KR20160109390A - High Intensity Focused Ultrasound Treatment Head - Google Patents

Abstract

Disclosed is a high-intensity focused ultrasound (HIFU) treatment head for rapidly and effectively removing bubbles. A high-intensity radiation frame of an HIFU transducer has a high-intensity ultrasonic radiation surface. A membrane forms an accommodation space for accommodating an ultrasonic transferring medium between the high-intensity ultrasonic radiation surface and the membrane. An imaging transducer penetrates through and is inserted into the center of the high-intensity radiation frame. An ultrasound transferring medium supplying unit supplies an external ultrasound transferring medium into the accommodation space, and sprays the ultrasound transferring medium from the outside to the inside of the high-intensity ultrasonic radiation surface, so that the ultrasound transferring medium flows around the high-intensity ultrasonic radiation surface. An ultrasound transferring medium discharge unit is adjacently arranged at the imaging transducer to discharge the ultrasound transferring medium inside the accommodation space to the outside.

Description

{High Intensity Focused Ultrasound Treatment Head}

The present invention relates to a high-intensity focused ultrasound treatment head used for treating high-intensity ultrasound energy by collecting high-energy ultrasound energy at a focus.

High-Intensity Focused Ultrasound (HIFU) is a procedure that burns lesions in the body using high-intensity heat of 65 to 100 degrees Celsius, which occurs when focusing high-intensity ultrasound energy in one place. In other words, when the ultrasound strong enough to be about 100,000 times stronger than the ultrasonic intensity used in diagnosis is focused on one place, heat is generated in the focus region, and the heat can be used to burn out the lesion tissue in the body.

Ultrasound itself is harmless to the human body and generates heat only at the focal point where the ultrasonic waves are concentrated, so that the lesion in the body can be treated non-invasively. High-intensity focused ultrasound therapy is available for pancreatic cancer, uterine myoma, and liver cancer, and active research is being conducted on prostate cancer, endometrial cancer, kidney cancer, breast cancer, soft tissue tumor, and bone tumor.

The high intensity focused ultrasound treatment head according to a conventional example includes a high intensity focused ultrasonic transducer at the end. The high intensity focused ultrasonic transducer is configured to emit high intensity focused ultrasonic waves. The membrane is mounted on a high intensity focused ultrasonic transducer to cover the high intensity ultrasound emission surface of the high intensity focused ultrasonic transducer. In this state, the ultrasonic transmission medium is filled in the receiving space between the high-intensity ultrasonic wave emitting surface and the membrane. Generally, deaerated water is used as an ultrasonic transmission medium. In addition, the high intensity focused ultrasound therapy head may be provided with an imaging transducer for acquiring diagnostic images.

The high-intensity focused ultrasound treatment head is positioned at the upper part of the patient, and irradiates a high-intensity focused ultrasonic wave through the high-intensity ultrasound irradiation surface while the membrane is in contact with the patient's skin. The high-intensity focused ultrasound is then transmitted to the patient's lesion through the filled water in the receiving space between the high intensity ultrasound radiating surface and the membrane.

On the other hand, after the membrane is initially installed or replaced in a high intensity focused ultrasonic transducer, water is filled into the empty accommodation space between the high intensity ultrasonic wave emitting surface and the membrane. In this process, air bubbles are generated and stick to the high intensity ultrasound emission surface. When the high intensity focused ultrasound treatment is performed in this state, the bubbles in the receiving space can be instantaneously generated at a high temperature by bursting by the high intensity focused ultrasonic waves. This can lead to serious risks such as burns to the skin of the patient. Further, the bubbles in the accommodation space may be a factor for distorting the diagnostic image data acquired by the imaging transducer.

Therefore, before performing high-intensity focused ultrasound therapy, it is necessary that all air bubbles in the receiving space be removed. At this time, the longer the time for removing the bubbles becomes, the longer the treatment time becomes. Therefore, it is preferable that the bubbles are quickly removed. In addition, high intensity focused ultrasound treatment may cause bubbles in the water due to high intensity focused ultrasound, which may adhere to the high intensity ultrasound emitting surface. In this situation, when high intensity focused ultrasound therapy is resumed, it can cause the above-mentioned problems. Therefore, it is necessary to remove bubbles quickly before high-intensity focused ultrasound therapy can be resumed.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a high-intensity focused ultrasound treatment head capable of removing bubbles more rapidly and effectively.

According to an aspect of the present invention, there is provided a high intensity focused ultrasound treatment head including a high intensity focusing ultrasonic transducer, a membrane, an imaging transducer, an ultrasonic transmission medium supply unit, and an ultrasonic transmission medium discharge unit. The high-intensity focusing ultrasonic transducer has a high-intensity ultrasonic generator for generating a high-intensity ultrasonic wave and a high-intensity ultrasonic wave generator having a concave curved surface at a central portion at the bottom. The high intensity ultrasonic transducer concentrates the high-intensity ultrasonic wave generated from the high- And a radiation frame. The membrane is mounted to cover the high intensity ultrasound emission surface of the high intensity ultrasound emission frame and forms a receiving space for receiving the ultrasound transmission medium between the high intensity ultrasound emission surface. The imaging transducer is inserted through the center of the high intensity ultrasound radiation frame. The ultrasound transmission medium supply unit is disposed at the edge of the high intensity ultrasound radiation frame to supply the ultrasound transmission medium into the accommodation space and injects the ultrasound transmission medium from the outside of the high intensity ultrasound emission plane to the inside of the high intensity ultrasound emission plane, And flows near the slope. The ultrasonic transmission medium ejection portion is disposed at a central portion of the high intensity ultrasonic radiation frame adjacent to the imaging transducer to eject the ultrasonic transmission medium in the accommodation space to the outside.

