WO2008006903A1

WO2008006903A1 - Device and method for determining internal pressure in a non-contact manner

Info

Publication number: WO2008006903A1
Application number: PCT/EP2007/057253
Authority: WO
Inventors: Michael Sorg; Axel Freiherr Von Freyberg; Gert Goch
Original assignee: Universität Bremen
Priority date: 2006-07-14
Filing date: 2007-07-13
Publication date: 2008-01-17
Also published as: DE102006033035B4; DE102006033035A1

Abstract

The invention relates to a device for determining the internal pressure of a deformable body (11), especially the internal pressure of an eye (11), in a non-contact manner, said device comprising a sound conductor (12) which has an open first end and a second end opposing said first end, and a sound transducer (13) which is arranged on the second end, facing the first end. According to the invention, the internal pressure of the eye (11) can be determined with high precision and without subjecting the eye (11) to a excessive load, when a sensor is used to detect the vibrations of the eye (11). The inventive device can also be used to effectively prevent the spread of infection.

Description

description

DEVICE AND METHOD FOR TOUCHLESS

INTERNAL PRESSURE DETERMINATION

The invention relates to a device for non-contact determination of the deformability of a deformable body, in particular the internal pressure of an eye, with a sound conductor having an open first end and a remote from this second end, and with a transducer facing the first end is arranged at the second end. Moreover, the invention relates to a method for the contactless determination of the internal pressure of a deformable body, in particular the internal pressure of an eye, in which with a sound transducer by means of a sound conductor, the body can be acted upon by a pressure wave.

By means of the direct measurement of the deformability of a body can draw conclusions about material properties and other characteristics of the body. For example, conclusions on the elasticity and on the internal pressure are possible. In particular, for the determination of the internal pressure of the eye today so-called touching applanation tonometer are usually used, with which a sufficiently accurate determination of intraocular pressure can be carried out. The Goldmann Applanation Tonotmeter is today considered a reference device. More inaccurate than the Goldmann Applanation Tonometer but easier to use are Mappay-Marg Handapplanation Tonometers. In addition to these touch-measuring tonometers, various air-pressure tonometers have also established themselves on the market. The eye is deformed without contact by means of an air jet. The intraocular pressure is calculated from the air velocity required for the deformation.

DE 100 39 896 A1 describes a device and a method of the type mentioned. In the known method and the known device Helmholzresonatoren be used to provide by way of resonance peak enough sound energy for adequate deformation of the eye. A disadvantage of the touching tonometer is that the contact of the measuring stamp with the cornea can lead to a transmission of pathogens. Furthermore, this touching tonometry requires local anesthesia of the eye with the known associated risks and disadvantages. Furthermore, for this reason, a measurement of the intraocular pressure by assistants or the patient himself is not possible. In addition to mechanical stress and the risk of injury to the corneal surface, local anesthetics often cause irritation of the anterior segment of the eye, which the patient perceives as painful or uncomfortable. In addition, when changes in the corneal surface due to edema or scarring as well as irregular corneal radii or astigmatism, applanation monomers provide unusable values. In addition, by means of a touching applanation tonometer, an examination following eye operations to control the success of the operation is possible only to a very limited extent. Likewise, with the usual Applanationstonometern a position-independent measurement, for example, on lying patients, not feasible.

These sometimes large problems can be partially avoided by means of non-contact tonometer, which applanate the cornea instead of a stamp, for example, with an air pulse. However, such non-contact tonometers sometimes provide unreliable results even with low corneal irregularities. They are therefore mainly used for screening because they are only suitable for accurate and reliable measurements. Furthermore, even with these known non-contact tonometers a large force on the eye for applanation is required. Likewise, the risk of spreading infection by sprayed tear fluid can not be ruled out.

In all known methods and devices, the corneal rigidity is not sufficiently considered. For all evaluation procedures it is assumed that the form the cornea is influenced only by the intraocular pressure and has no inherent rigidity. Even compensations in today's recognized measuring methods do not provide sufficient accuracy. There is a risk that in patients with a thin cornea due to supposedly low values of intraocular pressure glaucoma remains undetected, while in people with a thick cornea because of a supposedly high value of the intraocular pressure, a glaucoma treatment is also wrongly performed in an actually healthy patient. However, the consideration of the influence of the cornea is becoming increasingly important, because more and more people can be removed within the scope of a refractive surgery parts of the cornea.

