JPH02501892A - portable body monitoring device - Google Patents

Abstract

(57) [Summary] This bulletin contains application data before electronic filing, so abstract data is not recorded.

Description

[Detailed description of the invention] portable body monitoring device [Industrial application field] The present invention is a portable monitoring device, especially for acquiring and analyzing vital signs such as pulse, breathing, and body temperature. The present invention relates to a portable monitoring device suitable for storage and display.

[Conventional technology] Conventionally, devices for acquiring and storing vital signs have been proposed. However, this These devices are designed to treat only one vital sign. difference Furthermore, many devices are not truly portable.

Therefore, especially in hospitals, in order to obtain information about the pathological state of the patient, A large number of devices are used. Many of these devices are mounted on freestanding devices. A cable is required for connection from the patient to another free-standing device.

A known technique is disclosed in U.S. Pat. No. 4,606,352. . This patent specification describes a pocket-sized and complete dot matrix An electrocardiogram (ECG) monitoring device with a liquid crystal display is described. This device is an EC It simply detects and displays the G signal. The ECG signal.

It is just one type of ecological symptom information obtained from the human body. Doctors can accurately understand the patient's condition. In order to grasp this, a large amount of ecological symptom information is required.

British Patent No. 2,142,727 contains similar information that only provides limited information. A device has been described which has the disadvantages of:

In U.S. Patent Nos. 3.848.582 and 3.858.576.

A similar but more incomplete device is shown.

U.S. Patent Nos. 4,250.889, 4,230.127, 3,792,700 No. 4,083.3G6 states that the The ECG monitoring device is designed to be connected to the user or semi-permanently connected to the user. There is.

There are many publications in the public domain detailing the processing of ECG signals and the display of those signals. There are several. Examples of these include U.S. Pat. , 378 and 4,250.5030.

[Problem to be solved by the invention] In conventional technology, waveform distortion is not considered at all from the user's perspective. It was.

The way information is communicated to the user is always very important. For example, doctors are They are trained using a conventional stethoscope and are able to distinguish sounds from a conventional stethoscope. There is. Similarly, medical practitioners are also trained to provide information that is obtained directly from the patient and displayed on a high-resolution monitor. Become skilled at understanding unprocessed ECG signals.The technology for obtaining information has changed. However, the It is important that the information continues to be used.

The purpose of the present invention is to provide a portable monitor that can simultaneously measure and display multiple ecological symptom information. is to get the equipment.

Another object of the invention is to enable use of the various experiences gained with nine conventional devices. Electrical acquisition means can be used to obtain monitoring devices that provide information to experienced users. That is.

Yet another object of the present invention is to substantially overcome the above-mentioned drawbacks and to The objective is to obtain a portable monitoring device that can monitor information.

[Means to solve the problem] According to the present invention, the multifunctional electrode is arranged in a plane with respect to the first surface; data processing means for analyzing signals obtained from the functional electrodes; and said data processing means. It has an output means that outputs the information analyzed by the A portable and complete body monitoring device is obtained that detects and displays information.

[Example] Next, the present invention will be described in more detail with reference to the drawings showing nine embodiments of the present invention.

To illustrate the features of the invention, FIG. 2 shows an idealized electrocardiogram (ECG) waveform. . The symbols P, Q, R and S and their relationships are used by ECG monitoring devices and patients. used by hot-ray doctors to indicate the condition of the heartbeat. First aspect of the present invention The device of the second embodiment calculates the characteristics of this waveform according to a well-known algorithm. Videos that are analyzed and form part of the units of the first and second embodiments The patient's detected waveform is displayed on the display. Furthermore, the apparatus of the first and second embodiments detects other ecological symptom information at the same time. This ecological symptom information is also displayed on video in real time. displayed on the display.

ECG detection methods already exist in the past, but these require separate electrodes to be attached to the body. be. The device of the present invention simply places one unit on nine bodies, and the ECG waveform and other waveforms are displayed on the same unit. This makes it more compact. , offset the electrode placement of the device. Multiple multifunctional electrodes can detect multiple ecological symptoms. information and display it at the same time. This makes it possible to provide a powerful diagnostic device.

Referring to FIG. 1, one embodiment of the present invention is functionally illustrated as follows.

