RU181933U1 - DEVICE FOR ENDOLUMINAL TREATMENT OF BLOOD VASCULA - Google Patents

Abstract

The utility model relates to surgical instruments and devices for transferring non-mechanical forms of energy to the human body through laser radiation, in particular, for the endoluminal treatment of blood vessels. The objective of this device is to increase the reliability of larger diameter veins without the risk of complications, while significantly reducing complexity and reducing the total cost of the device. This is achieved by the fact that in the device for endoluminal treatment of a blood vessel containing a flexible waveguide, representing an optical fiber having an elongated axis, a proximal end optically connected to a radiation source, a distal end configured to be placed in a blood vessel and containing a tip 4 with an emitting surface, the emitting surface of the tip 4 is made on the quartz core 1 of the fiber and has the form of a part sphere 5 passing into a truncated cone 6 with an apex equal to one quarter of the diameter of the optical fiber and the total length of the tip equal to the diameter of the sphere 5. Part of the protective shell 3 KPA adjacent to the tip 4, made of a polymeric reflective layer 7 having a refractive index less than that of the quartz core fiber 1 and placed in a stainless steel capillary 8.

Description

The utility model relates to surgical instruments and devices for transferring non-mechanical forms of energy to the human body by laser radiation, in particular, for the endoluminal treatment of blood vessels.

A device is known for endoluminal laser ablation of varicose veins of the lower extremities (RF patent No. 2506921, IPC - A61B 18/22; A61N 51/01; A61N 5/06, 2014), including a flexible waveguide having an elongated axis, a proximal end, optically connected to a radiation source, a distal end configured to be placed in a blood vessel and comprising a tip with an emitting surface and a reflective surface spaced distally from the emitting surface and facing towards it to reflect the forward direction ed radiation to the side with respect to the elongated axis of the fiber to the portion of the surrounding vessel wall extending in the angular range from about 90 ° to about 360 ° in the form of a ring.

The disadvantages of this device is the lack of efficiency of laser ablation of large veins, since a narrowly localized and unidirectional radial distribution of laser energy to the inner wall of the vessel, carried out in the form of a local thin ring, at low levels of laser energy supplied to a varicose dilated vein may be insufficient for reliable endoluminal laser ablation of a vessel of large diameter and can lead to its recanalization, and, therefore, recurrence of varicose veins.

In addition, when using high levels of laser energy in this device, the thin annular distribution of the laser source radiation on the vessel wall creates a narrow local zone of a significant increase in temperature, which causes a rapid process of carbonization of biological tissue, its adhesion on the radiating surface of the waveguide, an increase in the depth of the necrosis of the vascular wall and increased risk of radiation perforation, which leads to the development of serious complications.

Closest to the claimed utility model is a device for endoluminal treatment of a blood vessel (RF Application No.2010137031 / 14, IPC АВВ 18/18), which contains a flexible waveguide, which is an optical fiber having an elongated axis, a proximal end, optically connected to a radiation source, and a distal end configured to be placed in a blood vessel and including emitting means for emitting radiation from the radiation source to the side with respect to the elongated axis of the waveguide passing into the corner in a wide range, a portion of the surrounding wall of the vessel, at least one emitting surface that forms a curved surface contour and extends in an angular range of at least about 90 ° to about 360 °, a reflective surface spaced from said at least one a surface emitting in the distal direction and facing towards it to reflect forward directed radiation to the side with respect to the elongated axis of the waveguide, the cover, which is rigidly attached to the waveguide, is sealed against it, essentially transparent to the emitted radiation, covers the specified at least one emitting surface and forms the interface between the gas and the waveguide, which refracts the emitted radiation to the side with respect to the elongated axis of the waveguide to the surrounding wall of the vessel, the reflective surface for reflecting radiation, located in the lid spaced from said at least one emitting surface and facing thereto to reflect forward directed radiation to the side with respect to the elongated axis of the waveguide, a radiation nickel, a temperature sensor thermally connected to the distal portion of the waveguide for monitoring the temperature in the blood vessel and transmitting signals corresponding to the temperature, and a control module electrically connected to the temperature sensor for controlling the output power of the radiation source, based on the specified module, and a tap drive connected with a waveguide with the possibility of transmitting a drive force to control the speed of the waveguide retraction, moreover, the control module is electrically connected to the outlet a driving drive for controlling the speed of removal of the waveguide depending on the temperature of the distal section of the waveguide.

