JP2003504151A - Apparatus for therapeutic treatment of blood vessels - Google Patents

Abstract

The device comprises a radially expandable stent (13) inserted into a blood vessel (10) in the human or animal body and left in the blood vessel as an inner lining. Stents have the property of vibrating and / or generating heat when subjected to ultrasound. A balloon catheter is provided to insert the stent into the vessel and to expand the stent to engage the interior surface of the vessel. The device further comprises a generator for emitting therapeutic ultrasound to wirelessly transmit energy from the extracorporeal location to the stent at a location within the blood vessel. According to the invention, the device determines the position of the stent in the body by means of the position marking means (22) in the stent and the transmission of diagnostic ultrasound and the reception of diagnostic ultrasound reflected by the position marking means. And an ultrasonic camera (17).

Description

Detailed Description of the Invention

The present invention relates to a radially expandable stent having the property of vibrating and / or generating heat when subjected to ultrasound, and for inserting the stent into a blood vessel and the inner surface of the blood vessel. A balloon catheter for expanding a stent to engage with, wherein the balloon catheter is left inside the blood vessel with the stent expanded as an inner lining after the balloon catheter is removed from the blood vessel, and the inner surface of the blood vessel. For the therapeutic treatment of blood vessels in the human or animal body, comprising a generator for emitting therapeutic ultrasonic waves to wirelessly propagate energy from an extracorporeal location to a stent at an intravascular location engaged with the stent. Of equipment.

A device of this kind is disclosed in International Patent Application No. PCT / SE98 / 02446.

Precisely positioning the stent within the blood vessel in a reliable manner so that the therapeutic treatment with the energy of the therapeutic ultrasound delivered to the stent from an extracorporeal location can be applied to the appropriate portion of the blood vessel. Being able to identify is important.

It is an object of the present invention to provide a device of the type referred to above which enables such a non-surgical procedure to accurately and reliably identify the position of a stent.

Another object of the invention is to improve the absorption properties of the stent in order to increase the generation of heat in the stent when subjected to therapeutic ultrasound and make the position of the stent more easily detectable. Is to give.

Another object of the present invention is to allow identification of a stent within a blood vessel, without impeding the insertion of the stent into the blood vessel or the therapeutic function of the stent when placed within the blood vessel. A means that can easily be included therein is to provide a device of the type mentioned above.

Yet another object of the present invention is to include a means in a device of the type mentioned above that allows the temperature of the stent to be determined when therapeutic ultrasound energy is delivered to the stent. That is.

The above stated object and other objects which will be apparent from the following description are claimed in
Is achieved by a device of the type mentioned above, which has the characteristics of

In order to explain the present invention in more detail, exemplary embodiments will be described with reference to the accompanying drawings.

FIG. 1 shows a blood vessel 1 located in a soft tissue 11 of the body covered by a skin 12.
0 is shown. A stent 13 is inserted into the blood vessel.
Forms part of the device described in International Patent Application No. PCT / SE98 / 02446. The energy of therapeutic ultrasound (0.5 MHz to 15 MHz) is delivered from the ultrasound transmitter 14 to the stent 13 and is focused on the stent, as indicated by the dash-dotted line 15. To the extent that ultrasonic energy is absorbed by the stent and converted into heat within the stent, therapeutic ultrasonic waves should be reflected as little as possible on the outer surface of the stent device.

The position of the stent in the blood vessel 10 is identified by any ultrasonic camera (ultrasonic diagnostic apparatus) having a well-known structure. This ultrasonic camera is provided with a pulsatile diagnostic ultrasonic field (2 MH) indicated by a dashed line 16 from a transmitter / receiver (transmitter / receiver) 17.
25 MHz) from the z, receives the ultrasound reflected from the body by the transceiver 17, transfers the ultrasound image to a display device, and is “seen” by an ultrasound camera by techniques known in the art. Display the image of the field of view.

Stents, such as those described in International Patent Application No. PCT / SE98 / 02446, have low reflection of diagnostic ultrasonic waves on their outer surfaces and therefore are distinguished on images provided by an ultrasonic camera. May become difficult, which causes the stent to be obscured in the ultrasound image on the display.

According to FIG. 2, in one embodiment of the invention, the stent 13 has an outer coating 19 made of, for example, plastic or silicone rubber, as described in International Patent Application No. PCT / SE98 / 02446. And an expandable socket 18 made of, for example, a metal net. In order to increase the absorption of diagnostic ultrasound energy into the stent in order to clearly display the stent in the acquired image on the display, a material such as carbon or tungsten powder is included in the coating 19. gas(
(Eg air) or liquid bubbles, or voids are included. Such materials, bubbles or voids may be distributed within the coating so as to obtain an increasing absorption gradient from the outer surface to the inner surface of the coating 19 along the thickness of the coating material. The gradient may also be formed by forming the coating 19 from a laminate in which the layers have different absorbencies such that the absorbency is increasing from the outer surface of the coating to the inner surface of the coating. Good.