Ecological sign detector 2 The detector is configured to detect various types of data from one human body by a detector/buffer circuit 22 (not shown). Obtain ecological symptom signals. These signals are displayed and analyzed in real time. these A detector connected to the human body to collect signals is placed against the external skin of the chest. It consists of three multifunctional electrodes. These detectors detect electrical signals from the heart The functions of ECG electrodes.

A microphone that detects heart sounds, a temperature detector that measures temperature, and a breathing sensor. and impedance detection technology.

Various electrical signals from the detector are exchanged with digital information for subsequent measurement and display. It is amplified and filtered to convert the signal.

This signal processor removes unnecessary signals and noise. The processed signal is from there to external devices such as stethoscopes, printers, media, computers, etc. The device will be sent.

Analog-digital converter 4 Analog electrical signals so that subsequent processing is easier.

converted into digital information.

Measurement/calculator 5 The digital information obtained from ecological symptom signals can be converted into parameters that are easy for users to use. must be processed to display the data. Heart rate measures the average period of the ECG It is calculated as follows. The respiration rate is calculated by measuring the average period of the respiration signal.

The waveform and calculated values must be usable by the user. this The display function is a screen (preferably a high resolution dot matrix LCD display). display).

Various analog waveforms as traces on the screen and calculated values as numbers The purpose is to display the values on the same screen. In addition, the screen Used to inform the user of defects or troubles and the current mode of operation. Below Previously stored information can be read back to the screen by the user for reanalysis. It is done. The LCD screen is a rectangular 240X22 on a 2 inch diagonal display. It has 0 pixels. The display is updated at a sweep rate of 12.5 cm per second. Ru. Such display units are available from manufacturers such as Epson, Casio, Toshiba, etc. It's on sale.

Storage means 7 Waveforms and calculated values are stored in memory for re-reading by the user. , making a hard copy on a printer connected via external output or re-analysis This makes it possible to redisplay it on the screen.

The operation of many different means is controlled by this control means. The user can choose which Indicates to the control microprocessor which signals need to be acquired, processed, and displayed. The operation of the device is controlled via a control switch 9.

First example Referring to FIG. 3, the external features of the first embodiment are shown. This example is It has electrodes 11, 12 and 13 protruding from the case 8. These electrodes 1 1. The parts 12 and 13 that come into contact with the skin are on the same plane.

The electrode 11 has a built-in microphone 19. The receiving surface of the microphone is It is flush with the skin contacting surface of pole 11. Microphones can listen to heart sounds and lung sounds. It is designed to detect sounds.

The electrode 13 has a temperature detector 20, such as a thermistor. Temperature sensor inspection The exit surface is flush with the skin contact surface of the electrode 13. The electrode 13 is in contact with the skin. The temperature sensor 20 detects skin/body temperature.

Electrode 12 is the reference electrode, but any electrode can provide the electrical signal for ECG reading. It can be used as a reference electrode.

Electrodes 12 and 13 have a diameter of approximately 1.8 cm, with electrode 11 having a diameter of approximately 1.8 cm. It has a diameter of approximately 3.20!11. The distance between the centers of electrodes 11 and 12 and The distance between the centers of electrodes 12 and 13 is 6CO+, and the distance between the centers of electrodes 11 and 13 is 6CO+. The distance is 8.5c+o.

Case 18 houses speaker 16 and video display 17. video display The device has a high resolution suitable for graphical display and measures approximately 6 cIl square. It is desirable to have a screen of

Additional controls are shown in FIG. The additional control functions shown in Figure 3 are 50 and 1 display degree control 51, earpiece (for stethoscope) 52, and stethoscope on/off control 53, power on/off switch 54, and external connections to the recorder/monitor. output 55, battery charging terminal 56 and record button 57. Caliplay 58 ．． Sweep button 59° Freeze button 60. A video camera with a reset button 61 and display operation control.

In actual use, the device is applied to the skin surface of the patient's chest. Correct position In order to determine the heart rate, the user must measure the heart rate.

Breathing 1 ECG waveforms can be monitored along with body temperature, heart sounds, and lung sounds. heartbeat and all parameters other than lung sounds are output to the second display unit 17. heartbeat The lung sounds are outputted from the speaker 16 or outputted to an external audio output.