The high intensity focused ultrasound treatment head according to the present invention includes a high intensity focusing ultrasonic transducer, a membrane, an ultrasonic transmission medium supply unit, and an ultrasonic transmission medium discharge unit. The high-intensity focusing ultrasonic transducer includes a high-intensity ultrasonic wave generator for generating high-intensity ultrasonic waves and a high-intensity ultrasonic wave radiation frame for focusing high-intensity ultrasonic waves generated from the high-intensity ultrasonic wave generator. The membrane is mounted to cover the high intensity ultrasound emission surface of the high intensity ultrasound emission frame and forms a receiving space for receiving the ultrasound transmission medium between the high intensity ultrasound emission surface. The ultrasound transmission medium supply unit is disposed in the high intensity ultrasound emission frame to supply the external ultrasound transmission medium into the accommodation space and inject the ultrasound transmission medium to flow in the vicinity of the high intensity ultrasound emission plane. The ultrasonic transmission medium discharge portion is disposed in the high-intensity ultrasonic wave radiation frame to discharge the ultrasonic transmission medium in the accommodation space to the outside.

According to the present invention, after the membrane is initially mounted or replaced in a high-intensity focusing ultrasonic transducer, the bubbles generated in the process of filling the space for receiving ultrasonic waves into the space for accommodating the space between the high-intensity ultrasonic wave emitting surface and the membrane are quickly removed can do. In addition, bubbles generated by high-intensity focused ultrasonic waves can be quickly removed from the accommodation space during high intensity focused ultrasound therapy. Therefore, the time required for high-intensity focused ultrasound therapy can be shortened.

According to the present invention, when the ultrasonic transmission medium in the receiving space is cooled, the temperature distribution of the ultrasonic transmission medium can be uniformized in the receiving space, so that the cooling temperature of the ultrasonic transmission medium can be accurately monitored.

1 is a cross-sectional view of a high intensity focused ultrasound therapy head according to an embodiment of the present invention.
FIG. 2 is a cross-sectional view for explaining the process of removing air bubbles while filling the receiving space with the ultrasonic wave transmission medium in FIG.
FIG. 3 is a cross-sectional view of FIG. 2 showing an enlarged view of region A. FIG.
Fig. 4 is a bottom view of Fig. 3 showing an example in which the jetting direction of the jetting guide member is inclined with respect to the radial direction of the high-intensity ultrasonic wave emitting surface.
5 is a bottom view showing another example of the discharge port.
Fig. 6 is a bottom view showing another example of the discharge port in Fig. 5;
7 is a bottom view showing another example of the injection guide member.
8 is a cross-sectional view of a high intensity focused ultrasound treatment head according to another embodiment of the present invention.

The present invention will now be described in detail with reference to the accompanying drawings. Here, the same reference numerals are used for the same components, and a detailed description of known functions and configurations that may unnecessarily obscure the gist of the present invention will be omitted. Embodiments of the present invention are provided to more fully describe the present invention to those skilled in the art. Accordingly, the shapes and sizes of the elements in the drawings and the like can be exaggerated for clarity.

1 is a cross-sectional view of a high intensity focused ultrasound therapy head according to an embodiment of the present invention. FIG. 2 is a cross-sectional view for explaining the process of removing air bubbles while filling the receiving space with the ultrasonic wave transmission medium in FIG. FIG. 3 is a cross-sectional view of FIG. 2 showing an enlarged view of region A. FIG.

1 to 3, the high-intensity focusing ultrasound treatment head 100 includes a high-intensity focusing ultrasonic transducer 110, a membrane 120, an imaging transducer 130, an ultrasonic transmission medium supply unit 140, And an ultrasonic transmission medium discharge unit 150.

The high intensity focused ultrasound transducer 110 is configured to emit high intensity focused ultrasound for patient treatment. The high-intensity focusing ultrasonic transducer 110 includes a high-intensity ultrasonic wave generator 111 and a high-intensity ultrasonic wave radiation frame 112.

The high-intensity ultrasonic wave generator 111 generates high-intensity ultrasonic waves. For example, the high-strength ultrasonic wave generator 111 may be mounted on the high-intensity ultrasonic wave radiation frame 112. Although not shown, the high-strength ultrasonic wave generator 111 can be electrically connected to the driving circuit board by wiring or the like. The driving circuit substrate may be disposed above the high-intensity ultrasound radiation frame 112.

