodied as chip circuit.As software, the selected step of the present invention may be embodied as a plurality of software instructions of being carried out by the computer that uses appropriate algorithm.In either case, the selected step of method and system of the present invention can be described to the data processor such as the computing platform of carrying out a plurality of instructions.

Description of drawings

Here, present invention is described with reference to accompanying drawing only to utilize example.Now particularly in detail with reference to the accompanying drawings, for the preferred embodiments of the invention are described, confirm which content is the most useful and more easily understands principle of the present invention and notion, has shown details of the present invention by means of example among the figure.In this, except the present invention being had the required content of basic understanding, structural details of the present invention is not done more detailed demonstration, the description that utilizes accompanying drawing to do can make those those skilled in the art recognize and realize several form of the present invention how in practice.

In the accompanying drawing:

Fig. 1 is " black surround " figure according to the system of the present invention's explanation;

Fig. 2 is an articulated arm perspective view as a positioning control system that supports shown radioactive emission detector according to the present invention's explanation;

Fig. 3 simplified schematic illustration a radioactive emission detector according to the present invention explanation, support a pair of three axisymmetric accelerometers, as a positioning control system.

Fig. 4 summary has been represented a radioactive emission detector of communicating by letter with the positioning control system of another type according to the present invention's explanation;

Fig. 5 is used for realizing the narrow angle of one embodiment of the invention or the simplification sectional view of wide-angle radioactive emission detector;

Fig. 6 has shown a scan protocols can using the detector among Fig. 5 to realize;

Fig. 7 is the simplification sectional view such as the radioactive emission detector of gamma camera that is used to realize another embodiment of the present invention of a space sensitive;

Fig. 8 has shown a scan protocols can using the detector among Fig. 7 to realize;

What Fig. 9 showed is a system according to the present invention's explanation, uses four positioning control systems to work in coordination with the position of following the tracks of a patient, a radioactive emission detector, an Image-forming instrument and a surgery instrument;

Figure 10 shown according to a pair of adapter that passes through of the present invention, and preferably flexible connector or one are connected to the use of the radioactive emission detector that the flexible linking device of adapter links to each other;

Figure 11 is according to a surgery instrument of the present invention's explanation and the sketch map of incidental system element;

Figure 12 is according to the simplicity of illustration explanation of an imaging system of preferred embodiment structure of the present invention and operation, comprises a radiation detector and position sensor, positioning control system, medical image system and coordinate readings system;

Figure 13 is the process that is connected to the nuclear radiation probe formation one dimension image of the positioning control system among Figure 12 of utilizing according to a preferred embodiment of the present invention;

Figure 14 is the simplification curve of the detection a radiation point source carried out according to the nuclear radiation detector that utilizes system among Figure 12 of a preferred embodiment of the present invention, and this curve is not further processed;

Figure 15 is an average algorithm flow chart according to the imaging system that is used for Figure 12 of a preferred embodiment of the present invention;

Figure 16 be the detection a radiation point source carried out according to the nuclear radiation probe that utilizes system among Figure 12 of a preferred embodiment of the present invention carrying out the simplification curve of average treatment;

Figure 17 and 18 is respectively hot cross and the hot bar shaped fault image sketch by the image of the gamma-ray probe generation of system among Figure 12;

Figure 19 is a minimization algorithm flow chart according to the imaging system that is used for Figure 12 of a preferred embodiment of the present invention;

Figure 20 be the detection a radiation point source carried out according to the nuclear radiation probe that utilizes system among Figure 12 of a preferred embodiment of the present invention carrying out the simplification curve of minimization;

Figure 21 is that this system produces the combination image by the position and the therapeutic equipments position of medical image, greatest irradiation point according to the simplicity of illustration explanation of an image reconstruction system of preferred embodiment structure of the present invention and operation;

Figure 22 is according to the simplified flow chart of the radiation diagram restructing algorithm of a preferred embodiment of the present invention;

Figure 23 A and 23B represent respectively is the figure of the radiolabel of observed autonomous thyroid tumor in by system of the present invention and the image that produced by the gammacamera of routine;

Figure 24 A and 24B represent respectively is the observed figure that is considered to the radiolabel of humerus Paget's disease in by system of the present invention and the image that produced by the gammacamera of routine;

Figure 25 A and 25B represent respectively is the figure of the radiolabel of observed chronic osteomyelitis in by system of the present invention and the image that produced by the gammacamera of routine; With

Figure 26 A and 26B represent respectively is the figure of the radiolabel of the observed skeleton metastasis (metastases) that produces from the neurocele glucagonoma in by system of the present invention and the image that produced by the gammacamera of routine;

What Figure 27 A-G illustrated is the operation that is used for the algorithm that the estimation radiation source distributes in a controlling value by provided by the invention.

Preferred embodiment

Of the present invention what relate to is a kind of radioactive emission detector, is furnished with a positioning control system, on function with two dimension or 3 D medical Image-forming instrument and/or enter with minimum or other Surigical tool integrate.With regard to the position of the imaging moiety of human body, the present invention can be used for calculating a concentrated radiopharmaceutical in the position of human body, for example, can carry out one effectively and the surgical operation that enters of the minimum of pinpoint accuracy with this information.

With reference to the accompanying drawings with relevant description, principle that the present invention may be better understood and work process.

Before in detail explaining at least one embodiment of the present invention, should be understood that application of the present invention be not limited to describe below or accompanying drawing shown in unit architecture and the details of configuration.The present invention can be used for other embodiment or implement in many ways or realization.And, should be understood that word that is adopted and term adopt for present invention is described here, and should not be construed as a kind of restriction.

Before at least four ten years, in medical literature by the agency of in the use radioactive substance labelling patient body the active tissue of pathology is arranged, determine the position of this tissue and the method for division by radioactive emission detector.From that time, obtained significant development for the technology of diagnosing and treatment positions and divides the tissue with labelled with radioisotope.In fact, in certain disease, as the diagnosis of cancer, blood clotting, myoclonic status and abscess/or treatment in, this method is becoming a kind of generally acknowledged way, input monoclonal antibody or other medicament in patient body, as with labelled with radioisotope (as ^99MTechnetium, ⁶⁷Gallium, ²⁰¹Thallium, ¹¹¹Indium, ¹²³Iodine, ¹⁸Fluorine and ¹²⁵Iodine) fibrinogen, fluorine-based deoxyglucose.This radiopharmaceutical agent helps to locate in specific tissue and cell type, and on pathology, increase specific radiopharmaceutic picked-up or combination in the active tissue such as the row center of living of cancerous tissue, like this, can detect the ray that following isotopic nuclear disintegration is emitted by a ray detector, with the active part of positioning tumor better.For example, this ray can be α, β-, β+and/or gamma-rays.

In the application of another form, can detect the blood flow grade in the blood vessel and flow into the grade of a tissue with radioactive substance, as coronary blood flow and the amount that enters cardiac muscle.

With reference now to accompanying drawing,, Fig. 1 has illustrated according to system of the present invention, is used for calculating the system of a radioactive radiation source in the position of a coordinate system, below this system is called system 20.

System 20 comprises a radioactive emission detector 22.Further comprise a positioning control system 24 according to system 20 of the present invention.System 24 links to each other with radioactive emission detector 22 and communication with it, so that with 2,3 or bigger, and the degree of freedom (x such as 4 or preferably 6, y, z, ρ, θ and φ) come monitoring detector 22 by two dimension of a coordinate system 28 definition or the position in the three dimensions.System 20 further comprises a data processor 26.As will be described in detail below, data processor 26 is designed and disposes to be used for the input of receiving position tracking system 24 and radioactivity seeker 22, calculates the position of radioactive radiation source in coordinate system 28.Here, term " coordinate system " and " three dimensions " can be used alternatingly.As shown in Figure 10, a pair of (or more) detector 22 that links to each other by a physical connector, its position is all tracked can be used to calculate the position of radioactive radiation source in coordinate system 28.If used more than one detector 22, then detector 22 preferably interconnects by an adapter 29.Adapter 29 is preferably flexible.Perhaps, by the motility that provides required that is connected between detector 22 and the adapter 29.

In this technology, positioning control system itself is well-known, can use a kind of in the several different methods, comes with 2,3, maximum can reach 6 degree of freedom and determine a two dimension or a three-dimensional position by a coordinate system definition.The variation that some positioning control system adopts movably physical connection and suitable mobile monitoring device (as potentiometer) to come tracing positional.Like this, this system gets final product the variation of tracing positional after detecting, and determines physical location thus at any time.An example of this positioning control system is soft joint arm.

Fig. 2 has shown a soft joint arm 30, comprises 6 spiral arm parts 32 and a support 34, therefore can provide position data with 6 degree of freedom.Can carry out the monitoring of change in location in one or more modes.For example, for each spiral arm 32 provides potentiometer or optical encoder 38, be used for monitoring the angle between the adjacent spiral arm 32, the angle of monitoring thus between each such spiral arm and the adjacent spiral arm changes, and comes the locus of the radioactive emission detector 22 of definite and soft joint arm 30 physical connections.

As shown in Figure 3, other positioning control system can be directly connected to radioactive emission detector 22, so that monitor its locus.An example of this positioning control system is three three (as orthogonal) directed accelerometers 36 of a class, can be used for monitoring the change in location of radioactive radiation source 22 in a space.As shown in Figure 3, can determine the position of detector 22 with a pair of such instrument with 6 degree of freedom.

As shown in Fig. 4 and 10, no matter the position that the front is determined how, other positioning control system redefines a position, the variation that comes tracing positional.Usually, the receiver/transmitter 40 that this system adopts one group of known location in a three dimensions to distribute, and the emitter/receiver 42 that links to each other with the physics of the object of monitored position respectively.In this case, adopting time-based triangulation and/or phase shift triangulation, come periodically to determine the position of monitored target, is the position of radioactivity seeker 22 in this example.For example, the comprehensive United States Patent (USP) 5,412,619 of reference here; 6,083,170; 6,063,022; 5,954,665; 5,840,025; 5,718,241; 5,713,946; 5,694,945; 5,568,809; 5,546,951; Introduced the example of a positioning control system under the multiple occasion of using acoustics (as ultrasound wave) electromagnetic radiation (as infrared ray, radio frequency) or magnetic field and optical encoding, adopting in 5,480,422 and 5,391,199.

Radioactive emission detector is well-known in the art, can use a kind of of some kinds of method kinds, determines the radioactive radiation amount of the part of an object or this object.According to the type of ray, such detector generally includes such material, when particle interaction that radioactive decay sends, this material in a wide linear range of operation to be proportional to the energy level emission electron or the photon of radiation collision energy level.Measurable during the emission of electronics or photon, therefore, be used for quantitatively determining radiation level.For example, (Pixellated) of pixelation or N type, P type, the PIN type solid probe of (unpixellated) of pixelation do not comprise Ge, Si, CdTe, CdZnTe, CdSe, CdZnSe, HgI ₂, TiBrI, GaAs, InI, GaSe, diamond, TlBr, PbI ₂, InP, ZnTe, HgBrI, a-Si, a-Se, BP, GaP, CdS, SiC, AlSb, PbO, BiI ₃With the ZnSe detector.Gas is (as CO ₂CH ₄) detector of filling comprises the ionization chamber detector, proportional coumter detector and Geiger counter tube detector.Scintillation detector comprises organic scintillator crystals and liquid, as C ₁₄H ₁₀, C ₁₄H ₁₂, C ₁₀H ₈Or the like.Plastics NE102A, NE104, NE110, Pilot U and inorganic scintillator are as NaI, CsI, BGO, LSO, YSO, BaF, ZnS, ZnOCaWo ₄And CdWO ₄Known scintillating fiber detector in addition.The scintillator coupling comprises the photomultiplier tube (PMT) of following type: profile form, front type, hemispherical, location-sensitive, icrochannel disc type photomultiplier tube (MCT-PMT) and electronics photomultiplier tube or photodiode (and photodiode array), and as Si photodiode, Si PIN photodiode, Si APD, GaAs (P) photodiode, GaP and CCD.

Fig. 5 has shown a narrow angle or wide angle radioactive emission detector 22 '.Narrow angle or wide angle radioactive emission detector 22 ' comprise a narrow slot (collimator), and (as wide angle: the 1-280 degree, preferably narrow angle: the 1-80 degree) ray ray of Dao Daing enters detector from a predetermined angle direction so that only allow.For example, the narrow angle or the wide angle radiation detector that are particularly suitable for the configuration among Figure 10 are by Neoprobe, Dublin, Ohio (www.neoprobe.com), USA, Nuclear Fields, USA (www.nufi.com), IntraMedical Imaging, Los Angeles, CA, USA (www.gammaprobe.com) makes.

As shown in Figure 6, a such detector is commonly used to by carrying out radioactive point-to-point measurement from the surface of a plurality of directions and range sweep radioactivity object.In the example shown in the figure, adopted from the scanning of four different directions.Should recognize, if collect enough radiation counters from different angle and distances, and in such scanning, monitor and write down the locus and the direction of detector 22 ' simultaneously, threedimensional model that so can an active area of reconstruct, and determine its locus.Adopt two or more detectors if unite,, then can collect the result quickly as the configuration that shows among Figure 10.

What Fig. 7 showed is the example of another radioactivity seeker, and promptly a space sensitive (pixelation) radioactive emission detector 22 " (as a gammacamera).In fact, detector 22 " comprise the array of many narrow angle detecting units 23.According to the present invention, adopt the amount that a such configuration reduces to measure and obtain enough data so that the required angle of the threedimensional model of reconstruct radial objects.For example, the United States Patent (USP) 4,019,057 of reference here; 4,550,250; 4,831,262; With 5,521, introduced the example of the sensitive radioactivity seeker in space that adopts under the multiple situation in 373.An additional example is that (http://www.ucl.ac.uk/Medphys/posters/giulia/giulia.htm) surveyed in the Compton.Fig. 8 has shown that another is by the sensitive radioactivity seeker 22 in space " (as gammacamera) scanning of carrying out.

Being used for a radioactive emission detector that has superiority especially of the present invention is the Compton gamma detector, because in the gamma detector of Compton, spatial resolution and sensitivity are irrelevant, obviously can surpass the noise equivalent sensitivity of directed imaging system, obtain the system of high spatial resolution.The Compton probe is a kind of novel gamma detector, and it utilizes the Compton scattering campaign to make up a source images, and need not by means of the mechanical collimation device.The Compton telescope is built in the seventies in 20th century first, is used for astronomical observation [people such as V.Schoenfelder, Astrophysical Journal 217 (1977) 306].Initial medical imaging Laboratory Instruments proposes [M.Singh, Med.Phys.10 (1983) 421] in the eighties in 20th century.The potential advantages of Compton gamma ray probe comprise that efficient is higher, need not that moving of detector can be carried out three-dimensional imaging and system is compact and light more.In the gamma ray probe of Compton, high energy gamma enters one second detector layer array from one first detector layer (or detector array) scattering.In two detectors, each gamma-rays energy stored is measured.Utilize the circuit that draws between two detectors, can find the solution the Compton scattering equation, to determine the possible direction of cone about this axis, gamma-rays must enter first detector with this direction.Obtain the intersection point of cone then according to a plurality of incidents, in the visible range of detector, to locate γYuan.Obviously, only consider the incident of coincideing, determine its energy more accurately, reduce to arrive the uncertainty of the space angle of cone.The electrical system of probe will combine with the detector layer with good energy resolution to the qualified measurement result that a plurality of detectors carry out.Play important effect in the imaging performance of the system that is chosen in of the geometry of ground floor detector and material, and depend on the material efficiency of the single Compton incident that (i) compares with other interaction; (ii) detector energy resolution; (iii) detector position resolution.Particularly, two total angular resolutions that unit construction produced, relevant with the pixel volume of energy resolution and detector.

Like this, introduce, a radioactive emission detector is connected on the positioning control system, can carry out the prompt radiation detection, and carry out the position simultaneously and follow the tracks of as the present invention.Like this, can accurately calculate shape, size and the profile of radiation object, and a three-dimensional exact position.

Therefore, the invention provides a kind of method, be used for determining the position of radioactive radiation source in a coordinate system.This method is that (a) that implement through the following steps provides a radioactive emission detector that is connected to a positioning control system and communicates by letter with it; (b) monitor the radiation of sending from radiation source, simultaneously, the position of monitoring radioactive emission detector in coordinate system determined the position of radioactive radiation source in coordinate system thus.

One of ordinary skill in the art would recognize that, should can project to by model that system 20 produces on any other coordinate system, perhaps, the coordinate system that other positioning control system can be shared be determined by positioning control system 24, as following further detailed description, need not carry out projection like this.

Like this, as showing further among Fig. 1 that system 20 of the present invention can be used for calculating the position of radioactive radiation source at one first coordinate system 28, and further it is projected on one second coordinate system 28 '.This system comprises radioactive emission detector 22, is connected to the positioning control system 24 and the data processor 26 of radioactive emission detector 22 and communication with it, and design and configuration are used for (i) from positioning control system 24 and radioactive emission detector 22 reception data inputs; (ii) calculate the position of radioactive emission detector in first coordinate system; (iii) the position with radioactive emission detector projects on second coordinate system.

The present invention also provides a kind of and has been used for calculating radioactive emission detector and projects to one second method in the coordinate system in the position of one first coordinate system and with it.This method is that (a) that implement through the following steps provides a radioactive emission detector that is connected to a positioning control system or communicates by letter with it; (b) monitor the radiation of sending from radiation source, simultaneously, the position of monitoring radioactive emission detector in first coordinate system determined the position of radioactive radiation source in first coordinate system thus, and it is projected on second coordinate system.

Should recognize that radioactive emission detector and one the combination coupled and/or positioning control system that communicates with can make a suitable data processor produce the two dimension or the 3-D view of radioactive radiation source.Can adopt an algorithm to come computed image intensity, for example, based on the probability function of an average radiation counting and generation piece image, wherein the interval of radiation counter is more little, image is bright more, and vice versa, and compensates downwards when a position is rescaned.For this reason, can adopt the detector of an orientation to carry out a free-hand scanning.

In one embodiment, when utilizing human region of detector scanning, detector is moved along a definite body curve and the three-dimensional surface of in fact following the tracks of pointer as position.Can utilize this information to determine the position of radioactive radiation source, so that produce the three-dimensional drawing of radiation source and body curve with respect to people's external surface.Also can be an open surgical procedures, as taking this method in the open thoracic surgery, so that the information of relevant function of organization is provided in real time for surgical operation.

Can be used for radioactive emission detector of the present invention and can be a βShe Xiantanceqi, gamma ray detector, positron detector or it makes up arbitrarily.Can adopt one to β radiation (and/or positron) and the sensitive detector of gamma-rays, for example,, improve the location by detecting gamma-rays apart from the distance in source and scan β or positron ray near radioactive source.A beta rediation detector is exclusively used in and detects the electronics that comes from radioactive source, as ¹³¹Iodine, or positron, as ¹⁸Fluorine.A gamma detector can be designed as a single energy detector, perhaps is designed to one and can utilizes light intensity in the flasher as the metric relatively detector of distinguishing dissimilar energy of gamma energy.And this detector can be designed as the detection by using (180 degree) that face with each other, meeting as the detector utilization of organ or tissue therebetween.Radioactivity seeker can have the different collimators of different-diameter.The collimator of macropore is used for obtaining low resolution high strength, and the collimator of aperture has high-resolution, but can reduce intensity.

