FR2591464A1 - Primary remote electrocardiographic examination station and installation including such a station - Google Patents

Abstract

The invention provides a primary remote electrocardiographic examination station, intended to be connected to electrocardiographic sensors, characterised in that it comprises in combination an amplification and filtering circuit CAF adapted to the processing of a raw electrocardiographic signal So picked up by the sensors, a frequency-processing circuit CTF adapted in order to determine the characteristic frequency of the said signal, a modulation circuit MOD adapted to provide an adapted signal to be transmitted by telephonic means, and a supply circuit ALR.

Description

 The present invention relates to the electrocardiographic examination and monitoring of patients located in a place inaccessible to traditional electronic or electrical medical devices, either because of their incarceration in a distant place, difficult to reach, or because of their stay in an atmosphere rich in explosive substances: gas (methane), dust (coal dust), vapors (gasoline vapors), etc.

 It is intended primarily for rescue teams from coal mines, but it can be used advantageously by other teams intervening under similar conditions.

 In underground mining operations, the rescue and rescue of workers walled in after a landslide is particularly laborious.

 On the occasion of an exceptional and sudden increase in ground pressure, there is a collapse of several meters of galleries, with the imprisonment of the personnel present on the site in the pocket created upstream. (Fortunately, this is a relatively rare event).

In order to avoid new landslides, endangering the lives of the immured and the rescuers, the rescue work takes place in several stages, from a district located below the disaster district
(a) location of the walled,
(b) piercing of a weak communication channel
diameter for phonic connections and
the supply of walled food and
medication,
(c) digging of an evacuation tunnel.

 The time elapsing between the drilling of the communication conduit and the completion of the evacuation tunnel can reach several days, even several weeks.

 Currently, medical teams, having no means of paraclinical investigation, conduct the treatment of their patients based on the information provided by them during voice communications.

 The precise rules governing these particular conditions of intervention make it possible to deal with a large number of situations.

 However, in certain circumstances, the absence of an instrumental means of diagnosis is likely to dramatically delay a therapeutic decision.

 The aim of the present invention is to remedy this deficiency by means of tele-electrocardiography.

 In the present context, TELE-ELETR () CARDIOGRAPHY means the transmission by wire of raw electrocadiographic signals, captured using electrodes suitably placed on the body of a patient, located at a distance which may exceed 1 (10 meters from the reception station.

 It is specified that the potential difference between any two points of the human body, conventionally defined for the attachment of electrocardiographic sensors, is one to two millivolts, under an impedance which can reach several hundreds of thousands of ohms.

 The term "raw electrocardiographic signals" designates the electrocardiographic signals before any transformation due to amplification or filtering.

 The aforementioned objective (remote transmission of electrocardiographic signals without prior amplification or filtering) would seem a priori difficult to achieve insofar as in current practice, all acts of diagnosis and monitoring based on the electrocardiogram imply the presence of the patient at proximity to the electrocardiography device, except in the case of radio transmission.

 In the particular case which concerns us (monitoring of patients walled in an underground exploitation), the transmission by hertzian way proves impracticable because of the obstacles opposed to the propagation of the hertzian waves by the structure of the underground mining environment on the one hand, and by the conditions of incarceration of the patients, on the other hand.

 The means implemented by the invention make it possible to circumvent these difficulties and to introduce electrocardiographic examination and monitoring into rescue operations.

 The invention achieves the above objective through the implementation, at the free end of the communication conduit, of a primary electrocardiogram monitoring station connected by a wire connection to electrodes placed on the chest of a walled subject, adapted, despite the attenuation along this connecting wire of the EKG signal, to amplify and filter it, to determine the frequency on the spot so as to compare it with limit values thresholds, and, very advantageously, modulating the alternating signal which constitutes this electrocardiogram so as to be able to transmit it by telephone to the nearest diagnostic center via an appropriate demodulator associated with this center. preferably, this primary treatment station is equipped with a display device adapted to display the shape of the electrocardiogram.