The high-strength ultrasonic wave generator 111 may include a piezoelectric element. When a voltage is applied by the driver circuit substrate, the piezoelectric element resonates and generates ultrasonic waves. Piezoelectric elements can be composed of piezoelectric ceramics such as lead zirconate titanate (PZT), single crystals, and composite piezoelectric materials in which these materials and polymer materials are combined. Also, the high-strength ultrasonic wave generator 111 may include an acoustic matching layer. The acoustic matching layer is located on one side of the piezoelectric element to enable resonance characteristics to be appropriately set. The high-intensity ultrasound generating unit 111 may be configured in various forms within a range capable of generating high-intensity ultrasound, and thus is not limited to the illustrated example.

The high-intensity ultrasound wave radiating frame 112 has a high-intensity ultrasound wave radiating surface 112a formed in a curved surface shape having a central concave at the bottom, and concentrates and emits the high-intensity ultrasound generated from the high- For example, the high-intensity ultrasound emission frame 112 may have a substantially hemispherical shape with a certain thickness.

The high intensity ultrasound radiation frame 112 may be received in the housing 103. The housing 103 may have a cylindrical shape with an internal space. The lower side of the housing 103 can be opened to expose the high intensity ultrasound wave radiating surface 112a of the high intensity ultrasound radiation frame 112. [ The high intensity ultrasound emission frame 112 may be formed such that a rim is coupled to the lower opening portion of the housing 103 to close the lower opening of the housing 103. [

The membrane 120 is mounted so as to cover the high intensity ultrasonic wave emitting surface 112a and forms a receiving space 102 for receiving the ultrasonic wave transmission medium 101 between the high intensity ultrasonic wave emitting surface 112a and the high intensity ultrasonic wave emitting surface 112a. The ultrasonic transmission medium 101 may be made of deaerated water or the like. For example, the membrane 120 is configured to enclose the lower opening of the housing 103 and a part of the side surface together, and may be sealed in the side surface of the housing 103. The membrane 120 is also capable of being coupled in a sealed manner to the rim of the high intensity ultrasound radiation frame 112, and thus is not limited to the illustrated example.

The membrane 120 may be made of a material having an acoustic impedance similar to that of the ultrasonic transmission medium 101 and having a low ultrasonic transmission loss and having excellent elasticity. For example, the membrane 120 may be made of a material such as ethylene propylene diene monomer (EPDM) rubber, latex rubber, silicone rubber, or the like. The membrane 120 has a shape as shown in FIG. 1 in a state in which the ultrasonic transmission medium 101 is not accommodated in the accommodation space 102. In this state, when the accommodation space 102 is filled with the set amount of the ultrasonic transmission medium 101, the membrane 120 can be deformed into an approximately hemispherical shape, as shown in Fig.

The imaging transducer 130 is for acquiring a diagnostic image of the subject. The practitioner can perform high-intensity focused ultrasound therapy while confirming the diagnostic image acquired by the imaging transducer 130. The imaging transducer 130 may be configured to transmit an ultrasound signal to a subject and to receive ultrasound signals reflected from the subject. For example, the imaging transducer 130 may be configured such that a piezoelectric element or the like is embedded in a cylindrical casing. Ultrasonic waves can be transmitted and received through the lower surface of the imaging transducer 130.

The imaging transducer 130 is inserted through the center of the high intensity ultrasound emission frame 112. An insertion hole for insertion of the imaging transducer 130 may be formed at the center of the high-intensity ultrasound radiation frame 112. The high-intensity ultrasound radiation frame 112 may include a flange portion 112b protruding along the upper opening of the insertion hole.

The periphery of the imaging transducer 130 can be surrounded by the partition 103a in the housing 103. [ The lower portion of the partition wall 103a can be coupled to the flange portion 112b of the high-intensity ultrasound emission frame 112. [ The imaging transducer 130 and the partition 103a may be sealed and coupled so that the ultrasonic transmission medium 101 does not leak between the imaging transducer 130 and the partition 103a.

The ultrasound transmission medium supply unit 140 is disposed at an edge portion of the high intensity ultrasound emission frame 112 to supply the external ultrasound transmission medium 101 into the accommodation space 102. The ultrasonic wave transmission medium supplying unit 140 injects the ultrasonic wave transmission medium 120 from the outside of the high intensity ultrasonic wave emitting surface 112a to the inside of the high intensity ultrasonic wave emitting surface 112a and flows in the vicinity of the high intensity ultrasonic wave emitting surface 112a. Therefore, the bubble 10 attached to the high-intensity ultrasonic wave emitting surface 112a is separated from the high-intensity ultrasonic wave emitting surface 112a by the ultrasonic wave transmission medium 101 flowing near the high-intensity ultrasonic wave emitting surface 112a, And can be guided and moved to the inside of the emitting surface 112a. Since the high intensity ultrasound wave radiating surface 112a has a concave curved surface at the center of the high intensity ultrasound wave radiating surface 112a, the bubble 10 detached from the high intensity ultrasound wave radiating surface 112a is converged to the highest portion of the high intensity ultrasound wave radiating surface 112a have.

