ENHANCED FOCUSED ULTRASOUND ABLATION USING
MICROBUBBLES
FIELD OF THE INVENTION The present invention relates generally to systems for performing therapeutic procedures using focused ultrasound, and more particularly to systems for enhanced tissue coagulation by generating microbubbles in a target tissue region.
BACKGROUND
High intensity focused acoustic waves, such as ultrasonic waves (acoustic waves with a frequency greater than about 20 kilohertz), may be used therapeutically to treat internal tissue regions within a patient. For example, ultrasonic waves may be used to induce coagulation and/or necrosis in a target tissue region. In ultrasonic tissue coagulation, the ultrasonic waves are absorbed by tissue to generate heat in the tissue. The absorbed energy heats the tissue cells in the target region to temperatures that exceed protein denaturation thresholds, usually above 60°C, resulting in coagulation and/or necrosis.
During a focused ultrasound procedure, small gas bubbles, or "microbubbles," may be generated in the liquid contained in the tissue when the ultrasonic waves are transmitted therethrough. Microbubbles may be formed due to tissue heating, the stress resulting from negative pressure produced by the propagating ultrasonic wave, and/or when the liquid ruptures and is filled with gas/vapor. Generally, steps are taken to avoid creating
microbubbles in the tissue, because once created, they may collapse due to the applied stress from an acoustic field. This mechanism, called "cavitation," may cause extensive tissue damage and may be difficult to control. U.S. Patent No. 6,309,355 discloses using cavitation induced by an ultrasound beam to create a surgical lesion.
SUMMARY OF THE INVENTION
The present invention is directed to systems for performing a therapeutic procedure using acoustic energy, and more particularly, to systems for enhanced tissue coagulation by generating microbubbles in a target tissue region.
In accordance with one aspect of the present invention, a system is provided that includes a piezoelectric transducer, drive circuitry, and a controller. The drive circuitry is coupled to the transducer to provide drive signals to the transducer, causing the transducer to transmit acoustic energy, e.g., towards a focal zone within a tissue structure. The controller is coupled to the drive circuitry, and is configured for sequentially changing the amplitudes of the drive signals from an intensity sufficient to generate microbubbles in tissue within the focal zone to a reduced intensity sufficient to heat the tissue within the focal zone without causing collapse or cavitation of the generated microbubbles, e.g., until tissue coagulation and/or necrosis occurs. Since microbubbles may dissipate from the tissue within the focal zone after time has passed, the controller may periodically repeat the process by increasing the
amplitudes of the drive signals to generate additional microbubbles and then reducing the intensity to heat the tissue without causing collapse of the microbubbles.
In one embodiment, the system is configured to direct acoustic energy at tissue at an intensity sufficient to generate microbubbles within a focal zone within the tissue. Acoustic energy at a lesser intensity is then directed at the focal zone to heat and/or necrose the tissue within the focal zone. The intensity of this second transmission is lower than the intensity needed to generate or cause collapse of the microbubbles. In order to maintain a population of microbubbles within the focal zone to enhance necrosis of the tissue during the sonication, the directing of acoustic energy above and below the threshold level may be alternately repeated one or more times during a single sonication.
BRIEF DESCRIPTION OF THE DRAWINGS
Preferred embodiments of the present invention are illustrated by way of example, and not by way of limitation, in the figures of the accompanying drawings, in which like reference numerals refer to like components, and in which:
FIG. 1A is a diagram of an ultrasound transducer focusing ultrasonic energy at a target tissue region within a patient; FIG. IB is a cross-sectional detail of the ultrasonic transducer and target tissue region of FIG. 1A with microbubbles generated in a focal zone of the transducer; and
FIG. 2 is a flowchart of a method for treating tissue using microbubbles to enhance heating, in accordance with the present invention.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Turning to the drawings, FIGS. 1A and IB show an exemplary embodiment of a focused ultrasound system 10 that includes an ultrasound transducer 14, drive circuitry 16 coupled to the transducer 14, and a controller
18 coupled to the drive circuitry 16. The transducer 14 may direct acoustic energy represented by beam 15 towards a target 42, typically a tumor or other tissue region, within a patient 40, as explained further below. The transducer 14 may include a single piezoelectric transducer element, or may include multiple piezoelectric elements (not shown) together providing a transducer array. In one embodiment, the transducer 14 may have a concave or bowl shape, such as a "spherical cap" shape, i.e., having a substantially constant radius of curvature such that the transducer 14 has an inside surface defining a portion of a sphere. Alternatively, the transducer 14 may have a substantially flat configuration (not shown) , and/or may include an outer perimeter that is generally, but not necessarily, circular. The transducer 14 may be divided into any desired number of elements (not shown) . In one embodiment, the transducer 14 may have an outer diameter of between about eight and sixteen centimeters (8-16 cm), a radius of curvature between about eight and twenty centimeters (8-20 cm), and may include between ten and forty (10-40) rings and between four and sixteen (4-16) sectors.
