CS217448B1 - Cryosurgical tool - Google Patents

Abstract

In a cryosurgical apparatus, the heat exchanger is provided with a filling formed by metallic grid or perforated foil wound up in the shape of strip around the middle part of exchanger frame and connected unremovably with its border to the contact plate in which axis a connection screw is placed, an electric temperature sensor and heat element being arranged at the exchanger frame or at the contact plate, for example resistance thermometer and heating winding and a separating partition being arranged among supply tube, tube for cooling medium drain off and vacuum mantle of the apparatus. The exchanger filling can be formed also by a system of metallic grids or perforated foils forming co-axial or concentric areas which are in thermal contact with the contact plate. <IMAGE>

Description

The invention is. relates to a cryosurgical instrument having a high cooling effect in a frontal fetus with a replaceable surgical tip and a coolant inlet and outlet tube, with electrical inlets arranged therein, a heat exchanger with a porous metal filler such as silver or copper, thermometer, heating elements and system channels. ·

Recent cryobiological investigations have shown that the most effective cryodestructure in cryosurgical procedures occurs when the lowest possible operating tip temperature is used, requiring this temperature to be established as soon as possible from the moment the device is put into operation.

For this reason, modern cryosurgical systems work mostly with liquid nitrogen and try to achieve maximum cooling capacity in the operating end.

Devices are known in which the desired effect is achieved by simple exchangers formed by a smooth or ribbed internal cavity of the applicator. The disadvantage of these simple exchangers is the relatively high consumption of the siphon, of the order of liters of liquid nitrogen per operation, with low cooling efficiency.

In other known cryosurgical devices, it is known. · Achieves the desired effect by increasing the heat exchange surface inside the heat exchanger using a porous environment of a high thermal conductivity material. This is the case, for example, with the cryosurgical applicator according to U.S. Pat. AO 199 443, in which the exchanger is filled with a column of planar meshes, for example of copper or silver, oriented perpendicular to the axis of the applicator.

This second variant is particularly effective when the cylindrical surface of the end piece of the cryosurgical instrument is used for cryodestruction, but its efficiency deteriorates significantly if only the face of the instrument is to be cooled, as is the case, for example, in gynecological or dermatological application. The development of cryosurgery places increasing demands on the variability of surgical endings, many of which are not axially symmetrical and require application to the surgical tissue at a preselected optimum angle. The thermal contact between the exchangeable terminal and the tool itself is usually mediated by a fixed screw connection, for example, which clearly defines each terminal in terms of its angular rotation.

The above drawbacks of the known cryogenic instruments are eliminated while achieving a high cooling capacity in the tool face that is at a cryogenic instrument of ^{d p} le VYN ^AL Cutting ^{characterized} by ^running in ^and AN ot.ro ^ ^ e ma ^ ri ^ lu from nětož is ^{characterized} Roben ^Fill výnténíku above.

Anisotropy is a dependence of physical properties on the direction in space. In this case, anisotropy of thermal conductivity is used. By a suitable design of the heat exchanger filler, it is possible to dissipate heat in a transverse direction perpendicular to the tool face. The present invention further solves the possibility of angular rotation of the operating tip while maintaining good thermal contact of the operating tip with the cooled face of the tool.

The essence. cryochiurgical tool with high cooling effect in the face, with replaceable operating tip and coolant tube inside the tube, heat exchanger with porous metal filling, for example silver or copper, thermometer, heating elements and channel system spěčívá that the above ^p ln exchanger is formed ^to ovovou s ^ ma no ^b of pens ^f orovanou ^{films and} also ^even in the form of a tape wound around the central part of the frame of the exchanger and connected detachably with its rim with hundreds of metal plate in which the axis is disposed a connecting bolt taking the skeleton of the exchanger. or an electrical temperature sensor, for example a resistance thermometer or a heating element, for example a heating coil, is provided in the contact plate, and a separating partition is provided between the supply tube, the coolant discharge tube and the vacuum housing of the tool.

^V LT ^er native embodiment kryoc ^h Irura ^g ick ^eh of the tool after ^d le VYN ^AL cut filler is exchange ^of preheater consists of a system of the end of the gauzes or perforated foils you face esophagus ^ h coaxial or concentric surfaces that are in thermal contact with the contact plate.

