DE2811325A1 - Oscillator circuit for heart surgery fibrillator - has battery powered symmetrical double transistor arrangement producing AF oscillations - Google Patents

Abstract

The fibrillator for heart surgery uses a symmetrical double circuit forming a generator for oscillations within the audio frequency range. The circuit has two transistors (T1, T3) with their collector electrodes connected to a capacitor (C1) forming a connection to one electrode (E1) and to the base electrodes of the corresponding transistors (T2, T4) forming part of their halves of the circuit. The emitters of the latter (T2, T4) are connected to opposite poles of a battery. The battery has a centre tapping (0) connected to the second electrode (E2) and connected by a resistor (R1) to two light emitting diodes (D1, D2) which are then connected to the two emitters of the first two transistors. The bases of these transistors (T1, T3) are connected to the collectors of the second two transistors (T2, T4).

Description

Cardiac surgery fibrillator

The invention relates to a fibrillator for cardiac surgery, consisting of from a generator and two electrodes, which are used briefly during a heart operation applied to the surface of the heart.

It is known that when the human body is exposed to low-frequency currents of corresponding strength or with direct current pulses that Heart and other muscle fibers put into continued disorderly activity become (fibrillation). It consists of rhythmic but not synchronous stretches and contractions of individual fibers, so that the function of the entire system is disturbed e.g. ventricular fibrillation.

In open heart surgery, this fact is used to to induce ventricular fibrillation through electrical stimuli. To this The purpose is to place electrodes with a surface area of about 1 cm2 at two points on the surface of the heart and applies a 50Hz voltage to the electrodes. The electric current stimulates and at the same time depolarizes a large part of the heart muscle. At the same time The endocardial impulses that normally reach the heart are depolarized Surface. The interlocking of the two processes results in an irregular one Depolarization, the different zones of the myocardium in different states of excitation and is responsible for the fibrillation.

To achieve this state, high current densities are required, since a sufficiently large area must be depolarized. Up to 10 volts are required to increase the fibrillation reach. For a smooth, complete fibrillation the voltage must even be increased with this method the danger9 that the myocardium will be damaged The previously known devices for generating fibrillation are network-dependent and give a 50 Hz alternating voltage to their electrodes between 1 and 30 volts, the electrodes are briefly connected to the surface of the heart brought into contact.

Another method to induce ventricular fibrillation and during the. Sustaining operation consists of 9 the ac or electrodes to which direct current pulses are applied during the entire operating phase 5 possible previously known fibrillators are to be connected to the upper surface of the heart large, hand-held9 mains-dependent devices9 have their electrodes over them. long supply cables placed on the surface of the heart0 These devices are therefore not fully sterilizable In addition, there is a risk9 that the fibrillation pulse will be transferred to the Hyocard per fibrillation pulse The electrical energy is so great9 that damage to the heart muscle is not certain Therefore, the task of the invention is 9 a fibrillator in the form of a small, handy device9 that is fully sterilizable and does not have the other disadvantages mentioned above0 This object is achieved in accordance with the invention solved9 that starting from a fibrillator of the initially called type, the generator from a symmetrical circuit with transistors is constructed, with two corresponding transistors complementary to each other are that the base and emitter electrodes of the first pair two symmetrically arranged complementary transistors each connected to one another and the collector electrodes on the base electrodes of the second pair two symmetrically arranged complementary transistors are connected, whose Collector electrodes with each other and via a capacitor with the base electrodes of the first two symmetrically arranged transistors are connected that the Emitter electrodes of the second pair of transistors at opposite poles of one Series connection of two batteries are present, with the center tap of the two Batteries via a resistor to the two emitter electrodes of the first transistor pair is performed, and that one electrode with the two collector electrodes of the second Transistor pair is connected, while the other electrode rests on the center tap.

te further advantageous embodiment of the fibrillator is from the Subclaims apparent.

The particular advantages of the fibrillator according to the invention exist in that it is a small, pen-shaped, network-independent device in the form of a Surgical instruments with firmly built electrodes are treated exactly like this one can be, i.e. fully sterilized and ready to hand on the operating table. The handy one Embodiment allows a rapid sweep of the heart muscle, with a Stimulation takes place in several places of the heart muscle and therefore with certainty fibrillation is achieved. The fibrillator according to the invention is also very economical in power consumption, as it is only when the electrodes are placed on the surface of the heart switches on automatically. It is also short-circuit proof.

An embodiment of the invention is shown in the drawing and is described in more detail below. Figure 1 shows an electrical circuit diagram the fibrillator according to the invention; FIG. 2 shows a complete fibrillator in FIG Shape of surgical instruments; Fig. 3 shows a sound source applied to the electrodes of the fibrillator can be switched on.

In Fig. 1, the emitter electrodes are two complementary transistors T1 and T3 are each connected to one another via a diode D1, D2 and are connected via a resistor R1 at the center tap O of two series-connected batteries U1, U2 a. The base electrodes of the two transistors T1 and T3 are also connected to each other and via a capacitor C1 on the interconnected collector electrodes of two subsequent ones, also placed mutually complementary transistors T2, T4. Here is the transistor T2 complementary to transistor T1 and T4 complementary to T3. The base electrode of transistor T2 is with the collector electrode of transistor T1, the base electrode of the transistor T4 is connected to the collector electrode of the transistor T3. The emitter electrodes of the transistors T2, T4 are connected to the plus or minus pole of the in Batteries U1 and U2 connected in series. Between the base and emitter electrodes a resistor R2 can be connected to the transistor T2. The electrode E1 is the same how the electrode E2 is attached to the heart surface, which represents a resistance RH is on the connection of the two collector electrodes of the transistors T2 and T4 led. The electrode E2 is at the center point 0 of the series circuit of the both batteries U1 and U2.