Another kind of probability is to adopt a collimator that moves or rotate with eccentric orfice, so that make incident photon be a different solid angle at any time, collects photon from eclipsed volume like this under different intervals.If probe moves or the eccentric orfice of collimator moves, the remainder of imaging processing is similar.

System 20 of the present invention can together use with other armarium, for example, but is not limited to any one in multiple Image-forming instrument and/or the surgical instrument.

In the art, Image-forming instrument is well-known, is used for two dimension (projection or cross section) or three-dimensional (cosequtive cross section) imaging main instruments has fluoroscope, computerized tomographic scanner, NMR (Nuclear Magnetic Resonance)-imaging device, ultrasonic imaging device and photographic camera.

Usually in the crown direction of medical image (i) that obtains and show human body on three orientation: for example passing on the cross section (plane) of shoulder, for example, two halves before and after cross-section shoulder is divided into human body; (ii) sagittal direction: the downward cross section (plane) from the centre for example is divided into left and right sides two halves with human body; (iii) axial: the cross section (plane) of vertical and people's long axis of body, two halves about human body is divided into.Also can obtain and show the view of inclination.

Polytype x-ray imaging is the key of the polytype cancer of diagnosis.Conventional x-ray imaging has developed more than 100 year, but ultimate principle is still identical when 1895 introduce first.A tuning x-ray source, and launch this X ray and pass the human body paid close attention to below being positioned at human body or on the cassette of back.The energy of X ray and wavelength allow it to pass the image of the internal structure of human body and generation such as bone.For example when X ray passes palm, be subjected to the decay of the tissue of its different densities that runs into.Because it is the density of bone is big, therefore big to the decay that X ray causes than the soft tissue around it.The difference on these absorb just and the variation of the corresponding levels of exposure of film have produced image.In fact, when X ray passed human body, X ray produced the projection by the comprehensive density of the three-dimensional pixel of its column of determining.

Fluoroscopy is a kind of method based on the principle that is used for detecting the unusual film X ray of upper gastrointestinal (GI) system (as the harmonization of the stomach intestinal tube).The fluoroscopy imaging produces a mobile X ray picture.The doctor can view screen, sees the piece image (as dancing heart) of patient body.Utilize additional television camera and fluoroscopy " image intensifier ", the fluoroscopy technology is greatly improved.Today, the x-ray system of many routines has the ability of switching between X-ray radiography and photofulorography pattern.Up-to-date x-ray system has the numeral utilized and surveys the ability of obtaining radioscopic image and fluoroscopic image.

Computer topography art (CT) is based on the principle of X ray, and wherein the detector with measured X ray profile substitutes film.Be the support of a rotation in the cover of CT scanner, a side is equipped with an X-ray tube, and opposite side is installed a detector.When runing rest centers on patient's rotational x-ray pipe and detector, produce a fan-shaped x-ray beam.X-ray tube and detector whenever revolve three-sixth turn, just obtain piece image or " section ".Utilize the lead system chopper of X-ray tube and X-ray detector front end, the thickness of this " section " is collimated between 1mm and the 10mm.

When X-ray tube and detector carried out 360 degree rotations, detector obtained a plurality of profiles of the X-ray beam of decay.Usually, in one 360 degree one encloses, 1,000 profile of can sampling.By detector each profile is spatially divided, and sent in about 700 autonomous channels.Then, utilizing special-purpose computer is a two dimensional image that is scanned " section " with the reverse reconstruct of each profile (or " back projection ").

CT gantry and table top have a plurality of microprocessors, and the moving of rotation, the table top of control gantry (on/down, advance/go out), inclination gantry are with the image that obtains to tilt and other function, such as the switch X-ray beam.CT comprises a slip ring, allows to transmit electric energy from regulated power supply to continuous rotating gantry.The innovation that electric slip ring is carried out has produced a kind of novel CT that is called helical scanning.Now, these screw types scanning instrument can be at tissue regions such as fast imaging during the ceasing breathing of 20-30 second such as pulmonarys.Screw type CT be not obtain one group may be because of the slight individual slices that move or breathe (and pulmonary/abdominal part move) offset direction of patient during section collecting, but when patient's body is organized fully on a position, obtain a batch data.Then, can carry out computer reconstruction, provide one such as the renal artery of complexity or the threedimensional model of aorta vessel to this batch data.Spiral CT can obtain to be particularly suitable for the CT data of three-dimensionalreconstruction.

MR is imaged on the soft tissue lesions of detection such as tumor and is better than CT, because it has excellent contrast resolution, it can show especially clearly that trickle soft tissue changes the surface.Like this, MR is diagnosing tumour of selecting usually and the method for searching for metastasis (metastases).MR utilizes magnetic energy and radio wave to produce single or lasting cross-sectional image or " section " of human body.The critical piece of most of MR system is large-scale tubulose or cylindrical magnets.In addition, the MR system that has the non-closed design of C type magnet or other type in addition.The magnetic field intensity of MR system is measured with metric unit " tesla ".Most of cylindrical magnets have the magnetic field intensity of 0.5-1.5 tesla, and most of non-closure or C type magnet have the magnetic field intensity of 0.01-0.35 tesla.

Inside in the MR system produces a magnetic field.Each MR monitoring generally includes 2-6 series of programs.One " MR program " is to obtain to produce one specific image direction and the picture appearance of a particular type or the data of " contrast ".During checking, open or close a radio signal, the result is, in the health outside the energy reflection ex vivo of different Atomic Absorption.These reflections are by " gradient coil " continuous measurement, and gradient coil is measured the MR signaling reflex by opening and closing.In rotary coordinate system, the net magnetization vector turns over the distance that the time span of and radio-frequency pulse is directly proportional from lengthwise position.After certain time, the net magnetization vector turns over 90 degree, is positioned on horizontal or the x-y plane.Can be in the net magnetisation on this position probing MRI.The angle that the net magnetization vector turns over is commonly called " upset " or " inclination " angle.Be greater than or less than 90 degree places in this angle, will on the x-y plane, still have a little magnetization component, therefore can detect.Radio-frequency coil is MRI system " antenna ", can propagate RF and/or receive inverse signal to the patient.When main coil was used as a transmitter, the RF coil can only be used for receiving; Also can be used to transmit and receive (transceiver).Surface coils is the simplest coil.Be circular or orthogonal simple wire ring, be positioned on the zone of being paid close attention to.

A digital computer is reconstructed into these reflections the image of one width of cloth human body.The advantage of MRI be it can be at an easy rate from any direction observation human body, and CT scanner can only obtain usually perpendicular to or approximately perpendicular to the sectional view of human body.

Ultrasonic imaging is a kind of multiduty scanning technique, utilizes sound wave to produce the image of organ or organizational structure, diagnoses.Ultrasound process is included near the patient skin interest region, on the skin as kidney, places a midget plant that is called pick off.Group of ultrasonic sensors has been closed the function that transmits and receives sound.This pick off produces penetrable human body and organic reflex's inaudible high frequency sound wave internally.When sound wave when the profile of structure or organ reflects internally, this sound wave of sensor.Different tissues is to the reflection difference of sound wave, and the signal of piece image can be measured and be converted to generation.These sound waves are to be converted to live image by the ultrasonic instrument reception and by computer and reconstruction software.

Ultrasonic scanning has many purposes, comprising: the diagnosis that disease and organizational structure are unusual, the auxiliary diagnostic procedure that carries out other is as aspiration biopsy etc.

Some ultrasonic technology has some restrictions: be not under any circumstance can both obtain preferable image, scanning may not can produce the same accurate result with other diagnosing image process.In addition, scanning result may be subjected to the influence that physical abnormalities, chronic disease, excessive mobile or incorrect pick off are placed.

Now, can utilize the ultrasound imaging techniques of two dimension (cross section) and three-dimensional (consequtive cross section).What deserves to be mentioned is Doppler's three-dimensional ultrasonic imaging.

In many cases, Image-forming instrument itself comprises that (as fluorescence imaging, CT MRI) and/or be integrated with positioning control system, can utilize such system to carry out the reconstruct of 3-D view model and a position in three dimensions is provided.

Should recognize, be similar to visual system, also can utilize photographic camera to produce 3 d image data by people's volume imaging of a plurality of (at least two) direction according to the present invention.Such imaging is specially adapted to open thoracic surgery operation or other open surgical procedures.In this technical field, the software that calculates a width of cloth 3-D view according to a pair of space mirror image is well-known.

Like this, as here and used in the claim subsequently, term " three-dimensional imaging instrument " is meant the imaging device of any kind, comprises the software and hardware that produces a width of cloth 3-D view.Such equipment can by successive, produce a width of cloth 3-D view as people's body section imaging of observing from single direction.Perhaps, such equipment can by from different perspectives or direction (being generally two angles) carry out imaging, then data are merged into a width of cloth 3-D view, produce a width of cloth 3-D view.

Surgical instrument in this field also is well-known, can utilize a kind of in the various configurations, carries out the surgical operation that minimum enters.Its example comprises laser probe, heart and angiosarcoma conduit, endoscope probe, biopsy needle, air tube or pin, excision equipment, ultrasound probe, optical fiber scope, laparoscopy probe, temperature probe and suction probe.The comprehensive United States Patent (USP) 6,083,170 of reference here for example; 6,063,022; 5,954,665; 5,840,025; 5,718,241; 5,713,946; 5,694,945; 5,568,809; 5,546,951; 5,480,422; 5,391,199; 5,800,414; 5,843,017; 6,086,554; 5,766,234; 5,868,739; 5,911,719; 5,993,408; 6,007,497; 6,021,341; 6,066,151; 6.071,281; Introduced the example of these surgical instruments that use at multiple medical treatment situation in 6,083,166 and 5,736,738.

For some application, these examples of applications are provided in the above-mentioned patent portfolio, surgery instrument integrates with positioning control system, can monitor the position of these instruments when putting into or lead by the treatment patient's body.

According to a preferred embodiment of the invention, surgery instrument is furnished with an additional radioactive emission detector that is connected or is placed in one with it.According to preferred version of the present invention, this additional detector is applicable to the position of the radioactive radiation of radiation source that send in the fine setting body and close.Because surgical technique and tools preferably is connected to a positioning control system or communication with it, can monitor the position of additional detector, utilize its reading to come the position in fine setting internal radiation source.Like this, according to this feature of the present invention, at least one external detector and one individual in detector determine the position in internal radiation source jointly with pinpoint accuracy.External detector provides the general location in source, is used for the guided surgery instrument, and detector is used for reaffirming to make really with a full accuracy and correctly having aimed at radioactive source before treatment or biopsy in the body.

According to this preferred embodiment of the present invention, used an above-mentioned external and individual interior detector, and for some application, can use detector in the single body, this detector to be connected to or to be integrated in the surgery instrument that its position has been carried out following the tracks of.

Use the isotope that needs careful selective emission medicament to use with external detector in the body.Can utilize the collimator tectosome external detector of suitable processing such as gamma-ray intense radiation, detector itself is very little in the body, in design and the textural restriction that is subjected to employed surgery instrument.Because being used for the gamma-ray collimator of high energy (80-511KeV) itself has strong robustness, be not easy to be used for miniature detector, the characteristics of electronics (β) and positron ray are: (i) when they are in low-yield and high chemical reaction ability, can be absorbed well by biological tissue; (ii) can be easy to utilize thin metal collimating device collimation and focusing.Use mental retardation (10-30KeV) gamma-rays in also can using in vivo, because can utilize Tantalum or Tungsten thin layer to collimate the positive photon of γ.Like this, the selective emission medicine sends γ and β and/or positron ray, monitors high energy gamma, is provided with that detector detects mental retardation γ, β and/or positron ray in the body and external detector is set.The isotope that sends high energy gamma and/or mental retardation γ, β and/or positron ray and itself can be used as the part of compound radiopharmaceutical agent includes, but are not limited to, ¹⁸F, ¹¹¹In and ¹²³The I radioactivity, radiopharmaceutical has, but is not limited to, 2-[ ¹⁸F] the fluoro-2-deoxy-D-glucose ( ¹⁸FDG), ¹¹¹In-Pentetreotide ([ ¹¹¹In-DTPA-D-Phe ¹]-octreotide), L-3-[ ¹²³I]-Iodo-alpha-methyl-tyrosine (IMT), O-(2-[ ¹⁸F] the fluoroethane base)-L-tyrosine (L-[ ¹⁸F] FET), ¹¹¹In-Capromab Pendetide (CYT-356, Prostascint) and ¹¹¹In-SatumomabPendetide (Oncoscint).

Figure 11 has illustrated a system according to this feature of the present invention.Surgical instrument 100 is connected on excision known in the art/attraction control element 102.Surgery instrument 100 comprises a radioactivity seeker 104, has a collimator 106, collimates mental retardation γ, β and/or positron ray.In certain embodiments, shown in arrow 108, detector 104 can translation in instrument 100.Have wherein that the positioning control system of an element 110 that is connected to instrument 100 and another element 112 with fixed position are used for 2,3, the highest 6 the degree of freedom position of monitoring instrument 100 at any time that can be.Radioactive emission detector 104 is communicated by letter with an enumerator 114, counts mental retardation γ, β and/or positron ray.All data are sent to a processor 116, and are handled by it.Can 2D or 3D data be carried out projection according to the imaging data that from the Image-forming instrument that utilizes a shared display device of describing in addition here, obtains.Also can work in coordination with the true and virtual image that shows surgery instrument itself.Can be installed to the example of inner commercially available radioactive emission detector, as biopsy needle, comprise S101 and the flicker plastic optical fiber of S104 or the optical fiber of communicating by letter with a flasher (detector coating or scintillation crystal) made as PPLASTIFO at the optical fiber edge.As known in the art, can be visually or report the energy level of the ray of detection by an acoustical signal.

With this, be equipped with a radioactive emission detector and link to each other with a positioning control system and/or the surgery instrument of communication has with it been formed a embodiment according to this feature of the present invention.The another one embodiment according to this feature of the present invention has been formed in like this one and conventional Image-forming instrument and/or the coefficient design of external beam radiotherapy radiation detector.In all cases, a radioactive emission detector and link to each other with a positioning control system and/or the surgery instrument of communication with it is used for finely tuning on the spot radioactive source in the human body is equipped with.

Should recognize, in the therapy that some minimum enters, even will monitor patient's position itself, for example, use the electronics or the physical standard labelling of certain position that is attached to health to monitor by positioning control system.

Like this, as described further below, project in the common coordinate system system, perhaps by the three-dimensional data and the position that will from above-mentioned device, receive, adopt a common coordinate system for all devices, can be with in the high-grade integrated display in data integration to a distant place.

Fig. 9 has shown the example of this desired result.In shown embodiment, utilize four independently positioning control system 50,52,54 and 56 follow the tracks of patient 58, Image-forming instrument 60, radioactive emission detector 62 and surgery instrument 64 respectively four positions in the coordinate system 66,68,70 and 72 independently.If the patient is immobilized, then need not to follow the tracks of patient's position.

Should be understood that, used any auxiliary device or all positioning control systems can be integrated in one or more common positioning control systems, used any auxiliary device or all positioning control systems can shared one or more coordinate systems, and the position data that the positioning control system of describing in any coordinate system obtains can project on any other coordinate system or an independence (the 5th) coordinate system 74.In a preferred embodiment, in order to be applicable to patient's trunk place, coordinate system should be one and consider that patient's chest is breathed the dynamic coordinate system system that moves during the treatment.

Shown in 76, the initial data that record is collected by detector 62 shown in 78, utilizes position and radioactivity to write down to produce the threedimensional model of a radiopharmaceutical picked-up part of patient's body organ.

Similarly, shown in 80, the imaging data that record is gathered by Image-forming instrument 60, the threedimensional model of the patient body organ that utilizes position and imaging data to write down to produce imaging.

Then, shown in 84, all data that collect are sent into a data processor for processing data 82, produce the radioactivity data of position of relevant patient 58 and surgery instrument 64 and a combination or the synergetic demonstration of imaging data.

The instrument 64 that then, can utilization itself can show in combination carries out more accurate treatment.Processor 82 can be that a single integral body maybe can comprise and a plurality ofly directly communicates by letter with one or more described devices or be integrated in wherein treating stations.

The invention provides a main advantage that is better than prior art, because it handles integrated in the position by two kinds of data relevant with body part of obtaining of imaging technique-conventional imaging and radiological imaging independently, make the surgeon can accurately locate the body part that to sample or to treat thus.

Should recognize that the equipment component of describing among Fig. 9 can be used as independently system.For example, being combined in of the combination of detector 62 and positioning control system thereof, instrument 64 and positioning control system thereof is enough in some situation to carry out interior therapeutic.As the purpose in order to diagnose only, and need not to carry out biopsy, then the positioning control system of the positioning control system of detector 62 and instrument 60 is just enough.

With reference now to Figure 12,, what this figure illustrated is an imaging system 200 that makes up and move according to a preferred embodiment of the present invention.Imaging system 200 preferably includes radioactivity probe 202, as top with reference to figure 5 and 10 described narrow angle radioactive emission detectors 22 '.

A position sensor 204 is provided, is used for the position of detection of radioactive probe 202.Position sensor 204 can be connected on the radioactivity probe 202 physically, also can separate with it.Position sensor 204 sends to a positioning control system 206 with the position data of sensing.Positioning control system 206 can be similar to earlier in respect of figures 1 described positioning control system, and position sensor 204 can be any pick off that is applicable to this type of positioning control system.

Another can be used for the method for located irradiation radiation source and be to use a small hand-held gammacamera 205 that is connected to position sensor 204 (as DigiRad2020tc ImagerTM, 9350Trade Place, San Diego, California 92126-6334, USA).

Positioning control system 206 can make radiation probe 202 freely carry out two dimension on the zone of being paid close attention to or three-dimensionally come flyback retrace, is preferably in the distance that each scanning room increases a weak point.Positioning control system 206 is followed the tracks of pop one's head in position in the 202 Position Tracking Systems coordinate systems of rays, as distance X p, Yp and the Zp with respect to initial point Op.

Imaging system 200 also comprises a medical imaging system 208, as, but be not limited to computer topography art (CT), NMR (Nuclear Magnetic Resonance)-imaging (MRI), ultrasonic imaging, PET (PET) and single PET (SPECT).Medical imaging system 208 provides patient 209 image in the imaging of medical coordinate system, as distance X m, Ym and the Zm with respect to initial point Om.

As described in the U.S. Patent application 09/610,490 of reference here, imaging system 200 also comprises a coordinate Accreditation System 210.Coordinate Accreditation System 210 is suitable for the coordinate to the coordinate registered location tracking system of medical imaging system.

Positioning control system 206, medical imaging system 208 and coordinate Accreditation System 210 are preferably carried out wired or wireless communication with a processing unit 212 (being also referred to as data processor 212).