 The invention provides a primary remote electrocardiographic examination station, intended to be connected to electrocardiographic sensors, characterized in that it comprises in combination an amplification and filtering circuit suitable for processing a raw electrocardiographic signal received by the sensors, a frequency processing circuit adapted to determine the characteristic frequency of said signal, a modulation circuit adapted to supply a signal adapted to be transmitted by telephone, and a supply circuit.

 The invention advantageously recommends that this primary station be combined, within a remote electrocardiogram monitoring device, with electrocardiographic electrodes formed from balsa strips impregnated with lithium chloride, the high performances of which are well known.

We can refer to this in particular to the following articles
- Clinical Trial of a Balsa-Lithium Electrode for
Conventional Electrocardiography by FISHMANN et al in The American
Journal of Cardiology, p. 346, December 1962 issue;
- Progress in Long Term Biomedical Monitoring of Human Heart
Rate Through the Use of Lithium Chloride Impregnated Balsa Electrodes by FK COOMBS in 1967 SWIEEECO Record 10-2-1, IEEE Cat NO F-72; or
- Some New Electrode Techniques for Long Term Physiologic
Monitoring by RICHARDSON et al in Aerospace medicine, Vol. 39, NO 7,
July 1968.

 The invention also provides a complete monitoring installation grouping together the aforementioned device and the demodulator of the associated diagnostic center.

The recommended device is formed:
- a primary reception station, located at the bottom of the
mine, and
- a terminal reception station, located in a center
medical, on the surface.

 During the electrocardiographic examination or monitoring operations, the patients receive the electrocardiographic sensors (electrodes) and the wires which connect them to the primary reception station, through the communication conduit.

 When it reaches the primary station, the electrocardiogram is amplified, filtered, then applied, unaltered, to three independent circuits.

 The first circuit performs- (a) the calculation of the frequency of the examined heart, (b) the instantaneous display of this frequency and (c) its comparison with the alarm thresholds, high and low, set by the examiner; (d) exceeding one of the thresholds instantly causes an alarm light to come on.

 The second circuit provides an undeformed signal, conforming to IRIG standards, making it possible to view the electrocardiogram on a traditional device (oscilloscope, oscillograph), meeting the safety rules in force in gassy mines.

 The third circuit is intended to modulate the electrocardiographic signal, to allow its transmission, via an existing telephone installation, to a terminal reception station, attached to a diagnostic and treatment center, without limitation of distance.

 On arrival at the terminal reception station, the electrocardiographic signal is applied to a demodulator which restores it, without deformation, to the IRIG standard, for the purposes of viewing, processing and archiving.

 All the modules constituting the electrocardiographic information collection chain described above, as well as their sources of power supply, have been designed and produced in accordance with the legislation governing the use of electrical devices in gassy mines.

The objects, characteristics and advantages of the invention appear from the following description, given by way of nonlimiting example, with reference to the appended drawings in which
FIG. 1 is a block diagram of an electrocardiogram monitoring installation according to the invention,
FIG. 2 is an electronic diagram of the amplification circuit of FIG. 1,
FIG. 3 is an electrical diagram of the modulator of FIG. 1,
FIG. 4 is an electrical diagram of the comparator of FIG. 1,
FIG. 5 is an electrical diagram of the frequency meter of FIG. 1,
FIG. 6 is an electrical diagram of the rechargeable power supply of FIG. 1,
FIG. 7 is an electrical diagram of the demodulator of FIG. 1, and
FIG. 8 is an electrical diagram of the supply of the demodulator of FIG. 7.

As shown by way of example in FIG. 1, a monitoring installation by tele-electrocardiography, according to the invention, consists of three sub-assemblies: (1) electrocardiography sensors (electrodes) and the corresponding wiring (not shown); (2) a primary PPS monitoring station, to which the sensors are connected by long wires (This station is here supplemented by a primary visualization console CV1 (oscilloscope), meeting the safety rules in force in gassy mines) ; and (3) a PTS terminal monitoring station located on the day connected to the PPS primary station by a two-wire telephone line
LT, here supplemented by a second CV2 display console.