For example, the jetting direction of the ultrasonic transmission medium supply unit 140 may be set to flow the ultrasonic transmission medium 101 along the high-intensity ultrasonic wave emitting surface 112a. The ultrasonic wave transmission medium 101 flows along the high intensity ultrasonic wave emitting surface 112a and can more effectively remove the bubble 10 from the high intensity ultrasonic wave emitting surface 112a. The ultrasonic transmission medium supply unit 140 may include at least one inlet port 141 and an injection inducing member 142.

The supply port 141 may be formed by passing the edge portion of the high-intensity ultrasound radiation frame 112 up and down. The supply port 141 can flow the ultrasonic transmission medium 101 through the inlet and flow out the ultrasonic transmission medium 101 through the outlet. A plurality of supply ports 141 may be provided. In this case, the supply ports 141 are arranged apart from each other along the edge portions of the high-intensity ultrasound emission frame 112. The supply ports 141 may be arranged at regular intervals.

The jetting guide member 142 is connected to the outlet of the supply port 141 so that the jetting direction is set to flow the ultrasonic transmission medium 101 along the high-intensity ultrasonic wave emitting surface 112a. The injection guide member 142 may be disposed in the receiving space 102. The jetting guide member 142 may receive the ultrasonic transmission medium 101 from the supply port 141 through the inlet port and inject the ultrasonic transmission medium 101 into the receiving space 102 through the jetting port 142a.

When a plurality of supply ports 141 are provided, the plurality of injection guide members 142 may be connected to the respective outlets of the supply ports 141. Then, the jetting guide members 142 are set so that each jetting direction causes the ultrasonic wave transmission medium 101 to flow along the high-intensity ultrasonic wave emitting surface 112a. The jetting direction of the jetting guide member 142 can be set to be parallel to the tangential direction of the portion of the high intensity ultrasonic wave emitting surface 112a adjacent to the jetting port 142a. Needless to say, the jetting direction of the jetting guide member 142 may be variously set in a range of flowing the ultrasonic wave propagating medium along the high-intensity ultrasonic wave emitting surface 112a.

The injection inducing member 142 may be attached to the high-intensity ultrasonic wave emitting surface 112a. The injection guide member 142 has a passage 142b connecting the inlet port and the injection port. The passageway 142b may be in the form of a tapered, or elongated, groove in contact with the high-intensity ultrasound wavefront 112a. Accordingly, the jetting port 142a of the jetting guide member 142 can be positioned as close as possible to the high-intensity ultrasonic wave emitting surface 112a. The passage 142b may be configured to extend in parallel to the high-intensity ultrasonic radiation surface 112a. Although not shown, the passage 142a may have a shape in which a portion in contact with the high-intensity ultrasonic wave radiating surface 112a is clogged, that is, in the form of an elongated hole. In addition, the injection guide member 142 may have a structure in which the inlet port is fitted and fixed to the outlet of the supply port 141.

The number of the supply ports 141 and the jetting pressure of the ultrasonic wave transmission medium 101 in the ultrasonic wave transmission medium supply unit 140 are set such that the bubbles 10 attached to the high intensity ultrasonic wave radiation surface 112a are separated from the high intensity ultrasonic wave radiation surface 112a To the ultrasonic wave transmission medium discharging unit 150. The ultrasonic wave transmission medium discharging unit 150 may be configured to move the ultrasonic wave to the ultrasonic transmission medium discharging unit 150,

A supply pipe 143 may be connected to each inlet of the supply ports 141. Although not shown, the supply tube 143 may be formed so as to wrap around the imaging transducer 130 at least one time in the inner space of the housing 103. The ultrasonic transmission medium 101 flowing along the inside of the supply pipe 143 can cool the internal space of the housing 103 through heat exchange. Therefore, it is possible to cool the high-intensity ultrasonic wave generator 111, the driving circuit board, and the like that generate heat during the high-intensity focused ultrasonic wave treatment.

The ultrasonic transmission medium discharging unit 150 discharges the ultrasonic transmission medium 101 in the receiving space 102 to the outside. The ultrasonic transmission medium ejection unit 150 is disposed at a central portion of the high-intensity ultrasonic radiation frame 112 adjacent to the imaging transducer 130. Accordingly, the ultrasonic transmission medium discharging unit 150 may be arranged at a higher position than the ultrasonic transmission medium supplying unit 140, and may be disposed at the highest position of the high-intensity ultrasonic wave emitting surface 112a. The bubbles 10 separated from the high intensity ultrasonic wave emitting surface 112a by the ultrasonic wave transmission medium supplying unit 140 and gathered at the highest position of the high intensity ultrasonic wave emitting surface 112a are separated by the ultrasonic wave transmitting medium discharging unit 150 .

For example, the ultrasound transmission medium outlet 150 may include at least one outlet port 151. The discharge port 151 may be formed through a central portion of the high-intensity ultrasound emission frame 112. The discharge port 151 can flow the ultrasonic transmission medium 101 in the accommodation space 102 through the inlet and allow the ultrasonic transmission medium 101 to flow out through the outlet. The plurality of discharge ports 151 may be provided. In this case, the discharge ports 151 may be arranged apart from each other along the periphery of the imaging transducer 130. The discharge ports 151 may be arranged at regular intervals.