FIG. 2 shows a complete fibrillator according to the invention in FIG outer shape of an L-shaped surgical set. The short leg 5 contains the electrodes E1 and E2. The generator is located in a hollow cylinder 4 made of insulating material housed.

The long leg 6, which is preferably made of metal with a plane-ground Surface is made, contains the batteries U1, U2.

In Fig. 3, a sound source S is shown which is connected to the electrodes E1, E2 of the fibrillator can be switched on. The sound source S is contacted via an annular contact 9 on which the electrode E2 of the fibrillator rests, as well as a contact plate 8 which is insulated and inserted into the annular contact 9 and is associated with electrode E1.

The electrical circuit of the fibrillator according to FIG. 1 works as follows: As soon as the heart comes into contact with electrodes E1, E2, discharges the capacitor C1 across the cardiac resistance, which is represented by the resistance RH is, assuming that the capacitor C1 is opposite the reference potential at Fund tap 0 is negatively charged at the time of observation. Through the occurring du a current flows into the base electrode of transistor T1, causing the transistor T2 becomes conductive. The capacitor C1 is thereby positively charged (positive feedback effect). When the charging is finished, at # goes to 0, the transistor T1 blocks and thus also the transistor T2. The capacitor C1 discharges again through the heart resistance N with the current direction reversed, so that the transistors T3 and T4 become conductive until the capacitor C1 is negatively charged. Then the repeats itself just described discharge process, so that a symmetrical square wave voltage with a frequency given by the size of the capacitor 1 occurs.

In the event of a short circuit at the output of the fibrillator9 doho if = o, will the capacitor C1 discharges and cannot be recharged because the transistors Block T2 or T4 When the short circuit is removed, capacitor C1 charges slowly increases again due to leakage currents. Resistor R1 is used to limit the current A defined initial state, i.e. positive or negative charge on the Konw capacitor C1 in idle state9 can be achieved by optionally installing an additional Resistance R2 between the base and collector electrode of the transistor T2 or T If Dio in the emitter leads of the transistors T1 and T3 are reached D19D2 these can be inserted9 in the form of light-emitting diodes for function control A simpler check of the functionality of the fibrillator can be used is, however, with the aid of a sound source S applied to electrodes E1 and E2 possible. Since the fibrillator has an audio frequency voltage at its electrodes - preferably 500 -looo Hz-of about 10 V emits9 no further amplification is required Therefore, an earpiece common in telephony technology can be used in a simple manner serve as sound source S0 The sound source is expediently fixed in one Container mounted9 the at the same time for the storage of one or redundancy reasons preferably two fibrillators according to the invention are used. Therefore, redundancy is necessary9 because a pen-shaped fibrillator was accidentally used during the operation slide off the sterile drape or in connection with a non-sterile object If a sterile fibrillator cannot be used immediately in such a case Available9, the successful course of the operation could be called into question be Blank page

Claims (7)

Fibrillator for cardiac surgery Patent claims 9 Fibrillator for cardiac surgery, consisting of a generator and 2 electrodes that are used during heart surgery briefly applied to the surface of the heart, thereby g e k e n n z e i c h n e t s that the generator consists of a symmetrical circuit with transistors (T1, T2, T3, T4) with two corresponding transistors (T1, T3; T2, T4) are complementary to each other that the base and emitter electrodes of the erm most Pair of two symmetrically arranged complementary transistors (T1DT3) each are connected to each other and the collector electrodes are connected to the base electrodes of the second pair of two symmetrically arranged complementary Transistors (T2, T4) are connected, the collector electrodes of which are connected to one another and via a capacitor (C1) with the base electrodes of the first two symmetrically arranged transistors (T (T1, T3) are connected that the emitter electrodes of the second transistor pair (T2, T4) at opposite poles of a series connection of two batteries tU1, U2) the center tap (0) of the two batteries (U1, U2) via a resistor (Ri) led to the two emitter electrodes of the first transistor pair (T1, T3) is, and that one electrode (Ei) with the two collector electrodes of the second Transistor pair (T2, T4) is connected, while the other electrode (E2) at the center tap (0) is present. 2. Fibrillator for cardiac surgery according to claim i, characterized g e k e n n z e i c h n e t that in one of the transistors of the second transistor pair (T2, T4) a resistor (R2) is inserted between the base and emitter electrodes. 3. Fibrillator for cardiac surgery according to claim i or 2, characterized in that g e k e n n n z e i c h n e t that in the emitter electrodes of the first transistor pair (T1, T3) LEDs (D1, D2) are inserted. 4. Fibrillator for cardiac surgery according to one of claims 1 to 3, in that the generator oscillates in the audio frequency range. 5. fibrillator for cardiac surgery according to claim 4, characterized g e k e n n z e i n e t that a sound source (S) is connected to the two electrodes (E1, E2) is connectable. 6. Fibrillator for cardiac surgery according to one of claims ì to 5, in that the electrodes (E1, E2) are annular and attached to both ends of a short hollow cylinder (4) made of insulating material that contains the generator. 7. fibrillator for cardiac surgery according to claim 6, characterized g e k e n n z e i -c h n e t that the hollow cylinder (4) containing the generator with the two ring-shaped electrodes (E1, E2) the short leg (5) of an approximately L-shaped, fully sterilizable surgical instruments, the long legs (6) of which hold the batteries (U1, U2) contains.