DE19923094A1 - Circuit arrangement for suppression of electrical leakage currents from electrodes connected to electrocardiograph (ECG) patient by generation of atypical output signal when electrode becomes loose - Google Patents

Abstract

Arrangement for suppression of electrical leakage currents and suppression of artifacts caused by such leakages on an ECG display when it is recorded and analyzed. For a multi-channel ECG apparatus low pass filters (TP1-TP3) and regulated amplifiers (V1-V3) are arranged between body electrodes (E1-E3) and ECG displays (S1-S3). A high frequency AC auxiliary voltage is connected via parallel high pass filters (HP2, HP3) limiters, amplifiers and time delays to the input of an AND gate (3). The output of this AND gate and the outputs of the amplifiers (V1-V3) are connected to a further AND gate (5) and a multivibrator. If one of the electrodes becomes loose or disconnected the signal to the last AND gate causes the mutlivibrator to generate an atypical signal such as a square wave signal and this causes visual and or audible alarms (L3, 8) to be triggered.

Description

The invention relates to an arrangement for interference suppression of electrical Derivatives of the body surface, e.g. B. ECG leads, especially for Avoiding derivative artifacts when recording and analyzing Long-term electrocardiograms and to avoid artifacts in the Recording of event EKG (event EKG).

Every ECG lead is based on the principle that suitable skin electrodes on the Body of the person to be monitored, usually on the chest. The electrodes are glued to the body or attached to the body with suction cups. In the case of hours of registration and normal movement of the person it comes in in many cases to loosen or even detach individual electrodes. The associated sudden change in skin contact resistance leads to so-called wobble artifacts or movement artifacts that inevitably arise are drawn and done by the subsequent or, if necessary, simultaneously computer-aided analysis cannot be recognized as such. Wrongly these artifacts are interpreted as arrhythmia and complicate the following visual analysis by medical personnel.

ECG recording devices with skin impedance control are already in place known. They indicate insufficient skin contact to the wearer. The lack  of these devices, however, is that for the duration of those carried out by the wearer Manipulation or in the absence of correction all artifacts are recorded. In addition, the alarm function in the recording device is in the known arrangement integrated, i.e. not available as a universal ballast. Farther If all electrode contacts are lost, a "cardiac arrest" during the analysis cannot be safely excluded.

The invention has for its object to provide an arrangement, the artifacts avoids single or multi-channel discharges of body currents, which insufficient skin contact of one or more electrodes. The The task continues to be the interference of the respective channel by acoustic and / or to signal an optical alarm and in the event of failure of all available electronics to transmit an or atypical channels an atypical signal.

This object is achieved in that between the record tion device, e.g. B. an EKG recorder, and an electronic body electrodes Monitoring circuit is arranged. This monitoring circuit measures the ohmic resistance or impedance, either between the electrodes of a Channel or each individual electrode against the other electrodes.

In one embodiment of the electrodes, it is possible to divide one electrode area in at least two electrically insulated parts, the ohmic Resistance or the impedance to the skin as a bridging conductor too to capture. If a defined skin electrode is exceeded Impedance turns off the affected channel or electrode, i. H. from Recording device electronically separated. At the same time it becomes visual and acoustic indicated which of the electrodes is faulty. If all available electrodes are faulty, an atypical special signal is displayed, which indicates the cause of the fault points.

When the corresponding electrode skin contacts are restored, the canal becomes electronically connected to the recorder again. So this process does not change several times within a short time, every electronic switch is on Assigned timer that a derivation channel only after a predetermined Time through permanent contact with the skin.  

The following description illustrates this function using an impedance over monitoring using a crossover or a high-low pass.

On the one hand, the low-frequency heart current signals are Filter and a subsequent regulated amplifier performed, on the other hand, a High-frequency AC voltage (approx. 1 V, 1 kHz) fed in as auxiliary voltage can pass a high-pass filter arranged parallel to the low-pass filter and secure contact of the body electrode E1. . . E3 signals, even if via the Low pass filter no signal is transmitted.

This monitoring arrangement also consists in that each high pass filter (HP2, HP3) an amplifier, a limiter, a time delay stage and one optical display, e.g. B. LED, which follows the safe contact of each body electrode signal. These signals are fed to a common AND gate, the Output is connected to the regulated amplifiers of all ECG leads and at -YES- enables them so that safe ECG recordings can be recorded.

If one of the body electrodes no longer has the required adhesion to the body, the contact resistance between the skin surface and the electrode becomes very high and the higher frequency voltage no longer reaches the high pass. At the exit the high pass no evaluable voltage signal is formed, so that also on Output of the common AND gate is zero and the individual regulated Amplifiers block the ECG leads. Instead, an atypical signal, e.g. B. a square wave signal from a multivibrator via a gate with negated input to the ECG leads performed, which identifies an artefact with this signal and at one Display unit for the holder of the electrodes optically a remedy for remedy and / or acoustically signaled.

In one embodiment of the invention, the body electrodes are in two conductive surfaces divided so that there is no electrical connection without physical contact of an electrode between the two electrode halves.

