Protection system for preventing defibrillation with incorrect or improperly connected electrodes
First Claim
1. In a defibrillator adapted to selectively monitor and defibrillate electrodes, respectively, said defibrillator having an enable input allowing said defibrillator to defibrillate when an enable signal is present on said enable input, a protection system for preventing said defibrillator from defibrillating when said defibrillator is improperly connected to the correct electrodes through a pair of electrode leads or properly connected to the incorrect electrodes through said electrode leads, said protection system comprising:
- impedance measurement circuit means connected between said electrode leads, said impedance measurement circuit generating an output signal indicative of the impedance between said electrodes;
processor means receiving the output signal from said impedance measuring circuit means and generating said enable signal when said output signal is indicative of an impedance within a range of impedances characteristic of a defibrillator electrode properly connected to said electrode leads; and
range adjusting means for causing said output signal to have a magnitude that is proportional to a relatively large multiple of said impedance in a low impedance range and to a relatively small multiple of said impedance in a high impedance range, thereby increasing the range of said impedance measurement circuit for a predetermined sensitivity and range of output voltages.
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Accused Products
Abstract
A protection circuit for a defibrillator that prevents a defibrillator pulse from being generated if the impedance between the defibrillator'"'"'s electrode leads is not characteristic of the impedance between a pair of defibrillator electrodes properly connected to the defibrillator. The impedance measuring circuit applies a current to the electrode leads and the resulting voltage is measured to provide an indication of the electrode'"'"'s impedance. The current is applied between the electrodes at about 33 kHz to approximate the impedance between a pair of defibrillator electrodes during a defibrillation pulse. The output of the measurement circuit is converted to an 8 bit word by an analog-to-digital converter and read by a microprocessor which compares the measured impedance to various impedance values in order to either generate an enable signal for the defibrillator or display messages indicative of open or short circuited electrode leads or a patient monitoring electrode connected to the electrode leads. the impedance measurement circuit operates in either of two ranges which are selected by the microprocessor on the basis of the measured impedance values.
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Citations
7 Claims
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1. In a defibrillator adapted to selectively monitor and defibrillate electrodes, respectively, said defibrillator having an enable input allowing said defibrillator to defibrillate when an enable signal is present on said enable input, a protection system for preventing said defibrillator from defibrillating when said defibrillator is improperly connected to the correct electrodes through a pair of electrode leads or properly connected to the incorrect electrodes through said electrode leads, said protection system comprising:
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impedance measurement circuit means connected between said electrode leads, said impedance measurement circuit generating an output signal indicative of the impedance between said electrodes; processor means receiving the output signal from said impedance measuring circuit means and generating said enable signal when said output signal is indicative of an impedance within a range of impedances characteristic of a defibrillator electrode properly connected to said electrode leads; and range adjusting means for causing said output signal to have a magnitude that is proportional to a relatively large multiple of said impedance in a low impedance range and to a relatively small multiple of said impedance in a high impedance range, thereby increasing the range of said impedance measurement circuit for a predetermined sensitivity and range of output voltages. - View Dependent Claims (2, 3, 4)
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5. A defibrillator adapted to both defibrillate through a defibrillation electrode and monitor a patient through a monitoring electrode, said defibrillation electrodes and said monitor electrodes being connected to the same pair of electrode terminals of said defibrillator, said defibrillator comprising:
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high voltage power supply means selectively applying a high voltage defibrillation pulse between said electrode terminals to defibrillate said patient; monitoring circuit means receiving an ECG signal from said patient between said electrode terminals; disable means for preventing said high voltage power supply means from applying said high voltage defibrillator pulse between said electrode terminals whenever an enable signal is not being applied to said disable means; an AC current source connected between said electrode terminals so that the voltage of an AC signal generated between said terminals is proportional to the impedance of the electrode connected between said terminals; detector means connected between said electrode terminals, said detector means generating a DC voltage that is proportional to the amplitude of the AC signal between said electrode terminals; range adjusting means for causing said AC signal to have a magnitude that is proportional to a relatively large multiple of said impedance in a low impedance range and to a relatively small multiple of said impedance in a high impedance range; and processor means receiving said binary coded signal, comparing the voltage of said binary coded signal to a range of acceptable values indicative of the impedance of a pair of defibrillation electrodes properly connected to said electrode terminals and to said patient, and generating said enable signal at an output port if said binary coded signal has a value within said range of acceptable values, said processing means further including range control means controlling the operation of said range adjusting means, said range control means causing said impedance between said electrode terminals in said low range and switching said impedance measuring means to said high range when said AC signal has a voltage indicative of an impedance larger than a first predetermined value. - View Dependent Claims (6, 7)
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Specification