JPH06197875A - Holter cardiograph - Google Patents

Abstract

PURPOSE:To prevent occurrence of electrical shock by commonly using a connector for receiving a signal from a patient's electrode attached to a patient's unit in order to temporarily store the signal in memory, and a connector connected to an external data analyzer, in order to reproduce and deliver a stored cardiographic signal. CONSTITUTION:During recording of a cardiographic signal, a receptacle 20 to which a patient's electrode 2 is attached, is connected to a connector 11, and a cardiographic detection signal is transmitted to a patient's unit 10 through the connector 11. Further, the signal is recorded in a memory 13 under the control of a CPU 15 through the intermediary of an A/D converter 12. During analysis of data, the receptacle 20 is removed from the connector 11, and a receptacle 21 to be connected to a data processing unit 4 is connected to the connecter 11. Further, data read from the memory 13 under the control of the CPU 15 is received by the data analyzer 4 through a route consisting of a connector 11, the receptacle 21 and the data analyzer 4, so that the data is subjected to a predetermined analyzing process.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a Holter electrocardiograph (portable electrocardiograph), and more particularly to a Holter electrocardiograph with improved use safety.

[0002]

2. Description of the Related Art Conventionally, an electrocardiograph has been used to examine the function of the heart of a patient. In recent years, a Holter electrocardiograph having an outer shape similar to that of a portable cassette tape recorder has been developed, and it has been put on a patient to record an electrocardiogram for about 1 to 2 days. This kind of electrocardiographic recorder periodically measures the electrocardiographic signal of the patient and records it in a built-in recording device. Then, when reproducing the recorded electrocardiographic signal,
A special analysis device is used for reproduction to diagnose the heart function.

There are roughly two types of conventional Holter electrocardiographic systems. Tape system In this system, an audio cassette tape is attached to a patient unit in the shape of a small portable cassette tape recorder (for example, Walkman (registered trademark) manufactured by Sony Corporation) to record an electrocardiogram. Next, the cassette tape, for which recording has been completed, is mounted in the analysis device, and is reproduced at high speed for analysis. IC system In this system, an IC memory is built in a patient unit in the shape of a small portable cassette tape recorder, and an electrocardiogram is recorded in this IC memory. Next, this unit is mounted on a dedicated analysis device for analysis.

FIG. 4 is a diagram showing an example of a conventional patient unit connection configuration. In the figure, 10 is a patient unit, 2 is a patient electrode connected to the unit, 3 is a patient electrode 2
Is a connector for connecting the patient unit 1. Reference numeral 4 is a data analysis device for reading and analyzing electrocardiographic data stored in the patient unit 1, and 5 is a connector to which the data analysis device 4 is connected. The patient unit 1 is operated by a battery, and the data analysis device 4 is operated by a commercial power source.

[0005]

In order to read out the electrocardiographic data stored in the patient unit 1 by the connection method shown in FIG. 3, the data analysis device 4 is attached with the patient electrode 2 attached to the patient. When connected to the patient unit 1, a circuit that allows a leakage current to flow is formed between the patient and the commercial power supply in a form including the commercial power supply receiving unit of the data analysis device, and the possibility of impairing electrical safety for the patient is significantly increased. . However, isolation of the patient circuit in the patient unit as a safety measure for this is not preferable in terms of size, weight, power consumption, and investment effectiveness.

The present invention has been made in view of the above problems, and an object of the present invention is to provide a Holter electrocardiograph in which the patient is not electrocuted in any case.

[0007]

SUMMARY OF THE INVENTION The present invention, which solves the aforementioned problems, provides a connector for temporarily storing a signal from a patient electrode attached to a patient unit,
It is characterized in that a connector for connecting with an external data analysis device for reproducing and outputting the electrocardiographic signal stored in the patient unit is shared.

[0008]

The connector for signal input from the electrode for the patient and the connector for connecting to the data analysis device at the time of data analysis are commonly used, and no other means for electrically contacting the other is provided. Therefore, according to this configuration, the patient electrode is connected to the patient, and in the state where it is also connected to the patient unit, it is also connected to the data analysis device to retrieve the analysis data from the patient unit. It no longer exists and essentially no electric shock to the patient.

[0009]

Embodiments of the present invention will now be described in detail with reference to the drawings. FIG. 1 is a block diagram of the principle of the present invention. The same parts as those in FIG. 4 are designated by the same reference numerals. In the figure, 11 is one connector used for both electrocardiographic data input and data analysis. Needless to say, since it is a single connector, it cannot be used simultaneously for inputting electrocardiographic data and for analyzing data.