When an AC voltage of approx. 1 V and 1 kHz is applied to one half of the electrode is from the second half of the electrode through a high-pass filter, and the following Amplifier, limiter and a time delay an evaluable signal on a Transfer display unit, the information about the safe contact of the body electrode gives. If, with the body electrode detached, there is no longer an ECG signal via the low-pass filter and amplifier is transferred to the ECG lead and it is initially unclear whether it is it is a loosened body electrode or cardiac arrest  the high-pass signal conducted on a display unit information about faulty contact of the body electrode.

In a further embodiment of the invention, a is attached to a divided body electrode DC voltage, e.g. B. 1 V, as an auxiliary voltage. Via a resistor network R1, R2, R3 of a Wheatston measuring bridge, the resistance R4 between the Electrode halves measured and sent to a positive or negative signal Operational amplifier led. At the input of the operational amplifier there are positive and negative pole. The resistance R4 changes between the electrode halves, e.g. B. by loosening the electrode from the body, the current direction changes and am There is a positive or negative signal at the output of the operational amplifier.

The output of the operational amplifier leads to a limiter and a time ver Delay level before a corresponding signal on the display unit at the carrier the electrode arrangement is transmitted. If the electrode is stuck, the opposite is true stood very small between the electrode halves and it will have a low pass and Transmit an evaluable ECG signal to the EKG leads. Becomes on the other hand, no signal can be transmitted to the ECG leads, at first only suspected that a body electrode has come off the body. The change of Signals on the display unit then provide information about the cause of the malfunction ECG lead.

The idea on which the invention is based is described in the description below using exemplary embodiments which are shown in more detail in the drawing, explained.

It shows:

Fig. 1 shows a circuit arrangement for continuous monitoring of, for example 3 A body electrode for ECG recording using an alternating voltage as auxiliary voltage;

Figure 2 shows a circuit arrangement for continuous monitoring of a divided body electrode for ECG recording using an alternating voltage as auxiliary voltage.

Fig. 3 shows a circuit arrangement for continuous monitoring of a divided body electrode for ECG recording using a DC voltage as auxiliary voltage;

The body electrodes E1. . . E3 are usually on the chest of one to be monitored Person attached. They are glued to the body, with a rubber band or with suction cups attached. In the event of loosening or even replacement of some or all of them Electrodes E1. . . E3 must not lead to an undesired incorrect analysis in the ECG Evaluation come. So-called wobble artifacts can be recognized as such and not to be interpreted as arrhythmia or cardiac arrest.

In the circuit arrangement acc. Fig. 1 with the 3 body electrodes E1, E2, E3, the body signals with firmly adhering electrodes are each transmitted via a low-pass filter with <40 Hz and the following regulated amplifier to the ECG output S1, S2, S3. An low voltage filter TP1 can be applied to the body electrode E1 of approximately 1 V and a frequency of approximately 1 kHz. . . TP3 doesn't happen. The impedance increases with the body electrode E1 z. B. by a loosened body electrode, no evaluable ECG signal is passed to the ECG lead S1 via the associated amplifier V1.

With the body electrodes E2 and E3, the low-pass filter TP2; TP3 each have a high-pass filter HP2, HP3 connected in parallel, which allows the base AC voltage with the higher frequency of approx. 1 kHz to pass and leads to an AND gate 3 via amplifier V2, V3, limiter B2, B3 and a time delay Z2, Z3 .

Before the input to the AND gate 5 can be used to detect or assign the body electrodes E2 and E3 signal transmitter, z. B. lamps L1, L2 may be arranged. The output of the AND gate 3 is routed to the regulated amplifiers V1, V2, V3 which, if YES, connect the ECG signals to the leads S1, S2, S3 at the output of the AND gate 3 . At the same time, the output of the AND gate 3 leads to a further gate 5 with a negated input. If the output of gate 3 is -JA-, the output of gate 5 is -NULL-.

On the 2nd input of gate 5 , the signal from a multivibrator, z. B. a rectangular pulse, which is then equally transmitted at the output of the gate 5 via the resistors R1, R2, R3 to the ECG outputs S1, S2, S3 when the output from gate 3 is -NULL-. For the EKG transmission, this atypical square-wave signal means that one or more body electrodes E1, E2, E3 no longer have sufficient adhesion to the skin of the wearer. By suitable arrangement of signal generators at the output of gate 3 , for. B. buzzer 8 , lamp L3, the erroneous electrode contact can be signaled to the wearer of the EKG device on a display unit. The buzzer 8 receives its signal via a gate 6 with a negated input from a tone generator G2.

In the arrangement according to FIG. 2, a body electrode 11 , 12 is used, the conductive surface of which is divided two or more times. There is a defined resistance R7 between the electrode surfaces 11 , 12 when there is reliable contact on the skin. When an AC voltage is applied to an electrode half 12 of, for example, 1 V and 1 kHz, an evaluable higher-frequency signal is transmitted from the second electrode half 11 via a high-pass filter HP4, amplifier 13 , limiter 14 and a time delay 15 to A1 of a display unit, which is transmitted via a reliable or a loose contact of the body electrode 11 , 12 provides information.