The problem underlying the invention is to provide an apparatus and a method for contactless determination of the internal pressure of a deformable body, with which can be determined reliably and with high accuracy of intraocular pressure, with damage to the cornea, as well as a spread of Infectious diseases are avoided by the measurement as possible and the device and the method of a patient is not perceived as unpleasant as possible.

The problem is solved in that in a device of the type mentioned a sensor for detecting the vibration of the body is provided. According to another aspect of the invention, the problem is solved in that in a method of the type mentioned by means of a sensor, the vibration of the body is detected to determine the internal pressure.

With the invention of the body to be measured, for example, the eye, arranged at the first end of the sound conductor and acted upon by means of the transducer with a pressure wave. This can be, for example, a rectangular pulse, a sine wave or another suitable sound signal. Because according to the invention with the sensor not the applanation of the eyeball, but its vibration is measured, relatively small pressure changes are required. Damage to the eye by the measurement is thus avoided. At the same time, neither direct contact with the tear fluid nor atomization of the same occurs due to a flow of air, so that a spread of infection is largely avoided here as well. In addition, with a well-known from vibration analysis of bridges, buildings and other structures evaluation of the intraocular pressure can be determined reliably and with high quality, with influences of the edge tissue and the cornea can be largely eliminated. The method and the device are position-independent, thus even with lying down patient averted and beyond so easily ausgestaltetbar that a self-measurement at home by patients themselves or their caregivers can be easily performed.

In a further development of the invention, the sensor is a microphone.

As a result, the vibration behavior of the body can be easily detected. But it is also possible that the transducer is used as a sensor. In this case, for example, a so-called microphone speaker can be used. As a result, the structure is particularly simple. Another embodiment is characterized in that the sensor is a linear pressure sensor. With this, the temporal pressure behavior in the sound conductor can be easily recorded. Another embodiment is characterized in that the sensor is an optical sensor. Also by means of such an optical sensor, the vibration behavior of the eyeball can be reliably detected. By using a combination of several of the aforementioned sensors, the accuracy can be improved.

In another embodiment of the invention, the sound conductor is a tube whose first end is formed for airtight placement on the tissue surrounding an eye. Such, in particular closed, tube is used reliably to conduct the sound or a pressure wave in general, with incorrect operations are recognized by leaks simple and significant in the measurement result. In this way, a misuse can be largely avoided.

A development of the invention is characterized by a control for driving the sound transducer and for evaluating the Sensor signal. By means of such a control, the internal pressure of the body can be determined automatically. For example, the controller may have a list of measurement results, each associated with an internal pressure. Preferably, the controller is configured to determine the acoustic impedance of the body. This acoustic impedance provides a good relationship to the internal pressure of the body. But it is also possible that the controller is designed to determine the amplitude and / or the phase. This makes the detection of the vibration of the body particularly easy. The controller may also be designed to determine the damping of the body. The damping of the body is also a characteristic measure of intraocular pressure. In particular, results in a low intraocular pressure, a large vibration amplitude and a large attenuation, while at a high intraocular pressure, a low amplitude and low attenuation is recorded. Another embodiment is characterized in that the control is designed to determine the vibration response and / or the impulse response. This vibration response and / or impulse response of the body provides characteristic information about the internal pressure. For example, means for detecting the voltage profile and / or the current profile can also be arranged on the sound transducer and / or on the sensor. This voltage curve or this current profile can be detected and evaluated particularly easily electronically.

Another embodiment of the invention is characterized by a laser for optically determining the vibration of the body. By means of this laser, for example, the white area of the eyeball can be illuminated and this area can be detected by means of an optical sensor. Thus, the oscillation of the eyeball can also be detected reliably and with little error.

Another embodiment of the invention is characterized by an additional microphone. On the one hand, incorrect operation can be reliably detected by means of such an additional microphone. On the other hand it allows This additional microphone to include higher frequencies of the vibration of the body in the evaluation.