In imaging system 200 runnings, after the radiopharmaceutical processes of having carried out patient 209, clinician/internist/surgeon (not showing in the drawings) can move or scanning radiation probe 202 in the surrounding target zone in inspection.By utilizing radiation probe 202 measuring radiation counting rates and utilizing the counts corrected rate to indicate by positioning control system 206 and proofread and correct this counting rate, obtain the physiological activity figure of target area, follow the tracks of moving or scanning motion of radiation probe 202.

With reference now to accompanying drawing 13,, this figure has illustrated the imaging form with radiation probe 202 according to a preferred embodiment of the present invention.For brevity, the example that shows among Figure 13 is at an one dimension pictorial form, but is readily appreciated that, for the pictorial form of other dimension, can adopt same principle.

Implement in the example of the present invention at one, radiation probe 202 can be a gamma-ray probe that comprises a collimator 211 and radiation detector 213.By probe collimator 211 gamma-rays is projected on the radiation detector 213, produce the signal of telecommunication according to detected radiation.Radiation probe 202 sends pulse, the signal of telecommunication that the pulsed height analyzer circuit analysis is produced by radiation detector 213 to a probe counter 215 that comprises pulsed height analyzer circuit (not showing in the drawings).If this signal of telecommunication is to be in the selected energy window, then count radiating energy level, i.e. the numerical value of radiation counter by probe counter 215.

The example of suitable radiation detector comprises solid probe (SSD) (CdZnTe, CdTe, HgI, Si, Ge or the like), scintillation detector (NaI (TI), LSO, GSO, CsI, CaF or the like), gas detector or scintillating fiber detector (S101, S104 or the like).

The position sensor 204 relevant with radiation probe 202 detects the position of radiation probes 202, positioning control system 206 calculate and monitoring radiation probe 202 Position Tracking Systems coordinate systems in the position.With 2,3, reach as high as that 6 degree of freedom calculates and monitor rectilinear direction displacement-X, Y and Z and around the rotation (promptly being respectively angle ρ, θ and the φ of rotation) of X, Y and Z axle.

The example of suitable positioning control system comprises measurement mechanical arm (FaroArm, http://www.faro.com/products/faroarm.asp), optical tracking system (Northern Digital Inc., Ontario, passive or the active system of Canada NDI-POLARIS), magnetic tracking system (NDI-AURORA), infra-red tracing system (E-PEN system, http://www.e-pen.com) and ultrasound wave tracking system (E-PEN system).

Processing unit 212 combines the radiation detection counting rate of probe counter 215 and the positional information of positioning control system 206, two dimension that the radiotracer that utilizes an imaging software algorithm 217 to form the intravital target area of patients distributes or 3-D view.Can with space probe positions and space counting rate common storage in a memorizer, perhaps on a computer monitor 214, be shown as signature corresponding to counting rate position, space.

The example that has shown such figure among Figure 14, expression be the untreated one dimension emulation of the dark radiation point source 218 (Figure 13) of the 30mm in human body that utilizes a 10mm nuclear radiation probe that is connected to positioning control system 206 202 to detect.The figure of Figure 14 has one about 500 maximum count rate to the probe positions that the surgeon is illustrated in about 50mm.

In a preferred embodiment of the invention, imaging software algorithm 217 has used an average treatment, improves the curve of Figure 14.Below with reference to Figure 15 this average treatment is described.

Probe counter 215 will pop one's head in counting rate information N (Xc, Yc, Zc, ρ, θ φ) is sent to processing unit 212 (step 301).Position sensor 204 with probe positions information (Xc, Yc, Zc, ρ, θ φ) sends into processing unit 212 (step 302).((dx, dy dz) also are imported into processing unit 212 (step 303) to probe parameter as physical size.

Subsequently, processing unit is searched three-dimensional pixels (that is: body image element) (step 304) of all expression probe intensity in the processing unit memorizer, i.e. Xc+dx, Yc+dy, Zc+dz.Processing unit 212 begins to calculate the computing number of times that carries out from image-forming information section start (step 305) each three-dimensional pixel, promptly M (Xc, Yc, Zc, ρ, θ, φ).The average counter rate (step 306) that processing unit 212 is fallen into a trap new according to following formula at each three-dimensional pixel then:

N(Xc+dx，Yc+dy，Zc+dz)＝

[N(Xc+dx，Yc+dy，Zc+dz)+N(Xc，Yc，Zc，ρ，θ，φ)]/[M(Xc+dx，Yc+dy，c+dz)+1]

Then, processing unit 212 checking lists are shown in N (Xc+dx, Yc+dy Zc+dz) locate the display image (step 307) of the three-dimensional pixel that receives.Then, next probe positions is repeated this algorithm (step 308).

Shown among Figure 16 the average algorithm among Figure 15 has been applied to the resulting figure of example among Figure 14.

What Figure 17 and 18 showed respectively is by the gamma-radiation probe of the link position tracking system 206 among Figure 15 and the hot intersection imaged image and the hot 4.77mm bar shaped imaged image of average algorithm generation.Detection image is to utilize a probe EG﹠amp who is connected to ScintiPack model 296; G Ortec NaI (TI) model 905-1 (thickness=1 ", diameter=1 ") form.Used positioning control system is can be from Ascension Technology Corporation, P.O.Box 527, Burligton, the Ascension miniBIRD that Vermont 05402 USA (http://www.ascension-tech.com/graphic.htm) buys.The magnetic of AscensionTechnology company is followed the tracks of and navigation system utilizes D.C. magnetic field to overcome obstruction and distortion that near metal produces.Signal can pass human body undampedly.

In other embodiments of the present invention, imaging software algorithm 217 can adopt a minimization to improve curve among Figure 14, such as following with reference to figure 19 description.

Probe counter 215 with surveymeter digit rate information N (Xc, Yc, Zc, ρ, θ φ) is sent to processing unit 212 (step 401).Position sensor 204 with detecting location information (Xc, Yc, Zc, ρ, θ φ) sends into processing unit 212 (step 402).((dx, dy dz) also are imported into processing unit 212 (step 403) to probe parameter as physical size.

Subsequently, processing unit 212 is searched the three-dimensional pixel (step 404) that volume is surveyed in all expressions, i.e. Xc+dx in the processing unit memorizer, Yc+dy, Zc+dz, processing unit 212 find those to have than the surveymeter digit rate value N (Xc, the Yc that import from the pixel of representing probe size the processing unit memorizer, Zc, ρ, θ, φ) high counting rate value (Xc+dx, Yc+dy, three-dimensional pixel (step 405) Zc+dz).Then, processing unit 212 is changed into the three-dimensional pixel of higher count rates surveymeter digit rate N (Xc, Yc, the Zc with input, ρ, θ, three-dimensional pixel (step 406) φ), and three-dimensional pixel N (Xc+dx, Yc+dy, the display image of Zc+dz) locating (step 407) of correction higher count rates value.Then next detecting location is repeated this algorithm (step 408).

Shown among Figure 20 the average algorithm among Figure 19 has been applied to the resulting figure of example among Figure 14.

The invention provides another algorithm, estimate distribution of radiation sources with a control volume, and it is described with reference to figure 27A-27G.In this algorithm, suppose that radiation source is included in the substantial radiation source of heterogeneous radiation on all directions, and suppose that this radiation source is positioned at and is evenly distributed in a limited volume.

With reference now to Figure 27 A and 27B,, shown a radiation sensor 600 among the figure, preferably have the shape the same usually with the tubulose collimator.As mentioned above, utilize radiation sensor 600 to write down photon 602, the average magnitude subnumber of unit interval is provided thus.Radiation sensor 600 can center on the volume of being paid close attention to 604 and move.Suppose that position and direction (position of the volume 604 that memory is studied) thereof at a given moment pick off 600 are known (Figure 27 A).

Being preferably the tubulose collimator provides the disk detector 606 of a photon.This quantum detector 606 preferably is placed on the tail end 608 of pipe, and the perforate front end 610 that photon can only pass through pipe arrives detectors 606 (Figure 27 B).

With reference now to Figure 27 C,, shown among the figure coordinate system (z), its initial point O is positioned at the center of radiation sensor 600 for x, y, (and x, y) plane is the plane of detector, the z axle be the collimation organ pipe the center.The physical dimension of collimator-Gao h and radius ρ are known.

Because the rotational symmetry of pipe, overall strength is the radiation source Q=Q (x of I obviously, y, x) along all direction heterogeneous radiations, only utilize Q to the axis (z axle) of collimator apart from r and Q apart from (x, y) planar distance z is determined the intensity part that the quantum detector 606 by radiation sensor 600 writes down.In other words, there is a function phi (r who only defines by collimator parameter ρ and h, z) (can be easy to utilize ρ, h, r and z to write out corresponding explicit expression), feasible radiant Q=Q (x by detector 606 records, y, x)=(r, (r, z) overall strength I's Q with radiant is directly proportional for intensity z) and φ.

With reference now to Figure 27 D.Discussion according to the front, if in a volume V with certain radiation profiles I (Q)=I (Q (r, z)) replace a radiant, then the radiant intensity by radiation sensor 600 records is proportional to following integration (ratio of its constant does not depend on radiation profiles and sensing station): $\underset{V}{\∫}I\left(Q(r,z)\right)\mathrm{\Φ}(r,z)\mathrm{dQ}......\left(1\right)$

The value that obtains according to the measuring method by formula (1) is discussed is now carried out the estimating algorithm of intensity distributions I (Q).For simplicity's sake, with reference to figure 27E first kind of situation of two-dimensional problems is discussed, wherein intensity I (Q) is to be distributed in certain two dimensional surface.As following description, three-dimensional problem is the direct vague generalization of two-dimensional problems.

Seen in Figure 27 E, radiation source is to be distributed among the planar rectangular area V.Consider two coordinate systems.First coordinate system be a sensor coordinates system for pick off 600 (x, y, z).Second coordinate system be corresponding to the radiation source plane (u, radiation source coordinate system v) (u, v, w).

Suppose each when increasing discrete time, in that (w) in the coordinate system, (z) direction of the origin position of system and z axle unit vector is known for x, y for u, v.In other words, movable sensor (w) position in the coordinate system and direction are known for u, v, and the supposition (w) coordinate system is immobilized for u, v.

(u distributes according to distribution function I (Q) in the given rectangular V of certain bounded that v) goes up on the plane to think radiation source.(u v) is unknown to I (Q)=I, seeks radiation (or radiant intensity) distribution function that defines among the V.

In order to make the estimation problem standardization of radiation distribution function I (Q), will think that function I (Q) is that certain finite dimensional space H according to the function that defines among the V obtains.In other words, evaluation function I (Q) itself not, but certain finite dimension approximation of estimation distribution function I (Q).

The simplest finite dimension approximation method is that rectangular V is divided into the some groups of rectangular elements that are equal to, and thinks the Space H of jump function corresponding with this division (promptly the spatial function in the unit of dividing is a constant), as shown in Figure 27 F.

If rectangular V enough accurately is divided into little rectangle, this jump function approaches so is enough to be used for estimating radiation profiles I (Q).

If each limit of rectangular V is divided into n part (Figure 27 F) that equates.M=n then ²Dimension for the Space H of the jump function of corresponding division.

Space H normally with (its natural scalar product is＜* * 〉) of the m-dimensional space isomorphism of n * n dimension matrix.

If I=is (I _Ij) _{I, j=1 ..., n}For the unknown elements of the H of needs estimations, suppose that unit I is the K functional { Φ by integration (1) form _k} _K=1...kMeasure:

<I，Φ _k>＝∑ _{i，j＝1...n}I _ijΦ _ij ^(k) (2)

Φ wherein _k=(Φ _Ij ^(k) _{I, j=1 ..., n,}K=1 ..., K (after the approaching of the function I (Q) that utilizes corresponding jump function to carry out, integration (1) being converted to and (2)).

Functional, Φ _k, k=1 ..., K is corresponding to K the discrete location (Figure 27 E) of pick off.(r, explicit expression z), each time k, pick off then can calculate all matrix Φ with respect to the position of viewing area V to the function phi of known formula (1) _k=(Φ _Ij ^(k)) _{I, j=1 ..., n}, k=1 ..., K.

Thus, can obtain following measure equation:

Ψ _k＝<I，Φ _k>+ε _k，k＝1，...，K (3)

Herein, Ψ _kBe the measurement result of the unknown elements I of Space H, ε _kBe random error (ε _kIndependent random variables, E ε _k=0, k=1 ..., K).

If M:H-＞H is the operator in the Space H of following form:

M＝∑ _k＝1..KΦ _kΦ _k. (4)

Thereby the linearity that can be got the best nothing skew of unit I by following formula is estimated $\hat{I}=M^{-1}\mathrm{\&Psi;},......\left(5\right)$

M wherein ^-1: H-＞H is the inverse operator of the operator M of formula (4), and:

Ψ＝∑ _k＝1..KΨ _kΦ _k， (6)

(Ψ wherein _kBe the measurement result of formula (3)).

Utilizing a problem (problem in the calculating when only the dimension m of Space H is very big) of estimation (5) is that the operator M:H-＞H of formula (3) is " irreversible ".In other words, estimation problem is " morbid state ".This means and in measure equation (3), have a noise ε _kEven this noise is very little, also may cause very big estimation error distance sometimes

This just means the additional adjustment of estimation problem needs.This is the general issues of finding the solution a large-scale system of linear equations.There is several method to find the solution such equation group.A kind of known method of finding the solution this type of equation group will be described below, but also can adopt multiple other method, comprise the gradient descending method, the method in (http://www-visl.technion.an.il/1999/99-03/www/) and other method well known in the art.And, can improve the reconstruct of image by considering the correction between eclipsed substantially measurement.In the following description, suppose for pixel or volume elements that a fixed jump function is arranged, also can adopt other ultimate principle that can be applicable to some application such as small echo, Gauss etc. better.

In order to obtain the estimation of rule

Substitute

Can utilize the characteristic vector of operator M to decompose:

If, ₁, ₂..., _mFor corresponding to eigenvalue ₁〉=λ ₂〉=... 〉=λ _mThe characteristic vector of 〉=0 operator M:H-＞H.

If R is certain natural number, 1＜R＜m (R is " a regularization parameter ").If H ^(R)Be R characteristic vector before utilizing ₁, ₂..., _RThe subspace of the Space H that generates.

H ^(R)＝sp{ _k} _k＝l…R． (7)

If: P ^(R): H-＞H ^(R)For at subspace H ^(R)On rectangular projection.

Can obtain following regularization estimation

If Φ _k ^(R)=P ^(R)Φ _{K, k=1 ..., K}

Ψ ^(R)＝∑ _k＝1...KΨ _kΦ _k ^(R)， (8)

M ^(R): H ^(R)-＞H ^(R)Operator for following formula

M ^(R)＝∑ _k＝1...KΦ _k ^(R)Φ _k ^(R) (9)

(operator M ^(R): be to the operator M of formula (4) subspace H to formula (7) ^(R)Constraint),

So, ${\hat{I}}^{\left(R\right)}={\left(M^{\left(R\right)}\right)}^{-1}{\mathrm{\&Psi;}}^{\left(R\right)}......\left(10\right)$

When suitable selective rule parameters R (so that do not make eigenvalue _RToo small) time, then estimation (10) is stable.

The method that several possible selection parameters R are arranged.A kind of method be with R as one " program parameters ", and " in test " obtain reasonably value.Another kind method is to select certain " optimization " value.If the random noise ε in the known formula (3) _kThe covariant operator, and the information of the unit I of relevant Space H is a priori result, then can adopt this method.

With the rectangular domain dimension excessive (especially under three-dimensional situation) that to be divided into a defective of a lot of the orthogonal methods that equate are Space H.If each limit of rectangular V is divided into n part that equates, the dimension of Space H will be n so ², the dimension of finding the solution the matrix of corresponding estimation equation is n ²* n ²=n ⁴(under three-dimensional situation, n ³* n ³=n ⁶).Obviously, for bigger n, this situation may produce serious memory space and computation time problem.

According to a preferred embodiment of the present invention, use the irregular division of rectangular V.This irregular division methods can significantly reduce the dimension of problem, helps COMPUTER CALCULATION.

More particularly, the defective of the rule of the above-described survey region V of institute division is to have considered in fact not have a plurality of unit of signal (Figure 27 F).Better method is only to make to adopt smaller units in the zone with high signal, and adopts bigger unit in the zone of low signal.

With reference now to Figure 27 G,, the figure illustrates the advantage of dividing according to the irregular unit of a preferred embodiment of the present invention.

In the phase I, carry out rule by " large-scale " unit and divide, and by measuring as mentioned above and estimating.In this method, carry out the intensity distributions estimation with large unit.

In second stage, some intensity is become 4 equal subelements (perhaps being divided into 8 subelements under three-dimensional situation) greater than the dividing elements of certain threshold value.For example, can obtain an appropriate threshold by (all large units) mean intensity is deducted twice (or three times) δ (standard deviation).These are divided by measuring as mentioned above and estimating.

Carry out dividing elements and measurement subsequently and estimation continuously, up to divide in certain smaller units reach required precision till, this precision is normally determined by the calculating of used computer and storage capacity.

Can handle three-dimensional problem with the identical method of two-dimensional case, that unique difference is to use is parallelepiped V, rather than rectangular V (Figure 27 D).Thus, the part of each division also is a parallelepiped.

Aforementioned algorithm can be used for multiple imaging system.For example, this algorithm can be popped one's head in radiation detector, the large-scale gammacamera of radiation probe detector array, different designs, together uses as bull photographing unit, conventional photographing unit and automatic white balance (AWB) scanner.This algorithm is applicable to SPECT and planar imaging, and is used for all types of isotopes with any type photon energy.

According to the discussion of front, those of skill in the art will appreciate that aforementioned algorithm can be used near the position of the uncertain region (based on systematic measurement error) predicting radiation source and this radiation source.This algorithm also guides user carries out additional measurement, makes the uncertain region minimum according to Systems Operator's needs.

Therefore, this algorithm comprises a feedback system, by analyzing to determine the border about the uncertain region of radiation source, and guides the medical worker to carry out additional scanning in these uncertain regions, improving precision, to reduce error, and make the border minimum of uncertain region thus.

The continuous sampling that utilizes radiation probe 202 to carry out can provide the position of tumor and the physiological radiation activity diagram of tumor region.Scanning by larger amt obtains higher safety and accuracy.

With reference now to Figure 21,, what this figure showed is an image reconstruction system 450 that constitutes and move according to a preferred embodiment of the present invention.Image reconstruction system 450 produces a combination image 451, this combination image is by image with greatest irradiation position (and uncertain region) in the processing unit 212 and Medical Instruments 452 in the medical image system 208, forms as the image of biopsy needle position.This combination image 451 makes the doctor can assess Medical Instruments 452 better with respect to position of (medical image system 208) tissue image and the position, radiation areas of being inferred by the radiation detection algorithm.

With reference now to Figure 22,, this figure shows is flow chart according to the radiation diagram restructing algorithm of a preferred embodiment of the present invention.

