DE1940803A1 - Heart stimulator - Google Patents

Description

Dr. Ing. A, van der Werft . Dr. Franz Lederer

PATENT ADVOCATE AUG 11, 1969

RAN 4701/11

F. Hoffinann-La Roche & Co. Aktiengesellschaft, Basel / Switzerland

Cardiac stimulator

The invention relates to a heart stimulator with a electrical pulse generator, leads that deliver the generated pulses to electrodes located near the heart of the Patients are to be arranged, an accumulator serving to feed the pulse generator, a receiving organ for high-frequency Shafts and a rectifier arranged between the latter and the accumulator. '.

It has already been suggested that such a heart + - To equip the stimulator with a transmitter powered by the accumulator, which emits electromagnetic waves, at least one of the puncture state of a component of the stimulator have dependent characteristics.

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The proposed transmitter allows you to determine the battery voltage at any time and also to check the pulse duration and the pulse frequency. The present invention is based on the knowledge that it should generally also suffice to merely monitor the charging of the accumulator, with a corresponding saving in the effort required for the transmitter. The heart stimulator according to the invention is characterized in that the pulse generator has at least one circuit element which changes the pulse characteristic in puncture of a charging current supplied to the battery by the rectifier.

Only the period of the pulse characteristic is preferred changed in puncture of the charging current, so that determined simply by measuring the pulse rate of the patient can be used to determine whether the battery is being charged with the correct amperage. It is also very advantageous between the Provide a device to stabilize the charging current for the rectifier and the accumulator.

In the drawing is an embodiment of the

subject of the invention shown, wherein Fig. 1 shows the circuit of the heart stimulator and Pig. 2 to explain how it works

serving diagram.

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The cardiac stimulator shown has a pulse generator 1, which is operated by a simultaneously serving as "earth", is surrounded by dashed lines as a block "shielding 2, which shields it from high-frequency waves. The operating .The pulse generator 1 required voltage is from a Accumulator 3 is supplied, which e.g. consists of several series-connected Ni-Cd cells 4, which diodes 5 in reverse direction are connected in parallel so that in the event of a defect in a cell 4, the current conduction through the diode 5 ™ parallel to the same is maintained. A rectifier bridge 6 with a smoothing capacitor 7 is provided for charging the accumulator 3. A coil designed to receive high frequency waves

8 is connected to the input of the rectifier bridge 6. When the accumulator 3 is to be charged, a smaller one becomes High frequency transmitter, ζ.B * with a frequency of about 27 MHz, brought into the vicinity of the patient provided with the cardiac stimulator and put into operation.

The rectifier bridge 6 is on the output side via a Conductor 9 to the positive pole of the accumulator 3 »and over a conductor 10 is connected to a current stabilizing device 11. A conductor 12 leads from the latter via a shielding inductance 13 to a conductor 14 of the pulse generator 1, which is connected to a small resistor 15 * of e.g. 39Λ is. The charging circuit closes via a conductor 16 connected to this resistor 15, which is connected to the negative,

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earthed pole of the accumulator j5 is connected.

The current stabilizing device 11 has a transistor 17, the emitter of which is connected to the conductor 10 via a small resistor 18 and a capacitance 19 connected in parallel to it. The collector of the transistor 17 is connected to the conductor 12 via a diode 20, while its base is connected to the collector of a second transistor 21 and to a high resistor 22, e.g. 22 KSX, the other side of which is connected to the conductor 9 connected is. The emitter of the transistor 21 is connected to the conductor 10 and its base to the emitter of the transistor 17. If, as a result of an increase in the current supplied by the rectifier bridge 6, the voltage drop across the resistor 18 increases, the current flowing through the transistor 21 changes, whereby the bias voltage of the transistor 17 is changed in the sense of an increase in its resistance and the current to a predetermined limit value is stabilized, for example to a value of approx. 15 mA. The current supplied to the accumulator 3 can therefore never assume a value that is harmful to this accumulator 3, regardless of how strong the transmitter is and how close it is brought to the patient.

