RU2136238C1 - Electrosurgical device - Google Patents

Abstract

FIELD: medical equipment, in particular, radio frequency electrosurgical equipment, mainly endoscopic surgical instruments. SUBSTANCE: electrosurgical device has a surgical instrument with electrode system 2 connected to radio-frequency oscillator 3, impedance measuring unit 4 and control unit 5 connected to form impedance main feedback of oscillator 3 with electrode system 2. To enhance reliability, one or several temperature-sensitive elements of the zone of operation and/or other points (6,7,8) of the body of operated patient are introduced in the device. The temperature- sensitive elements are connected to the input of the respective correcting control channels in control unit 5. The control unit correcting channels are made for limiting the power applied to the electrode system irrespective of the impedance level. Control unit 5 uses the cascade circuit and has master controller 9 coupled to the control channels, as well as comparison element 12 and power regulator 10 connected to its output. Transducer of applied power (11) installed for sending a signal to comparison element 12 is connected to the electrode system. EFFECT: enhanced reliability of device control. 1 cl, 1 dwg, 2 ex

Description

 The invention relates to medical equipment and can be used in the construction of high-frequency electrosurgical equipment for various purposes. Its most effective use is in the construction of endoscopic surgical instruments.

 It is known an electrosurgical device (ECU) containing an electric power source, a catheter with an electric heating electrode system (ES) and a heat absorber made with the possibility of heat removal in the area of contact of the working electrode with tissue (US patent N 5230349, A 61 N 1/05, 1993) . To control the flow of coolant, the ECU is equipped with an automatic temperature control system equipped with an electrode temperature sensor connected to a controller with an actuator installed with the ability to change the flow rate of the coolant depending on the temperature of the working end of the electrode (US patent N 5342357, A 61 B 17/39, 1994 )

 However, this device is inconvenient in operation due to the lack of control and regulation of the size, configuration and temperature of the ablation zone.

 An ECM is also known, which contains a control unit (CU) connected in series, a high-frequency (RF) power source, and an electrode system. The device is also equipped with a power measurement unit supplied to the electrode system, an impedance measurement unit and a storage device. The control circuit is configured to programmatically control the input power depending on the impedance with a proportional control algorithm (Russian patent N 2008830, A 61 B 17/39, 1994).

 The disadvantage of this device is the impossibility of its use without information about the impedance control program according to the criterion of optimal tissue destruction, which is obviously a know-how object.

 Closest to the claimed one is an ECM, including a surgical instrument with an ES connected to a high-frequency generator (HHF), an impedance measuring unit (BII) and a control unit (BU) included with the formation of the main impedance feedback between the HF and ES with the possibility of adjusting the impedance (PCT patent 94/24951, A 61 B 17/39).

 However, the use of this device does not guarantee optimal operation, since the impedance, being an indirect criterion, does not fully determine its quality with respect to the size, configuration and temperature of the ablation zone, since the impedance control is unreliable due to the possible carbonization of biological tissue.

 The technical problem to be solved is to increase the reliability of ECM control.

 To solve this problem, an ECU containing a surgical instrument with an electrode system connected to a high-frequency generator, an impedance measuring unit and a control unit connected with the possibility of forming an impedance main feedback of the generator with the electrode system additionally contains one or more temperature sensors installed in the zone the operation and / or other points on the body of the patient being operated on and connected to the input of the corresponding corrective control channels in the control unit with the possibility of issuing a signal limiting the power supplied to the electrode system regardless of the impedance level, and the control unit contains a cascade driving controller connected to the control channels and connected to its output through a comparison element, a power controller, while a sensor is connected to the electrode system input power, installed with the possibility of applying a signal to the comparison element.

 It is advisable to arrange the first temperature sensor on an electrode located directly in the surgical area. This sensor gives a signal to the control channel, limiting the power supplied to the ES in case of tissue overheating in the operation zone, regardless of the impedance level.

 Other temperature sensors, if necessary, are located at points in the patient’s body where the temperature determines the presence or absence of unwanted overheating, including those that can cause postoperative complications. Based on these sensors, the remaining corrective channels are formed, acting similarly.