In addition, the device includes a wire conductor connected to the waveguide with the possibility of detachment or rigidly fixed to it and including a distal section extending in the distal direction from the distal end of the waveguide for conducting the waveguide through the blood vessel, at least one laser source that generates laser radiation at least at a wavelength of about 1470 nm or about 1950 nm ± about 30 nm, with a power of not more than 10 W, and the proximal end of the waveguide is optically connected to the specified at least one laser source, and the specified at least one emitting surface of the waveguide emits radiation to the side with respect to the elongated axis of the waveguide to the surrounding wall of the vessel in the form of an annular spot passing along the axis, an electrical outlet device connected to the waveguide with the possibility transmitting the driving force and performing with the possibility of removing the waveguide through the blood vessel with the supply of laser radiation with an average speed of energy supply to the vessel wall of less than about 30 J / cm, about traction means for reflecting forward-directed radiation to the side with respect to the elongated axis of the waveguide and covering means for enveloping the emitting means and forming a gas interface for refracting the emitting radiation to the side with respect to the elongated axis of the waveguide, diffuse emitting means for emitting diffuse radiation in the direction relative to the elongated axis of the waveguide to a portion of the waveguide extending along the axis and regulating means for controlling the length of the diffuse emitting means .

The disadvantage of this device is the fact that it cannot provide a sufficiently high reliability for larger diameter vein ablation due to the fact that the unidirectional radial distribution of laser energy to the inner wall of the vessel creates a local zone of a significant increase in temperature, which causes a rapid carbonization process, leads to an increase the depth of coagulation necrosis of the vascular wall, its possible perforation and the development of complications.

In addition, the disadvantages of this device include its complexity, since supplying the device in the head region with a temperature sensor requires an additional process during the manufacture of the device, and the inclusion of an additional control module in the device significantly increases the cost of the product.

The task set by the applicant is to eliminate these shortcomings.

This is achieved by the fact that in a device for endoluminal treatment of a blood vessel containing a flexible waveguide, which is an optical fiber having an elongated axis, a proximal end optically connected to a radiation source, a distal end configured to be placed in a blood vessel and containing a tip with an emitting surface, the emitting surface of the tip is made on the quartz core of the fiber and has the form of a part of a sphere turning into a truncated cone with an apex equal to one quarter diameter optical fiber and a total length equal to the tip diameter of the sphere. The part of the fiber sheath adjacent to the tip is made of a polymer reflective layer with an optical refractive index less than that of the quartz fiber core and is placed in a stainless steel capillary.

The execution on the quartz core of a fiber of a tip with an emitting surface, having the form of a part of a sphere turning into a truncated cone with an apex equal to one quarter of the diameter of the optical fiber and the total length of the tip equal to the diameter of the sphere, allows you to create emitting surfaces that form a distribution diagram of optical radiation, both along the optical axis optical fiber with an effect directly on the anterior lying sections of the vascular wall and blood, and in the form of a circularly formed continuous field of la grain radiation of a given width with an effect on the inner wall of the vessel, which allows the most efficient distribution of laser energy and reduce areas of local hyperthermia on the vascular wall, while maintaining the total level of laser energy sufficient for reliable obliteration of the vessel and reduce the risk of postoperative complications.

A decrease in the fraction of the radiation energy emitted along the axis of the fiber from the end part in the range of angles allows one to reduce the negative thermal effect of the excess laser radiation energy on the vascular wall and, mainly, to realize the effect of laser blood coagulation with indirect thermal effect on the vascular wall of vapor bubbles formed during boiling blood in the lumen of the vessel, thereby significantly reducing the risk of possible coagulation perforation of the venous wall of the vessel.