In image processing program, adopt the deconvolution method usually.The example of this deconvolution method has been described in the people's such as Sapia of reference here the United States Patent (USP) 6,166,853.(still, should recognize, these examples and the present invention should be confined to United States Patent (USP) 6,166, the deconvolution method of introducing in 853.)

In common image acquisition procedures, light (perhaps other electromagnetic wave energy) passes a limited slit to imaging plane.The image of gained is the result of convolution in the slit of the light of source object and imaging system.Usually can directly utilize the Fourier transform in slit to obtain a ssystem transfer function.As known in the art, only in two dimension, promptly exist on the x-y plane because the blurring effect that convolution produces.A point spread function (PSF) is one and is used to describe the fuzzy expression formula of two-dimensional convolution.In fact PSF results from the imaging by point source.The Fourier transform of PSF is the ssystem transfer function by the convolution acquisition of ssystem transfer function and Di Lake-delta-function.The physics equivalence that point source is Di Lake-delta-function, in frequency domain, Di Lake-delta-function is a unified operator of crossing over frequency spectrum.Therefore, the Fourier transform of PSF should be the Fourier transform in slit.But, the blooming that PSF comprises noise and causes such as effects such as aberration.

Can eliminate or weaken the influence of PSF by deconvolution overall blurring effect.

With reference to Figure 22, in situation of the present invention, Fourier transform that can be by detector slit is also considered noise and is determined the transfer function (step 500) of radiation detector such as the blooming that effects such as aberration cause.The example of a transfer function can be that a normalization distributes.Utilize mathematical technique, can determine the deconvolution (step 502) of transfer function.

The meter reading of each locus of detector constituted all volume elements in the detector visible range (perhaps the pixel during X-Y scheme, term used herein " volume elements " comprises pixel and volume elements) radiation counter and.At at least one volume elements place, be preferably in each volume elements place, specify a count value (step 504) according to the deconvolution of the exclusive transfer function of used detector.An available additional mathematical method is handled the different numerical value (step 506) that each volume elements obtains from the observed multiple reading of different detectors.For example, this processing can constitute a simple algebraic mean value, minima or average inverse reciprocal, so that produce a single reading value of each volume elements.Utilize deconvolution to come that reconstruct reduces then or do not have the volume elements (step 508) of the radiation diagram of blurring effect.

Algorithm as described herein is not only applicable to utilize the analysis of the reading that directed ray detector obtains, and is applicable to the ray detector of space sensitivity (pixelated).In this case, can be according to the reading of handling each pixel at the used algorithm of directed beam detector.Utilize the implicit of the sensitive detector in space to be intended that in order to save Measuring Time by receiving reading from a plurality of and column direction.Like this, produce a large amount of eclipsed low-resolution images, form a high-resolution image through handling then.In addition, can the sensitive detector of scanning space, further utilize above-mentioned algorithm to improve resolution.

Therefore, being applicable to that the algorithm of orientation detector is applicable to the sensitive detector in space too, only is not a radiation reading in each position, but parallel processing one big group discrete location.Each pixel can be regarded a discrete detector with by the angle of the geometry regulation of used segmentation collimator as.Each pixel takies different locus, therefore utilizes algorithm described herein, it can be regarded as a new single direction probe positions.Also can scan whole group pixel by the sensitive detector of scanning space, obtain one group of new data point of reposition as using directed detector.In case each pixel according to the detector of space sensitive has obtained a low-resolution image, can adopt high resolution algorithm to produce a high-definition picture.For example, the J.Acoust.Soc.Am. of reference here, Vol.77, No.2, in February, 1985,567-572 page or leaf; Yokota and Sato, IEEE Trans.Acoust.Speech SignalProcess. (in April, 1984); Yokota and Sato, Acoustical ImagingPlenum, New York, nineteen eighty-two, Vol.12; H.Shekarforoush and R.Chellappa, " Data-Driven Multi-channel Super-resolution withApplication to Video Sequences ", Journal of Optical Society ofAmerica-A, vol.6, no.3, pp.481-492,1999; H.Shekarforoush, J.Zerubia and M.Berthod, " Extension of Phase Correlation toSub-pixel Registration ", IEEE Trans.Image Processing, toappear; P.Cheeseman, B.Kanefsky, R.Kruft, J.Stutz, and R.Hanson, " Super-Resolved Surface Reconstruction From MultipleImages, " NASA Technical Report Fia-94-12, in December, 1994; A.M.Tekalp, M.K.ozkan, and M.I.Sezan, " High-Resolution ImageResolution for Lower-Resolution Image Sequences and Space-Varying Image Resolution; " IEEE International Conference onAcoustics, Speech, and Signal Processing (San Fransisco, CA), pp.III-169-172, March 23-26,1992, suitable high resolution algorithm has been described among the http://www-visl.technion.ac.il/1999/99-03/www/. Result of the test

In a series of clinical trial, on one's body ultimate principles more of the present invention are verified the patient who has injected suitable radiopharmaceutical agent at its condition of illness in advance.Have a magnetic potential according to utilization and put the scanning that the hand-held detector of tracking system is carried out predetermined affected areas, made up two-dimentional color-coded graph.The figure that shows the radiation counter grade of gained is compared with the image of conventional gammacamera.The radioactivity medicament that detects comprises ¹⁸FDG, ^99MTc-MDP, ^99MTC sodiumpertechnetate, ^99MTc erthrocytes.In the condition of illness below, from the image of image neutralization that produces by system of the present invention, can observe similar radioactive label figure by conventional gammacamera generation.

Figure 23 A and 24B represent is the radioactive label figure of 58 years old man's observing from the image that the image neutralization that produced by system of the present invention is produced by conventional gammacamera respectively autonomous thyroid tumor.

Figure 24 A and 24B represent is the doubting to being the pagetoid radioactive label figure of humerus of 89 years old woman observing from the image that the image neutralization that produced by system of the present invention is produced by conventional gammacamera respectively.

Figure 25 A and 25B represent is the radioactive label figure of 19 years old woman's observing from the image that the image neutralization that produced by system of the present invention is produced by conventional gammacamera respectively chronic osteomyelitis.

Figure 26 A and 26B represent is the radioactive label figure of skeleton metastasis (metastases) of 18 years old man's observing from the image that the image neutralization that produced by system of the present invention is produced by conventional gammacamera respectively medulloblastoma.

A series of existing therapies of utilizing the advantage of system and method for the present invention are provided below:

In cancer diagnosis, system and method for the present invention can be used for from external or take cancer and/or guidance by endoscopy and enter formula diagnosis (biopsy).Its example comprises, but be not limited to the pulmonary carcinoma biopsy, the breast carcinoma biopsy, biopsy of prostate, the cervical cancer biopsy, the lymphatic cancer biopsy, the thyroid carcinoma biopsy, brain cancer biopsy, the osteocarcinoma biopsy, the colon cancer biopsy, human primary gastrointestinal cancers splanchnoscopy and biopsy, the splanchnoscopy of cancer of vagina, the splanchnoscopy of carcinoma of prostate is taken (passing through rectum), the splanchnoscopy of ovarian cancer is taken (passing through vagina), the splanchnoscopy of cervical cancer is taken (passing through vagina), the splanchnoscopy of bladder cancer and shooting (passing through urethra), the splanchnoscopy of gallbladder cancer and shooting (passing through stomach), the shooting of pulmonary carcinoma, the shooting of breast carcinoma, melanomatous shooting, the shooting of the brain cancer, the shooting of lymphatic cancer, the shooting of renal carcinoma, the shooting of human primary gastrointestinal cancers (from the outside).

Under specific MRI situation, radiation detector can or be packaged together with a little RF coil combination, is used to transmit and receive or only be used for being received in that prostate or near the qualification position (as vagina, airway, top intestines and stomach or the like) other are diagnosed and the MRI signal of the transrectal probe for the treatment of.

System and method of the present invention also helps the directed locating therapy of cancer.Its example includes, but are not limited in pulmonary carcinoma, breast carcinoma, carcinoma of prostate, uterus carcinoma, hepatocarcinoma, lymphatic cancer, thyroid carcinoma, the brain cancer, osteocarcinoma, colon cancer (by the endoscopy of rectum), gastric cancer (by the endoscopy in thoracic cavity), the thoracic cavity cancer, carcinoma of small intestine (by the endoscopy in rectum or thoracic cavity), bladder cancer, renal carcinoma, the tumor chemotherapy of the inside of adopting in the situation of cancer of vagina and ovarian cancer, the internal tumours plesioradiotherapy, the internal tumours cryogenic ablation, the internal tumours radiofrequency ablation, the excision of internal tumours ultrasound wave, the internal tumours laser ablation.

At cardiac disease, the present invention helps following processing, method and system wherein is used in perfusion, tissue survival ability and the inner blood flow (only with air bag or in conjunction with the orientation that stretches) of assessment tissue in the PTCA process, the damage of evaluate cardiac in the situation of cardiogenic shock, the damage of evaluate cardiac behind myocardial infarction, in the assess heart failure situation, come tissue is assessed the vigor and the perfusion of assessment internal blood vessel before the CABG operation according to organizational vitality and perfused tissue.

Radiation detector can be installed in the conduit that enters heart by blood vessel, estimates the ischemia in the heart, so that the treatment of guiding excision probe or other type is positioned at the appropriate location in the heart.It is the location blood clot that another kind can utilize application of the present invention.For example, can utilize above-mentioned radiation detector to assess or distinguish new blood clot and old blood clot.Therefore, for example radiation detector can be placed on the very little lead of bore, as lead used among the PTCA, so that carry out the imaging of internal clot.Can search for the internal clot in the aortic arch, all be to be caused by wherein blood clot because be about 75% apoplexy.

Also can utilize method and system of the present invention to assess perfused tissue, tissue survival ability and inner blood flow in following process: survival ability is organized in assessment, the CABG process of mark infarction; The CABG process that forms success or not again of assessment blood vessel.

The present invention also has many other application on therapeutics, for example, inject short distance treatment seed, ultrasound wave radio frequency cryotherapy and located irradiation excision but be not limited to.

Should recognize that the present invention also can be used for many other therapeutic processes.

For clarity sake, independently in the embodiment some feature of the present invention is being described, also can in a single embodiment, adopting these combination of features.On the contrary, for simplicity's sake, in a single embodiment, a plurality of features of the present invention are described, also can utilize these features individually or in any suitable sub-portfolio.

Although invention has been described in conjunction with specific embodiment, obviously, for those those skilled in the art, can revise and change the present invention.Thus, the present invention comprises correction and the change in all aims that belong to additional claim and the scope.This description has been quoted publication all printings or electronic form, patent and the patent application of mentioning in the description on the whole, has been equivalent to quote specifically and independently each independent publication, patent or patent application.In addition, should not quoting and prove that understanding this reference is operable prior art of the present invention with any reference in the present patent application.

Claims (254)

1. one is used for calculating the system of a radioactive radiation source in the position of a coordinate system, and this system comprises:

A) radioactive emission detector;

B) positioning control system that links to each other and/or communicate with this radioactive emission detector; With

C) data processor, it is designed and is configured to be used for to receive the data input from this positioning control system and radioactive emission detector, and is used for calculating the position of radioactive radiation source in a coordinate system.

2. according to the system of claim 1, wherein radioactive radiation source is to select the aberrant angiogenesis of the abscess of composition, radiopharmaceutical labelling of relevant inflammation of blood vessel grumeleuse, radiopharmaceutical labelling of malignant tumor, radiopharmaceutical labelling from the benign tumor that comprises the radiopharmaceutical labelling, radiopharmaceutical labelling and radiopharmaceutical labelling.

3. according to the system of claim 1, wherein radioactive emission detector is to select from the radioactivity seeker that comprises a low-angle radioactive emission detector, wide angle radioactive emission detector, a plurality of independent low-angle radioactive emission detector and a space sensitive.

4. according to the system of claim 1, wherein positioning control system be from comprise a joint arm positioning control system, positioning control system, one based on accelerometer based on potentiometric positioning control system, positioning control system, positioning control system based on radio frequency based on sound wave, one based on the positioning control system in magnetic field and one based on selecting the optical positioning control system.

5. method that is used for determining the position of radioactive radiation source in a coordinate system, the step that this method comprises has:

A) provide a radioactive emission detector that links to each other or communicate with a position tracker; With

B) monitor the radioactivity of sending from radioactive radiation source, simultaneously, the position of monitoring radioactive emission detector in coordinate system determined the position of this radioactive radiation source in coordinate system thus.

6. according to the method for claim 5, wherein radioactive radiation source is to select the aberrant angiogenesis of the abscess of composition, radiopharmaceutical labelling of relevant inflammation of blood vessel grumeleuse, radiopharmaceutical labelling of malignant tumor, radiopharmaceutical labelling from the benign tumor that comprises the radiopharmaceutical labelling, radiopharmaceutical labelling and radiopharmaceutical labelling.

7. according to the method for claim 5, wherein radioactive emission detector is to select from the radioactivity seeker that comprises a low-angle radioactive emission detector, wide angle radioactive emission detector, a plurality of independent low-angle radioactive emission detector and a space sensitive.

8. according to the method for claim 5, wherein positioning control system be from comprise a joint arm positioning control system, positioning control system, one based on accelerometer based on potentiometric positioning control system, positioning control system, positioning control system based on radio frequency based on sound wave, one based on the positioning control system in magnetic field and one based on selecting the optical positioning control system.

9. a system is used for calculating a radioactive radiation source in the position of first coordinate system, and further this position is projected on one second coordinate system, and this system comprises:

(a) radioactive emission detector;

A) positioning control system that links to each other and/or communicate with this radioactive emission detector; With

B) data processor is designed and is configured to be used for

I. receive the data input from this positioning control system and radioactive emission detector;

Ii. calculate the position of radioactive radiation source in first coordinate system; With

Iii. the position with radioactive radiation source projects on one second coordinate system.

10. according to the system of claim 9, wherein radioactive radiation source is to select the aberrant angiogenesis of the abscess of composition, radiopharmaceutical labelling of relevant inflammation of blood vessel grumeleuse, radiopharmaceutical labelling of malignant tumor, radiopharmaceutical labelling from the benign tumor that comprises the radiopharmaceutical labelling, radiopharmaceutical labelling and radiopharmaceutical labelling.

11. according to the system of claim 9, wherein radioactive emission detector is to select from the radioactivity seeker that comprises a low-angle radioactive emission detector, wide angle radioactive emission detector, a plurality of independent low-angle radioactive emission detector and a space sensitive.

12. according to the system of claim 9, wherein positioning control system be from comprise a joint arm positioning control system, positioning control system, one based on accelerometer based on potentiometric positioning control system, positioning control system, positioning control system based on radio frequency based on sound wave, one based on the positioning control system in magnetic field and one based on selecting the optical positioning control system.

13. a method is used for calculating a radioactive radiation source in the position of first coordinate system, and further this position is projected on one second coordinate system, this system comprises:

A) provide a radioactive emission detector that links to each other or communicate with a positioning control system; With

B) monitor the radioactivity of sending from radioactive radiation source, simultaneously, the position of monitoring radioactive emission detector in first coordinate system determined the position of this radioactive radiation source in first coordinate system thus, and this position is projected on second coordinate system.

14. according to the method for claim 13, wherein radioactive radiation source is to select the aberrant angiogenesis of the abscess of composition, radiopharmaceutical labelling of relevant inflammation of blood vessel grumeleuse, radiopharmaceutical labelling of malignant tumor, radiopharmaceutical labelling from the benign tumor that comprises the radiopharmaceutical labelling, radiopharmaceutical labelling and radiopharmaceutical labelling.

15. according to the method for claim 13, wherein radioactive emission detector is to select from the radioactivity seeker that comprises a low-angle radioactive emission detector, wide angle radioactive emission detector, a plurality of independent low-angle radioactive emission detector and a space sensitive.

16. according to the method for claim 13, wherein positioning control system be from comprise a joint arm positioning control system, positioning control system, one based on accelerometer based on potentiometric positioning control system, positioning control system, positioning control system based on radio frequency based on sound wave, one based on the positioning control system in magnetic field and one based on selecting the optical positioning control system.

17. a system is used to calculate the position of a patient's body organ and the radiopharmaceutical picked-up position partly of organ, this system comprises:

A) the three-dimensional imaging Medical Instruments that links to each other and/or communicate with a primary importance tracking system is used for calculating the position of organ in first coordinate system;

B) radioactive emission detector that links to each other and/or communicate with second position system, the position of radiopharmaceutical picked-up part in second coordinate system that is used for following the tracks of organ; With

C) at least one data processor, be designed and be configured to be used for from above-mentioned three-dimensional imaging instrument, primary importance tracking system, radioactive emission detector and second position tracking system, to receive the data input, and calculate the position of radiopharmaceutical picked-up part in a common coordinate system system of organ and organ.

18. according to the system of claim 17, wherein first coordinate system is used as common coordinate system, so the position of the radiopharmaceutical of organ picked-up part in second coordinate system is projected on this first coordinate system.

19. according to the system of claim 17, wherein second coordinate system is used as common coordinate system, so the position of organ in first coordinate system is projected on this second coordinate system.

20. according to the system of claim 17, wherein first coordinate system, second coordinate system and common coordinate system system are single coordinate systems.

21. system according to claim 17, wherein each of first coordinate system, second coordinate system and common coordinate system system all is a coordinate system independently, thus the radiopharmaceutical of organ picked-up part in first coordinate system the position and the position of radiopharmaceutical picked-up part in second coordinate system of organ all be projected on the common coordinate system system.

22. according to the system of claim 17, wherein primary importance tracking system and second position tracking system are single positioning control systems.

23., wherein communicate between Image-forming instrument and a image display apparatus as the collaborative expression visually of the radiopharmaceutical picked-up part of organ and this organ according to the system of claim 17.

24. according to the system of claim 17, wherein radioactive emission detector is to select from the radioactivity seeker of a low-angle radioactive emission detector, wide angle radioactive emission detector, a plurality of independent low-angle radioactive emission detector and a space sensitive.

25. according to the system of claim 17, wherein positioning control system be from a joint arm positioning control system, positioning control system, one based on accelerometer based on potentiometric positioning control system, positioning control system, positioning control system based on radio frequency based on sound wave, one based on the positioning control system in magnetic field and one based on selecting the optical positioning control system.

26. according to the system of claim 17, wherein Image-forming instrument is selected from comprise fluoroscope, computerization tomography shadowgraph device, NMR imaging equipment, ultrasonic imaging device and photographic camera.

27. according to the system of claim 17, wherein radiopharmaceutical agent is from comprising ¹³¹I, ⁶⁷Ga, ^99MTc contain methoxyl group the isobutyl group isonitrile, ²⁰¹TICI, ¹⁸The fluorine-based deoxyglucose of F-, ¹²⁵The I-Fibrinogen and ¹¹¹Select among the In-octreotide.

28. a method is used to calculate the position of a patient's body organ and the radiopharmaceutical picked-up position partly of organ, the step that this method comprises has:

A) provide the three-dimensional imaging Medical Instruments that links to each other and/or communicate with a primary importance tracking system, be used for calculating the position of organ in first coordinate system;

B) provide a radioactive emission detector that links to each other and/or communicate with second position tracking system, be used for following the tracks of the position of radiopharmaceutical picked-up part in second coordinate system of organ; With

C) from above-mentioned three-dimensional imaging instrument, primary importance tracking system, radioactive emission detector and second position tracking system, receive the data input, and calculate the position of radiopharmaceutical picked-up part in a common coordinate system system of organ and organ.