Reference numeral 12 is an A / D converter for converting an electrocardiographic signal connected to the connector 11 into digital data, and 1
3 is a memory for storing the output of the A / D converter 12, 14
Is a three-state buffer, one of which is connected to the memory 13 and the other of which is connected to the connector 11. A CPU 15 controls the operations of the A / D converter 12, the memory 13, and the three-state buffer 14.

Reference numeral 2 is a patient electrode, 20 is a socket for connecting a plurality of patient electrodes 2 together to a connector 11,
Reference numeral 21 is a socket for connecting to the connector 11 when analyzing data. The socket 21 is connected to the data analysis device 4. The operation of the apparatus configured as described above will be described below. (When recording an electrocardiographic signal) At this time, the socket 20 to which the patient electrode 2 is attached is connected to the connector 11. At this time, the side of the 3-state buffer 14 connected to the A / D converter 12 has a high impedance, and the output side of the 3-state buffer 14 does not affect the input of the A / D converter 12.

In this state, the electrocardiographic signal detected from the body surface of the patient enters the patient unit 10 via the connector 11.
Then, it is converted into digital data by the A / D converter 12 for each channel. The electrocardiographic signal converted into digital data is written in the memory 13 under the control of the CPU 15. (At the time of data analysis) At this time, the socket 20 is removed from the connector 11, and the socket 21 connected to the data analysis device 4 is connected to the connector 11 instead. Also, C
The PU 15 activates the 3-state buffer 14. In this state, the data read from the memory 13 under the control of the CPU 15 enters the data analysis device 4 through the three-state buffer 14 in the route of the connector 11 → socket 21 → data analysis device 4 and a predetermined analysis is performed. Processing is performed.

FIG. 2 is a circuit diagram showing a main part of an embodiment of the present invention. The same parts as those in FIG. 1 are designated by the same reference numerals. In the figure, 11 is a connector, EL1 to EL
It is composed of signal input / output terminals of 8 channels up to 8 and analog ground (AGND) and ground (GND) terminals. The potential of this AGND is the A / D converter 1
It is supplied from 0, and when the power supply of the circuit is + 5V, it becomes + 2.5V at the midpoint between it and ground.
This AGND is coupled to an indifferent electrode (not shown) attached to the patient, so that the DC reference potential of the indifferent electrodes (6 in this case) is this AGND (= + 2.5V). On the other hand, of the data terminals, the electrocardiographic signals are actually input to the six channels of EL1 to EL6 of the signal input / output terminals. On the other hand, the digital data at the time of data analysis is 8 bits and the input / output terminals EL1 to E
Use all L8.

U1 to U6 are ECG amplifiers for amplifying electrocardiographic signals, and 30 is an A / D for multiplexing the outputs of these ECG amplifiers U1 to U6 and converting them into digital data.
It is a conversion unit. The A / D converter 30 includes a multiplexer in the A / D converter 12 of FIG. And
The output of the A / D converter 30 is given to a memory (not shown). A test pulse CAL for measuring the gain of each amplifier is applied to the other input of this ECG amplifier. The analog ground of the A / D converter 30 is connected to the AGND of the connector 11 via a resistor.
It is connected to the terminal. When this AGND is dropped to GND, the digital input / output mode is set. The potential of this AGND enters the other port through the gates G1 and G2 as a sense signal of the connection partner.

Reference numeral 14 is a 3-state buffer. The 3-state buffer 14 has an input mode, an output mode,
It can take three modes, a high impedance mode. The input mode is a mode for receiving data from the connector 11, and the output mode is a mode for outputting the data stored in the internal memory to the outside. The high impedance mode is a mode in which the output of the 3-state buffer 14 is set to high impedance and disconnected from the connector 11.

Reference numeral 31 is a control circuit which receives an address bus, a data bus, a clock φ and an R / W signal (read / write control signal) and gives a control signal to the three-state buffer 14. The control circuit 31 includes the CPU 15 shown in FIG. The control circuit 31 controls not only the operation of the 3-state buffer 14 but also the operations of the A / D conversion unit 30 and the memory (not shown). The operation of the circuit thus configured will be described below. (Electrocardiographic signal recording mode) In this mode, the control circuit 31
Applies a control signal to the 3-state buffer 14 and puts its output in the high impedance mode. Therefore, EC
This 3-state buffer 14 is provided at the input of the G amplifier Ui.
Can be considered substantially unconnected.
Therefore, the ECG amplifier Ui can perform desired signal sampling without being affected by the 3-state buffer 14.