According to the invention, a higher cooling effect is achieved over known cryosurgical instruments by arranging the exchanger filler so that it is in direct thermal contact with the interface plate and not through the exchanger shell and the exchanger filler has significantly greater conductivity towards the interface plate and low conductivity in the coolant flow direction. . Nast ^R c ^j given ^E terminates ^p CE jetož with fillers ^least mangers is vyWořena of porous ^¹H about mattriálu with strongly anisotropic properties with a higher heat in ^ i \ ^ (^ St ^ i in the axial direction, has a significantly higher thermal efficiency than tools with heat exchanger filler of thermally isotropic material while maintaining the same value of the surface area of the exchanger filler to its volume.

An exemplary embodiment of a cryosurgical instrument according to the invention is shown schematically in the accompanying drawings, in which Fig. 1 shows a longitudinal section of a cryosurgical instrument according to one embodiment, Fig. 2 shows a longitudinal section of a cryosurgical instrument according to a second embodiment; Fig. 4 shows a longitudinal section of a cryosurgical instrument according to a third embodiment and Fig. 4 shows a cross section of a cryosurgical instrument according to a third embodiment.

The basic part of the operating tool according to the first variant shown in Fig. 1 is a heat exchanger consisting of a shell J, an exchanger, a contact plate 2 and a heat exchanger filler 2 consisting of a porous material whose thermal conductivity in the axial direction is significantly greater. than in the radial direction. For example, the exchanger filler 6 is formed from a silver or copper mesh in the form of a strip, which is wound around the central part of the exchanger frame 1 and is releasably connected to its contact plate 2 by its edge, for example by soldering. The exchanger filler J may also consist of a system of coaxial rolls, which are either made of mesh or fabric of high thermal conductivity, for example silver or copper or perforated foil or perforated thin sheets.

In the axis of the contact plate 2, there is a connecting screw 6, on which the replaceable end 10 of the desired shape is screwed, which with its planar surface bears on the contact plate 2. A temperature sensor formed for example by a wire winding is fastened to the exchanger frame 1. The temperature sensor 2 is optionally in thermal contact with the contact plate 2, which is particularly advantageous if a thermocouple is used as the temperature sensor 2.

A channel 1 and a main channel 8 or auxiliary channels 2 are formed in the exchanger frame 1. The channel 2 is formed, for example, by a circular slot, the main channels 8 are, for example, a set of holes or notches. The inlet tube 11 and the coolant discharge tube 12 into which the inlets to the temperature sensor 2 and the heating element 6, such as the heating coil, are generally introduced, are housed in a vacuum housing 13. The exchanger space is separated from the vacuum space by a separating partition.

In an alternative embodiment of the Cryo-Surgical Instrument shown in Figure 2, the interface plate 2 forms a single unit with the skeleton of a heating element 6, for example a heating coil.

The temperature sensor 2 is either placed inside the contact plate 2 or wound next to the heating element 6 on the contact plate 2. In this case, the exchanger filler 2 is formed by a symmetrical concentric array or similar curve surfaces, e.g. The inlet and outlet of the liquid coolant is provided by the inlet pipe 11 and the pipe 12 for the refrigerant outlet. The space containing the exchanger filler 2 is separated from the vacuum insulating space enclosed by the insulating sheath 13 from the bulkhead.

Another embodiment of the operating tool is shown in FIG. 3. It is also intended for operating tools of larger diameters and solves the problem of gripping axially unsymmetrical operating terminals at any angle of rotation about the tool axis. Skeleton 2 is formed by a tube heat exchanger with inlet openings 16 and on-the wound Pyšek sížky metal or perforated ^Oli e f, ^k esters above forms ^a pre ^Fill 2 exchanger. The edge Uhoto h ^ ^P u ^p is áaku evně ⁿ ot ^{EP-temperature} sensor g or heating element 6 for example by threading into the edge. screen mesh or insertion ^into J8 soon ^boo with ^Itk y ^r M on its edge. Off ^{I H} J replacing Cart ^ te is contacted with ^p Elne ^hundred co ^Vou destičkou.2 and from the second face is closed by a cover plate 12 · The space available in electronic format containing ^ln 2 ^{for the} exchange ^of the U is O ^d va UOV ^{eh to} the free space only ^p limited ^é it vacuum jacket 13 parted by the separating partition JG. ·

