RU87081U1 - LASER CATHETER WITH FIBER OPTICAL SENSOR - Google Patents

Abstract

1. A laser catheter with a fiber optic sensor, containing a flexible tube, with an optical fiber for coagulation located inside it and at least one optical fiber with a sensing element, while the end sections of the optical fibers are located in the sleeve, in the axial channel of which is placed optical fiber for coagulation, characterized in that the sleeve is provided with at least one off-axis channel, the axis of which is inclined relative to the axis of the channel with the optical fiber for coagulation, in which optical fiber with a sensitive element with the ability to move outside and inside the sleeve. ! 2. A laser catheter with a fiber optic sensor, characterized in that the sleeve is equipped with two off-axis channels located diametrically opposite. ! 3. Laser catheter with fiber optic sensor, characterized in that the sleeve is equipped with three off-axis channels.

Description

The invention relates to medicine, namely, to the design of a laser catheter with a fiber optic sensor for monitoring the thermal effect on pathological biological tissue in the internal cavity of the human body.

A known design of a fiber catheter for laser coagulation [1], consisting of a flexible tube with an optical fiber that transmits coagulation radiation, and an optical fiber with a heat-sensitive element at the end section, while the end sections of both optical fibers are fixed in an opaque sleeve. The design drawback is the need for the sleeve to contact the biological tissue during coagulation, which limits the scope of the catheter, and for some medical procedures there is a risk of perforation of the organ wall.

As a prototype, we should consider the design of the instrument [2], consisting of a flexible tube in which an optical fiber for coagulation and an optical fiber with a sensing element are placed, while the terminal sections of the optical fibers are located in the sleeve, in the axial (through) channel of which the optical fiber is placed for coagulation. The design drawback is the lack of temperature control of the directly coagulated biological tissue, because the end portion of the optical fiber with the sensitive element, as in the analogue, remains closed by the volume of the sleeve, overheating of the biological tissue is possible.

These disadvantages are absent in the proposed laser catheter with a fiber optic sensor containing a flexible tube, in which an optical fiber is located, transmitting radiation for coagulation of biological tissue and at least one optical fiber with a sensing element at the terminal section, while the terminal sections of the optical fibers located in the sleeve, in the axial channel of which is placed an optical fiber for coagulation. Additionally, the sleeve is equipped with at least one off-axis channel, the axis of which is inclined relative to the axis of the channel with an optical fiber for coagulation, in which an optical fiber with a sensing element is located with the possibility of moving outside and inside the sleeve.

The technical result implemented in this application is the ability to control the temperature of the biological tissue directly, because the terminal portion of the optical fiber with the sensing element can move to direct contact with the biological tissue through at least one off-axis channel of the sleeve, the axis of which is inclined relative to the axis of the channel with the optical fiber for coagulation. Direct measurement of the temperature of the biological tissue avoids overheating of the biological tissue during laser coagulation. The safe insertion of a laser catheter with a fiber optic sensor into the internal cavity of an organ of the human body is performed with a recessed end portion of the optical fiber into the sleeve. The latter eliminates the risk of injury or perforation of the organ wall. The use of two off-axis channels located diametrically opposite provides direct measurement of the temperature of the biological tissue in two sections of the biological tissue, which eliminates the possibility of overheating on the surface of the coagulated biological tissue. The use of three off-axis channels allows the temperature to be measured in three different areas of the biological tissue, which eliminates the possibility of overheating of the coagulated biological tissue and prevents damage to the biological tissue adjacent to the coagulation zone.

The essence of the proposal is illustrated using figure 1, depicting a schematic diagram of a laser catheter with a fiber optic sensor. The laser catheter with a fiber optic sensor has a flexible tube 2, an optical fiber for coagulation 3, an optical fiber 1 with a sensing element 4, a sleeve 5 with an axial channel 6 (in which the terminal portion of the optical fiber 3 for coagulation is located), an off-axis channel 7 (in which is located with the ability to move the end portion of the optical fiber 1 with the sensing element 4).

A laser catheter with a fiber optic sensor operates as follows. The design of a laser catheter with a fiber optic sensor, containing a tube 2 with an optical fiber 3 and an optical fiber 1 with a sensing element 4 recessed into the sleeve 5, is inserted through a medical endoscope into the internal cavity of the patient’s organ. The output end of the laser catheter with a fiber optic sensor is fed to the irradiation site of the biological tissue, after which the optical fiber 1 with the sensing element 4 is pulled out of the off-axis channel 7 until it contacts the biological tissue. Laser radiation is produced by the radiation transmitted by the optical fiber 3, while the sensitive element 4 registers the temperature at the point of contact with the biological tissue. After the end of the laser irradiation, the terminal portion of the optical fiber 1 with the sensing element 4 moves inside the sleeve 5. The laser catheter with the fiber optic sensor is removed through the endoscope from the cavity of the patient’s organ.

Here is a specific example of a laser catheter with a fiber optic sensor.

The hollow tube 2 (FIG. 1) is made of Tefzel fluoropolymer with an outer diameter of about 5.8 mm. We used an optical fiber 3 of the quartz-polymer type with a light guide core diameter of 0.4 mm and an optical fiber 1 (two samples) of the quartz-quartz type with a light guide core diameter of 0.1 mm. A heat-sensitive element 4 of monocrystalline silicon with a transverse size of up to 0.12 × 0.12 mm ^{2 was} welded to the terminal portion of the end face of the optical fiber 1. The metal sleeve 5 had an axial channel with a diameter of 0.75 mm (to accommodate the output section of the optical fiber 3) and off-axis channels located diametrically opposite, with a diameter of about 1.2 mm to accommodate the heat-sensitive element 4 of the terminal section of the optical fiber 1. A laser catheter with a fiber optic sensor can be conducted through the operating channel (cross-section diameter 6.0. mm) of the Olympus GIF-XT30 gastrofibroscope.

Literature

[1] Utility Model Patent No. 75292, IPC A61B 5/01.

[2] V.A. Korolev, V.T. Potapov “Fiber instrument for laser intravenous coagulation in the treatment of varicose veins” // Bulletin of new medical technologies. - 2007. - T.XIV. - No. 2. - S. 140-141.

Claims (3)

1. A laser catheter with a fiber optic sensor, containing a flexible tube, with an optical fiber for coagulation located inside it and at least one optical fiber with a sensing element, while the end sections of the optical fibers are located in the sleeve, in the axial channel of which is placed optical fiber for coagulation, characterized in that the sleeve is provided with at least one off-axis channel, the axis of which is inclined relative to the axis of the channel with the optical fiber for coagulation, in which optical fiber with a sensitive element with the ability to move outside and inside the sleeve. 2. A laser catheter with a fiber optic sensor, characterized in that the sleeve is equipped with two off-axis channels located diametrically opposite. 3. Laser catheter with fiber optic sensor, characterized in that the sleeve is equipped with three off-axis channels.