RU64048U1 - CRYOSURGICAL DEVICE - Google Patents

Abstract

The invention relates to medicine, namely, cryosurgery and can be used for endoscopic operations with the aim of cryodestruction of tumors of the liver and pancreas.

Into a cryosurgical device consisting of a handle made of heat-insulating material and coaxially located with it the working part housing with a distal end made in the form of a hemisphere, with a cryoagent supply channel placed in it, connected by means of a flexible gas pipeline with a container filled with refrigerant, and a channel for its removal, an additional block of manual discrete pressure control in the cryoagent supply channel is introduced, consisting of a heating element and a power supply, controlled by a button located on a handle connected via a switching circuit to a heating element placed in a container with a cryoagent and using a connector with a power supply, also, an insert of porous material with high thermal conductivity is placed inside the distal end of the working part, placed inside and close to its inner surface, and the housing of the working part contains a vacuum multilayer insulation located inside the sealed space formed by the inner surface of the housing of the working part and the outer surface thu channel for the removal of the cryoagent. Also, multilayer insulation consists of a combination of layers of materials with high reflectivity and gaskets with low thermal conductivity, and the liner of a porous material with high thermal conductivity is made in the form of a hemisphere with a central blind hole. The proposed cryosurgical device has a more efficient thermal insulation of the body of the working part, which allows to reduce the cooling rate of its external surface, helps to prevent excessive thermal trauma to the surrounding biological tissues and increase the refrigerating capacity by increasing the heat capacity of the distal end of the working part. 3 FIG.

Description

The utility model relates to the field of medical technology, namely cryosurgical devices, and can be used for endoscopic operations with the goal of cryodestruction of tumors of the liver and pancreas.

Known devices for cryosurgery intended for use in open surgical interventions and surgical interventions performed endoscopically [2, 3, 4, 5, 6, 7, 8]. Liquid nitrogen is mainly used as a cryoagent [9]. The disadvantages of the known devices is the limited scope in the context of surgical interventions performed by endoscopic access.

The constructive device of the working parts of cryosurgical instruments for laparoscopic surgery must meet the specific requirements for these instruments, such as:

- the outer diameter of the working parts of the instruments is selected based on the sizes of trocars (access instruments) ⌀5 mm, ⌀10 mm, ⌀12 mm, as the most common in abdominal surgery;

- the length of the housing of the working part of the apparatus (300-350 mm);

- temperature level inside the working parts (up to -180 ° С)

- limited time of cryosurgical exposure (≤10 min)

Closest to the claimed invention in technical essence is the cryosurgical device described in the patent [10]. The known device is intended for cryosurgical interventions during laparoscopic operations. The cryosurgical device consists of a handle and a coaxially located cylindrical body of the working part with a distal end in the form of a hemisphere with cryogen supply and removal channels located in it. Liquid nitrogen, N _{2, is} used as a cryoagent. From the inside, the handle and the body of the working part are covered throughout with a layer of heat-insulating material.

However, the thermal insulation available in the known cryosurgical device does not sufficiently reduce the cooling rate of the outer surface of the working part body, which in turn leads to freezing of the surrounding tissues

the abdominal wall to the surface of the trocar, and the thin-walled design of the distal end, which does not have sufficient heat capacity, does not contribute to the creation of conditions for the intensification of heat transfer between the distal end of the instrument and the patient’s tissue, and the specific consumption of the cryoagent at a given time of continuous operation in cooling mode remains quite high [11, 12].

A new technical task is the creation of a cryosurgical device for laparoscopic operations with more efficient thermal insulation of the working part body, which allows to reduce the cooling rate of its external surface, which helps to prevent excessive thermal trauma to the surrounding biological tissues and increase the device's cooling capacity by increasing the heat capacity of the distal end of the working part

To solve the problem in a cryosurgical device, consisting of a handle made of heat-insulating material and coaxially located with it the working part body with a distal end made in the form of a hemisphere, with a cryoagent supply channel located in it, connected by means of a flexible gas pipeline with a container filled a cryoagent, and a channel for its removal, an additional unit for manual discrete pressure adjustment in the cryoagent supply channel is introduced, consisting of a heating element and a power supply unit, Led by a button located on a handle connected via a switching circuit to a heating element placed on a container with a cryoagent and using a connector with a power supply, an insert of porous material with high thermal conductivity is also installed inside the distal end of the working part, placed inside and adjacent to it the inner surface, and the body of the working part contains a vacuum multilayer insulation located inside the sealed space formed by the inner surface of the body sa working part and the outer surface of the channel for removal of the cryoagent.