29. according to the method for claim 28, wherein first coordinate system is used as common coordinate system, so the position of the radiopharmaceutical of organ picked-up part in second coordinate system is projected on this first coordinate system.

30. according to the method for claim 28, wherein second coordinate system is used as common coordinate system, so the position of organ in first coordinate system is projected on this second coordinate system.

31. according to the system of claim 28, wherein first coordinate system, second coordinate system and common coordinate system system are single coordinate systems.

32. method according to claim 28, wherein each of first coordinate system, second coordinate system and common coordinate system system all is a coordinate system independently, thus organ in first coordinate system the position and the position of radiopharmaceutical picked-up part in second coordinate system of organ all be projected on the common coordinate system system.

33. according to the method for claim 28, wherein primary importance tracking system and second position tracking system are single positioning control systems.

34., wherein communicate between Image-forming instrument and a image display apparatus as the collaborative expression visually of the radiopharmaceutical picked-up part of organ and this organ according to the method for claim 28.

35. according to the method for claim 28, wherein radioactive emission detector is to select from the radioactivity seeker that comprises a low-angle radioactive emission detector, wide angle radioactive emission detector, a plurality of independent low-angle radioactive emission detector and a space sensitive.

36. according to the method for claim 28, wherein positioning control system be from comprise a joint arm positioning control system, positioning control system, one based on accelerometer based on potentiometric positioning control system, positioning control system, positioning control system based on radio frequency based on sound wave, one based on the positioning control system in magnetic field and one based on selecting the optical positioning control system.

37. according to the method for claim 28, wherein Image-forming instrument is selected from comprise fluoroscope, computerization tomography shadowgraph device, NMR imaging equipment, ultrasonic imaging device and photographic camera.

38. according to the method for claim 28, wherein radiopharmaceutical agent be from ¹³¹I, ⁶⁷Ga, ^99MTc contain methoxyl group the isobutyl group isonitrile, ²⁰¹TICI, ¹⁸The fluorine-based deoxyglucose of F-, ¹²⁵The I-Fibrinogen and ¹¹¹Select among the In-octreotide.

39. a system is used for carrying out an individual Medicine and Surgery operation in the radiopharmaceutical picked-up part of a patient's body organ, this system comprises:

A) radioactive emission detector links to each other with the primary importance tracking system and communicates with, and is used for following the tracks of the position of radiopharmaceutical picked-up part in first coordinate system of organ.

B) surgical instrument links to each other with second position tracking system and communicates with, and is used for following the tracks of the position of surgical instrument in second coordinate system.

C) at least one data processor, be designed and be configured to be used for from above-mentioned primary importance tracking system, radioactive emission detector and second position tracking system, to receive the data input, and calculate the position of radiopharmaceutical picked-up part in a common coordinate system system of surgical instrument and organ.

40. system according to claim 39, wherein surgical instrument comprises an additional radioactive emission detector, and at least one above-mentioned data processor further is designed and is configured to be used for from this additional radioactive emission detector to receive the data input, determines the position of radiopharmaceutical picked-up part in the common coordinate system system of organ more accurately.

41. according to the system of claim 39, wherein second coordinate system is used as common coordinate system, so the position of surgical instrument in first coordinate system is projected on this second coordinate system.

42. according to the method for claim 39, wherein first coordinate system is used as common coordinate system, so the position of the radiopharmaceutical of organ picked-up part in second coordinate system is projected on this first coordinate system.

43. according to the system of claim 39, wherein first coordinate system, second coordinate system and common coordinate system system are single coordinate systems.

44. system according to claim 39, wherein each of second coordinate system, first coordinate system and common coordinate system system all is a coordinate system independently, thus surgical instrument in second coordinate system the position and the position of radiopharmaceutical picked-up part in first coordinate system of organ all be projected on the common coordinate system system.

45. according to the system of claim 39, wherein primary importance tracking system and second position tracking system are single positioning control systems.

46. according to the system of claim 39, further comprise an image display apparatus, be used for the position of the radiopharmaceutical picked-up part of collaborative this surgical instrument of expression and this organ.

47. according to the system of claim 39, wherein radioactive emission detector is to select from the radioactivity seeker that comprises a low-angle radioactive emission detector, wide angle radioactive emission detector, a plurality of independent low-angle radioactive emission detector and a space sensitive.

48. according to the system of claim 39, wherein positioning control system be from comprise a joint arm positioning control system, positioning control system, one based on accelerometer based on potentiometric positioning control system, positioning control system, positioning control system based on radio frequency based on sound wave, one based on the positioning control system in magnetic field and one based on selecting the optical positioning control system.

49. according to the system of claim 39, wherein surgical instrument is selected from comprise laser microprobe, cardiac catheter, cardiovascular plastic catheter, splanchnoscopy probe, biopsy needle, ultrasonic probe, optical fiber scope, suction tube, laparoscopy probe, thermoprobe and suction probe.For open surgical operation, need to increase an indicating device.

50. according to the method for claim 39, wherein radiopharmaceutical agent is from comprising ¹³¹I, ⁶⁷Ga, ^99MTc contain methoxyl group the isobutyl group isonitrile, ²⁰¹TICI, ¹⁸The fluorine-based deoxyglucose of F-, ¹²⁵The I-Fibrinogen and ¹¹¹Select among the In-octreotide.

51. according to the method for claim 39, further comprise a three-dimensional imaging instrument that links to each other and/or communicate with the 3rd positioning control system, be used for calculating the position of organ in system of 3 axes.

52. method according to claim 51, wherein data processor further is designed and is configured to be used for to receive the data input from above-mentioned three-dimensional imaging instrument and the 3rd positioning control system, calculates the radiopharmaceutical picked-up part and the position of organ in a common coordinate system system of above-mentioned surgery instrument and organ.

53. system according to claim 52, wherein second coordinate system is used as common coordinate system, so position and organ the position in system of 3 axes of the radiopharmaceutical of organ picked-up part in first coordinate system is projected on this second coordinate system.

54. according to the system of claim 52, wherein first coordinate system is used as common coordinate system, so position and organ the position in system of 3 axes of surgical instrument in second coordinate system is projected on this first coordinate system.

55. system according to claim 52, wherein system of 3 axes is as common coordinate system, surgical instrument in second coordinate system the position and the position of radiopharmaceutical picked-up part in first coordinate system of organ be projected on this system of 3 axes.

56. according to the system of claim 52, wherein unify common coordinate system system of first coordinate system, second coordinate system, three-coordinate is single coordinate system.

57. system according to claim 52, wherein unify each of common coordinate system system of second coordinate system, first coordinate system, three-coordinate all is a coordinate system independently, so the position of surgical instrument in second coordinate system, position and organ the position in system of 3 axes of radiopharmaceutical picked-up part in first coordinate system of organ all are projected on the common coordinate system system.

58. according to the system of claim 51, wherein primary importance tracking system, second position tracking system and the 3rd positioning control system are single positioning control systems.

59. according to the system of claim 51, further comprise an image display apparatus, be used for the radiopharmaceutical picked-up part of collaborative this surgical instrument of expression and organ and the position of organ.

60. according to the system of claim 51, wherein Image-forming instrument is selected from comprise fluoroscope, computerization tomography shadowgraph device, NMR imaging equipment, ultrasonic imaging device and photographic camera.

61. according to the system of claim 51, wherein positioning control system be from a joint arm positioning control system, positioning control system, one based on accelerometer based on potentiometric positioning control system, positioning control system, positioning control system based on radio frequency based on sound wave, one based on the positioning control system in magnetic field and one based on selecting the optical positioning control system.

62. a method is used for carrying out an individual Medicine and Surgery operation in the radiopharmaceutical picked-up part of a patient's body organ, the step that this method comprises has:

A) provide a radioactive emission detector, link to each other with the primary importance tracking system and communicate with, be used for following the tracks of the position of radiopharmaceutical picked-up part in first coordinate system of organ.

B) provide a kind of surgical instrument, link to each other with second position tracking system and communicate with, be used for following the tracks of when carrying out the operation of inside and outside section the position of surgical instrument in second coordinate system.

C) when carrying out the operation of inside and outside section, from above-mentioned primary importance tracking system, radioactive emission detector and second position tracking system, receive the data input, and calculate the position of radiopharmaceutical picked-up part in a common coordinate system system of surgical instrument, organ and organ.

63. method according to claim 62, wherein surgical instrument comprises an additional radioactive emission detector, and at least one above-mentioned data processor is further designed and be configured to be used for from this additional radioactive emission detector receive the data input position of the part of the radiopharmaceutical of definite organ picked-up more accurately in the common coordinate system system.

64. according to the method for claim 62, wherein second coordinate system is used as common coordinate system, so the position of the radiopharmaceutical of organ picked-up part in first coordinate system is projected on this second coordinate system.

65. according to the method for claim 62, wherein first coordinate system is used as common coordinate system, so the position of surgical instrument in second coordinate system is projected on this first coordinate system.

66. according to the method for claim 62, wherein first coordinate system, second coordinate system and common coordinate system system are single coordinate systems.

67. method according to claim 62, wherein each of first coordinate system, second coordinate system and common coordinate system system all is a coordinate system independently, thus surgical instrument in second coordinate system the position and the position of radiopharmaceutical picked-up part in first coordinate system of organ all be projected on the common coordinate system system.

68. according to the method for claim 62, wherein primary importance tracking system and second position tracking system are single positioning control systems.

69. according to the method for claim 62, further comprise an image display apparatus, be used for the position of the radiopharmaceutical picked-up part of collaborative this surgical instrument of expression and organ position and this organ.

70. according to the method for claim 62, wherein radioactive emission detector is to select from the radioactivity seeker that comprises a low-angle radioactive emission detector, wide angle radioactive emission detector, a plurality of independent low-angle radioactive emission detector and a space sensitive.

71. according to the method for claim 62, wherein positioning control system be from comprise a joint arm positioning control system, positioning control system, one based on accelerometer based on potentiometric positioning control system, positioning control system, positioning control system based on radio frequency based on sound wave, one based on the positioning control system in magnetic field and one based on selecting the optical positioning control system.

72. according to the method for claim 62, wherein surgical instrument is selected from comprise laser microprobe, cardiac catheter, cardiovascular plastic catheter, splanchnoscopy probe, biopsy needle, ultrasonic probe, optical fiber scope, suction tube, laparoscopy probe, thermoprobe and suction probe.

73. according to the method for claim 62, wherein radiopharmaceutical agent is from comprising ¹³¹I, ⁶⁷Ga, ^99MTc contain methoxyl group the isobutyl group isonitrile, ²⁰¹TICI, ¹⁸The fluorine-based deoxyglucose of F-, ¹²⁵The I-Fibrinogen and ¹¹¹Select among the In-octreotide.

74. according to the method for claim 62, further comprise the step that a three-dimensional imaging instrument is provided, this three-dimensional imaging power device links to each other with the 3rd positioning control system and/or communicates with, and is used for calculating the position of organ in system of 3 axes.

75. method according to claim 74, further comprise from above-mentioned three-dimensional imaging instrument and the 3rd positioning control system receiving the data input, calculate the radiopharmaceutical picked-up part of above-mentioned surgery instrument and organ and the step of the position of organ in a common coordinate system system.

76. according to the method for claim 74, wherein primary importance tracking system, second position tracking system and the 3rd positioning control system are single positioning control systems.

77., further comprise by the position of a visual device collaborative expression surgical instrument and organ and the radiopharmaceutical of this organ and absorb the step of the position of part according to the method for claim 74.

78. according to the method for claim 74, wherein Image-forming instrument is selected from comprise fluoroscope, computerization tomography shadowgraph device, NMR imaging equipment, ultrasonic imaging device and photographic camera.

79. according to the method for claim 74, wherein positioning control system be from comprise a joint arm positioning control system, positioning control system, one based on accelerometer based on potentiometric positioning control system, positioning control system, positioning control system based on radio frequency based on sound wave, one based on the positioning control system in magnetic field and one based on selecting the optical positioning control system.

80. method according to claim 75, wherein second coordinate system is used as common coordinate system, so position and organ the position in system of 3 axes of the radiopharmaceutical of organ picked-up part in first coordinate system is projected on this second coordinate system.

81. according to the method for claim 75, wherein first coordinate system is used as common coordinate system, so position and organ the position in system of 3 axes of surgical instrument in second coordinate system is projected on this first coordinate system.

82. method according to claim 75, wherein system of 3 axes is as common coordinate system, surgical instrument in second coordinate system the position and the position of radiopharmaceutical picked-up part in first coordinate system of organ be projected on this system of 3 axes.

83. according to the method for claim 75, wherein unify common coordinate system system of first coordinate system, second coordinate system, three-coordinate is single coordinate system.

84. method according to claim 75, wherein unify each of common coordinate system system of first coordinate system, second coordinate system, three-coordinate all is a coordinate system independently, so the position of surgical instrument in second coordinate system, position and organ the position in system of 3 axes of radiopharmaceutical picked-up part in first coordinate system of organ all are projected on the common coordinate system system.

85. the two dimension of a radioactive radiation source that is used for producing human body or the system of 3-D view, this system comprises:

A) radioactive emission detector;

B) positioning control system that links to each other and/or communicate with this radioactive emission detector; With

C) data processor is designed and is configured to be used for to receive the data input from this positioning control system and radioactive emission detector, produces the two dimension or the 3-D view of this radioactive emission detector.

86. a method is used for producing the two dimension of a radioactive radiation source of human body or the system of 3-D view, this method comprises:

A) utilize a radioactive emission detector that human body is scanned;

B) use a positioning control system that links to each other and/or communicate with this radioactive emission detector, determine the position of this radioactive emission detector in a three-dimensional coordinate system; With

C), produce the two dimension or the 3-D view of this radioactive radiation source from this positioning control system and the input of radioactive emission detector date processing.

87. one is used for calculating the system of a radioactive radiation source in the position of a coordinate system, this system comprises:

A) at least two radioactive emission detectors;

B) positioning control system that links to each other with this radioactive emission detector and/or communicate with and

C) data processor is designed and is configured to be used for to receive the data input from this positioning control system and at least two above-mentioned radioactive emission detectors, calculates the position of radioactive radiation source in a coordinate system.

88. according to the system of claim 87, wherein above-mentioned at least two radioactive emission detectors are interconnective physically by a flexible connector.

89. a method is used for determining a radioactive radiation source in the position of a coordinate system, the step that this method comprises has:

A) radioactive emission detector that provides at least one to link to each other and/or communicate with positioning control system; With

B) monitoring simultaneously, is monitored this position of at least one radioactive emission detector in coordinate system from the radioactivity that radioactive radiation source sends, and determines the position of this radioactive radiation source in coordinate system thus.

90., wherein provide above-mentioned at least two radioactive emission detectors according to the method for claim 89.

91. according to the method for claim 89, wherein above-mentioned at least two radioactive emission detectors are interconnective physically by a flexible connector.

92. a system is used for calculating the position of radioactive radiation source one the first coordinate decorum, and further this position is projected on one second coordinate system, this system comprises:

A) at least two radioactive emission detectors;

B) positioning control system that links to each other with above-mentioned at least two radioactive emission detectors and/or communicate with and

C) data processor is designed and is configured to be used for

I. receive the data input from this positioning control system and at least two above-mentioned radioactive emission detectors;

Ii. calculate radioactive radiation source in first coordinate system the position and

Iii. the position with radioactive radiation source projects on second coordinate system.

93. according to the system of claim 92, wherein above-mentioned at least two radioactive emission detectors are interconnective physically by a flexible connector.

94. a method is used for calculating a radioactive radiation source in the position of one first coordinate system, and this position is projected on one second coordinate system, the step that this method comprises has:

A) radioactive emission detector that provides at least one and a positioning control system to link to each other and/or communicate with; With

B) monitor the radioactivity of sending from radioactive radiation source, simultaneously, monitor this position of at least one radioactive emission detector in first coordinate system, determine the position of this radioactive radiation source in first coordinate system thus, and this position is projected on second coordinate system.

95. system, be used for carrying out an individual Medicine and Surgery operation in the radiopharmaceutical picked-up part of a patient's body organ, this system comprises a surgical instrument, link to each other with a positioning control system and communicate with, be used for following the tracks of the position of this surgical instrument in a coordinate system, this surgical instrument comprises a coupled radioactive emission detector, is used for monitoring on the spot radiopharmaceutical.

96. according to the system of claim 95, wherein this radioactive emission detector is to β ray and positron radiation-sensitive.

97. according to the system of claim 95, wherein surgical instrument comprises a device for cutting tissue.

98. according to the system of claim 95, wherein surgical instrument comprises a tissue sampling device.

99. according to the system of claim 95, wherein tissue sampling device comprises an aspirator.

100. a system that is used for calculating the position of a radioactive radiation source in a coordinate system, this system comprises

A) surgical instrument is designed and is configured to be used for entering patient's body, this surgical instrument comprise one coupled or be integrated in wherein radioactive emission detector;

B) positioning control system that links to each other and communicate with this surgical instrument; With

C) data processor is designed and is configured to be used for to receive the data input from above-mentioned positioning control system and radioactive emission detector, and calculates the position of radioactive radiation source in coordinate system.

101. according to the system of claim 100, wherein radioactive radiation source is to select the aberrant angiogenesis of the abscess of composition, radiopharmaceutical labelling of relevant inflammation of blood vessel grumeleuse, radiopharmaceutical labelling of malignant tumor, radiopharmaceutical labelling from the benign tumor that comprises the radiopharmaceutical labelling, radiopharmaceutical labelling and radiopharmaceutical labelling.

102. according to the system of claim 100, wherein radioactive emission detector is a low-angle radioactive emission detector or a wide angle radioactive emission detector.

103. according to the system of claim 100, wherein positioning control system be from comprise a joint arm positioning control system, positioning control system, one based on accelerometer based on potentiometric positioning control system, positioning control system, positioning control system based on radio frequency based on sound wave, one based on the positioning control system in magnetic field and one based on selecting the optical positioning control system.

104. a system is used for calculating the position of radioactive radiation source one the first coordinate decorum, and further this position is projected on one second coordinate system, this system comprises:

A) surgical instrument is designed and is configured to be used for entering patient's body, and this surgical instrument comprises coupled or integrated wherein a radioactive emission detector;

B) positioning control system that links to each other and/or communicate with above-mentioned surgical instrument; With

C) data processor is designed and is configured to be used for

I. receive the data input from this positioning control system and radioactive emission detector;

Ii. calculate the position of radioactive radiation source in first coordinate system;

Iii. calculate the position of surgical instrument in first coordinate system; With

Iv. the position with radioactive radiation source and surgical instrument projects on one second coordinate system.