In alternative embodiments, the transducer 14 may include one or more transducer elements having a variety of geometric shapes, such as hexagons, triangles, squares, and the like, and may be disposed about a central axis, preferably but not necessarily, in a substantially uniform or symmetrical configuration. The configuration of the transducer 14, however, is not important to the present invention, and any of a variety of ultrasound transducers may be used, such as flat circular arrays, linear arrays, and the like. Additional information on the construction of transducers appropriate for use with the present invention may be found, for example, in U.S. patent application Serial No. 09/884,206, filed June 9, 2001.
The transducer 14 may be mounted within a casing or chamber (not shown) filled with degassed water or similar acoustically transmitting fluid. The chamber may be located within a table (not shown) upon which a patient 40 may be disposed, or within a fluid-filled bag mounted on a movable arm that may be placed against a patient's body (not shown). The contact surface of the chamber, e.g., the top of the table, generally includes a flexible membrane (not shown) that is substantially transparent to ultrasound, such as mylar, polyvinyl chloride (PVC), or other suitable plastic material. A fluid- filled bag (not shown) may be provided on the membrane that may conform easily to the contours of the patient 40 disposed on the table, thereby acoustically coupling the patient 40 to the transducer 14 within the chamber. In addition or alternatively, acoustic gel, water, or other fluid may be provided
between the patient 40 and the membrane to facilitate further acoustic coupling between the transducer 14 and the patient 40.
A positioning system (not shown) may be connected to the transducer 14 for mechanically moving the transducer 14 in one or more directions, and preferably in any of three orthogonal directions. Alternatively, a focal distance (a distance from the transducer 14 to a focal zone 38 of the acoustic energy emitted by the transducer 14) may be adjusted electronically, mechanically, or using a combination of mechanical and electronic positioning, as is known in the art. In addition, the system 10 may include an imaging device (not shown) for monitoring use of the system before or while treating a patient. For example, the system 10 may be used in conjunction with a magnetic resonance imaging (MRI) device, such as that disclosed in U.S. Patent Nos. 5,247,935, 5,291,890, 5,368,031, 5,368,032, 5,443,068 issued to Cline et al., and U.S. Patent Nos. 5,307,812, 5,323,779, 5,327,884 issued to Hardy et al.
With particular reference to FIG. 1 A, the transducer 14 is coupled to the driver 16 and/or the controller 18 for generating and/or controlling the acoustic energy emitted by the transducer 14. The driver 16 generates one or more electronic drive signals, which, in turn, are controlled by controller 18. The transducer 14 converts the electronic drive signals into acoustic energy represented by energy beam 15. The vibrational energy propagated by the transducer 14 is transmitted through the target medium within the chamber, such as degassed water.
The controller 18 and/or driver 16 may be separate or integral components of the transducer 14. It will be appreciated by one skilled in the art that the operations performed by the controller 18 and/or driver 16 may be performed by one or more controllers, processors, and/or other electronic components, including software or hardware components. Thus, the controller 18 and/or the driver 16 may be provided as parts of the transducer 14, and/or as a separate subsystem. The terms controller and control circuitry may be used herein interchangeably, and the terms driver and drive circuitry may be used herein interchangeably. The driver 16 may generate drive signals in the ultrasound frequency spectrum that may be as low as twenty kiloHertz (20KHz), and that typically range from 0.5 to 10MHz. Preferably, the driver 16 provides electrical drive signals to the transducer 14 at radio frequencies (RF), for example, between about 0.5-10 MHz, and more preferably between about 0.5 and 3.0 MHz. When electrical drive signals are provided to the transducer 14, the transducer 14 emits acoustic energy 15 from its inside surface, as is well known to those skilled in the art.