The positive pole of the accumulator 3 is via a shielding inductance 23 connected to a conductor 24 of the pulse generator 1. Between the positive conductor 24 and the

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earthed conductors 16 are five connected in parallel Current branches that are formed:

1) from a capacitor 25;

2) from the series connection of a transistor 2b and a resistor 27;

3) from the series connection of a transistor 39 > a diode 41, two resistors 42 and 43 and the resistor 15 located in the charging circuit; Λ

4) from the series connection of a resistor 46 and a transistor 53; ■ -

5) from the series connection of a transistor 54 and of a capacitor 5 °

The base of the transistor 26 is connected via a network J> k, which consists of the series connection of a capacitor 35 and a high resistor 36, of e.g. 68 ΚΛ, and a very high resistance (37 »of e.g. 1 MA, which is arranged in parallel with this series connection, to the connection point 44 of the resistors 42 and 43. The base of the transistor 39 is connected via a resistor 45 to the connection point 47 of the resistor 46 and the transistor 53. The base of the transistor 53 is connected to the connection point 29 of the Transistor 26 and the resistor 27. The base of the transistor 54 is connected via a resistor 52 to the connection point 51 of the resistor and the transistor 53. Between the connection points

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19A0803

Points 44 and 51, a capacitor 48 is arranged.

Two terminals 62 and 65 are, in a conventional manner connected via insulated lines to cardiac excitation electrodes, not shown, which are located in the vicinity of the patient's heart are arranged. The terminal 62 is connected to the connection point 55 via a capacitor 59 and a shielding inductance 57 of transistor 54 and capacitor 56 connected while the terminal 65 on the one hand with the grounded conductor 16 and on the other hand via a resistor 6l to the connection point 58 of the capacitor 59 and the shielding inductance 57 in FIG Connection.

The pulse generator 1 is an astable multivibrator whose mode of operation is based on Pig. 2 is to be explained, in which the solid curve V represents the potential of the point in puncture of the time t in normal operation. The dashed curve V ¹ , however, shows the potential profile of this point 44 during the charging of the accumulator J5. The zero line in the diagram corresponds to the earth potential on which the conductor 16 is located. The voltage of the accumulator 3 is denoted by U and the charging current by J. Disregarding the extremely low internal consumption of the multivibrator circuit when the accumulator 5 is charged, the voltage drop across the resistor 15 is equal to JR, ^ * so that the bottom line of the diagram represents the potential of the conductor 14 during the

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Charging represents.

In normal operation, the potential V of point 44 is zero at time t and all four transistors 26, 39 * 53 * 54 are in the conductive state. The capacitor 48 is now charged in the branch 39, 41, 42, 48, 53, the time constant ^r 4p " ^C 48 of which is ^relatively small ^11. In the absence of the network 34, the potential V would have the value U at which the transistor 26 blocks, As a result of a charge reversal of the capacitor * 35 contained in the network 34 during the pulse period, the potential of the transistor base is changed in a manner known per se so that the transistor 26 is blocked at a well-defined time t. occurs while V is still well below U. The blocking of transistor 26 results in the sudden blocking of transistors 39 * 53 and 54. The potential V now suddenly rises to almost 2 U because the right 3 position (or point 51 ) of the capacitor 48 charged to almost U is connected to the voltage conductor 24 instead of the conductive transistor 53, now via the resistor 46. The capacitor 48 is now discharged in the branch 46, 48, 43, 15, with a r relatively large time constants (Rj ₄₅ + R ^) · C ^ g, in which current branch the resistance R ₁₁ - is negligible and also R ^. If at a point in time t ^ the potential has fallen sufficiently far below U, the transistor 26 becomes conductive again, which suddenly also the transistors 39, 53 ^ur * d 5 ^ again

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makes conductive, so that at the _{time t which practically coincides with t 2} , a new working cycle of the pulse generator 1 begins.

It is clear that the cardiac stimulation electrodes connected to the connecting terminals 62 and only receive current via the transistor 54 during the time interval * tf ', which lasts from t to t, but not during the time interval f ^, which starts from t. until tp, or t, lasts. The cardiac stimulation electrodes will receive pulses P, where the pulse duration T * can be, for example, 2 msec, while the pulse period T = f ' ₁ ^{+ /} ^ ρ is, for example, about 1 second, which corresponds to a pulse frequency of 1 Hz «The diagram of Fig. 2 is purely qualitative and is only intended to serve to understand the mode of operation, for example, the pulses P have a voltage amplitude of the value U when idling, but this would result in a very unfavorable representation in the drawing.