105. according to the system of claim 104, wherein radioactive radiation source is to select the aberrant angiogenesis of the abscess of composition, radiopharmaceutical labelling of relevant inflammation of blood vessel grumeleuse, radiopharmaceutical labelling of malignant tumor, radiopharmaceutical labelling from the benign tumor that comprises the radiopharmaceutical labelling, radiopharmaceutical labelling and radiopharmaceutical labelling.

106. according to the system of claim 104, wherein radioactive emission detector is a low-angle radioactive emission detector or a wide angle radioactive emission detector.

107. according to the system of claim 104, wherein positioning control system be from comprise a joint arm positioning control system, positioning control system, one based on accelerometer based on potentiometric positioning control system, positioning control system, positioning control system based on radio frequency based on sound wave, one based on the positioning control system in magnetic field and one based on selecting the optical positioning control system.

108. a method is used for calculating the position of radioactive radiation source one the first coordinate decorum, and this position is projected on one second coordinate system, the step that this method comprises has:

A) provide a surgical instrument, design and structure are used for entering patient's body, this surgical instrument comprise one coupled or be integrated in wherein radioactive emission detector, this surgical instrument links to each other with a positioning control system and/or communicates with; With

B) monitor the radioactivity of sending from radioactive radiation source, simultaneously, the position of monitoring radioactive emission detector in first coordinate system, determine this radioactive radiation source and the position of surgical instrument in first coordinate system thus, and the position of this radioactive radiation source is projected on second coordinate system.

109. according to the system of claim 108, wherein radioactive radiation source is to select the aberrant angiogenesis of the abscess of composition, radiopharmaceutical labelling of relevant inflammation of blood vessel grumeleuse, radiopharmaceutical labelling of malignant tumor, radiopharmaceutical labelling from the benign tumor that comprises the radiopharmaceutical labelling, radiopharmaceutical labelling and radiopharmaceutical labelling.

110. according to the system of claim 108, wherein radioactive emission detector is a low-angle radioactive emission detector or a wide angle radioactive emission detector.

111. according to the system of claim 108, wherein positioning control system be from comprise a joint arm positioning control system, positioning control system, one based on accelerometer based on potentiometric positioning control system, positioning control system, positioning control system based on radio frequency based on sound wave, one based on the positioning control system in magnetic field and one based on selecting the optical positioning control system.

112. a system is used to calculate the position of a patient's body organ and the radiopharmaceutical picked-up position partly of organ, this system comprises:

A) the three-dimensional imaging Medical Instruments that links to each other and/or communicate with a primary importance tracking system is used for calculating the position of organ in first coordinate system;

B) design and construct a shell surgical unit, be used to enter patient's body, described shell surgical unit comprise one coupled or be integrated in wherein radioactive emission detector, described surgical instrument is used for following the tracks of the position of radiopharmaceutical picked-up part in second coordinate system of organ; With

C) at least one data processor, be designed and be configured to be used for from above-mentioned three-dimensional imaging instrument, primary importance tracking system, radioactive emission detector and second position tracking system, to receive the data input, and calculate the radiopharmaceutical picked-up part and the position of surgical instrument in a common coordinate system system of organ and organ.

113. according to the system of claim 112, wherein first coordinate system is used as common coordinate system, so the position of the radiopharmaceutical of organ picked-up part in second coordinate system is projected on this first coordinate system.

114. according to the system of claim 112, wherein second coordinate system is as common coordinate system, so organ and the position of surgical instrument in first coordinate system are projected on this second coordinate system.

115. according to the system of claim 112, wherein first coordinate system, second coordinate system and common coordinate system system are single coordinate systems.

116. system according to claim 112, wherein each of first coordinate system, second coordinate system and common coordinate system system all is a coordinate system independently, so the radiopharmaceutical of the position in first coordinate system of organ and organ picked-up part and the position of surgical instrument in second coordinate system all are projected on common coordinate system unites.

117. according to the system of claim 112, wherein primary importance tracking system and second position tracking system are single positioning control systems.

118., wherein communicate between Image-forming instrument and a image display apparatus as the collaborative expression visually of the radiopharmaceutical picked-up part of organ and this organ according to the system of claim 112.

119. according to the system of claim 112, wherein radioactive emission detector is low-angle radioactive emission detector or a wide angle radioactive emission detector.

120. according to the system of claim 112, wherein positioning control system be from comprise a joint arm positioning control system, positioning control system, one based on accelerometer based on potentiometric positioning control system, positioning control system, positioning control system based on radio frequency based on sound wave, one based on the positioning control system in magnetic field and one based on selecting the optical positioning control system.

121. according to the system of claim 112, wherein Image-forming instrument is selected from comprise fluoroscope, computerization tomography shadowgraph device, NMR imaging equipment, ultrasonic imaging device and photographic camera.

122. according to the system of claim 112, wherein radiopharmaceutical agent is from comprising 2-[ ¹⁸F] the fluoro-2-deoxy-D-glucose, ¹¹¹In-Pentetreotide, L-3-[ ¹²³I]-Iodo-alpha-methyl-tyrosine, O-(2-[ ¹⁸F] the fluoroethane base)-L-tyrosine, ¹¹¹In-CapromabPendetide and ¹¹¹Select among the In-Satumomab Pendetide.

123. a method is used to calculate the position of a patient's body organ and the radiopharmaceutical picked-up position partly of the interior organ of patient's body, the step that this method comprises:

A) provide a three-dimensional imaging Medical Instruments that links to each other and/or communicate with a primary importance tracking system, be used for calculating the position of organ in first coordinate system;

B) provide a surgical instrument, be designed and be configured to be used for entering patient's body, this surgical instrument comprise one coupled or be integrated in wherein radioactive emission detector, this surgical instrument links to each other with a second position tracking system and/or communicates with, and follows the tracks of the position of the radiopharmaceutical picked-up part of organ in the second coordinate system kind; With

C) receive the data input from above-mentioned three-dimensional imaging instrument, primary importance tracking system, radioactive emission detector and second position tracking system, and calculate the position of radiopharmaceutical picked-up part in a common coordinate system system of organ, surgical instrument and organ.

124. according to the method for claim 123, wherein first coordinate system is used as common coordinate system, so the radiopharmaceutical of organ is absorbed part and the position of surgical instrument in second coordinate system is projected on this first coordinate system.

125. according to the method for claim 123, wherein second coordinate system is used as common coordinate system, so the position of organ in first coordinate system is projected on this second coordinate system.

126. according to the method for claim 123, wherein first coordinate system, second coordinate system and common coordinate system system are single coordinate systems.

127. method according to claim 113, wherein each of first coordinate system, second coordinate system and common coordinate system system all is a coordinate system independently, thus organ in first coordinate system the position and the position of position in second coordinate system of the radiopharmaceutical picked-up part of organ all be projected on the common coordinate system system.

128. according to the method for claim 113, wherein primary importance tracking system and second position tracking system are single positioning control systems.

129. according to the method for claim 113, wherein Image-forming instrument and a radiopharmaceutical picked-up part and visually the working in coordination with between the image display apparatus of representing of surgical instrument as organ, this organ communicate.

130. according to the method for claim 113, wherein radioactive emission detector is low-angle radioactive emission detector or a wide angle radioactive emission detector.

131. according to the method for claim 113, wherein positioning control system be from comprise a joint arm positioning control system, positioning control system, one based on accelerometer based on potentiometric positioning control system, positioning control system, positioning control system based on radio frequency based on sound wave, one based on the positioning control system in magnetic field and one based on selecting the optical positioning control system.

132. according to the method for claim 113, wherein Image-forming instrument is selected from comprise fluoroscope, computerization tomography shadowgraph device, NMR imaging equipment, ultrasonic imaging device and photographic camera.

133. according to the method for claim 113, wherein radiopharmaceutical agent is from comprising 2-[ ¹⁸F] the fluoro-2-deoxy-D-glucose, ¹¹¹In-Pentetreotide, L-3-[ ¹²³I]-Iodo-alpha-methyl-tyrosine, 0-(2-[ ¹⁸F] the fluoroethane base)-L-tyrosine, ¹¹¹In-CapromabPendetide and ¹¹¹Select among the In-Satumomab Pendetide.

134. system according to claim 1, wherein data processor is applicable to the counting rate of radioactive emission detector and the positional information of positioning control system is merged, and is applicable to the radiotracer distribution image of formation comprising the target area of radioactive radiation source.

135. according to the system of claim 134, further comprise a memorizer, be applicable to stored position information and counting rate.

136. according to the system of claim 134, further comprise a display, be suitable for above-mentioned positional information and counting rate are shown as figure corresponding to the labelling of this positional information and counting rate.

137. according to the system of claim 134, wherein data processor is suitable for handling above-mentioned counting rate and positional information.

138. according to the system of claim 137, wherein coordinate system comprises orthogonal linear axis X, Y and Z, and rotates ρ, θ and φ respectively around X, Y and Z, wherein in this coordinate system, position of detector information is defined as (Xc, Yc, Zc, ρ, θ, φ), DCR is defined as N (Xc, Yc, Zc, ρ, θ, φ), the physical size of detector be defined as (dx, dy, dz); In addition, wherein data processor is suitable for amassing by searching the expression detector body, is defined as Xc+dx, Yc+dy, all of Zc+dz are called as the body image element of three-dimensional pixel, determine each three-dimensional pixel of expression fall into a trap M (Xc+dx, the Yc+dy of digit rate and the calculated number of times of positional information, Zc+dz), with according to N (Xc+dx, Yc+dy, Zc+dz)=[N (Xc+dx, Yc+dy, Zc+dz)+N (Xc, Yc, Zc, ρ, θ, φ)]/[M (Xc+dx, Yc+dy, Zc+dz)+1] calculate average counter rate in each three-dimensional pixel, ask for the meansigma methods of counting rate and positional information.

139. according to the system of claim 137, wherein coordinate system comprises orthogonal linear axis X, Y and Z, and rotates ρ, θ and φ respectively around X, Y and Z, wherein in this coordinate system, position of detector information is defined as (Xc, Yc, Zx, ρ, θ, φ), DCR is defined as N (Xx, Yc, Zc, ρ, θ, φ), the physical size of detector be defined as (dx, dy, dz); In addition, wherein data processor is suitable for amassing by searching the expression detector body, is defined as Xc+dx, Yc+dy, all of Zc+dz are called as the body image element of three-dimensional pixel, search those and have than the DCR N (Zc that imports, Yc, Zc, ρ, θ, φ) the three-dimensional pixel of high counting rate and these three-dimensional pixels with higher counting rate are changed into DCR N (Xc with input, Yc, Zc, ρ, θ, three-dimensional pixel φ) minimizes counting rate and positional information.

140. system according to claim 9, wherein data processor is applicable to the counting rate of radioactive emission detector and the positional information of positioning control system is merged, and is applicable to the radiotracer distribution image of formation comprising the target area of radioactive radiation source.

141. according to the system of claim 140, further comprise a memorizer, be applicable to stored position information and counting rate.

142. according to the system of claim 140, further comprise a display, be suitable for above-mentioned positional information and counting rate are shown as figure corresponding to the labelling of this positional information and counting rate.

143. according to the system of claim 140, wherein data processor is suitable for handling above-mentioned counting rate and positional information.

144. according to the system of claim 143, wherein coordinate system comprises orthogonal linear axis X, Y and Z, and rotates ρ, θ and φ respectively around X, Y and Z, wherein in this coordinate system, position of detector information is defined as (Xc, Yc, Zc, ρ, θ, φ), DCR is defined as N (Xc, Yc, Zc, ρ, θ, φ), the physical size of detector be defined as (dx, dy, dz); In addition, wherein data processor is suitable for amassing by searching the expression detector body, is defined as Zc+dx, Yc+dy, all of Zc+dz are called as the body image element of three-dimensional pixel, determine each three-dimensional pixel of expression fall into a trap M (Xc+dx, the Yc+dy of digit rate and the calculated number of times of positional information, Zc+dz), with according to N (Xc+dx, Yc+dy, Zc+dz)=[N (Xc+dx, Yc+dy, Zc+dz)+N (Xc, Yc, Zc, ρ, θ, φ)]/[M (Xc+dx, Yc+dy, Zc+dz)+1] calculate average counter rate in each three-dimensional pixel, ask for the meansigma methods of counting rate and positional information.

145. according to the system of claim 143, wherein coordinate system comprises orthogonal linear axis X, Y and Z, and rotates ρ, θ and φ respectively around X, Y and Z, wherein in this coordinate system, position of detector information is defined as (Xc, Yc, Zc, ρ, θ, φ), DCR is defined as N (Xc, Yc, Zc, ρ, θ, φ), the physical size of detector be defined as (dx, dy, dz); In addition, wherein data processor is suitable for amassing by searching the expression detector body, is defined as Xc+dx, Yc+dy, all of Zc+dz are called as the body image element of three-dimensional pixel, search those and have than the DCR N (Xc that imports, Yc, Zc, ρ, θ, φ) the three-dimensional pixel of high counting rate and these three-dimensional pixels with higher counting rate are changed into DCR N (Xc with input, Yc, Zc, ρ, θ, three-dimensional pixel φ) minimizes counting rate and positional information.

146. system according to claim 17, wherein at least one data processor is applicable to the counting rate of radioactive emission detector and the positional information of positioning control system is merged, and is applicable to the radiotracer distribution image of formation comprising the target area of radioactive radiation source.

147. according to the system of claim 146, further comprise a memorizer, be applicable to stored position information and counting rate.

148. according to the system of claim 146, further comprise a display, be suitable for above-mentioned positional information and counting rate are shown as figure corresponding to the labelling of this positional information and counting rate.

149. according to the system of claim 146, at least one wherein above-mentioned data processor is suitable for improving above-mentioned counting rate and positional information.

150. according to the system of claim 149, wherein coordinate system comprises orthogonal linear axis X, Y and Z, and rotates ρ, θ and φ respectively around X, Y and Z, wherein in this coordinate system, position of detector information is defined as (Xc, Yc, Zc, ρ, θ, φ), DCR is defined as N (Xc, Yc, Zc, ρ, θ, φ), the physical size of detector be defined as (dx, dy, dz); In addition, wherein data processor is suitable for amassing by searching the expression detector body, is defined as Xc+dx, Yc+dy, all of Zc+dz are called as the body image element of three-dimensional pixel, determine each three-dimensional pixel of expression fall into a trap M (Xc+dx, the Yc+dy of digit rate and the calculated number of times of positional information, Zc+dz), with according to N (Xc+dx, Yx+dy, Zc+dz)=[N (Xc+dx, Yc+dy, Zc+dz)+N (Xc, Yc, Zc, ρ, θ, φ)]/[M (Xx+dx, Yc+dy, Zc+dz)+1] calculate average counter rate in each three-dimensional pixel, ask for the meansigma methods of counting rate and positional information.

151. according to the system of claim 149, wherein coordinate system comprises orthogonal linear axis X, Y and Z, and rotates ρ, θ and φ respectively around X, Y and Z, wherein in this coordinate system, position of detector information is defined as (Xc, Yc, Zc, ρ, θ, φ), DCR is defined as N (Xc, Yc, Zc, ρ, θ, φ), the physical size of detector be defined as (dx, dy, dz); In addition, wherein data processor is suitable for amassing by searching the expression detector body, is defined as Xc+dx, Yc+dy, all of Zc+dz are called as the body image element of three-dimensional pixel, search those and have than the DCR N (Xc that imports, Yc, Zc, ρ, θ, φ) the three-dimensional pixel of high counting rate and these three-dimensional pixels with higher counting rate are changed into DCR N (Xc with input, Yc, Zc, ρ, θ, three-dimensional pixel φ) minimizes counting rate and positional information.

152. system according to claim 39, wherein above-mentioned at least one data processor is applicable to that the positional information with the counting rate of radioactive emission detector and positioning control system merges, and is applicable to the radiotracer distribution image of formation comprising the target area of radioactive radiation source.

153. according to the system of claim 152, further comprise a memorizer, be applicable to stored position information and counting rate.

154. according to the system of claim 152, further comprise a display, be suitable for above-mentioned positional information and counting rate are shown as figure corresponding to the labelling of this positional information and counting rate.

155. according to the system of claim 152, wherein data processor is suitable for handling above-mentioned counting rate and positional information.

156. according to the system of claim 155, wherein coordinate system comprises orthogonal linear axis X, Y and Z, and rotates ρ, θ and φ respectively around X, Y and Z, wherein in this coordinate system, position of detector information is defined as (Xc, Yc, Zc, ρ, θ, φ), DCR is defined as N (Xc, Yc, Zc, ρ, θ, φ), the physical size of detector be defined as (dx, dy, dz); In addition, wherein data processor is suitable for amassing by searching the expression detector body, is defined as Xc+dx, Yc+dy, all of Zc+dz are called as the body image element of three-dimensional pixel, determine each three-dimensional pixel of expression fall into a trap M (Xc+dx, the Yc+dy of digit rate and the calculated number of times of positional information, Zc+dz), with according to N (Xc+dx, Yc+dy, Zc+dz)=[N (Xc+dx, Yc+dy, Zc+dz)+N (Xc, Yc, Zc, ρ, θ, φ)]/[M (Xc+dx, Yc+dy, Zc+dz)+1] calculate average counter rate in each three-dimensional pixel, ask for the meansigma methods of counting rate and positional information.

157. according to the system of claim 155, wherein coordinate system comprises orthogonal linear axis X, Y and Z, and rotates ρ, θ and φ respectively around X, Y and Z, wherein in this coordinate system, position of detector information is defined as (Xc, Yc, Zc, ρ, θ, φ), DCR is defined as N (Xc, Yc, Zc, ρ, θ, φ), the physical size of detector be defined as (dx, dy, dz); In addition, wherein data processor is suitable for amassing by searching the expression detector body, is defined as Xc+dx, Yc+dy, all of Zc+dz are called as the body image element of three-dimensional pixel, search those and have than the DCR N (Xc that imports, Yc, Zc, ρ, θ, φ) the three-dimensional pixel of high counting rate and these three-dimensional pixels with higher counting rate are changed into DCR N (Xc with input, Yc, Zc, ρ, θ, three-dimensional pixel φ) minimizes counting rate and positional information.

158. system according to claim 85, wherein data processor is applicable to the counting rate of radioactive emission detector and the positional information of positioning control system is merged, and is applicable to the radiotracer distribution image of formation comprising the target area of radioactive radiation source.

159. according to the system of claim 158, further comprise a memorizer, be applicable to stored position information and counting rate.

160. according to the system of claim 158, further comprise a display, be suitable for above-mentioned positional information and counting rate are shown as figure corresponding to the labelling of this positional information and counting rate.

161. according to the system of claim 158, wherein data processor is suitable for handling above-mentioned counting rate and positional information.