The controller 18 may control a phase component of the drive signals to respective elements of the transducer 14, e.g., to control a shape of a focal zone 38 generated by the transducer 14 and/or to move the focal zone 38 to a desired location. For example, the controller 18 may control the phase shift of the drive signals based upon a radial position of respective transducer elements of the transducer 14, e.g., to adjust a focal distance of the focal zone (i.e., the
distance from the face of the transducer 14 to the center of the focal zone 38). In addition or alternatively, the controller 18 may control the positioning system to move the transducer 14, and consequently the location of the focal zone 38 of the transducer 14, to a desired location, i.e., within the target tissue region 42.
The controller 18 may also control amplitude (and/or other aspects) of the drive signals, and therefore, the intensity or power level of the acoustic waves transmitted by the transducer 14. For example, the controller 18 may cause the drive circuitry 16 to provide drive signals to the transducer 14 above a threshold such that the acoustic energy emitted by the transducer 14 may generate microbubbles in fluid within tissue in the focal zone. Subsequently, the controller 18 may lower the intensity below the threshold to a level at which no microbubbles are formed in the tissue within the focal zone, yet may still necrose, coagulate, or otherwise heat tissue, as explained below. During use, a patient 40 may be disposed on the table with water, acoustically conductive gel, and the like applied between the patient 40 and the bag or membrane, thereby acoustically coupling the patient 40 to the transducer 14. The transducer 14 may be focused towards a target tissue region within a tissue structure 42, which may, for example, be a cancerous or benign tumor. The transducer 14 may be activated by supplying a set of drive signals at one or more frequencies to the transducer 14 to focus acoustic energy at the target tissue region 42, represented by energy beam 15. As the acoustic energy 15 passes through the patient's body, the acoustic energy 15 is converted to heat,
which may raise the temperature of the target mass 42. The acoustic energy 15 may be focused on the target mass 42 to raise the temperature of the target mass tissue 42 sufficiently to coagulate and/or necrose the tissue 42, while minimizing damage to surrounding healthy tissue. Upon completing the sonication, the transducer 14 may be deactivated, e.g., for sufficient time to allow heat absorbed by the patient's tissue to dissipate. The transducer 14 may then be focused on another portion of the target tissue region 42, e.g., adjacent the previously treated tissue, and the process repeated, as shown in FIG. 2. Alternatively, the acoustic beam may be steered continuously or discretely without any cooling time, e.g., using a mechanical positioner or electronic steering.
This alternating sequence during a single sonication may provide several advantages as compared to conventional focused ultrasound ("FUS") ablation without microbubbles. For example, if an intensity level is utilized in the heating without bubble collapse step (step 64) that is comparable to conventional FUS ablation, a substantially larger focal zone 38 may created. For example, due to the enhanced energy absorption, the resulting focal zone 38 may be about two to three times larger than conventional FUS ablation, thereby necrosing or otherwise heating a larger volume of tissue within the target tissue structure 42. This increased ablation volume may require fewer sonications to a ablate an entire target tissue structure.
Alternatively, a lower intensity level may be used as compared to conventional FUS, thereby generating a comparably sized focal zone while
using substantially less energy. This may reduce energy consumption by the system 10 and/or may result in substantially less energy being absorbed by surrounding tissue, particularly in the near field. With less energy absorbed, cooling times between sonications may be substantially reduced. For example, where conventional FUS may require ninety seconds or more of cooling time between sonications, systems in accordance with the present invention may allow cooling times of about forty seconds or less.
Thus, in either case, an overall treatment time to ablate or otherwise treat a target tissue structure may be substantially reduced as compared to conventional FUS without microbubbles.
While the invention is susceptible to various modifications and alternative forms, specific examples thereof have been shown in the drawings and are herein described in detail. It should be understood, however, that the invention is not to be limited to the particular forms or methods disclosed, but to the contrary, the invention is to cover all modifications, equivalents and alternatives falling within the scope of the appended claims.