A discharge pipe 152 may be connected to each outlet of the discharge ports 151. The outlet port 151 may extend to the flange portion 112b and the outlet pipe 152 may be connected to the flange portion 112b. The discharge pipe 152 may be connected to the circulation device (not shown) together with the supply pipe 143. The circulation device can be configured to deaerate and cool the ultrasound transmission medium 101 discharged from the receiving space 102 through the discharge pipe 152 and supply the ultrasound transmission medium 101 back into the receiving space 102 through the supply pipe 143 have. The discharge tube 152 is formed so as to surround the imaging transducer 130 at least once in the internal space of the housing 103 as in the case of the supply tube 143 so that the high intensity ultrasound generating unit 111 and the driving circuit substrate Can be cooled.

An example of the operation of the high-intensity focused ultrasound therapy head 100 will be described with reference to FIGS. 1 to 3. FIG.

After the membrane 120 is initially mounted or replaced in the high intensity focusing ultrasonic transducer 110 by the operator, the ultrasonic transmission medium 101 is moved by the ultrasonic transmission medium supply unit 140 to the high intensity ultrasonic wave emitting surface 112a and the membrane 120 into the empty accommodation space 102. At this time, the ultrasonic transmission medium 101 is filled in the accommodation space 102 by a predetermined amount while being injected from the outside of the high-strength ultrasonic wave emitting surface 112a to the inside of the high intensity ultrasonic wave emitting surface 112a by the ultrasonic transmission medium supplying unit 140 . In this process, when the bubble 10 is generated in the accommodation space 102 and stuck to the high-intensity ultrasonic wave emitting surface 112a, the ultrasonic wave transmission medium 101 flows near the high-intensity ultrasonic wave emitting surface 112a at the time of jetting , The bubble 10 is detached from the high-intensity ultrasound wave radiating surface 112a. Thereafter, the bubble 10 is partially moved to the periphery of the imaging transducer 130 and collected.

In this state, the ultrasonic transmission medium 101 is discharged from the receiving space 102 by the ultrasonic transmission medium discharging unit 150 and the ultrasonic transmission medium 101 is discharged to the ultrasonic transmission medium supplying unit 140 by the amount of the ultrasonic transmission medium 101 And supplies the ultrasonic transmission medium 101 into the receiving space 102. [ In this process, when discharging the ultrasonic transmission medium 101 by the ultrasonic transmission medium discharging unit 150, the bubbles 10 gathered around the imaging transducer 130 are discharged together with the ultrasonic transmission medium 101 . When the ultrasonic transmission medium 101 is supplied into the receiving space 102 by the ultrasonic transmission medium supply unit 140, the residual bubbles 10 are transferred to the imaging transducer 130 by the flow of the ultrasonic transmission medium 101. [ It continues to gather around. The collected bubbles 10 can be discharged by the ultrasonic transmission medium discharging unit 150.

By this process, the bubble 10 in the accommodation space 102 can be removed more quickly and effectively. As a result, it is possible to shorten the time required for filling the ultrasonic wave transmission medium 101 with a predetermined amount in the accommodation space 102 without the bubble 10 for the high-intensity focused ultrasonic wave treatment.

Then, the high intensity focused ultrasound therapy head 100 is placed on the patient's upper side, and the high-intensity focused ultrasound wave is emitted by the high intensity focused ultrasonic transducer 110 while the membrane 120 is in contact with the patient's skin. Then, the high-intensity focused ultrasound can be irradiated to the lesion area of the patient through the ultrasound transmission medium 101 between the high-intensity ultrasound radiation frame 112 and the membrane 120.

In this way, in the process of irradiating and treating the high-intensity focused ultrasonic wave once, the ultrasonic wave transmission medium 101 can be heated by the high-intensity focused ultrasonic wave. Therefore, the bubble 10 may be generated in the receiving space 102 and stuck to the high-intensity ultrasonic wave emitting surface 112a. Before resuming high-intensity focused ultrasound therapy, the ultrasonic transmission medium is circulated in order to replace the heated ultrasonic transmission medium 101 in the accommodation space 102 with the external cooled ultrasonic transmission medium, The bubble 10 can be quickly removed.

The ultrasound transmission medium 101 is discharged from the receiving space 102 by the ultrasound transmission medium discharge unit 150 and the ultrasound transmission medium 101 is discharged by the amount of the ultrasound transmission medium 101 The ultrasonic wave transmission medium 101 in the cooled state is supplied into the receiving space 102 by the ultrasonic wave transmitting medium 101. [ The bubble 10 is continuously collected around the imaging transducer 130 by the flow of the ultrasonic transmission medium 101 when the ultrasonic transmission medium 101 is supplied by the ultrasonic transmission medium supply unit 140 The bubbles 10 thus collected can be discharged together with the ultrasonic wave transmission medium 101 by the ultrasonic wave transmission medium discharging unit 150. Therefore, the bubble 10 in the accommodation space 102 can be removed more quickly and effectively.