162. according to the system of claim 161, wherein coordinate system comprises orthogonal linear axis X, Y and Z, and rotates ρ, θ and φ respectively around X, Y and Z, wherein in this coordinate system, position of detector information is defined as (Xc, Yc, Zc, ρ, θ, φ), DCR is defined as N (Xc, Yc, Zc, ρ, θ, φ), the physical size of detector be defined as (dx, dy, dz); In addition, wherein data processor is suitable for amassing by searching the expression detector body, is defined as Xc+dx, Yc+dy, all of Zc+dz are called as the body image element of three-dimensional pixel, determine each three-dimensional pixel of expression fall into a trap M (Xc+dx, the Yc+dy of digit rate and the calculated number of times of positional information, Zc+dz), with according to N (Xc+dx, Yc+dy, Zc+dz)=[N (Xc+dx, Yc+dy, Zc+dz)+N (Xc, Yc, Zc, ρ, θ, φ)]/[M (Xc+dx, Yc+dy, Zc+dz)+1] calculate average counter rate in each three-dimensional pixel, ask for the meansigma methods of counting rate and positional information.

163. according to the system of claim 161, wherein coordinate system comprises orthogonal linear axis X, Y and Z, and rotates ρ, θ and φ respectively around X, Y and Z, wherein in this coordinate system, position of detector information is defined as (Xc, Yc, Zc, ρ, θ, φ), DCR is defined as N (Xc, Yc, Zc, ρ, θ, φ), the physical size of detector be defined as (dx, dy, dz); In addition, wherein data processor is suitable for amassing by searching the expression detector body, is defined as Xc+dx, Yc+dy, all of Zc+dz are called as the body image element of three-dimensional pixel, search those and have than the DCR N (Xc that imports, Yc, Zc, ρ, θ, φ) the three-dimensional pixel of high counting rate and these three-dimensional pixels with higher counting rate are changed into DCR N (Xc with input, Yc, Zc, ρ, θ, three-dimensional pixel φ) minimizes counting rate and positional information.

164. system according to claim 87, wherein data processor is applicable to the counting rate of radioactive emission detector and the positional information of positioning control system is merged, and is applicable to the radiotracer distribution image of formation comprising the target area of radioactive radiation source.

165. according to the system of claim 164, further comprise a memorizer, be applicable to stored position information and counting rate.

166. according to the system of claim 164, further comprise a display, be suitable for above-mentioned positional information and counting rate are shown as figure corresponding to the labelling of this positional information and counting rate.

167. according to the system of claim 164, at least one wherein above-mentioned data processor is suitable for improving above-mentioned counting rate and positional information.

168. according to the system of claim 167, wherein coordinate system comprises orthogonal linear axis X, Y and Z, and rotates ρ, θ and φ respectively around X, Y and Z, wherein in this coordinate system, position of detector information is defined as (Xc, Yc, Zc, ρ, θ, φ), DCR is defined as N (Xc, Yc, Zc, ρ, θ, φ), the physical size of detector be defined as (dx, dy, dz); In addition, wherein data processor is suitable for amassing by searching the expression detector body, is defined as Xc+dx, Yc+dy, all of Zc+dz are called as the body image element of three-dimensional pixel, determine each three-dimensional pixel of expression fall into a trap M (Xc+dx, the Yc+dy of digit rate and the calculated number of times of positional information, Zc+dz), with according to N (Xc+dx, Yc+dy, Zc+dz)=[N (Xc+dx, Yc+dy, Zc+dz)+N (Xc, Yc, Zc, ρ, θ, φ)]/[M (Xc+dx, Yc+dy, Zc+dz)+1] calculate average counter rate in each three-dimensional pixel, ask for the meansigma methods of counting rate and positional information.

169. according to the system of claim 167, wherein coordinate system comprises orthogonal linear axis X, Y and Z, and rotates ρ, θ and φ respectively around X, Y and Z, wherein in this coordinate system, position of detector information is defined as (Xc, Yc, Zc, ρ, θ, φ), DCR is defined as N (Xc, Yc, Zc, ρ, θ, φ), the physical size of detector be defined as (dx, dy, dz); In addition, wherein data processor is suitable for amassing by searching the expression detector body, is defined as Xc+dx, Yc+dy, all of Zc+dz are called as the body image element of three-dimensional pixel, search those and have than the DCR N (Xc that imports, Yc, Zc, ρ, θ, φ) the three-dimensional pixel of high counting rate and these three-dimensional pixels with higher counting rate are changed into DCR N (Xc with input, Yc, Zc, ρ, θ, three-dimensional pixel φ) minimizes counting rate and positional information.

170. system according to claim 92, wherein data processor is applicable to the radiation detector counting rate of above-mentioned at least two radioactive emission detectors and the positional information of positioning control system is merged, and is applicable to the radiotracer distribution image of formation comprising the target area of radioactive radiation source.

171. according to the system of claim 170, further comprise a memorizer, be applicable to stored position information and counting rate.

172. according to the system of claim 170, further comprise a display, be suitable for above-mentioned positional information and counting rate are shown as figure corresponding to the labelling of this positional information and counting rate.

173. according to the system of claim 170, wherein data processor is suitable for handling above-mentioned counting rate and positional information.

174. according to the system of claim 173, wherein coordinate system comprises orthogonal linear axis X, Y and Z, and rotates ρ, θ and φ respectively around X, Y and Z, wherein in this coordinate system, above-mentioned at least two position of detector information are defined as (Xc, Yc, Zc, ρ, θ, φ), DCR is defined as N (Xc, Yc, Zc, ρ, θ, φ), the physical size of detector be defined as (dx, dy, dz); In addition, wherein data processor is suitable for amassing by searching the expression detector body, is defined as Xc+dx, Yc+dy, all of Zc+dz are called as the body image element of three-dimensional pixel, determine each three-dimensional pixel of expression fall into a trap M (Xc+dx, the Yc+dy of digit rate and the calculated number of times of positional information, Zc+dz), with according to N (Xc+dx, Yc+dy, Zc+dz)=[N (Xc+dx, Yc+dy, Zc+dz)+N (Xc, Yc, Zc, ρ, θ, φ)]/[M (Xc+dx, Yc+dy, Zc+dz)+1] calculate average counter rate in each three-dimensional pixel, ask for the meansigma methods of counting rate and positional information.

175. according to the system of claim 173, wherein coordinate system comprises orthogonal linear axis X, Y and Z, and rotates ρ, θ and φ respectively around X, Y and Z, wherein in this coordinate system, these at least two position of detector information are defined as (Xc, Yc, Zc, ρ, θ, φ), DCR is defined as N (Xc, Yc, Zc, ρ, θ, φ), the physical size of detector be defined as (dx, dy, dz); In addition, wherein data processor is suitable for amassing by searching the expression detector body, is defined as Xc+dx, Yc+dy, all of Zc+dz are called as the body image element of three-dimensional pixel, search those and have than the DCR N (Xc that imports, Yc, Zc, ρ, θ, φ) the three-dimensional pixel of high counting rate and these three-dimensional pixels with higher counting rate are changed into DCR N (Xc with input, Yc, Zc, ρ, θ, three-dimensional pixel φ) minimizes counting rate and positional information.

176. system according to claim 95, further comprise a data processor, wherein this data processor is applicable to the radiation detector counting rate of radioactive emission detector and the positional information of positioning control system is merged, and is applicable to the radiotracer distribution image of formation comprising the target area of radioactive radiation source.

177. according to the system of claim 176, further comprise a memorizer, be applicable to stored position information and counting rate.

178. according to the system of claim 176, further comprise a display, be suitable for above-mentioned positional information and counting rate are shown as figure corresponding to the labelling of this positional information and counting rate.

179. according to the system of claim 176, wherein data processor is suitable for handling above-mentioned counting rate and positional information.

180. according to the system of claim 179, wherein coordinate system comprises orthogonal linear axis X, Y and Z, and rotates ρ, θ and φ respectively around X, Y and Z, wherein in this coordinate system, position of detector information is defined as (Xc, Yc, Zc, ρ, θ, φ), DCR is defined as N (Xc, Yc, Zc, ρ, θ, φ), the physical size of detector be defined as (dx, dy, dz); In addition, wherein data processor is suitable for amassing by searching the expression detector body, is defined as Xc+dx, Yc+dy, all of Zc+dz are called as the body image element of three-dimensional pixel, determine each three-dimensional pixel of expression fall into a trap M (Xc+dx, the Yc+dy of digit rate and the calculated number of times of positional information, Zc+dz), with according to N (Xc+dx, Yc+dy, Zc+dz)=[N (Xc+dx, Yc+dy, Zc+dz)+N (Xc, Yc, Zc, ρ, θ, φ)]/[M (Xc+dx, Yc+dy, Zc+dz)+1] calculate average counter rate in each three-dimensional pixel, ask for the meansigma methods of counting rate and positional information.

181. according to the system of claim 179, wherein coordinate system comprises orthogonal linear axis X, Y and Z, and rotates ρ, θ and φ respectively around X, Y and Z, wherein in this coordinate system, position of detector information is defined as (Xc, Yc, Zc, ρ, θ, φ), DCR is defined as N (Xc, Yc, Zc, ρ, θ, φ), the physical size of detector be defined as (dx, dy, dz); In addition, wherein data processor is suitable for amassing by searching the expression detector body, is defined as Xc+dx, Yc+dy, all of Zc+dz are called as the body image element of three-dimensional pixel, search those and have than the DCR N (Xc that imports, Yc, Zc, ρ, θ, φ) the three-dimensional pixel of high counting rate and these three-dimensional pixels with higher counting rate are changed into DCR N (Xc with input, Yc, Zc, ρ, θ, three-dimensional pixel φ) minimizes counting rate and positional information.

182. system according to claim 100, wherein data processor is applicable to the radiation detector counting rate of radioactive emission detector and the positional information of positioning control system is merged, and is applicable to the radiotracer distribution image of formation comprising the target area of radioactive radiation source.

183. according to the system of claim 18, further comprise a memorizer, be applicable to stored position information and counting rate.

184. according to the system of claim 182, further comprise a display, be suitable for above-mentioned positional information and counting rate are shown as figure corresponding to the labelling of this positional information and counting rate.

185. according to the system of claim 182, wherein data processor is suitable for handling above-mentioned counting rate and positional information.

186. according to the system of claim 185, wherein coordinate system comprises orthogonal linear axis X, Y and Z, and rotates ρ, θ and φ respectively around X, Y and Z, wherein in this coordinate system, position of detector information is defined as (Xc, Yc, Zc, ρ, θ, φ), DCR is defined as N (Xc, Yc, Zc, ρ, θ, φ), the physical size of detector be defined as (dx, dy, dz); In addition, wherein data processor is suitable for amassing by searching the expression detector body, is defined as Xc+dx, Yc+dy, all of Zc+dz are called as the body image element of three-dimensional pixel, determine each three-dimensional pixel of expression fall into a trap M (Xc+dx, the Yc+dy of digit rate and the calculated number of times of positional information, Zc+dz), with according to N (Xc+dx, Yc+dy, Zc+dz)=N (Xc+dx, Yc+dy, Zc+dz)+N (Xc, Yc, Zc, ρ, θ, φ)]/[M (Xc+dx, Yc+dy, Zc+dz)+1] calculate average counter rate in each three-dimensional pixel, ask for the meansigma methods of counting rate and positional information.

187. according to the system of claim 185, wherein coordinate system comprises orthogonal linear axis X, Y and Z, and rotates ρ, θ and φ respectively around X, Y and Z, wherein in this coordinate system, position of detector information is defined as (Xc, Yc, Zc, ρ, θ, φ), DCR is defined as N (Xc, Yc, Zc, ρ, θ, φ), the physical size of detector be defined as (dx, dy, dz); In addition, wherein data processor is suitable for amassing by searching the expression detector body, is defined as Xc+dx, Yc+dy, all of Zc+dz are called as the body image element of three-dimensional pixel, search those and have than the DCR N (Xc that imports, Yc, Zc, ρ, θ, φ) the three-dimensional pixel of high counting rate and these three-dimensional pixels with higher counting rate are changed into DCR N (Xc with input, Yc, Zc, ρ, θ, three-dimensional pixel φ) minimizes counting rate and positional information.

188. system according to claim 104, wherein data processor is applicable to the radiation detector counting rate of radioactive emission detector and the positional information of positioning control system is merged, and is applicable to the radiotracer distribution image of formation comprising the target area of radioactive radiation source.

189. according to the system of claim 188, further comprise a memorizer, be applicable to stored position information and counting rate.

190. according to the system of claim 188, further comprise a display, be suitable for above-mentioned positional information and counting rate are shown as figure corresponding to the labelling of this positional information and counting rate.

191. according to the system of claim 188, wherein data processor is suitable for handling above-mentioned counting rate and positional information.

192. according to the system of claim 191, wherein coordinate system comprises orthogonal linear axis X, Y and Z, and rotates ρ, θ and φ respectively around X, Y and Z, wherein in this coordinate system, position of detector information is defined as (Xc, Yc, Zc, ρ, θ, φ), DCR is defined as N (Xc, Yc, Zc, ρ, θ, φ), the physical size of detector be defined as (dx, dy, dz); In addition, wherein data processor is suitable for amassing by searching the expression detector body, is defined as Xc+dx, Yc+dy, all of Zc+dz are called as the body image element of three-dimensional pixel, determine each three-dimensional pixel of expression fall into a trap M (Xc+dx, the Yc+dy of digit rate and the calculated number of times of positional information, Zc+dz), with according to N (Xc+dx, Yc+dy, Zc+dz)=[N (dx+Xc, dy+Yc, Zc+dz)+N (Xc, Yc, Zc, ρ, θ, φ)]/[M (Xc+dx, Yc+dy, Zc+dz)+1] calculate average counter rate in each three-dimensional pixel, ask for the meansigma methods of counting rate and positional information.

193. according to the system of claim 191, wherein coordinate system comprises orthogonal linear axis X, Y and Z, and rotates ρ, θ and φ respectively around X, Y and Z, wherein in this coordinate system, position of detector information is defined as (Xc, Yc, Zc, ρ, θ, φ), DCR is defined as N (Xc, Yc, Zc, ρ, θ, φ), the physical size of detector be defined as (dx, dy, dz); In addition, wherein data processor is suitable for amassing by searching the expression detector body, is defined as Xc+dx, Yc+dy, all of Zc+dz are called as the body image element of three-dimensional pixel, search those and have than the DCR N (Xc that imports, Yc, Zc, ρ, θ, φ) the three-dimensional pixel of high counting rate and these three-dimensional pixels with higher counting rate are changed into DCR N (Xc with input, Yc, Zc, ρ, θ, three-dimensional pixel φ) minimizes counting rate and positional information.

194. system according to claim 112, wherein above-mentioned at least one data processor is applicable to that the positional information with the counting rate of radioactive emission detector and positioning control system merges, and is applicable to the radiotracer distribution image of formation comprising the target area of radioactive radiation source.

195. according to the system of claim 194, further comprise a memorizer, be applicable to stored position information and counting rate.

196. according to the system of claim 194, further comprise a display, be suitable for above-mentioned positional information and counting rate are shown as figure corresponding to the labelling of this positional information and counting rate.

197. according to the system of claim 194, wherein above-mentioned at least one data processor is suitable for improving above-mentioned counting rate and positional information.

198. according to the system of claim 197, wherein coordinate system comprises orthogonal linear axis X, Y and Z, and rotates ρ, θ and φ respectively around X, Y and Z, wherein in this coordinate system, position of detector information is defined as (Xc, Yc, Zc, ρ, θ, φ), DCR is defined as N (Xc, Yc, Zc, ρ, θ, φ), the physical size of detector be defined as (dx, dy, dz); In addition, wherein above-mentioned at least one data processor is suitable for by searching the expression detector body long-pending, is defined as Xc+dx, Yc+dy, all of Zc+dz are called as the body image element of three-dimensional pixel, determine each three-dimensional pixel of expression fall into a trap M (Xc+dx, the Yc+dy of digit rate and the calculated number of times of positional information, Zc+dz), with according to N (Zc+dx, Yc+dy, Zc+dz)=[N (dx+Xc, dy+Yc, Zc+dz)+N (Xc, Yc, Zc, ρ, θ, φ)]/[M (Xc+dx, Yc+dy, Zc+dz)+1] calculate average counter rate in each three-dimensional pixel, ask for the meansigma methods of counting rate and positional information.

199. according to the system of claim 197, wherein coordinate system comprises orthogonal linear axis X, Y and Z, and rotates ρ, θ and φ respectively around X, Y and Z, wherein in this coordinate system, position of detector information is defined as (Xc, Yc, Zc, ρ, θ, φ), DCR is defined as N (Xc, Yc, Zc, ρ, θ, φ), the physical size of detector be defined as (dx, dy, dz); In addition, wherein above-mentioned at least one data processor is suitable for by searching the expression detector body long-pending, be defined as Xc+dx, Yc+dy, all of Zc+dz are called as the body image element of three-dimensional pixel, search those and have than the DCR N (Xc that imports, Yc, Zc, ρ, θ, φ) the three-dimensional pixel of high counting rate, change into DCR N (Xc, Yc, Zc with the three-dimensional pixel that these is had higher counting rate with input, ρ, θ, three-dimensional pixel φ) minimizes counting rate and positional information.

200., further comprise the counting rate of radioactive emission detector and the positional information of positioning control system are merged, and formation is comprising the radiotracer distribution image of the target area of radioactive radiation source according to the method for claim 5.

201., further comprise positional information and counting rate are stored in the memorizer according to the method for claim 200.

202., further comprise above-mentioned positional information and counting rate are shown as figure corresponding to the labelling of this positional information and counting rate according to the method for claim 200.

203., further comprise and handle above-mentioned counting rate and positional information according to the method for claim 200.

204. according to the method for claim 203, wherein coordinate system comprises orthogonal linear axis X, Y and Z, and rotates ρ, θ and φ respectively around X, Y and Z, wherein in this coordinate system, position of detector information is defined as (Xc, Yc, Zc, ρ, θ, φ), DCR is defined as N (Xc, Yc, Zc, ρ, θ, φ), the physical size of detector be defined as (dx, dy, dz); In addition, wherein precision is handled and is comprised that look-up table shows the detector volume, is defined as Xc+dx, Yc+dx, all of Zc+dz are called as the body image element of three-dimensional pixel, determine each three-dimensional pixel of expression fall into a trap digit rate and the calculated number of times of positional information M (Xc+dx, Yc+dy, Zc+dz), with according to N (Xc+dx, Yc+dy, Zc+dz)=[N (Xc+dx, Yc+dy, Zc+dz)+N (Xc, Yc, Zc, ρ, θ, φ)]/[M (Xc+dx, Yc+dy, Zc+dz)+1] calculate the average counter rate in each three-dimensional pixel.

205. according to the method for claim 203, wherein coordinate system comprises orthogonal linear axis X, Y and Z, and rotates ρ, θ and φ respectively around X, Y and Z, wherein in this coordinate system, position of detector information is defined as (Xc, Yc, Zc, ρ, θ, φ), DCR is defined as N (Xc, Yc, Zc, ρ, θ, φ), the physical size of detector be defined as (dx, dy, dz); In addition, wherein the precision processing comprises that look-up table shows the detector volume, is defined as Xc+dx, Yc+dy, all of Zc+dx are called as the body image element of three-dimensional pixel, search those and have than the DCR N (Xc that imports, Yc, Zc, ρ, θ, φ) the three-dimensional pixel of high counting rate and these three-dimensional pixels with higher counting rate are changed into DCR N (Xc with input, Yc, Zc, ρ, θ, three-dimensional pixel φ).

