RU143680U1 - ELECTROSURGICAL BIPOLAR SCALPEL - Google Patents

Abstract

1. An electrosurgical bipolar scalpel, including a blade with a cutting edge located at the distal end, made of crystalline nanostructured partially stabilized zirconia, conductive coatings isolated from each other, made of titanium nitride, are applied to both blade planes, the thickness of each of which is 0.05-0.1 mm, at the proximal end of the handle there are two contacts isolated from each other for inputting a high-frequency electric current, azhdy of which is connected to a respective conductive pokrytiem.2. The scalpel according to claim 1, characterized in that the height of the cutting edge of the blade is 0.3-0.8 mm. 3. An electrosurgical bipolar scalpel according to claim 1, characterized in that the blade length is (30.0 ± 5.0) mm4. The electrosurgical bipolar scalpel according to claim 1, characterized in that the maximum width of the blade (10.0 ± 2.0) mm.

Description

The utility model relates to medical electrosurgical instruments and can be used in surgical operations for dissection and simultaneous coagulation of biological tissues and blood vessels.

The bipolar scalpel is intended for dissection of soft tissues with the possibility of coagulation of intersected small and medium blood vessels using high-frequency electric current. The bipolar design of the scalpel provides localization of the high-frequency current in a small area of the patient’s tissue, which makes it possible to operate in the open heart region with minimal risk of causing arrhythmia.

Known electrosurgical device for cutting and coagulation, consisting of a blade made of medical steel, an additional bipolar electrode, an insulated handle with contacts for current input [US patent No. 4651734]. The disadvantage of such a bipolar instrument is the participation in the process of coagulation of a metal electrode, part of which is also a cutting blade, as a result of which, despite the special processing and hardening of a metal blade directly interacting with biological tissue, it rapidly degrades due to electrochemical processes. In this case, trauma to dissected biological tissues takes place.

Closest to the proposed utility model is an electrosurgical bipolar scalpel [RF patent for utility model No. 95500], including a blade made of crystalline nanostructured partially stabilized zirconia (NSCTs), with insulated metal conductive layers located on opposite planes, and located on the proximal end handles contacts for inputting high-frequency electric current.

The disadvantages of the known scalpel is its low durability and wear resistance of the metal coating of the blade, because it has little adhesion to NESC.

The technical result of the proposed utility model is to improve the operational properties of the electrosurgical scalpel, which ensures simultaneous coagulation of biological tissues adjacent to the blade of the electrosurgical scalpel during the dissection process and has increased wear resistance and durability.

The specified technical result is achieved by the fact that in the electrosurgical bipolar scalpel, including a blade located at the distal end with a cutting edge made of crystalline nanostructured partially stabilized zirconia, conductive coatings isolated from each other, made of nitride, are applied to both planes of the blade, except for the cutting edge. titanium, the thickness of each of which is 0.05-0.1 mm, two contacts isolated from each other are located at the proximal end of the handle to enter a high-frequency electric current, each of which is connected to a corresponding conductive coating.

The specified technical result is also achieved by the fact that the height of the cutting edge of the blade is 0.3-0.8 mm

The essence of the utility model is illustrated in figure 1-2.

Figure 1 presents the proposed bipolar electrosurgical scalpel and used together with the scalpel high-frequency current generator and connecting cable, where:

1 - insulated handle with contacts 2, 3 - high-frequency current delivery cable, 4 - blade with a cutting edge 5, 6 - conductive layer on the planes of the blade, 7 - high-frequency electric current generator.

Figure 2 presents a section of the blade 4 of the bipolar electrosurgical scalpel, where 5 is the cutting edge of the blade 4, 6 is a conductive layer on the planes of the blade.

The electrosurgical bipolar scalpel contains an insulated handle 1 with contacts 2 for introducing a high-frequency electric current from a high-frequency generator 7, a dielectric blade 4 with a cutting edge 5, two conductive layers 6 of titanium nitride insulated from each other, acting as electrodes. The electrodes of the bipolar scalpel are connected to a high-frequency generator by a radio-frequency cable 3.

The proposed bipolar electrosurgical scalpel operates as follows.

A high-frequency electric current from the high-frequency generator 7 is fed through a cable 3 to the contacts for inputting a high-frequency electric current 2 located on the proximal end of the handle 1. These contacts are independently connected to the conducting layers (electrodes) 6 sprayed on both sides of the dielectric blade 4 located at the distal end of said scalpel. Moreover, the conductive layers 6 isolated from each other, located on the cutting blade 4 of the tool, are active bipolar electrodes that have two points of contact with the biological tissue.

The high-frequency current supplied to the proposed scalpel (figure 1) flows between the points of contact of the electrodes with the biological tissue, causing coagulation. During the surgeon's incision, the biological tissue is mechanically dissected with the cutting edge of the dielectric blade of the scalpel, while the conductive layers of titanium nitride sprayed onto the blade provide electrocoagulation, acting as a bipolar electrode. When a biological tissue is dissected, coagulation begins from the moment it contacts the conductive electrodes of the dielectric blade, so the height of the cutting edge determines the depth of the cut before the coagulation process is switched on. The height of the cutting edge of the non-conductive part of the dielectric blade of crystalline nanostructured partially stabilized zirconia is 0.3-0.8 mm, which corresponds to the average diameter of the coagulated blood vessels. The length of the blade is 30.0 ± 5.0 mm, and the maximum width of the blade is 10.0 ± 2.0 mm

In the proposed bipolar scalpel, the coagulating electrodes are titanium nitride surfaces deposited directly on a non-SCCe blade by vacuum deposition. Titanium nitride has good adhesion to NFSCe and low adhesion to biological tissue compared to metals. In addition, it has a low electrical resistivity, which is very important for electrodes. The proposed bipolar scalpel allows for smooth mechanical dissection with a super-sharp cutting edge of the blade made of NPF, and hemostasis can be performed in coagulation mode (with low heating compared to the dissection mode with a traditional monopolar instrument), avoiding unwanted necrosis and injury to biological tissues in the dissection area.

Claims (4)

1. An electrosurgical bipolar scalpel, including a blade with a cutting edge located at the distal end, made of crystalline nanostructured partially stabilized zirconia, conductive coatings isolated from each other, made of titanium nitride, are applied to both blade planes, the thickness of each of which is 0.05-0.1 mm, at the proximal end of the handle there are two contacts isolated from each other for inputting a high-frequency electric current, azhdy of which is connected to a respective conductive coating. 2. The scalpel according to claim 1, characterized in that the height of the cutting edge of the blade is 0.3-0.8 mm. 3. The electrosurgical bipolar scalpel according to claim 1, characterized in that the blade length is (30.0 ± 5.0) mm 4. The electrosurgical bipolar scalpel according to claim 1, characterized in that the maximum width of the blade (10.0 ± 2.0) mm.