 Thus, in the proposed ECU, a new principle is implemented for controlling the power supplied to the ES by the signal of the main feedback on impedance with a corrective effect on temperature.

 Due to the fact that the electrosurgical operation is characterized by high dynamics of changing operating parameters, in order to improve the quality of their regulation, the control unit is implemented in a cascade scheme with the possibility of generating at the output of the first cascade a set value of the power supplied to the electrode system and adjusting it by the second cascade. This embodiment is most preferred.

 In FIG. 1 shows a functional diagram of the proposed ECU.

 The ECC contains a surgical instrument introduced into the area of operation on biological tissue 1 with an ES 2 connected to an HHF 3 operating in the range of 400-3000 kHz, BII 4, BU 5, which is turned on to form the main feedback of the HHF 3 with ES 2, sensors 6, 7 and 8 temperatures set in the area of the operation and, if necessary, at other points in the patient’s body. The control unit 5 is equipped with corrective control channels, an appropriate temperature sensor is connected to the input of each of them, while the corrective channels of control unit 5 are configured to limit the power supplied to ES 2 when the temperature is exceeded relative to its limit value at any control point.

 This scheme can be implemented on the basis of any ES-equipped instrument intended for use in high-frequency electrosurgery (high-frequency electrosurgical unit, endoscope, etc.).

 GHF 3 is a two-stage rectangular voltage generator with quartz frequency stabilization. To reduce the radio interference affecting, in particular, the measuring circuits, the GHF 3 is equipped with output RF filters. The output power of the GHF 3 is from 1 to 20 watts. The effective value of the current through ES 2 is from 0.14 to 0.6 A.

 BII 4 is made according to a scheme that provides for measuring the effective values of voltage and current of ES 2 and calculating the impedance using a divider of the values of these parameters.

 The control unit 5 comprises a master controller 9 and a power controller 10 connected in a cascade circuit. In this case, the sensor 11 of the power supplied to it is connected to the ES 2, and the input of the power controller 10 is connected to the output of the master controller 9 through the comparison element 12, which is configured to generate a signal of the difference of the effective value of the power generated by the sensor 11, and its predetermined value generated on output of the master controller 9.

 The device operates as follows.

 GHF 3 supplies voltage to the ES 2 of the ECC, which heats the biological tissue 1 in the surgical intervention zone according to the criterion of ensuring the impedance level specified in accordance with the current regulatory and methodological documents for the optimal conduct of electrosurgical exposure.

 The impedance value measured by block 4 is fed to the input of the control unit 5, which compares the measured value with the set value and, based on the results of the comparison, generates a control signal to the generator 3 to change the power supplied to the electric power supply unit 2, thereby adjusting the impedance value at a given level. At the same time, the master regulator 9 provides a predetermined value of the power supplied to the ES 2 depending on the impedance value measured by the BII 4, or on the temperature value received from the sensors 6 - 8. The controller 10 controls the power supplied to the ES 2 according to the difference signal and set by the controller 9 values.

 ECU operates in the described mode of automatic control of impedance, if no signal from temperature sensors 6, 7 or 8 is received through any of the inputs of the correcting control channels about the excess of the corresponding preset value. In the latter case, the control unit 5 will automatically switch to the mode of generating power supplied to the ES 2 by the control signal from the corresponding temperature sensor. In this mode, the input power is regulated not by impedance, but by temperature at the corresponding control point. The control algorithm, which is implemented when the limit temperature measured by the sensors 6 - 8 is exceeded, provides for a reduction in the power supplied to the ES 2, up to a complete shutdown of the microwave oven 3. It is adjusted separately for each correction channel.

 ECU performance is illustrated by the following examples.

 Example 1. The ECHO of FIG. 1 is connected to an ES consisting of an active needle electrode introduced into the dog’s biological tissue, the non-working part of which is coated with an electrically insulating shell, and a passive electrode made in the form of a flexible electrically conductive plate in contact with the body surface of the operated animal. The active electrode is configured to extend its working part from the insulating shell to the required length in the range from 2 to 24 mm. It is introduced into the surgical intervention area through the operating channel of an endoscope equipped with an optical channel used to control the positioning of the electrode entry point. The operation is carried out under ultrasound control.