 The primary PPS monitoring station mainly comprises an amplification and filtering circuit CAF intended to receive the electrocardiographic signals So coming from a patient, a modulator MOD mounted between the amplification and filtering circuit and the telephone line LT, and a CTF frequency processing circuit suitable for measuring the characteristic frequency of the electrocardiographic signal. The latter circuit here comprises a comparator CP and an FM frequency counter equipped with display elements EV1 and EV2. An ALR autonomous rechargeable power supply provides these circuits with the electrical energy necessary for their operation. All of these circuits are intrinsically safe.

The CAF amplification and filtering circuit is shown in Figure 2; this circuit mainly comprises seven operational amplifiers Aûl to A07 distributed in three stages: a first stage (stage I) of the differential type, a second stage (stage
II) with non-inverting amplifier with non-linear gain, intended to eliminate parasitic frequencies, and a third stage (stage III) with non-inverting amplifier and second order rejector filter.

 - First stage: The first stage consists of a differential amplifier, whose inputs are protected against leakage currents.

 A01 and A02 are unit gain amplifiers, used to adapt the high impedance of the "patient - sensor - lead wire" chain to the operating requirements of the differential amplifier A04.

- Second stage: The output of the amplifier A04 is applied by the circuit C1-R7, to the positive input of the amplifier
A05, whose output is in turn applied to the positive input of amplifier A06.

 Amplifiers A05 and A06 are non-inverting amplifiers, comprising low-pass filters.

 A potentiometer Pi makes it possible to adjust the quiescent current of the amplifier A06 whose output is applied to the third stage.

 - Third stage: The third stage consists of an operational amplifier A07, with second order rejector filter, composed of resistors R13-14-15, capacitors C3-4-5-6 and feedback circuit C7- C8-R17-RlB.

 The output signal S1 of this amplification and filtering circuit is applied to the modulator MOD and to the comparator CP.

 The MOD modulator (FIG. 3) mainly comprises an integrated circuit IC1, with which resistors R19 and R20 are associated, capacitors C9 and C10, and a potentiometer P2 which is used to adjust the carrier frequency.

 The operation of the modulator is based on the principle of frequency modulation. Its output 52 is isolated from the line LT using a capacitor C1. The signal S2 is modulated by S1, so that S2 = carrier frequency + S1.

 The comparator CP is shown in FIG. 4. I1 comprises a non-linear amplifier 1C2 and a comparator 1C3. A potentiometer P3 makes it possible to adjust the reference potential applied to the comparator IC. Output 53 provides a logic level of + 5V or zero, depending on the value of S1 with respect to P3.

 The frequency meter in Figure 5, for measuring the heart rate, has three circuits: (a) a clock circuit, (b) a counting circuit with its EVI display element and (c) an alarm circuit with its EV2 display element.

Frequency counting and display circuit:
The clock circuit consists of a 1C9 quartz oscillator and its dividers (IC5-IC6-IC7 and IC4-1).

 The circuits IC11 and IC12 are used to synchronize the counter In21, as well as the flip-flops IC22.

 IC24-25-26-27-28 transform the signal into binary coded decimal, for display.

 IC41-42-43 are the decoders of - 1C47-48-49 displays.

Alarm circuit
IC13-14-15 and IC16-17-18 determine the high alarm and low alarm frequencies.

 IC35-36-37 route these frequencies to the IC44-45-46 alarm displays.

 IC29-30-31-32-33-34 are the logical comparators which activate, as the case may be, the high alarm or the low alarm.

 IC35-36-37 - select the frequency of high alarm or low alarm for 11 display.

 IC38-39-40 are the decoders of the 1C44-45-46 alarm frequency displays.

 The autonomous safety supply @@@ rs @ edue (figure 6): the elements D2 to D10 and R34-R35-R36 serving this supply in accordance with the legislation relating to so-called intrinsically safe circuits, intended to operate in greasy mines .

The demodulator (Figure 7). It includes @@ sses:
1. IC52 transforms the configuration input signal not
periodic, in a square signal, intended to suck IC50.

2. IC50 is the receiver itself
R40-C21 determines the frequency of clean supply of the
modulator. The demodulated signal is preferred over the
pin 7.

The carrier frequency is eliminated by the R42 filters
C23-R43-C24-C25.