At the same time, the low-frequency ECG signal is conducted to leads S1, S2, S3. If, with the electrode 11 , 12 released, no ECG signal is transmitted to the leads S1, S2, S3 via the low-pass filter TP4 and the amplifier 16 and it is initially unclear whether it is a detached body electrode or a cardiac arrest the higher-frequency signal at A1 of a display unit reveals a faulty or detached contact of the electrodes 11 , 12

In a further embodiment of the invention (Fig. 3) is connected to the divided electrode body 11, 12 a DC voltage, for example. B. 1 V =, as an auxiliary voltage. Via a resistor network R1, R2, R3, e.g. B. a Wheatstonian bridge, the resistance R7 between the electrode halves 11 , 12 is constantly measured and parallel to the ECG lead via low-pass filter TP5 and amplifier 17 to an Operationsver 18 out. A positive or negative voltage wave occurs at the output of the operational amplifier 18 and makes a statement about the electrode contact via the measured resistance between the electrode halves.

The operational amplifier 18 is followed at the output by a limiter 19 and a time delay 20 before a signal at A1 on an indicator unit on the support of the electrodes 11 , 12 signals an artifact or a safe contact.

When the electrode 11 , 12 adheres firmly, the resistance R7 between the electrode halves 11 , 12 is very small and a clear ECG signal is transmitted at S1, S2, S3 via the low-pass filter 16 and the amplifier 17 .

However, if S1. . . S3 no ECG signal transmitted, the body electrode 11 , 12 may have detached from the body. The change in the signal at A1 of the display unit provides information about the cause of the disturbance in the ECG lead.

Claims (3)

1. Arrangement for interference suppression of electrical discharges of the body surface, for. B. ECG leads, in particular to avoid lead artifacts when recording and analyzing long-term electrocardiograms and to avoid artifacts when recording event EKGs (event EKGs), characterized in that

• - That between the EKG recording (S1... S3) and the body electrodes (E1... E3) an electronic monitoring arrangement is connected, which the low-frequency body signals via a low-pass filter (TP1... TP3) and controlled amplifier ( V1 ... V3) leads to the ECG leads (S1 ... S3),
• - That a higher-frequency AC voltage (approx. 1 V) fed in as auxiliary voltage passes through a high-pass filter (HP2, HP3) arranged in parallel with the low-pass filter (TP1 ... TP3), the output signal of which passes through a downstream amplifier (V4, V5), limiter ( B2, B3), time delay (Z2, Z3) on the input of an AND gate ( 3 ) and its output signal leads to the regulated amplifiers (V1 ... V3) and the outputs of the regulated amplifiers (V1 ... V3) unlocks,
• - That the output signal from the AND gate ( 3 ) leads to a further gate ( 5 ) with a negated input and a further input of the gate ( 5 ) is connected to a multivibrator ( 4 ),
• - That the output of the gate ( 5 ) is connected to all ECG leads (S1 ... S3) and if the body electrodes (E1 ... E3) are incorrectly held, an atypical signal from the multivibrator ( 4 ), e.g. B. transmits a square wave signal, and this continues to lead to a visual and acoustic display (L3; 8 ) on the wearer of the device.

2. Arrangement for interference suppression of electrical discharges of the body surface, for. B. ECG leads, in particular to avoid lead artifacts when recording and analyzing long-term electrocardiograms and to avoid artifacts when recording event EKG (event EKG), characterized in that the conductive surfaces of the body electrodes (E1... E3) are divided, at an electrode half (12) a higher-frequency alternating voltage (about 1 V) is connected as an auxiliary voltage and on the second partial surface (11) is the derivative of the ECG signal via a low-pass filter (TP4 ) and amplifier ( 16 ), and parallel to the low-pass filter TP4, a monitoring arrangement is switched, which consists of a high-pass filter (HP4) and subsequent amplifier ( 13 ), a limiter ( 14 ) and a time delay ( 15 ) and on A1. . . A3 leads a display unit. 3. Arrangement for interference suppression of electrical discharges of the body surface, for. B. ECG leads, in particular to avoid lead artifacts when recording and analyzing long-term electrocardiograms and to avoid artifacts when recording event EKGs (event EKGs), characterized in that

• - That the conductive surfaces ( 12 ; 11 ) of the body electrodes (E1 ... E3) are divided, to which a DC voltage as auxiliary voltage and a resistor network (R1, R2, R3) in the manner of a wheatstonian bridge with the variable resistance R7 between the Electrode halves ( 12 ; 11 ) is placed, the signal to an operational amplifier ( 18 ) and the output of the operational amplifier ( 18 ) leads to a limiter ( 19 ) and a time delay ( 20 ) and A1 of a display unit, and
• - That parallel to the operational amplifier ( 18 ), a low-pass filter (TP5), which is followed by an amplifier ( 17 ), for deriving the ECG signal via S1. . . S3 is arranged.