In this state, the electrocardiographic signal (analog signal) input from the connector 11 is the E signal of each channel.
After being amplified by the CG amplifier Ui, it enters the A / D conversion unit 30. In the A / D conversion unit 30, first, the multiplexer sequentially switches the inputs, and the respective inputs are converted into digital signals by the A / D converter. The converted digital signal is sequentially stored in a memory (not shown). (Data Analysis Mode) In this mode, the control circuit 31 gives a control signal to the 3-state buffer 14 and sets the 3-state buffer 14 to either the input mode or the output mode. When outputting electrocardiographic data stored in the internal memory to an external analyzer, the 3-state buffer 1
4 becomes the output mode. As a result, the digital data read from the memory via the data bus enters the connector 11 via the three-state buffer 14 and then exits from the connector 11 to the outside.

When storing data from the outside in the internal memory, the control circuit 31 sets the 3-state buffer 14 in the input mode. As a result, data from the outside
The data enters the 3-state buffer 14 via the connector 11, the data bus is taken from the 3-state buffer 14, and the data is stored in a memory (not shown). At this time, the input / output data of the 3-state buffer 14 is input as the input signal of the ECG amplifier Ui, but this time has no influence because the electrocardiographic signal recording operation is not performed.

FIG. 3 is a diagram showing a configuration example of the signal input section. In the figure, D1 and D2 are diodes connected in anti-parallel. 2.5 V is connected to one end of this diode circuit via a resistor. G11 and G12 are circuits forming a part of the 3-state buffer 14. G11, G
Reference numeral 12 is a 3-state buffer. The operating states of these three-state buffers can be controlled by control signals from the control circuit 31. By putting two 3-state buffers in a high-impedance state, they can be separated from an external circuit. G11 is active, G12 is a high-impedance input mode, G11 is a high-impedance mode, and G12 is an output mode. Become.

In the electrocardiographic signal recording mode, G11, G12
Both have a high impedance, but at this time, the diode D1, to prevent noise from flowing into the analog circuit side.
D2 prevents noise from wrapping around. Then, the potential at the connection point of the diode circuit is clipped to 2.5V.

In the above-mentioned embodiment, since the DC potential of the indifferent electrode of the patient is fixed to AGND (= + 2.5V) as described above, the potentials of the other indifferent electrodes also take into account the distribution of the polarization potential at most. It is within the range of Therefore, the circuit of the anti-parallel diodes D ₁ and D ₂ has a high impedance and works to prevent the propagation of noise. Further, although the case of the IC type Holter electrocardiograph has been described as an example in the above-mentioned embodiment, the gist of the present invention is not limited to this, and the present invention can be similarly applied to other types such as a tape type. it can.

[0022]

As described above in detail, according to the present invention, it is possible to provide a Holter electrocardiograph in which the patient is not electrocuted in any case, which contributes to the improvement of safety.

[Brief description of drawings]

FIG. 1 is a principle block diagram of the present invention.

FIG. 2 is a circuit diagram showing a main part of an embodiment of the present invention.

FIG. 3 is a diagram illustrating a configuration example of a signal input unit.

FIG. 4 is a diagram showing a configuration example of a conventional patient unit.

[Explanation of symbols]

 2 Patient Electrode 4 Data Analysis Device 10 Patient Unit 11 Connector 12 A / D Converter 13 Memory 14 3 State Buffer 15 CPU 20 Socket 21 Socket

Claims (4)

[Claims] 1. A connector for temporarily storing a signal from a patient electrode attached to a patient unit, and a connector for connecting with an external data analysis device for reproducing and outputting an electrocardiographic signal stored in the patient unit. Holter electrocardiograph that also uses a connector. 2. A Holter monitor as claimed in claim 1, characterized in that it has no means for making electrical contact with anything other than its only connector. 3. The patient unit, a connector for signal connection, an A / D converter for converting an electrocardiographic signal into a digital signal, a memory for storing an output of the A / D converter, and a memory for storing the output of the A / D converter. 3. A 3-state buffer for receiving an output and a CPU for controlling the overall operation, wherein an input section of the A / D converter and an input / output terminal of the 3-state buffer are commonly connected. Holter ECG as described. 4. The three-state buffer is connected to the A / D converter input section with high impedance when the patient unit is set to the electrocardiographic recording mode. Holter ECG as described.