Multilayer insulation consists of a combination of layers of materials with high reflectivity and gaskets with low thermal conductivity. Also, the liner of a porous material with high thermal conductivity is made in the form of a hemisphere with a central blind hole made in it.

New is that in the cryosurgical device an additional block of manual discrete pressure adjustment in the cryoagent supply channel is introduced, consisting of a heating element and a power supply, controlled by a button located on the handle; connected via a switching circuit with a heating element located in a container with a refrigerant and by means of a connector with a power supply, also inside the distal

At the end of the working part, an insert of a porous material with high thermal conductivity is additionally installed, and the working part casing contains a vacuum multilayer insulation located inside the sealed space formed by the inner surface of the working part casing and the outer surface of the cylindrical channel for removal of the cryoagent.

Multilayer insulation consists of a combination of layers of materials with high reflectivity, such as, for example, aluminum foil, and gaskets with low thermal conductivity, such as, for example, glass paper. [13]. Also, the liner of a porous material with high thermal conductivity (for example, porous copper, porous titanium nickelide) is made in the form of a hemisphere with a central blind hole and is placed inside and close to the inner surface of the distal end of the working part.

The implementation of the handle of the cryosurgical device made of heat-insulating material creates more comfortable conditions for staff in the process.

The cryoagent pressure control unit using the button located on the handle allows manual discrete adjustment of the gaseous cryoagent, and the insertion of the liner into the distal end of the working part made of a material with high thermal conductivity in the form of a hemisphere located inside and close to its inner surface allows intensifying heat transfer with tissue destruction, which at the same time helps to reduce the specific consumption of cryoagent.

In contrast to the prototype, the execution of the housing of the working part from a material with low thermal conductivity and evacuated multilayer insulation can significantly reduce the cooling rate of the housing of the working part, which in turn avoids thermal injury to the surrounding tissues of the abdominal wall.

Next, the utility model is illustrated by figures of graphic images and a photograph of the main components of the cryosurgical device.

Figure 1 presents a General view of a cryosurgical device.

Figure 2 shows the handle with a coaxially located working part.

Figure 3 presents a General view of the handle with the working part in plan.

The cryosurgical device shown in Figs. 1 and 2 consists of a container 1 (for example, a thermos) filled with a liquid cryoagent - liquid nitrogen. An electric heater 2 is located inside the tank 1, a flexible gas pipeline 3 for supplying a gaseous cryoagent is connected at one end to the tank 1, and at the other end is connected to the handle 4, on which there is a button 5 for switching on / off the heating element 2.

The housing of the working part 6 with the distal end in the form of a hemisphere 7. The porous liner 8 in the form of a hemisphere is fixed from the inside and close to the hemisphere 7 of the distal end of the working part 6. The vacuum multilayer insulation 9 is located inside the sealed space formed by the inner surface of the housing of the working part 6 and the outer surface tube 10, which is a channel for removal of the cryoagent. The concentrically located inner tube 11 is a channel for supplying a cryoagent. Sealing sleeve 12. Flexible gas line 13 for removal of spent cryoagent. A power supply 14 that converts the voltage of the electrical network 220 V to a safe voltage of 12 V for powering the electric heater 2. Stand 15 for mounting the vessel 1 and power supply 14. The safety valve 16 is located in the cover 17 of the vessel 1. Connector 18 for connecting the power source 14 to heater 2 and buttons 5. Moreover, heating element 2, control button 5, power source 14, connector 18 form a block for manual discrete adjustment of the pressure of the gaseous cryoagent.

The cryosurgical device operates as follows:

The power supply 14 is off. Unscrew the lid 17 of the container 1 and, using an overflow device (for example, PU-301), fill it with liquid nitrogen. The cap 17 is screwed. The flexible gas line 3 is connected to the cover 17 of the thermos 1. The handle 4 is connected to the flexible gas line 3 for supply and the flexible gas line 13 for removal of the cryoagent. The switching circuit of the heating element 2 from the button 5 is located in the flexible gas pipeline 3. The normal state of the contacts of the control button 5 is open. The power circuit of the heating element 2 and the control buttons 5 are connected to the power supply 14 using the connector 18. Turn on the power supply 14. The device is ready for operation.