In another embodiment, a material having a plurality of micropores, such as the material marketed under the trademark GORTEX, is coated on the socket to increase absorption of ultrasonic energy. As a result, a void is formed on the surface of the stent.

FIG. 3 discloses another embodiment of a stent forming part of the device of the present invention. In this case, four (or more) axial ribs 20 are formed on the outer surface of the coating 19, which ribs 20 contain materials or bubbles or voids that increase the absorption of ultrasonic energy. There is. The rib material can be a porous material with closed cells. The ribs 20 can also be formed directly on the socket 18 without the coating, for example integrally with the coating 19 when the coating is extruded onto the socket.

The ribs 20 not only facilitate the identification of the stent in the image created on the display of the ultrasound camera, but also absorb the energy of the therapeutic ultrasound for heating the stent.

According to FIG. 4, the ribs 21 extend spirally around the socket so that the heat generated in the ribs by the energy of the therapeutic ultrasound supplied to the stent is distributed around the entire circumference of the stent. It offers the advantage of being distributed. The rib 21 can be constructed and manufactured in the same manner as the rib 20.

Preferably the rib thickness should be greater than the wavelength of the therapeutic ultrasound.

In the embodiments described thus far, ultrasonic absorption is increased to enhance heating of the stent by the energy of therapeutic ultrasonic waves supplied by an external source, acquired by an ultrasonic camera. The material of the stent has been modified to facilitate identification of the stent in the image.

The present invention further comprises a stent of the type referred to in the present application with a stent having landmarks disposed at each end. The landmarks can be passive or active. Figure 5
The mark 22 is a passive mark, and is composed of bubbles or metal balls each containing a gas or a liquid. The landmark reflects the ultrasound waves and is reproduced in the acquired image on the display of the ultrasound camera as a prominent point with respect to the structure of the surrounding tissue displayed on the display. Therefore, when determining the position of the stent, the mark can be easily detected in the image. The air bubble reflects the second harmonic of the ultrasonic wave over a wide range, and the first harmonic of this harmonic is used to control the display device of the ultrasonic camera.
By using one, a clearer indication of the position of the stent can be obtained.

The active landmark is a transponder that transmits ultrasound signals that are activated by the diagnostic ultrasound field and received by the transceiver (transmitter / receiver) of the ultrasound camera. FIG. 6 discloses a stent with transponders 23 at both ends.
The transponder of one embodiment comprises a piezoelectric crystal that receives energy from diagnostic ultrasound and emits ultrasound pulses that are received by the transceiver of the ultrasound camera.

The transponder 23 can also consist of a microchip, which is supplied with energy by the coil 24 of FIG. 1 which emits electromagnetic radiation starting above 150 Hz. The microchip is activated by diagnostic ultrasound waves to generate and emit ultrasound signals that are received by the transceiver of the ultrasound camera.

Stents can be equipped with passive or active type temperature indicators. More than one bubble is provided in the stent to act as a passive landmark as described above. However, the bubbles are filled with different types of liquid that vaporize at different temperatures. FIG. 7 shows three bubbles 25A, 25B and 25C filled with liquid, where the liquid vaporizes at a relatively low temperature in bubble 25A, at an intermediate temperature in bubble 25B and at a relative temperature in bubble 25. Vaporizes at extremely high temperatures. Since the characteristics of the display obtained on the display of the ultrasonic camera are different depending on whether the bubbles are filled with liquid or vapor, the obtained display indicates that the stent is above a certain temperature. It is possible to know if it is down or down. The difference between the display of a liquid-filled bubble and the display of a vapor-filled bubble is particularly apparent if the ultrasound camera is operating at the second harmonic or higher harmonics.

Active indication of the temperature of the stent can be achieved by a piezoelectric crystal attached to the stent along with a transponder circuit. An electronic circuit (microchip) provided on the stent and coupled to the piezoelectric crystal is energized by a coil that transmits electromagnetic energy to the electronic circuit (compare with FIG. 1), and the electronic circuit shows the temperature of the piezoelectric crystal. In connection with the dependent vibrations, different electromagnetic frequencies are emitted, the signals of which are received by the in vitro measuring system.

FIG. 8 discloses a stent with a resistance wire, for example a platinum wire, which is embedded in the sheath 12 of the stent, but in the axial ribs provided on the stent. It is also possible. Further, in this case, an electronic circuit 27 (microchip) for transmitting an electromagnetic signal is provided on the stent,
Energy is applied as described above. The signal emitted by the electronic circuit depends on the resistance of the resistance wire 26, which in turn depends on the temperature of the stent. The resistance wire does not interfere with the expansion of the stent,
It can have a zigzag shape as shown in FIG. Socket 18
When constructed from a metal net, it can be connected to an electronic circuit to form an antenna.