If the accumulator 3 is charged, the pulse generator 1, however, operates substantially in the manner described V / else on, with the difference that the discharge of capacitor 48 in the current path 46, 4Ö, carried 4J5 via conductor 14, the potential by J · R _{15 is} smaller than that of the head Ib. While, according to the curve V ¹ shown in dashed lines, the duration of the pulses P 'is practically the same as the normal pulse duration f, is due to the faster discharge

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of the capacitor 48, the time interval f 'is shorter than the time interval T ρ and thus the pulse period T ^{1 is} smaller than the pulse period T.

In the case of the current stabilization device 11 guaranteed, stabilized charging current of 15 mA, T 'can e.g. be around 0.9 T, i.e. the frequency of the heartbeats increases by about $ 10, i.e. to about 1.1 Hz, while the battery is charging. This increase in heart rate is important for the f The patient is completely harmless and it is possible to determine whether there is a charge by simply observing his pulse rate of the accumulator takes place with the desired charging current or not. If the frequency increase is less than the setpoint, For example, if it is around $ 10, the transmitter will be brought closer to the patient or its output increased. One lets then operate the transmitter until 'the accumulator has consumed a predetermined number of ampere-hours, with you check your heart rate from time to time to be sure that the charging current has not changed.

While in the present circuit the pulse duration f .. is not changed by the charging current and the pulse period T is shortened, it is easily possible to design the pulse generator in such a way that the pulse period is lengthened or the pulse duration is changed when the accumulator is charged. In the latter B'alle could be used to determine the existence of

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Its charging current does not just watch the pulse, but would have to record an electrocardiogram, because only off such the change in the pulse duration would be recognizable. When using an electrocardiograph one could in principle also observe other changes in the impulse characteristics in the puncture of the charging current, e.g. a splitting of the impulse in · two or more closely adjacent pulses, quite apart from the complication of the pulse generator required for this - it is obviously most expedient to be able to get along with just observing the pulse rate.

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Claims (9)

19A0803 Patent claims / L ■ * I 1st / heart stimulator with an electrical pulse generator, Leads which deliver the generated impulses to electrodes which are to be arranged in the vicinity of the patient's heart, an accumulator serving to feed the pulse generator, a receiving element for high-frequency waves and one between the latter and the accumulator arranged rectifier, characterized in that the pulse generator (1) at least a circuit element (15) which has the impulse characteristic in puncture of the rectifier (6) to the accumulator (3) supplied charging current (J) changed. 2. Heart stimulator according to claim 1, characterized in that the period (T) of the Impulschrakteristik in puncture of the Charging current (J) is changed. 3. Heart stimulator according to claim 2, characterized in that the circuit element is one through which the charging current (J) flows Resistor (15), whose voltage drop (J.FLj.) Is a charging or the discharge time of a capacitor (48) is influenced. 4. Heart stimulator according to claim 3> characterized in that that the pulse generator (l) is an astable multivibrator, in which the charging and discharging of the capacitor (48) through two transistors (39, 53) are controlled, which are in parallel 009811/0974 6AD Q8K31NAL 19A0803 Branches (39, 41, 42, 43, 15; 46, 5J) are located, which in turn One of these branches is opened via a third transistor (26) as a function of the course of the potential (V) at a point (44) and blocked while the pulses (P) are applied to said electrodes via a fourth transistor (54) v / earth, and that when opening or blocking said third transistor (26) the other three transistors (39, 53, 54) can also be opened or blocked suddenly. 5 · Heart stimulator according to claim 4, characterized in that that between said point (44) and the base of the third transistor (26) a network (34) is arranged for the purpose of more precise definition of the pulse duration (,) contains a capacitor (35), which is reloaded once in the course of a pulse period (T) will. 6. Heart stimulator according to one of claims 4 or 5, characterized in that the potential (V) of said point (44) during the pulse period (T) is almost double Accumulator voltage (2U) reached. 7 · Heart stimulator according to claim 1, - characterized in that that between the rectifier (6) and the accumulator (3) a device (11) for stabilizing the charging current (J) is provided. 0098 11/0974 8. Heart stimulator according to claim 7, characterized in that the Stabilisierungsvorrichfeung (11) has a first transistor (17) located in the charging circuit, which is controlled by a second transistor (21), which in turn from the voltage drop in one with the first transistor (IT ) resistor (18) connected in series is controlled. 9. Heart stimulator according to claim 1, characterized in that ^ that the pulse generator (1) is provided with means (2,15,23,57) is to shield it from high frequency waves. 009811/0974