A development of the invention is characterized by a Peilhilfe. By means of such a direction finding aid, which can be for example an optical display or a cross, it is possible to achieve an optimal positioning of the eyeball in the measuring system for the measurement. The aiming aid can be fluorescent or excitable. For example, in the embodiment as a handheld device for the home application area, a display can be used inside the device as a sighting aid. In an attempt to read the display and recognize the detected values, the patient then automatically positions his eye.

A development of the method according to the invention is characterized in that by means of a controller, the amplitude and / or the phase of the vibrations is detected. These values allow an accurate and reliable determination of the internal pressure of the body. By means of the control, however, the oscillation response and / or the impulse response of the body can also be evaluated. The processing of the acquired data becomes particularly simple when induced voltages detected by the controller are evaluated by the sensor. By means of the control, for example, the induced voltages can be converted into pressure values. In this case, in each case associated pressure values can be associated, in particular by means of lists of individual induced voltages. It is also possible that the control determines the damping by the body. A large damping is assigned to a low internal pressure and a low damping to a high internal pressure. The determination of the internal pressure is preferably carried out by means of a model-based evaluation. The eye is regarded as a sound or pressure transducer, which is coupled via an air column with another sound or pressure transducer.

Embodiments of the invention will be explained in more detail with reference to the drawings. Show it:

Fig. 1 is a schematic representation of a tonometer with the

Inventive features, FIG. 2 is a schematic circuit diagram of the tonometer of FIG. 1; FIG.

Fig. 3 is a schematic representation of a rectangular pulse, a

Vibration at high internal pressure and vibration at low internal pressure,

Fig. 4 is a schematic circuit arrangement of another

Tonometers, and

Fig. 5 is a schematic representation of a tonometer with optical vibration detection.

Fig. 1 shows a schematic representation of a tonometer 10 with the features of the invention. The tonometer 10 is used to measure the intraocular pressure of an eye 11. For this purpose, the tonometer 10 has a sound conductor 12, which is formed in the embodiment shown as a tube 12 with a closed wall. An open end of the tube 12 is airtight pressed against the surrounding the eye 11 tissue. At the end facing away from the eye 11 of the tube 12, a sound transducer 13, namely a speaker 13 is arranged. The loudspeaker 13 is connected to a controller 14, by means of which the loudspeaker 13 can be activated to generate a sound wave. As indicated by a double arrow, the controller 14 is used at the same time to read the signal detected by the speaker 13.

Fig. 2 shows schematically the switching arrangement of the tonometer 10 of Fig. 1. As the figure can be seen, the speaker 13 is electrically energized by means of a voltage source 15. The voltage source 15 is either part of the controller 14 or controlled by this. By means of a voltage measuring device 16, the voltage profile is measured at the coil of the speaker 13.

In the circuit, a measuring resistor 17 is also arranged. Another voltage device 18 measures the voltage drop across the measuring resistor 17. From this voltage drop, the current profile can be determined via the voice coil of the speaker 13.

Fig. 3 shows in Figure a a sound pulse generated by the loudspeaker 13. The sound pulse is in the embodiment shown as Rectangular pulse formed. Figure b shows the measured waveform of an eye with low internal pressure. As can be seen from the figure, a low internal pressure leads to overshoot with high amplitude but also great damping.

In Fig. 3 c, the waveform in an eye with high

Internal pressure shown. As can be seen from the figure, a high internal pressure of the eye leads to a low oscillation amplitude but on the other hand to a low attenuation, i. H. to an intense ringing.

By detecting the vibration behavior, the internal pressure of the eye can thus be determined precisely and reliably.

Fig. 4 shows a further embodiment of a circuit arrangement of a tonometer in a schematic representation. In the figure, a sound transducer 19 is connected to a power source 20 similar to the power source 15. In the exemplary embodiment shown, the microphone transducer 19 is connected to a resistor 22, the voltage drop across the resistor 22 being measured by means of a voltage measuring device 23. In this way, the current profile of the microphone coil 21 can be determined from the voltage drop across the measuring resistor 22.

Fig. 5 shows a schematic representation of a tonometer 24 as a further embodiment with the features of the invention. The tonometer 24 has a similar structure to the tonometer 10. The same elements bear the same reference numbers. Unlike the tonometer 10, the tonometer 24 has a sound conductor 25, which is similar to the sound conductor 12 is formed as a tube 25 with a closed wall.