The obtained information is recorded on a recording medium or output to an external monitor device.

Possible functions as shown in the storage display system.

They are Caliplayed, Swive, Freeze and Record.

Devices powered by external means or internally rechargeable batteries are not suitable for auscultation. can receive audio or electrical input from the device. The equipment is also. More sophisticated processing Twelve ECG inputs can be received for display and display.

Optional external devices include a temperature sensor and printer.

There is a charger, blood pressure monitor, recorder/computer and central patient monitoring device.

FIG. 4 shows an example of the output of the video display 17 of this embodiment.

The display includes an ECG waveform 23 on which heart rate 24 and body temperature 25 are digitally displayed. displayed in the file. Users can obtain multiple ecological symptom information in real time with their eyes. This allows early and appropriate response to the patient's condition on the spot.

Reference numbers correspond to those in FIG. 3 and represent the same components. first and second The essential difference between the embodiments lies in the electrode shapes of electrodes 11, 12 and 13. second In the embodiment, the maximum distance between electrodes 11 and 12 is as shown.

Within the limits of case size.

Referring to FIG. 6, the second embodiment displays the ECG waveform on the display 17 in real time. Digitally displays heart rate 241 body temperature 25 and respiration rate 26 in analog format Ru.

FIG. 7 shows a block diagram of the electric circuit of the second embodiment. This example is a microprocessor 30. EPROM31. RAM32. Display controller 33. Address de 0 is from analog input of respiration 1 body temperature and ECG and control switch. digital input. Serial I10 link 39 is a printer or computer Provided for connection with.

The microprocessor 30 is Motorola's MC68HC11 microprocessor. controller chip can be used.

Analog-to-digital conversion capabilities along with other features including qualitatively suitable low power have. In this example.

The LCD display is a 240x220 pixel display and outputs 12.50I+ per second. Updated with Swiverate. Due to this.

An effective screen of approximately 50 Hz, which is a diagnostic mass particle but is sufficient for bedside use. bandwidth.

The data acquisition by the analog-to-digital converter of the microprocessor 30 is 1 Approximately 200 samples per second.

Diagnostic capability in a band of approximately 100 Hz is obtained.

During normal operation, the screen scans the acquired ECG waveform horizontally across the screen. Crawl and hold the waveform output on a 2 inch diagonal screen for approximately 3 seconds. pretend button 60 (Figures 3 and 5) allows you to leave the waveform as is if desired. It is also possible to freeze.

The RAM 32 has approximately 32 memories and stores digitally obtained ECG waveforms. 16K is used to hold it.

Therefore, in one normal state, it operates as an 80 second buffer for ECG waveforms. this When the unit is used for more than 80 seconds.

Information is written in a first-in, first-out format. Memory contents using serial I10 port 39.

Can be dumped to a printer/personal computer. This boat has infrared link It is desirable to consist of Thereby, even if device 1 is in use, the necessary It is possible to dump information from Alternatively, RAM32 or at least its Some can be used to remember specific frozen screens.

FIG. 8 shows a column of input circuits that can be used in the first and second embodiments. . This input circuit is provided within the electrode 13 and receives a signal from the thermistor 20. It has a skin temperature detection circuit, the signal of which is supplied to the microprocessor 30. before being applied to amplifier 40. Takara type MB can be used as a thermometer. . Also, a microphone 19 provided in the electrode 11 receives a signal from the microphone 19. An icrophone circuit is shown, the signals of which are passed through buffer amplifiers 41 . band pass Filter 42. in turn to the microprocessor 30 and earphones if necessary. It is also supplied to a buffer amplifier 43 which drives 440. earphones are used If so, an electronic stethoscope can be provided.

The electrodes are usually constructed of stainless steel to avoid DC offset in this embodiment. Platinum-plated stainless steel is used for this purpose.

The thermistor 20 in the electrode 13 is designed to respond quickly and faithfully to changes in body temperature. , must be electrically and thermally isolated from the electrode structure. temperature of the mouth and rectum For temperature detection, the thermistor has a probe that connects to an external input board 50. There is.

As shown in FIG. 8, the stethoscope assembly with microphone 19 is It is covered with a membrane similar to that used in stethoscopes, with a skin contact membrane and a micro An acoustic chamber is formed between the phone 19 and the receiving horn.