-Výměnných Mounting terminals 10 which are provided with an outer thread at libolné ezimutální position secures cap nut 21st stop coupling nut 21 in ^an axial direction of zajiětuje ^Walking rka ^20. TERA EVN ^{p E p} with ^p ro Ojén ^{dl f} ou en ^r m LAST vacuum ^{p 1} and ^p 3 on the plate ^{of each} case saestykovou second

The inlet duct 1 arranged in the exchanger filler 2 is provided with inlet openings 16 for the passage of liquid refrigerant into the exchanger filler 2. The heat exchanger filler 2 is fixed by means of spacers 17.

The function of the cryosurgical instrument with a high cooling effect in the face is as follows:

Liquid refrigerant, for example liquid nitrogen, is fed to channel X through the inlet tube 11 and after passing through the exchanger fillers 2, refrigerant vapors pass through the main channels -8 or auxiliary channels g into the coolant drainage tube 12 into which the temperature sensor 2 inlets are usually introduced. The cooling of the tool is provided either in the manner described above or in the opposite direction, i.e. the liquid coolant is supplied through the coolant outlet pipe 12, enters the exchanger filler 2 through the main channels 8 and exits through the channel X into the inlet pipe. In the latter case, it is advantageous to lead the leads to the temperature sensor 2 and the heating element 6 - through a hole drilled in the extension of one of the main channels 8 into the channel X, which is thickened after the leads are extended; the inlets are then led out of the tool through the inlet pipe Ц

The liquid coolant inlet and outlet of the second variant are provided by the inlet pipe 11 and the coolant outlet pipe 12. The possibilities of confusing their function, including the substitution of the location of the leads, are the same as those described in the description of the function of the first embodiment.

In the third variant, the liquid coolant is supplied via a supply tube Ц. through the inlet openings 16 it passes into the exchanger filler 2 where it evaporates, and between the spacers 17, the refrigerant vapors pass into the refrigerant discharge pipe 12.

Claims (6)

SUBJECT OF THE INVENTION First cryosurgical instrument with a high cooling effect in the end face, with removable operating terminal with a tube for supplying and discharging cooling, electrical connections arranged inside this tube, a heat exchanger with a porous metal filled, thermometer, heating elem ^e nt ^y and a system of channels , ^{wherein considerable} Eny that. ^Fill above (3) ^{characterized of} preheater is formed ^of ENA ^to ovovou with ^Itk or ou ^va pe ^r foro Nou ^f OLIIA shaped strip wound Otol st edn ^{of t s C} to skeletons ⁽¹⁾ mangers and ^p ^ .s Ojen nerozeb ^s ratelně its otoajem with the contact ^d six ^RC ou ⁽²⁾ in its ^iz axis m ^s of ^this' connecting screw (4), wherein on the frame (1) of the exchanger or the contact plate (2) is arranged a temperature sensor ( 5) and / or a heating element (6) and a separating partition (15) is provided between the coolant supply pipe (11) and the coolant outlet pipe (12) and the vacuum housing (13) of the tool. 2. Cryosurgical instrument^paccording to point 1^Cdetermined by the fact that^{flax (3)} the exchanger is t, v ° system of metal s^andno^bo per^Fplowed foe, you^tvářícíc^hkO^andxi^{environmental} neto^toOⁿce^n- thermal surfaces that are in thermal contact with the contact plate (2). Cryosurgical instrument according to Claims 1 and 2, characterized in that the heating element (6) and the temperature sensor (5) are arranged in the edges of the metal meshes or perforated foils forming the exchanger filler (3) or between their layers. Cryosurgical instrument according to Claims 1 and 2, characterized in that the separating partition (15) and the vacuum jacket (13) extend as far as the contact plate (2). Cryosurgical instrument according to Claims 1 and 2, characterized in that the connecting screw (4) is connected to the contact plate (2) by a removable through connection. Cryosurgical instrument according to Claim 1, characterized in that the tool contact plate (2) and the replaceable end piece (10) are mechanically and thermally connected to each other by a cap nut (21), which together with the support (20) is located on the contact plate (2). ) or a replaceable terminal (10), the opposing contact plate (2) or the replaceable terminal (10) being threaded.