The helical ribs 21 provided according to FIG. 4, together with the coating 19, can form a resonant circuit, the resonant frequency of the resonant circuit varying with the temperature of the stent. The electronic circuit energized by the coil 24 as described above and forming the transmitter for the electromagnetic signal is connected to the resonant circuit. Therefore, the frequency of the electromagnetic signal transmitted by the electronic circuitry and received by the in vitro measurement system is representative of the temperature of the stent.

In a modified embodiment of this embodiment, the resonant circuit has a fixed resonant frequency that does not change with temperature. However, the resistance of the resonant circuit (energy loss factor) varies with the temperature of the stent, so the magnitude of the signal emitted at a fixed resonant frequency is indicative of the temperature of the stent.

[Brief description of drawings]

[Figure 1]   FIG. 3 is a diagrammatic view of a blood vessel with a stent inside, showing the functioning of the device of the present invention.

2 is a partial cutaway perspective view of the stent disclosed in International Patent Application No. PCT / SE98 / 02446. FIG.

FIG. 3 is a perspective view of a stent showing various embodiments of landmarks on the stent.

FIG. 4 is a perspective view of a stent showing various embodiments of landmarks on the stent.

FIG. 5 is a perspective view of a stent showing various embodiments of landmarks on the stent.

FIG. 6 is a perspective view of a stent showing various embodiments of landmarks on the stent.

[Figure 7]   FIG. 6 is a partial side view of a stent with bubbles indicating temperature.

[Figure 8]   FIG. 6 is a perspective view of a stent showing various embodiments of a temperature indicator.

[Figure 9]   FIG. 6 is a perspective view of a stent showing various embodiments of a temperature indicator.

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Claims (16)

[Claims] 1. A radially expandable stent (13) having the property of (a) vibrating and / or generating heat when subjected to ultrasonic waves, and (b) the stent being a blood vessel (13). 10) A balloon catheter for insertion into and for expanding a stent to engage an inner surface of a blood vessel, the stent being expanded as an inner lining after the balloon catheter has been withdrawn from the blood vessel. A balloon catheter left in the vessel, and (c) a generator for emitting therapeutic ultrasound to wirelessly propagate energy from an extracorporeal location to the stent at an intravascular location engaging the inner surface of the vessel. 14) A device for therapeutic treatment of blood vessels in the human or animal body, comprising: (14) position marking means (20, 21, 22, 23) of the stent; An ultrasonic camera (17) for determining the position of the stent in the body by transmitting the ultrasonic wave for cutting and receiving the diagnostic ultrasonic wave reflected by the position mark means. For the therapeutic treatment of blood vessels characterized by: 2. The position-marking means comprises one or more ribs (20, 21) on the outer surface of the stent, the ribs being formed of or containing an ultrasonic-absorbing material. An apparatus for therapeutic treatment of blood vessels according to claim 1. 3. The device for therapeutic treatment of blood vessels according to claim 2, wherein the rib or ribs (20) extend axially along the stent. 4. The device for therapeutic treatment of blood vessels according to claim 2, wherein the rib or ribs (21) extend spirally along the stent. 5. The device for therapeutic treatment of blood vessels according to claim 1, wherein the position-marking means comprises a coating of the stent with microscopic holes. 6. A blood vessel according to claim 1, wherein the position marking means forms at least one bubble or void (22) in the outer coating (19) of the stent at each end of the stent. Device for therapeutic treatment of. 7. The apparatus for therapeutic treatment of blood vessels according to claim 1, wherein the position-marking means comprises at each end of the stent at least one ball of ultrasonically reflective material. 8. A device for therapeutic treatment of blood vessels according to claim 1, wherein said position marking means comprises a transponder (23). 9. The device for therapeutic treatment of blood vessels according to claim 8, wherein the transponder (23) comprises a piezoelectric element which emits an ultrasonic signal when energized by diagnostic ultrasonic waves. 10. The transponder (23) according to claim 9, comprising a piezoelectric element and a radio transmitter that emits ultrasonic pulses when the piezoelectric element is energized by diagnostic ultrasonic waves. Equipment for the therapeutic treatment of blood vessels. 11. The device for therapeutic treatment of blood vessels according to claim 1, wherein a temperature indicator is provided on the stent. 12. The temperature indicator comprises at least one bubble filled with liquid (
25A, 25B, 25C), wherein the liquid trapped within the foam vaporizes at a predetermined temperature. 13. A plurality of bubbles (25A, 25B, 2) enclosing a liquid.
5C) is provided and the liquid vaporizes at different temperatures. 14. The temperature indicator is a wireless transmitter (2) whose resistance is controlled.
Device for the therapeutic treatment of blood vessels according to claim 11, comprising 6, 27). 15. A resistance wire (26) is incorporated into the outer coating (19) of the stent, and the wireless transmitter (27) is operative to function to control frequency depending on the temperature of the stent. 15. A device for therapeutic treatment of blood vessels according to claim 14 connected to a. 16. The spiral rib or ribs (21) form part of a resonant circuit for radio waves, the resonant frequency of the resonant circuit varying as a function of temperature. A device for the therapeutic treatment of blood vessels according to.