Further, when you press the button 5 due to the heating of the element 2 in the tank 1 creates excessive pressure. The gaseous fraction of liquid nitrogen formed in this case is fed through a flexible gas pipeline to the supply channel — a tube 11 for cooling the distal end of the working part 7, made in the form of a hemisphere with a porous liner 8 inside and adjacent to it made of a material with high thermal conductivity (for example, porous copper, porous titanium nickelide). After cooling the distal end 7 of the working part, the gaseous fraction of liquid nitrogen enters the channel for removal, from the tube 10, through the handle 4 through a flexible gas line 13, and then is discharged into the atmosphere.

When the apparatus reaches the operating temperature mode when using liquid nitrogen as a cryoagent, it is 1-2 minutes, and the operating temperature range

apparatus, within which a temperature change is possible, providing a cryogenic process in contact with tissue, is in the range from -120 ° C to -180 ° C.

In case of exceeding the maximum permissible pressure of the gaseous fraction in the tank with the refrigerant - tank 1, the safety valve 16 automatically enters into operation, through which an emergency discharge of cryogenic vapor occurs.

After the apparatus reaches the operating temperature, the working part of the cryosurgical device is inserted into the abdominal cavity and cryodestruction of the pathological formation in the liver and pancreas is performed under the control of the laparoscope.

Thus, the proposed cryosurgical device for laparoscopic surgery with the aim of cryosurgical effects on tumors of the liver and pancreas avoids unnecessary thermal trauma to the surrounding tissues of the abdominal wall.

Sources of information taken into account

1. M.M.Damirov, N.N. Mikbaridze. A cryogenic method of treating benign diseases of the cervix uteri. " Guidelines. Moscow. 2004.

2. Cryosurgical unit "ErboKryo-12". Prospectus from ERBE Elektromedizin GmbH. 1998.

3. Cryosystem "CRYO 6". Prospectus from ERBE Elektromedizin GmbH. 2000.

4. The family of medical cryoapplicators KMT-01. Prospectus "NPK" "Cryomedical Technologies". Omsk 1994.

5. Cryodestructor "CryoIney". Prospectus of the company "KrioTek" 2004.

6. Cryodestructor ERBOKRYO-DERM Erbe. Prospectus from ERBE Elektromedizin GmbH. 2000.

7. Patent US 3613689; A61b 17/36; Oct. 19, 1971. Cryosurgical Apparatus.

8. Patent US 4946460; A61b 17/36; August 7, 1990. Apparatus for cryosurgery.

9. GOST 9293-74. Gaseous and liquid nitrogen. Technical conditions

10. Patent RU 2189795. A61B 18/02; 09.27.2002. Cryosurgical instrument.

11. GOST 4.129-85. Medical cryogenic technique. Nomenclature of indicators.

12. GOST 21957-76. The technique is cryogenic. Terms and Definitions.

13. Baron R.F. "Cryogenic systems." Publishing house "Energoatom". Moscow. 1989.

Claims (3)

1. A cryosurgical device consisting of a handle made of heat-insulating material and coaxially located with it the working part body with a distal end made in the form of a hemisphere, with a cryoagent supply channel placed therein, connected by means of a flexible gas pipeline with a tank filled with refrigerant, and channel for its removal, characterized in that it additionally introduced a block of manual discrete pressure adjustment in the cryogenic agent supply channel, consisting of a heating element and a power supply, controlled by located on the handle connected via a switching circuit with a heating element placed in a container with a cryoagent and using a connector with a power supply, an insert made of a porous material with high thermal conductivity is also installed inside the distal end of the working part, placed inside and adjacent to it the inner surface, and the body of the working part contains a vacuum multilayer insulation located inside the sealed space formed by the inner surface of the body of the working hour and the channel and the outer surface for discharging cooling agent. 2. The device according to claim 1, characterized in that the multilayer insulation consists of a combination of layers of materials with high reflectivity and gaskets with low thermal conductivity. 3. The device according to claim 1, characterized in that the liner of a porous material with high thermal conductivity is made in the form of a hemisphere with a central blind hole.