206., further comprise the ray detector counting rate of radioactive emission detector and the positional information of positioning control system are merged, and formation is comprising the radiotracer distribution image of the target area of radioactive radiation source according to the method for claim 28.

207., further comprise positional information and counting rate are stored in the memorizer according to the method for claim 206.

208., further comprise above-mentioned positional information and counting rate are shown as figure corresponding to the labelling of this positional information and counting rate according to the method for claim 206.

209., further comprise and handle above-mentioned counting rate and positional information according to the method for claim 206.

210. according to the method for claim 209, wherein coordinate system comprises orthogonal linear axis X, Y and Z, and rotates ρ, θ and φ respectively around X, Y and Z, wherein in this coordinate system, position of detector information is defined as (Xc, Yc, Zc, ρ, θ, φ), DCR is defined as N (Xc, Yc, Zc, ρ, θ, φ), the physical size of detector be defined as (dx, dy, dz); In addition, wherein precision is handled and is comprised that look-up table shows the detector volume, is defined as Xc+dx, Yc+dy, all of Zc+dz are called as the body image element of three-dimensional pixel, determine each three-dimensional pixel of expression fall into a trap digit rate and the calculated number of times of positional information M (Xc+dx, Yc+dy, Zc+dz), with according to N (Xc+dx, Yc+dy, Zc+dz)=[N (Xc+dx, Yc+dy, Zc+dz)+N (Xc, Yc, Zc, ρ, θ, φ)]/[M (Xc+dx, Yc+dy, Zc+dz)+1] calculate the average counter rate in each three-dimensional pixel.

211. according to the method for claim 209, wherein coordinate system comprises orthogonal linear axis X, Y and Z, and rotates ρ, θ and φ respectively around X, Y and Z, wherein in this coordinate system, position of detector information is defined as (Xc, Yc, Zc, ρ, θ, φ), DCR is defined as N (Xc, Yc, Zc, ρ, θ, φ), the physical size of detector be defined as (dx, dy, dz); In addition, wherein the precision processing comprises that look-up table shows the detector volume, is defined as Xc+dx, Yc+dy, all of Zc+dz are called as the body image element of three-dimensional pixel, search those and have than the DCR N (Xc that imports, Yc, Zc, ρ, θ, φ) the three-dimensional pixel of high counting rate and these three-dimensional pixels with higher counting rate are changed into DCR N (Xc with input, Yc, Zc, ρ, θ, three-dimensional pixel φ).

212., further comprise the ray detector counting rate of radioactive emission detector and the positional information of positioning control system are merged, and formation is comprising the radiotracer distribution image of the target area of radioactive radiation source according to the method for claim 62.

213., further comprise positional information and counting rate are stored in the memorizer according to the method for claim 212.

214., further comprise above-mentioned positional information and counting rate are shown as figure corresponding to the labelling of this positional information and counting rate according to the method for claim 212.

215., further comprise and handle above-mentioned counting rate and positional information according to the method for claim 212.

216. according to the method for claim 215, wherein coordinate system comprises orthogonal linear axis X, Y and Z, and rotates ρ, θ and φ respectively around X, Y and Z, wherein in this coordinate system, position of detector information is defined as (Xc, Yc, Zc, ρ, θ, φ), DCR is defined as N (Xc, Yc, Zc, ρ, θ, φ), the physical size of detector be defined as (dx, dy, dz); In addition, wherein precision is handled and is comprised that look-up table shows the detector volume, is defined as Xc+dx, Yc+dy, all of Zc+dz are called as the body image element of three-dimensional pixel, determine each three-dimensional pixel of expression fall into a trap digit rate and the calculated number of times of positional information M (Xc+dx, Yc+dy, Zc+dz), with according to N (Xc+dx, Yc+dy, Zc+dz)=[N (dx+Xc, dy+Yc, Zc+dz)+N (Xc, Yc, Zc, ρ, θ, φ)]/[M (Xc+dx, Yc+dy, Zc+dz)+1] calculate the average counter rate in each three-dimensional pixel.

217. according to the method for claim 215, wherein coordinate system comprises orthogonal linear axis X, Y and Z, and rotates ρ, θ and φ respectively around X, Y and Z, wherein in this coordinate system, position of detector information is defined as (Xc, Yc, Zc, ρ, θ, φ), DCR is defined as N (Xc, Yc, Zc, ρ, θ, φ), the physical size of detector be defined as (dx, dy, dz); In addition, wherein the precision processing comprises that look-up table shows the detector volume, is defined as Xc+dx, Yc+dy, all of Zc+dz are called as the body image element of three-dimensional pixel, search those and have than the DCR N (Xc that imports, Yc, Zc, ρ, θ, φ) the three-dimensional pixel of high counting rate and these three-dimensional pixels with higher counting rate are changed into DCR N (Xc with input, Yc, Zc, ρ, θ, three-dimensional pixel φ).

218., further comprise the ray detector counting rate of radioactive emission detector and the positional information of positioning control system are merged, and formation is comprising the radiotracer distribution image of the target area of radioactive radiation source according to the method for claim 86.

219., further comprise positional information and counting rate are stored in the memorizer according to the method for claim 218.

220., further comprise above-mentioned positional information and counting rate are shown as figure corresponding to the labelling of this positional information and counting rate according to the method for claim 218.

221., further comprise and handle above-mentioned counting rate and positional information according to the method for claim 218.

222. according to the method for claim 221, wherein coordinate system comprises orthogonal linear axis X, Y and Z, and rotates ρ, θ and φ respectively around X, Y and Z, wherein in this coordinate system, position of detector information is defined as (Xc, Yc, Zc, ρ, θ, φ), DCR is defined as N (Xc, Yc, Zc, ρ, θ, φ), the physical size of detector be defined as (dx, dy, dz); In addition, wherein precision is handled and is comprised that look-up table shows the detector volume, is defined as Xc+dx, Yc+dy, all of Zc+dz are called as the body image element of three-dimensional pixel, determine each three-dimensional pixel of expression fall into a trap digit rate and the calculated number of times of positional information M (Xc+dx, Yc+dy, Zc+dz), with according to N (Xc+dx, Yc+dy, Zc+dz)=[N (Xc+dx, Yc+dy, Zc+dz)+N (Xc, Yc, Zc, ρ, θ, φ)]/[M (Xc+dx, Yc+dy, Zc+dz)+1] calculate the average counter rate in each three-dimensional pixel.

223. according to the method for claim 221, wherein coordinate system comprises orthogonal linear axis X, Y and Z, and rotates ρ, θ and φ respectively around X, Y and Z, wherein in this coordinate system, position of detector information is defined as (Xc, Yc, Zc, ρ, θ, φ), DCR is defined as N (Xc, Yc, Zc, ρ, θ, φ), the physical size of detector be defined as (dx, dy, dz); In addition, wherein the precision processing comprises that look-up table shows the detector volume, is defined as Xc+dx, Yc+dy, all of Zc+dz are called as the intensity pixel of three-dimensional pixel, search those and have than the DCR N (Xc that imports, Yc, Zc, ρ, θ, φ) the three-dimensional pixel of high counting rate and these three-dimensional pixels with higher counting rate are changed into DCR N (Xc with input, Yc, Zc, ρ, θ, three-dimensional pixel φ).

224., further comprise the ray detector counting rate of radioactive emission detector and the positional information of positioning control system are merged, and formation is comprising the radiotracer distribution image of the target area of radioactive radiation source according to the method for claim 89.

225., further comprise positional information and counting rate are stored in the memorizer according to the method for claim 224.

226., further comprise above-mentioned positional information and counting rate are shown as figure corresponding to the labelling of this positional information and counting rate according to the method for claim 224.

227., further comprise and handle above-mentioned counting rate and positional information according to the method for claim 224.

228. according to the method for claim 227, wherein coordinate system comprises orthogonal linear axis X, Y and Z, and rotates ρ, θ and φ respectively around X, Y and Z, wherein in this coordinate system, position of detector information is defined as (Xc, Yc, Zc, ρ, θ, φ), DCR is defined as N (Xc, Yc, Zc, ρ, θ, φ), the physical size of detector be defined as (dx, dy, dz); In addition, wherein precision is handled and is comprised that look-up table shows the detector volume, is defined as Xc+dx, Yc+dy, all of Zc+dz are called as the body image element of three-dimensional pixel, determine each three-dimensional pixel of expression fall into a trap digit rate and the calculated number of times of positional information M (Xc+dx, Yc+dy, Zc+dz), with according to N (Xc+dx, Yc+dy, Zc+dz)=[N (Xc+dx, Yc+dy, Zc+dz)+N (Xc, Yc, Zc, ρ, θ, φ)]/[M (Xc+dx, Yc+dy, Zc+dz)+1] calculate the average counter rate in each three-dimensional pixel.

229. according to the method for claim 227, wherein coordinate system comprises orthogonal linear axis X, Y and Z, and rotates ρ, θ and φ respectively around X, Y and Z, wherein in this coordinate system, position of detector information is defined as (Xc, Yc, Zc, ρ, θ, φ), DCR is defined as N (Xc, Yc, Zc, ρ, θ, φ), the physical size of detector be defined as (dx, dy, dz); In addition, wherein the precision processing comprises that look-up table shows the detector volume, is defined as Xc+dx, Yc+dy, all of Zc+dz are called as the body image element of three-dimensional pixel, search those and have than the DCR N (Xc that imports, Yc, Zc, ρ, θ, φ) the three-dimensional pixel of high counting rate and these three-dimensional pixels with higher counting rate are changed into DCR N (Xc with input, Yc, Zc, ρ, θ, three-dimensional pixel φ).

230. method according to claim 94, further comprise the ray detector counting rate of above-mentioned at least one radioactive emission detector and the positional information of positioning control system are merged, and formation is comprising the radiotracer distribution image of the target area of radioactive radiation source.

231., further comprise positional information and counting rate are stored in the memorizer according to the method for claim 230.

232., further comprise above-mentioned positional information and counting rate are shown as figure corresponding to the labelling of this positional information and counting rate according to the method for claim 230.

233., further comprise and handle above-mentioned counting rate and positional information according to the method for claim 230.

234. according to the method for claim 233, wherein coordinate system comprises orthogonal linear axis X, Y and Z, and rotates ρ, θ and φ respectively around X, Y and Z, wherein in this coordinate system, above-mentioned at least one position of detector information is defined as (Xc, Yc, Zc, ρ, θ, φ), DCR is defined as N (Xc, Yc, Zc, ρ, θ, φ), the physical size of above-mentioned at least one detector be defined as (dx, dy, dz); In addition, wherein precision is handled and is comprised that look-up table shows the detector volume, is defined as Xx+dx, Yc+dy, all of Zc+dz are called as the body image element of three-dimensional pixel, determine each three-dimensional pixel of expression fall into a trap digit rate and the calculated number of times of positional information M (Xc+dx, Yc+dy, Zc+dz), with according to N (Xc+dx, Yc+dy, Zc+dz)=[N (Xc+dx, Yc+dy, Zc+dz)+N (Xc, Yc, Zc, ρ, θ, φ)]/[M (Xc+dx, Yc+dy, Zc+dz)+1] calculate the average counter rate in each three-dimensional pixel.

235. according to the method for claim 233, wherein coordinate system comprises orthogonal linear axis X, Y and Z, and rotates ρ, θ and φ respectively around X, Y and Z, wherein in this coordinate system, above-mentioned at least one position of detector information is defined as (Xc, Yc, Zc, ρ, θ, φ), DCR is defined as N (Xc, Yc, Zc, ρ, θ, φ), the physical size of above-mentioned at least one detector be defined as (dx, dy, dz); In addition, wherein the precision processing comprises that look-up table shows the detector volume, is defined as Xc+dx, Yc+dy, all of Zc+dz are called as the body image element of three-dimensional pixel, search those and have than the DCR N (Xc that imports, Yc, Zc, ρ, θ, φ) the three-dimensional pixel of high counting rate and these three-dimensional pixels with higher counting rate are changed into DCR N (Xc with input, Yc, Zc, ρ, θ, three-dimensional pixel φ).

236. method according to claim 108, further comprise the ray detector counting rate of radioactive emission detector and the positional information of positioning control system are merged, and formation is comprising the radiotracer distribution image of the target area of radioactive radiation source.

237., further comprise positional information and counting rate are stored in the memorizer according to the method for claim 236.

238., further comprise above-mentioned positional information and counting rate are shown as figure corresponding to the labelling of this positional information and counting rate according to the method for claim 236.

239., further comprise and handle above-mentioned counting rate and positional information according to the method for claim 236.

240. according to the method for claim 239, wherein coordinate system comprises orthogonal linear axis X, Y and Z, and rotates ρ, θ and φ respectively around X, Y and Z, wherein in this coordinate system, the positional information of monitor is defined as (Xc, Yc, Zc, ρ, θ, φ), DCR is defined as N (Xc, Yc, Zc, ρ, θ, φ), the physical size of detector be defined as (dx, dy, dz); In addition, wherein precision is handled and is comprised that look-up table shows the detector volume, is defined as Xc+dx, Yc+dy, all of Zc+dz are called as the body image element of three-dimensional pixel, determine each three-dimensional pixel of expression fall into a trap digit rate and the calculated number of times of positional information M (Xc+dx, Yc+dy, Zc+dz), with according to N (Xc+dx, Yc+dy, Zc+dz)=[N (Xc+dx, Yc+dy, Zc+dz)+N (Xc, Yc, Zc, ρ, θ, φ)]/[M (Xc+dx, Yc+dy, Zc+dz)+1] calculate the average counter rate in each three-dimensional pixel.

241. according to the method for claim 239, wherein coordinate system comprises orthogonal linear axis X, Y and Z, and rotates ρ, θ and φ respectively around X, Y and Z, wherein in this coordinate system, the positional information of monitor is defined as (Xc, Yc, Zc, ρ, θ, φ), DCR is defined as N (Xc, Yc, Zc, ρ, θ, φ), the physical size of detector be defined as (dx, dy, dz); In addition, wherein the precision processing comprises that look-up table shows the detector volume, is defined as Xc+dx, Yc+dy, all of Zc+dz are called as the body image element of three-dimensional pixel, search those and have than the DCR N (Xc that imports, Yc, Zc, ρ, θ, φ) the three-dimensional pixel of high counting rate and these three-dimensional pixels with higher counting rate are changed into DCR N (Xc with input, Yc, Zc, ρ, θ, three-dimensional pixel φ).

242., further comprise the ray detector counting rate of radioactive emission detector and the positional information of positioning control system are merged, and formation is comprising the radiotracer distribution image of the target area of radioactive radiation source according to the method for claim 123.

243., further comprise positional information and counting rate are stored in the memorizer according to the method for claim 242.

244., further comprise above-mentioned positional information and counting rate are shown as figure corresponding to the labelling of this positional information and counting rate according to the method for claim 242.

245., further comprise and handle above-mentioned counting rate and positional information according to the method for claim 242.

246. according to the method for claim 245, wherein coordinate system comprises orthogonal linear axis X, Y and Z, and rotates ρ, θ and φ respectively around X, Y and Z, wherein in this coordinate system, the positional information of monitor is defined as (Xc, Yc, Zc, ρ, θ, φ), DCR is defined as N (Xc, Yc, Zc, ρ, θ, φ), the physical size of detector be defined as (dx, dy, dz); In addition, wherein precision is handled and is comprised that look-up table shows the detector volume, is defined as Xc+dx, Yc+dy, all of Zc+dz are called as the body image element of three-dimensional pixel, determine each three-dimensional pixel of expression fall into a trap digit rate and the calculated number of times of positional information M (Xc+dx, Yc+dy, Zc+dz), with according to N (Xc+dx, Yc+dy, Zc+dz)=[N (Xc+dx, Yc+dy, Zc+dz)+N (Xc, Yc, Zc, ρ, θ, φ)]/[M (Xc+dx, Yc+dy, Zc+dz)+1] calculate the average counter rate in each three-dimensional pixel.

247. according to the method for claim 245, wherein coordinate system comprises orthogonal linear axis X, Y and Z, and rotates ρ, θ and φ respectively around X, Y and Z, wherein in this coordinate system, the positional information of monitor is defined as (Xc, Yc, Zc, ρ, θ, φ), DCR is defined as N (Xc, Yc, Zc, ρ, θ, φ), the physical size of detector be defined as (dx, dy, dz); In addition, wherein the precision processing comprises that look-up table shows the detector volume, is defined as Xc+dx, Yc+dy, all of Zc+dz are called as the body image element of three-dimensional pixel, search those and have than the DCR N (Xc that imports, Yc, Zc, ρ, θ, φ) the three-dimensional pixel of high counting rate and these three-dimensional pixels with higher counting rate are changed into DCR N (Xc with input, Yc, Zc, ρ, θ, three-dimensional pixel φ).

248. a method that is used for the reconstruct of lonizing radiation collection of illustrative plates, this method comprises:

A) determine the transfer function of a radiation detector;

B) determine a deconvolution of this transfer function;

C) count value based on this deconvolution is composed at least one the three-dimensional pixel in the visual field of this detector; With

D) utilize this at least one three-dimensional pixel of this deconvolution reconstruct.

249., wherein use deconvolution to comprise the blooming that reduces this at least one three-dimensional pixel at least according to the method for claim 248.

250., further be included in and handle the observed a plurality of readings of different detectors that this at least one three-dimensional pixel receives on the mathematics according to the method for claim 248.

251. according to the method for claim 250, wherein Mathematical treatment comprises definite value, is used for substituting the single reading value of above-mentioned at least one three-dimensional pixel.

252. according to the method for claim 251, wherein the step of a definite value comprises the inverse of the average inverse of the reading of determining at least one algebraic mean value, a minima and above-mentioned at least one three-dimensional pixel.

253. a system is used to calculate the position of a patient's body organ and the radiopharmaceutical picked-up position partly of organ, this system comprises:

A) the two-dimensional imaging Medical Instruments that links to each other and/or communicate with a primary importance tracking system is used for calculating the position of organ in first coordinate system;

B) radioactive emission detector that links to each other and/or communicate with second position system, the position of radiopharmaceutical picked-up part in second coordinate system that is used for following the tracks of organ; With

C) at least one data processor, be designed and be configured to be used for from above-mentioned two-dimensional imaging power device, primary importance tracking system, radioactive emission detector and second position tracking system, to receive the data input, and calculate the position of radiopharmaceutical picked-up part in a common coordinate system system of organ and organ.

254. a method is used to calculate the position of a patient's body organ and the radiopharmaceutical picked-up position partly of organ, this system comprises:

A) provide the two-dimensional imaging Medical Instruments that links to each other and/or communicate with a primary importance tracking system, be used for calculating the position of organ in first coordinate system;

B) provide a radioactive emission detector that links to each other and/or communicate with second position system, be used for following the tracks of the position of radiopharmaceutical picked-up part in second coordinate system of organ; With

C) from above-mentioned two-dimensional imaging instrument, primary importance tracking system, radioactive emission detector and second position tracking system, receive the data input, and calculate the position of radiopharmaceutical picked-up part in a common coordinate system system of organ and organ.

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