The tissues of the liver, kidneys and prostate gland of 20 dogs are subjected to electrosurgical treatment. The operation is performed under intravenous anesthesia with the following values of the regime parameters: frequency - 1760 kHz; impedance set value - 600-700 Ohm; the length of the working part of the active electrode is 10 mm. In operations on the liver and kidney, a temperature sensor 6 is installed on the working part of the active electrode. In these test series, one corrective temperature feedback channel with a setting of 90-98 ^o C is implemented. For operations on the prostate, temperature sensors 7 and 8 are additionally connected, which are installed in the rectum and in the urethra. The operation algorithm of the BU 5 provides, upon reaching the tissue temperature of the active electrode 95-98 ^o C, switching the ECU to the mode of limiting the power supplied to the ES 2 from the calculation of the temperature control at this control point, regardless of the impedance value. When conducting surgery on the prostate, the operation algorithm of BU 5 additionally provides for a complete shutdown of the voltage supplied to the ES 2 when the temperature measured by sensors 7 or 8 is exceeded, the values are 42 and 50 ^o C, respectively.

 For a comparative assessment, a series of tests is carried out, where the ES 2 is connected to the prototype ECU, which is achieved by disconnecting the corrective feedback channels in temperature. Comparative tests of the proposed device with the prototype is carried out with adequate modes of unregulated parameters.

The results of comparative tests are presented in table. 1. As can be seen from the table, the use of the proposed ECU allows you to get a zone of necrosis with a volume of 5.8-7.2 cm ³ , while the prototype device gives a smaller volume of the zone of necrosis - from 4.2 to 4.7 cm ³ . The differences obtained are statistically significant at p = 0.05.

Example 2. Electrosurgical treatment is performed on 45 hyperplastic nodes of the human prostate gland isolated during transvesical adenomectomy in patients with benign prostatic hyperplasia. The active electrode is introduced into the tissue of a hyperplastic assembly placed in a tray with a hypertonic solution of sodium chloride, at the bottom of which a passive electrode is placed. The temperature of the tissue at the active electrode is measured. Performance parameters: frequency - 440 kHz, the set impedance value is 600-700 Ohms, the maximum allowable temperature of the active electrode is 80-95 ^o C.

 For control, a series of operations is carried out using a prototype ECU with adequate modes of unregulated parameters.

The results of comparative tests are presented in table. 2. As can be seen from the table, the use of the proposed ECU allows you to get a zone of necrosis of the prostate gland with a volume of 3.7-4.8 cm ³ , while the prototype device gives a zone of necrosis only in a volume of 2.6-3.1 cm ³ (the differences are significant when p = 0.05).

 As can be seen from the above examples, the use of the proposed device in comparison with the prototype provides optimal conduct of electrosurgical exposure, as evidenced by a statistically significant increase in the necrosis zone by 1.4-1.5 times, as well as a decrease in the deviation of the average value of this parameter within the limits indicated in the table . 1 and 2. An increase in the volume of necrosis was achieved due to the exclusion of carbonization of the operated area of biological tissue, which occurred in 65-75% of cases of ECU use without corrective feedbacks. Thus, the implemented principle of controlling the power supplied to the ES by the signal of the main impedance feedback with the corrective effect on temperature makes it possible to increase the reliability of ECU operation.

Claims (1)

 An electrosurgical device comprising a surgical instrument with an electrode system connected to a high-frequency generator, an impedance measuring unit and a control unit connected with the possibility of forming an impedance main feedback of the generator with the electrode system, characterized in that it further comprises one or more temperature sensors installed in the area of the operation and / or other points of the body of the operated patient and connected to the input of the corresponding correction channels alarm in the control unit with the possibility of issuing a signal limiting the power supplied to the electrode system regardless of the impedance level, and the control unit contains a master controller connected in cascade, connected to the control channels and connected to its output through a comparison element, the power controller, while the electrode system is connected to the input power sensor installed with the possibility of applying a signal to the comparison element.

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