3. IC 51 is a linear gain amplifier, the
role is to restore the signal under - -
standardized.

The demodulator supply (Figure
- It: step down transformer
- Dll-D12: righting bridge,
- C3G-C32: filtering,
- IC53-IC54: voltage regulators,
- R53-54-57-58: used to determine the output voltage,
- R52-56: current limiting resistors.

I1 has thus been described a chain of examination and fS remote monitoring, by means of the electrocardiogram having the following particularities
- Association of an amplification circuit and a filtering circuit adapted to the processing of the electrocardiogram (composite signal of 1-2 mV), coming from a subject distant from 10 to 100 meters, (as opposed to the means characterized by the presence of the patient near the recorder), thanks to the peculiarities of the first amplification stage, composed of two amplifiers with unity gain, which serve to adapt the high impedance of the chain "patient - sensors - wires" at the input impedance of the differential amplifier A4.

- Measurement of the frequency of said electrocardiogram, monitoring
(1) instantaneous display of the heart rate,
(2) its comparison with a high threshold and a low threshold,
(3) instant display of an alarm, high or low,
if the pre-established thresholds are exceeded.

 - Development of an electrocardiographic signal, conforming to the international standard, for oscilloscopic or oscillographic display at a primary reception station.

 - Modulation of the signal for its transmission by means of a telephone line to a terminal reception station linked to a diagnostic center, without limitation of distance.

 - Demodulation of the signal, at the terminal reception station, followed by its restitution in a standardized form, for oscilloscopic or oscillographic display, for the purposes of exploitation and archiving.

 The modules used in the composition of the examination and monitoring chain were designed and produced in accordance with the regulations governing the use of electrical devices in gassy mines.

 The device, originally designed for the rescue of patients walled in at the bottom of a coal mine, is also usable in all situations of rescue of incarcerated patients and, as a result, difficult to access by traditional means of diagnosis and monitoring.

Claims (9)

REVEICTTOS  1. Primary remote electrocardiographic examination station, intended to be connected to electrocardiographic sensors, characterized in that it comprises in combination an amplification and filtering circuit (CAF) adapted to the processing of a raw electrocardiographic signal ( SO)) picked up by the sensors, a frequency processing circuit (CTF) adapted to determine the characteristic frequency of said signal, a modulation circuit (MOD) adapted to supply a signal adapted to be transmitted by telephone, and a circuit d 'food (ALR).  2. Primary station according to claim 1, characterized in that the amplification and filtering circuit comprises a first stage of differential type comprising a differential amplifier (A04) preceded by two amplifiers with unity gain (A01, A02) intended to adapt the impedance of a chain comprising the sensors, a connection cable to said primary station and a patient carrying these sensors, to the input impedance of said differential amplifier (A04).  3. Primary station according to claim 2, characterized in that the amplification and filtering circuit (CAF) further comprises a second stage with non-inverting amplifier with non-linear gain (A05, A06) and a third stage with non-amplifier inverter (A07) and with second order rejector filter (R13-14-15; C3-4-5; C7 C 8 - R17 - R18).  4. Primary station according to any one of claims 1 to 32 characterized in that the modulation circuit (MOD) comprises a circuit (IC1) adapted to frequency modulate the incident signal (S1).  5. Primary station according to any one of claims 1 to 4, characterized in that the frequency processing circuit comprises a clock circuit (IC9; IC4-1; 1C5; IC6: IC7), a counting circuit ( IC21, IC 22) and an alarm circuit (IC 29 to IC 34) adapted to compare the measured frequency with a low frequency threshold and a high frequency threshold.  6. Primary station according to claim 5, characterized in that the frequency processing circuit (CTF) comprises a display element (EV1) associated with the counting circuit and a second display element (EV2) associated with the alarm circuit .  7. Primary station according to any one of claims 1 to 6, characterized in that it further comprises a primary display console - (CVi> adapted to display the cardiographic signal.  8. Installation for a remote electrocardiographic examination comprising a primary station according to any one of claims 1 to 7, characterized in that it further comprises electrocardiographic sensors including balsa strips impregnated with lithium chloride.  9 salon installation claim 8, characterized in that it further comprises a terminal monitoring station (pts) comprising a demodulator adapted to be connected by telephone to the primary station (PPS).