The tonometer 24 has a laser 26 and an optical sensor 27. By means of the laser 26, a white area of the eye 24 is irradiated. The oscillation of the eye 11 after excitation by a sound pulse of The speaker 13 is then detected by means of the optical sensor 27 and evaluated by the controller 14.

In the embodiment shown, the intraocular pressure is determined on the basis of a model-based evaluation. The eye is regarded as a sound or pressure transducer, which is coupled via an air column with another sound or pressure transducer.

[0033] List of Reference Numerals:

10 tonometer

[0035] 11 eye

12 tube

13 loudspeakers

14 control

15 voltage source

[0040] 16 voltmeter

17 resistance

18 voltmeter

19 microphone speakers

20 voltage source

21 microphone coil

22 resistance

23 voltage measuring device

24 tonometer

25 pipe

26 lasers

27 sensor

Claims

claims

1. A device for non-contact determination of the deformability of a deformable body (11), in particular the internal pressure of an eye (11), with a sound conductor (12, 25) having an open first end and a second end facing away from this, and with a Sound transducer (13, 19), which is arranged at the first end facing the second end, characterized by a sensor (21, 27) for detecting the vibration of the body (11).

2. Apparatus according to claim 1, characterized in that the sensor is a microphone (21).

3. Apparatus according to claim 1 or 2, characterized in that the sound transducer (13, 19) is used as a sensor.

4. Device according to one of the preceding claims, characterized in that the sensor is a linear pressure sensor.

5. Device according to one of the preceding claims, characterized in that the sensor is a microphone speaker (19).

6. Device according to one of the preceding claims, characterized in that the sensor is an optical sensor (27).

7. Device according to one of the preceding claims, characterized in that the sound conductor is a tube (12, 25) whose first end is formed for airtight placement on the one eye (11) surrounding tissue.

8. Device according to one of the preceding claims, characterized by a controller (14) for driving the sound transducer (13, 19) and for evaluating the sensor signal.

9. Apparatus according to claim 8, characterized in that the controller (14) for determining the amplitude and / or the phases is formed.

10. Apparatus according to claim 8 or 9, characterized in that the controller (14) for determining the damping of the body (11) is formed.

11. Device according to one of claims 8 to 10, characterized in that the controller (14) is designed for determining the acoustic impedance of the body.

12. Device according to one of claims 8 to 11, characterized in that the control is designed to determine the vibration response and / or the impulse response.

13. Device according to one of the preceding claims, characterized by means (16, 18, 23) for detecting the voltage waveform and / or the current waveform on the sound transducer (13, 19) and / or on the sensor (21).

14. Device according to one of the preceding claims, characterized by a laser (26) for optically determining the vibration of the body (11).

15. Device according to one of claims 8 to 14, characterized in that by means of the controller (14), the internal pressure is automatically determined.

16. Device according to one of the preceding claims, characterized by an additional microphone.

17. Device according to one of the preceding claims, characterized by a Peilhilfe.

18. The apparatus according to claim 17, characterized in that the Peilhilfe is an optical display or a cross.

19. The apparatus of claim 17 or 18, characterized in that the direction finder is fluorescent or excitable.

20. Device according to one of the preceding claims, characterized by an embodiment as a hand-held device.

21. A method for the contactless determination of the internal pressure of a deformable body (11), in particular the internal pressure of an eye (11), in which with a sound transducer (13, 19) by means of a sound conductor (12, 25) of the body (11) with a pressure wave can be acted upon, characterized in that by means of a sensor (21, 27) the vibration of the body (11) is detected for determining the internal pressure.

22. The method according to claim 21, characterized in that by means of a controller (14), the amplitude and / or the phase of the oscillation is detected.

23. The method according to claim 21 or 22, characterized in that by means of the controller (14) the vibration response and / or the impulse response of the body (11) is evaluated.

24. The method according to any one of claims 21 to 23, characterized in that by means of the controller (14) of the sensor (21) detected induced voltages are evaluated.

25. The method according to claim 24, characterized in that by means of the controller (14), the induced voltages are converted into pressure values.

26. The method according to any one of claims 21 to 25, characterized in that by means of the controller (14), the damping by the body (11) is determined.

27. The method according to any one of the preceding claims, characterized in that the determination of the internal pressure is carried out by means of a model-based evaluation.