Since the high-intensity focused ultrasound treatment can be resumed in the state where the bubble 10 in the accommodation space 102 is removed, it is possible to prevent the phenomenon that the bubble 10 bursts during the high- have. Thus, the patient can safely receive high intensity focused ultrasound therapy without risk of burns. Further, the diagnostic image data obtained by the imaging transducer 130 can be prevented from being distorted due to the bubble 10.

4, the jetting direction SD of the jetting guide member 142 of the ultrasonic transmission medium supply unit 140 may be inclined with respect to the radial direction RD of the high-intensity ultrasonic wave emitting surface 112a . Accordingly, the ultrasonic transmission medium injected from the injection inducing member 142 can flow in the form of a spiral on the high-intensity ultrasonic wave emitting surface 112a, as indicated by the arrows.

Since the ultrasonic wave propagating medium injected from the jetting guide member 142 flows in a spiral form from the outside of the high intensity ultrasonic wave emitting surface 112a to the inside of the high intensity ultrasonic wave emitting surface 112a as described above, It is subjected to rotational motion such as vortex. Accordingly, the region where the flow of the ultrasonic transmission medium occurs can be increased in the high-intensity ultrasonic wave emitting surface 112a. Accordingly, the process of removing the bubble from the high-intensity ultrasonic wave emitting surface 112a and moving it to the ultrasonic transmission medium discharging unit 150 can be performed quickly.

When a plurality of the injection guide members 142 are provided, the injection guide members 142 may be set to have the same inclination direction with respect to the radial direction RD of the high-intensity ultrasonic radiation surface 112a. For example, the injection inducing members 142 are inclined counterclockwise with respect to the radial direction RD of the high-intensity ultrasonic wave emitting surface 112a so that the ultrasonic wave propagating medium flows in a counterclockwise helical manner . Alternatively, the jetting inductors 142 may be inclined in the clockwise direction with respect to the radial direction RD of the high-intensity ultrasonic wave emitting surface 11 so as to cause the ultrasonic wave propagating medium to flow in a clockwise direction have.

Since the ultrasonic wave propagating medium jetted from the jetting guide members 142 flows in a spiral form from the outer side of the high intensity ultrasonic wave emitting surface 112a to the inside of the high intensity ultrasonic wave emitting surface 112a as described above, the high intensity ultrasonic wave emitting surface 112a to rotate like a whirlpool. At this time, the ultrasonic transmission medium injected from any one of the injection inducing members 142 may be mixed with the ultrasonic transmission medium injected from the other injection inducing member 142.

Accordingly, the region where the flow of the ultrasonic wave transmission medium occurs can be further increased in the high-intensity ultrasonic wave emitting surface 112a. Therefore, the bubbles can be easily removed from the high-intensity ultrasonic wave emitting surface 112a. The bubbles separated from the high intensity ultrasonic wave emitting surface 112a are separated from the ultrasonic wave transmission medium discharge unit 150 and the ultrasonic wave transmission medium discharge unit 150. In this case, since the ultrasonic wave transmission medium discharge unit 150 is disposed higher than the ultrasonic transmission medium supply unit 140, The ultrasonic transmission medium can be smoothly collected toward the ultrasonic transmission medium discharge unit 150 by the difference in height between the medium supply units 140 and then quickly discharged through the ultrasonic transmission medium discharge unit 150.

In addition, when the ultrasonic transmission medium is spirally injected in the process of cooling the ultrasonic transmission medium 101 in the accommodation space 102, the ultrasonic transmission medium flows over the entire high-strength ultrasonic wave irradiation surface 112a, The temperature distribution of the transfer medium can be made even. Therefore, the cooling temperature of the ultrasonic transmission medium can be accurately monitored. On the other hand, the jetting guiding members 142 may be inclined at the same angle with respect to the radial direction of the high-intensity ultrasonic wave emitting surface 112a.

As shown in FIG. 5, the discharge port 151 'may have a structure in which a band-shaped inlet is formed along the periphery of the imaging transducer 130 on the high-intensity ultrasound wave radiating surface 112a. When the periphery of the imaging transducer 130 is circular, the inlet of the discharge port 151 'may be a circular band. In this case, the discharge port 151 'may be formed as a circular band-shaped depression along the periphery of the imaging transducer 130 from the high-intensity ultrasonic wave emitting surface 112a. The discharge port 151 'may be formed along the periphery of the insertion hole of the high-intensity ultrasound radiation frame 112.

The discharge port 151 'may have at least one outlet formed in the flange portion 112b of the high-intensity ultrasound radiation frame 112 and connected to the depression groove. Since the discharge port 151 'has a band-shaped inlet along the periphery of the imaging transducer 130, the ultrasonic transmission medium injected from each of the jetting inductive members 142 is guided by the imaging transducer 130 The air bubbles can be collected more effectively in the process of flowing along the periphery of the air bubbles.

6, the plurality of discharge ports 151 " may be formed as recessed grooves, respectively, in the shape of arcs of an arc along the periphery of the imaging transducer 130, .