A decrease in the fraction of the radiation energy emitted from the side surfaces of the optical tip in the form of a circularly formed continuous field of laser radiation of a given width on the inner wall of the vessel, instead of one or more thin circular rings, reduces the intensity of locally acting intense laser radiation on the vascular wall and avoids undesirable temperature damage surrounding tissues and pain from the patient. The combination of the simultaneous action of two radiation fluxes with an individual energy and spatial distribution of the field in each of them significantly increases the efficiency of the process of laser obliteration of the vessel. This is achieved, among other things, by individual separation of functions for each energy flow, in particular, a circularly formed continuous field of laser radiation of a given width in the angular range from 50 ° to 90 ° provides the main energy contribution of radiation to the heating and coagulation of the inner wall of the vessel, conical beam the laser radiation flux with a vertex located on the axis of the optical fiber in the angular range from 10 ° to 50 ° provides additional thermal effect of radiation on the narrowing walls of the venous th channel, increasing the reliability of the ablation of the vessel compared to the prototype.

The use of a polymer reflective layer with a refractive index less than that of the quartz core of the fiber for fixing the optical fiber to the tip, and the placement of a part of the fiber without a protective shell adjacent to the tip coated with a polymer reflective layer in a stainless steel capillary makes it easier to fix the tip to the optical fiber with repeated use of the device.

Moreover, the absence of the need to place on the tip of the temperature sensors and the inclusion of a special control module in the device also reduces the complexity of the proposed device and significantly reduces the cost of its manufacture in comparison with the prototype.

The figure shows a general view of the device.

A device for endoluminal treatment of a blood vessel contains an optical fiber with an elongated axis, including a quartz core 1, reflecting 2 and protective 3 shell. A tip 4 is made on the quartz core 1 with an emitting surface in the form of a part of a sphere 5 turning into a truncated cone 6. The part of the protective shell 3 adjacent to the tip 4 is made of a polymer reflective layer 7 with a refractive index less than that of the quartz core 1 placed in the capillary 8 stainless steel.

A device for endoluminal treatment of a blood vessel works as follows. After connecting the optical fiber to the apparatus, set the parameters of laser radiation. After the intravenous catheter is inserted, an endoluminal laser ablation device is endovasally inserted. Ultrasonic visualization of the position inside the vessel of the tip 4 increases the capillary 8, made of stainless steel. After the device is inserted into a vein, laser radiation with a given intensity is supplied to the distal end of the optical fiber, where the tip 4 is located. Moreover, in the part of the sphere 5 of the tip 4, an energy flow is formed in the form of a circularly formed continuous field of laser radiation of a given width in the angular range from 50 ° to 90 °, which provides the main energy contribution of radiation to the heating and coagulation of the inner wall of the vessel. The second energy flow is formed in the part of the tip, having the shape of a truncated cone 6, along the axis of the optical fiber in the angular range from 10 ° to 50 °, which provides additional thermal effect of radiation on the narrowing walls of the venous channel. At the same time, the part of the protective shell 3 adjacent to the tip 4, made of a polymer reflective layer 7 with a refractive index less than that of the quartz core 4, placed in the stainless steel capillary 8 during laser radiation, on the one hand reliably fixes the tip 4 to the quartz core 1 optical fiber, and on the other - does not allow energy loss during operation of the device. Gradual endoluminal laser ablation of the entire vein is performed as the device is removed back under direct ultrasonic visualization of the positioning of the tip 4 located on the distal part of the optical fiber. The device for the endoluminal treatment of a blood vessel ends with the simultaneous extraction of the entire optical fiber. Thus, endoluminal laser ablation is performed gradually throughout the vein as the device is removed.

Claims (1)

A device for the endoluminal treatment of a blood vessel, containing a flexible waveguide, which is an optical fiber having an elongated axis, a proximal end, optically connected to a radiation source, a distal end configured to be placed in a blood vessel and containing a tip with an emitting surface, characterized in that the emitting surface of the tip is made on the quartz core of the fiber and has the form of a part of a sphere turning into a truncated cone with an apex equal to one quarter of the diameter meter of optical fiber and the total length of the tip equal to the diameter of the sphere, while the part of the protective sheath of the fiber adjacent to the tip is made of a polymer reflective layer with a refractive index less than that of a quartz fiber core and is placed in a stainless steel capillary.

Images