Bonding of soft biological tissues by passing high frequency electric current therethrough

The present invention is directed to a technique for bonding soft biological tissue to close an incision therein and, in particular, to heating of the tissue with high frequency electric current in combination with compression of the tissue. A technique for bonding soft biological tissue having an i...

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Hauptverfasser: Paton, Boris E, Lebedev, Vladimir K, Vorona, David S, Karchemsky, Volodimir I, Furmanov, Yuri A, Lebedev, Alexsey V, Vasilchenko, Valery A, Sidorenko, Dmitry F, Iemchenko-Ribko, Vitaly P, Ivanova, Olga N, Furmanov, Alexandr Y, Zhyvodernikov, Yevgen V, Lyashenko, Andrei A, Savitskaya, Irina M
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creator Paton, Boris E
Lebedev, Vladimir K
Vorona, David S
Karchemsky, Volodimir I
Furmanov, Yuri A
Lebedev, Alexsey V
Vasilchenko, Valery A
Sidorenko, Dmitry F
Iemchenko-Ribko, Vitaly P
Ivanova, Olga N
Furmanov, Alexandr Y
Zhyvodernikov, Yevgen V
Lyashenko, Andrei A
Savitskaya, Irina M
description The present invention is directed to a technique for bonding soft biological tissue to close an incision therein and, in particular, to heating of the tissue with high frequency electric current in combination with compression of the tissue. A technique for bonding soft biological tissue having an incision therein with forceps adapted to grip a portion of the tissue on both sides of the incision. Electrodes are secured to the forceps for contacting the tissue portion. An electrical power source provides a high frequency electrical signal to the electrodes to be passed through the tissue portion. The electrical power source is controlled to provide the electrodes with one voltage signal during a first of two stages, and another voltage signal during a second of the two stages. During the first stage the voltage rises linearly. During the second stage, the voltage is stabilized and is modulated with a low frequency rectangular signal. A clamping means applies force with the forceps to compress the tissue at one level or at different levels during two time periods while the high frequency voltage is passed through the electrodes. The tissue impedance is measured as a function of time, with its minimal value being determined and stored. At an instant when the impedance reaches its minimal value, the linear rise of the high frequency voltage is stopped, and the voltage is stabilized at the attained level. After that the ratio of the tissue impedance to its minimal value is determined as a function of time. The passing of the high frequency voltage to the electrodes is stopped as soon as such ratio reaches a preset value, which is specific for each tissue being bonded. The material for making electrodes is selected so that the electrode may serve as an effective heat sink for conducting heat away from the tissue surface. The electrodes are dimensioned relative to the thickness of tissue in a compressed state.
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A technique for bonding soft biological tissue having an incision therein with forceps adapted to grip a portion of the tissue on both sides of the incision. Electrodes are secured to the forceps for contacting the tissue portion. An electrical power source provides a high frequency electrical signal to the electrodes to be passed through the tissue portion. The electrical power source is controlled to provide the electrodes with one voltage signal during a first of two stages, and another voltage signal during a second of the two stages. During the first stage the voltage rises linearly. During the second stage, the voltage is stabilized and is modulated with a low frequency rectangular signal. A clamping means applies force with the forceps to compress the tissue at one level or at different levels during two time periods while the high frequency voltage is passed through the electrodes. 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title Bonding of soft biological tissues by passing high frequency electric current therethrough
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