Also shown in FIG. 8 is a buffer input circuit for the ECG signal. three electrodes 11 , 12 and 13, the rEcGIJ positive signal from the electrode 11 is the rEcGIJ signal from the negative electrode 13. Provides the CG2J signal and reference signal to the buffer input circuit. buffer circuit itself before supplying to the 400 MHz constant current source 44 and the microprocessor 30. It has an amplifier 45 that supplies a bandpass filter 46 and an amplifier 47 to the . The RMS voltage detector provides an RMS signal of the ECG waveform to the microprocessor 30. supply.

9.10 and 11 are flowcharts illustrating the operation of microprocessor 30. It is. The software for driving the ECG and heart rate display of FIG. 9 is shown. 10th The figure shows the software for respiration display. Figure 11 shows the software for temperature display. . This software includes other software that controls the microprocessor 39. Both are stored in the EPROM 31.

The respiration measurement electrode ECGI (electrode 11) is a 400K)lz sine wave for approximately 11 people. Used to pass electrical current through the human body. Changes in human body impedance due to changes in oxygen content , which appears as voltage fluctuations in the reference power supply. RMS voltage detector 48 detects the RMS voltage of this variation. The data is read by the MS and provided to the microprocessor 30. The software outlined in Figure 10 Using the software, the patient's respiration rate is output on a display (shown at 26 in Figure 6). .

The second embodiment operates similarly to the first embodiment. Furthermore, as shown in Figure 6, , a respiration rate readout 26 may also be provided.

In addition to the embodiments described above, various modifications are possible within the scope of the claims of the present application. .

In particular, various variations in the structure of the electrodes can be used. In addition, the configuration and Regarding directionality and directionality, the displayed ECG waveform is considered a "standard" by well-known technology. It is important that the information is only displayed as shown.

Brief description of the drawing Figure 1 is a block diagram of an embodiment of the present invention, and Figure 2 is an idealized electrocardiogram (ECG). FIG. 3 is a diagram showing the characteristics of the external shape of the first embodiment, and FIG. 4 is a diagram showing the characteristics of the first embodiment. A diagram showing an example of output from the video output device in the embodiment, and FIG. 5 is an outline of the second embodiment. Figure 6 shows an example of output from the video output device in the second embodiment. 7 is a block diagram of the hardware section in the second embodiment, and FIG. 8 is a block diagram of the hardware section in the second embodiment. A block diagram of the input buffer 7 circuit applicable to the first and second embodiments, FIG. A flowchart showing the operation of the CG and heart rate display software, FIG. A flowchart showing the operation of the respiration display software, Figure 11 shows the temperature display software. 3 is a flowchart showing the operation of the software.

Fle, 1 FICy, 4 FICy, 6 Submission of translation of written amendment (Article 184-8 of the Patent Law) July 24, 1999 Yoshi, Commissioner of the Patent Office 1) Takeshi Moon 1. Display of patent application PCT/AU8810001θ 2. Name of the invention 3. Patent applicant Address: Palmaine, New South Wales 2041, Commonwealth of Australia Darling Street name: Micromedical Industries Pete Egui. limited 4. Agent〒105 Address: Daisan Mori Building, 5B, 1-4-10 Nishi-Shinbashi, Minato-ku, Tokyo! -1507・ 15235, date of submission of amendment <1) One translation of the written amendment In the field of quest Scope of claims (1) A plurality of multifunctional electrodes arranged in a plane with respect to the first surface; a data processing means for analyzing the signal obtained from the active electrode; and a data processing means for analyzing the signal obtained from the active electrode; It has an output means for outputting the analyzed information, and can simultaneously output multiple pieces of ecological symptom information in real time. A portable body monitoring device characterized by detecting and displaying.

(2) At least two of the plurality of multifunctional electrodes are arranged so that the monitoring device is connected to the patient's chest. to receive an electrocardiogram signal from the skin-contacting surface of the electrode when applied to the skin of the electrode. and the electrodes send the electrocardiogram signal to the data processing means. A portable body monitoring device according to claim 1.

(3) At least one of the plurality of multifunctional electrodes is a sound detector. The portable body monitoring device according to claim 1 or 2.