As shown in FIG. 7, each of the jetting guide members 142 'may be in the form of a tube. The injection inducing member 142 'may be fitted to the supply port 141. The jetting guide member 142 'can be attached to the edge of the high-intensity ultrasonic wave emitting surface 112a. The injection inducing member 142 'may be directly connected to the supply pipe 143.

8 is a cross-sectional view of a high intensity focused ultrasound treatment head according to another embodiment of the present invention.

Referring to FIG. 8, the high-intensity focused ultrasound therapy head 200 according to the present embodiment may have a configuration in which the imaging transducer 130 is omitted in the above-described embodiment.

The high-intensity focusing ultrasonic transducer 210 includes a high-intensity ultrasonic wave generator 211 for generating high-intensity ultrasonic waves and a high-intensity ultrasonic wave radiating frame 212 for focusing the high-intensity ultrasonic waves generated from the high- . The ultrasonic wave generator 211 may be configured in the same manner as the ultrasonic wave generator 111 of the above-described embodiment.

The high-intensity ultrasound wave radiating surface 212a may have a concave curved shape with a center at the bottom of the high-intensity ultrasound radiation frame 212. The membrane 220 is mounted so as to cover the high-intensity ultrasound emission surface 212a of the high-intensity ultrasound emission frame 212. [ The membrane 220 forms a receiving space 202 for receiving the ultrasonic transmission medium 101 between the ultrasonic wave emitting surface 212a and the high intensity ultrasonic wave emitting surface 212a. The membrane 220 may be constructed in the same manner as the membrane 120 of the above-described embodiment.

The ultrasound transmission medium supply unit 240 is disposed in the high intensity ultrasound emission frame 212 to supply the external ultrasound transmission medium 101 into the accommodation space 202. The ultrasonic wave transmission medium supply unit 240 injects the ultrasonic wave transmission medium 101 to flow in the vicinity of the high intensity ultrasonic wave emitting surface 212a. The bubbles attached to the high intensity ultrasonic wave emitting surface 212a are easily separated from the high intensity ultrasonic wave emitting surface 212a by the ultrasonic wave transmission medium 101 flowing near the high intensity ultrasonic wave emitting surface 212a, And can move along the flow direction of the medium 101. The ultrasonic wave transmission medium supply unit 240 can jet the ultrasonic transmission medium 101 from the outside of the high intensity ultrasonic wave emitting surface 212a to the inside of the high intensity ultrasonic wave emitting surface 212a. Accordingly, the bubbles can be collected and guided to the center of the high-intensity ultrasonic wave emitting surface 212a.

The jetting direction of the ultrasonic wave transmission medium supply unit 240 may be set to flow the ultrasonic wave transmission medium 101 along the high intensity ultrasonic wave emitting surface 212a. Accordingly, the ultrasonic wave transmission medium 101 can efficiently remove air bubbles from the high-intensity ultrasonic wave emitting surface 212a while flowing along the high-intensity ultrasonic wave emitting surface 212a. The jetting direction of the ultrasonic wave transmission medium supply unit 240 may be inclined with respect to the radial direction of the high intensity ultrasonic wave emitting surface 212a. Accordingly, the region where the flow of the ultrasonic wave transmission medium 101 occurs can be increased in the high-intensity ultrasonic wave emitting surface 212a. The ultrasonic transmission medium supply unit 240 may be configured in the same manner as the ultrasonic transmission medium supply unit 140 of the above-described embodiment.

The ultrasonic transmission medium discharge unit 250 is disposed in the high-intensity ultrasonic wave radiation frame 212 to discharge the ultrasonic transmission medium 101 in the accommodation space 202 to the outside. The ultrasonic transmission medium discharging unit 250 can discharge the ultrasonic transmission medium 101 inside the high-intensity ultrasonic wave emitting surface 212a.

When the high intensity ultrasound wave radiating surface 212a is formed in a curved shape with a center at the bottom of the high intensity ultrasound wave radiating frame 212, the ultrasound transmission medium discharging portion 250 may be positioned higher than the ultrasound transmission medium supplying portion 240 have. The ultrasonic transmission medium discharge unit 250 may be disposed at the apex of the high-intensity ultrasonic wave emitting surface 212a. Accordingly, the bubbles separated from the high-intensity ultrasonic wave emitting surface 212a smoothly move to the peak of the high-intensity ultrasonic wave emitting surface 212a and are collected in the ultrasonic wave transmitting medium discharging unit 250, and can be quickly discharged. The ultrasound transmission media outlet 250 may include at least one outlet port.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is clearly understood that the same is by way of illustration and example only and is not to be taken by way of limitation and that those skilled in the art will recognize that various modifications and equivalent arrangements may be made therein. It will be possible. Accordingly, the true scope of protection of the present invention should be determined only by the appended claims.

101 .. Ultrasonic transmission medium
102, 202.
110, 210 .. High intensity focusing ultrasonic transducer
112, 212 .. High intensity ultrasound radiation frame
112a, 212a. High intensity ultrasound emitting surface
120, 220 .. Membrane
130 .. Imaging transducer
140, 240 .. Ultrasonic transmission medium supply part
141 .. Supply Port
142, 142 '
150, 250 .. Ultrasonic transmission medium discharge unit
151, 151 ' 151 ", 251,

Claims (14)

Intensity ultrasound generating unit having a high-intensity ultrasound generating unit having a high-intensity ultrasound emitting surface formed in a curved surface shape concaved at the center at a lower portion and a high-intensity ultrasound emitting frame for focusing and emitting high-intensity ultrasound generated from the high- High intensity focused ultrasonic transducer;
A membrane mounted to cover the high intensity ultrasound emission plane of the high intensity ultrasound emission frame and forming a receiving space for receiving the ultrasound transmission medium between the high intensity ultrasound emission plane and the high intensity ultrasound emission plane;
An imaging transducer inserted through the center of the high intensity ultrasound radiation frame;
Wherein the ultrasound transmission medium is disposed at an edge portion of the high intensity ultrasound radiation frame to supply an external ultrasound transmission medium into the accommodating space and emit the ultrasound transmission medium from the outside of the high intensity ultrasound emitting plane to the inside of the high intensity ultrasound emitting plane, An ultrasonic wave transmission medium supply unit for flowing the ultrasonic wave in the vicinity of the slope; And
An ultrasonic transmission medium discharge unit disposed at a central portion of the high intensity ultrasound radiation frame adjacent to the imaging transducer for discharging the ultrasonic transmission medium in the accommodation space to the outside;
Wherein the high intensity focused ultrasound treatment head comprises: The method according to claim 1,
Wherein the ultrasonic transmission medium supply unit comprises:
At least one supply port formed through an edge portion of the high intensity ultrasound radiation frame and an injection inducing member connected to an outlet of the supply port and configured to inject the ultrasound transmission medium along the high intensity ultrasound emission plane Wherein said high intensity focused ultrasound treatment head is a high intensity focused ultrasound treatment head. 3. The method of claim 2,
Wherein the jetting member is inclined with respect to a radial direction of the high-intensity ultrasound wave radiating surface. The method of claim 3,
The injection guide member
Wherein a plurality of supply ports are provided corresponding to the plurality of supply ports and are connected to the respective outlets of the supply ports and the inclination directions of the high intensity focused ultrasound waves are set to be the same with respect to the radial direction of the high intensity ultrasound wave radiating surface Treatment head. The method according to claim 1,
Wherein the ultrasound transmission medium discharging portion includes at least one discharge port formed through a central portion of the high-intensity ultrasound radiation frame. The method according to claim 1,
Wherein the ultrasonic transmission medium discharging portion includes a discharge port formed on the high-intensity ultrasonic wave emitting surface and having a band-shaped inlet formed along the periphery of the imaging transducer. A high intensity focused ultrasound transducer having a high intensity ultrasound generating unit for generating high intensity ultrasound and a high intensity ultrasound radiation frame for focusing and emitting high intensity ultrasound generated from the high intensity ultrasound generating unit;
A membrane mounted to cover the high intensity ultrasound emission plane of the high intensity ultrasound emission frame and forming a receiving space for receiving the ultrasound transmission medium between the high intensity ultrasound emission plane and the high intensity ultrasound emission plane;
An ultrasound transmission medium supply unit disposed in the high intensity ultrasound emission frame for supplying an external ultrasound transmission medium into the accommodation space and injecting the ultrasound transmission medium to flow in the vicinity of the high intensity ultrasound emission plane; And
An ultrasonic transmission medium discharge unit disposed in the high-intensity ultrasonic wave radiation frame for discharging the ultrasonic transmission medium in the accommodation space to the outside;
Wherein the high intensity focused ultrasound treatment head comprises: 8. The method of claim 7,
Wherein the ultrasonic transmission medium supplying unit injects the ultrasonic transmission medium from the outside of the high-intensity ultrasonic wave emitting surface to the inside of the high-intensity ultrasonic wave emitting surface. 9. The method of claim 8,
Wherein the jetting direction of the ultrasonic transmission medium supply unit is set to flow the ultrasonic transmission medium along the high intensity ultrasonic wave emitting surface. 10. The method of claim 9,
Wherein the jetting direction of the ultrasonic wave transmission medium supplying unit is inclined with respect to the radial direction of the high-intensity ultrasonic wave emitting surface. 9. The method of claim 8,
Wherein the ultrasound transmission medium discharging unit discharges the ultrasound transmission medium from the inside of the high intensity ultrasound wave radiating surface. 12. The method of claim 11,
Wherein the high intensity ultrasound wave radiating surface has a concave curved shape with a center at a lower portion of the high intensity ultrasound radiation frame so that the ultrasound transmission medium discharge portion is located higher than the ultrasound transmission medium supplying portion. 8. The method of claim 7,
Further comprising an imaging transducer inserted through the center of the high intensity ultrasound radiation frame. 14. The method of claim 13,
Wherein the ultrasound transmission medium discharge unit is disposed adjacent to the imaging transducer.

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