(4) At least one of the plurality of multifunctional electrodes has a temperature that detects the patient's skin temperature. The portable body monitoring device according to claim 1 or 2, wherein the portable body monitoring device is a degree detector.

(5) The electrode has a direct voltage in the range of 1.5 to 3.5 CIl+ on the surface that contacts the skin. Portable body monitoring device according to one of claims 1 to 4, characterized in that it has a diameter. Place.

(6) The output means includes a video display that displays waveforms and digital data. Portable body monitoring device according to one of claims 1 to 5, characterized in that it comprises:

(7) The plurality of multifunctional electrodes include first and second electrodes. Portable body monitoring device according to one of claims 1 to 6.

(8) The plurality of multifunctional electrodes have first, second, third, and fourth electrodes. Portable body monitoring device according to one of claims 1 to 6, characterized in that:

(9) The plurality of multifunctional electrodes are arranged on the same plane and in a triangular shape. , comprising a second and a third electrode. portable body monitoring device.

(10) All sides on the same plane and determined by the triangular shape are 10 or less 10. The portable body monitoring device according to claim 9.

(11) Some of the plurality of multifunctional electrodes have special single-task data. Portable body monitoring according to one of claims 1 to 10, characterized in that it provides: Device.

(12) The tasks include electrocardiogram waveform detection, sound detection, temperature detection, and breathing detection. and detecting a respiration rate. Monitoring equipment.

(13) each electrode of the plurality of multifunctional electrodes provides two or more tasks; At least two of the plurality of multifunctional electrodes perform a common task of detecting electrocardiogram signals. Some of the plurality of multifunctional electrodes are capable of detecting electrocardiogram waveforms and detecting sounds.

Process selected tasks among temperature detection, respiration detection, and respiration rate detection. Portable body monitoring device according to one of claims 1 to 10, characterized in that:

(14) The portable body monitoring device according to one of claims 1 to 13 is placed on the patient's chest. A method for monitoring ecological symptoms, characterized in that information on ecological symptoms of a body is monitored.

(15) a plurality of multifunctional electrodes arranged in a plane with respect to the first surface; a data processing means for analyzing the signal obtained from the functional electrode; It has an output means for outputting the analyzed information, and can simultaneously output multiple ecological symptom information in real time. A portable body monitoring device that detects and displays information is placed on the patient's chest to determine biological signs of the body. An ecological symptom monitoring method characterized by monitoring climate information.

international search report ,,,,,,,,,,,,,,,,,,,,,,,,,,,,,,, PCT/AU 8 8100016) My, ■fu Riero αMgoαGL9su ni n00Luηgo0ming-蓬红工■ko layer 8800016

Claims (7)

[Claims] (1) A plurality of multifunctional electrodes arranged in a plane with respect to the first surface; a data processing means for analyzing the signal obtained from the active electrode; and a data processing means for analyzing the signal obtained from the active electrode; It has an output means for outputting the analyzed information, and can simultaneously output multiple pieces of ecological symptom information in real time. A portable body monitoring device characterized by detecting and displaying. (2) The plurality of multifunctional electrodes are arranged in a triangular shape on the same plane. Portable body monitoring device according to claim 1, characterized in that it has second and third electrodes. Place. (3) The first electrode has a sound detector, and the second electrode has a temperature detector. 17. The portable body monitoring device according to claim 16. (4) All sides determined by the triangular shape on the same plane are 10 cm or less 18. The portable body monitoring device according to claim 16 or 17. (5) The electrode has a diameter in the range of 1.5 to 3.5 cm on the surface that contacts the skin. Portable body monitoring device according to one of claims 16 to 18, characterized in that it has Place. (6) The output means is a video table displaying ECG waveforms and digital data. Portable body according to one of claims 16 to 19, characterized in that it has an indicator. Monitoring equipment. (7) a plurality of multifunctional electrodes arranged in a plane with respect to the first surface; a data processing means for analyzing the signal obtained from the active electrode; and a data processing means for analyzing the signal obtained from the active electrode; It has an output means for outputting the analyzed information, and can simultaneously output multiple pieces of ecological symptom information in real time. A portable body monitoring device that detects and displays physical signs is placed on the patient's chest to monitor the body's biological signs. An ecological symptom monitoring method characterized by monitoring information.