JPH0248252B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION TECHNICAL FIELD The present invention relates to a device for monitoring epileptic convulsions, tremors, breathing, heart movements, etc. in a subject, such as a patient in bed.

TECHNICAL BACKGROUND For technology related to the present invention, see Finnish Patent No. 55113. In the invention according to this patent, electrodes are attached to the patient so that various data related to the biological current generated by the patient can be observed. However, in this patented invention, the electrodes have to be attached to the patient as described above, and if they come off, proper operation cannot be performed, and there are also disadvantages such as psychological stress caused by attaching the electrodes to the patient. Also,
Various devices for measuring a patient's pulse have also been developed, but these devices also require electrodes to be attached to the human body and have the same problems as the above-mentioned patented invention.

Furthermore, although it is known in the prior art to use ballistocardiography to record the recoil movements of the body caused by vibrating heartbeats, this device requires a well-balanced bed and a vibration-free bed. It is necessary to prepare a room and is expensive, so it has been difficult to widely apply this for clinical use.

Purpose of the Invention In view of the above, an object of the present invention is to provide a device that can monitor the convulsions, breathing, heart movement, etc. of a subject without attaching electrodes to the subject such as a patient. It is something to do.

Structure of the Invention In other words, the device according to the present invention can treat epileptic seizures, tremors, breathing, and
A device for monitoring heart movement or other movements without directly attaching a detection means to a subject, comprising an active layer and a sensing electrode attached to a bed on which the subject is placed, and an amplifier connected to the sensing electrode. and monitoring means connected to an amplifier, the active layer comprising at least two mutually contacting layer members having different dielectric constants, the contact between both layer members being determined by a force applied to the active layer. The movement of the surfaces relative to each other causes a change in the charge distribution at the contact surface between the layered members, and a sensing electrode senses the change in charge,
It is characterized in that an electrical signal is transmitted to the amplifier, and the transmitted signal is transmitted to the monitoring means and converted into a visual, acoustic or mechanical signal.

Functions and Effects of the Invention The device according to the present invention has the above-described configuration, and the test subject only needs to lie on the bed on which the device according to the present invention is set.
The required monitoring action is performed without any parts of the device, such as electrodes, being attached directly to the body. That is, the movement of the subject on the bed due to heartbeat, breathing, or epilepsy is transmitted to the active layer, causing slight changes in the relative positions of the layer members that make up the active layer. , causing a change in the charge distribution on the contact surfaces of those layer members,
The sensing electrode transmits a corresponding signal to the monitoring means, and the required monitoring is performed. The signals transmitted to the monitoring means are caused by various movements of the human body, and depending on the desired monitoring purpose, a necessary movement signal can be extracted by filtering the required band.

As can be seen from the above, in the present invention, there is no need to attach electrodes to the human body in order to monitor the movement of the human body, so that the drawbacks of the prior art described above can be avoided.

Embodiments Hereinafter, the present invention will be described in detail based on embodiments shown in the accompanying drawings.

FIG. 1 shows a recording pinerest 11 and a (preferably) foamed plastic pinetress 2 thereon.
A patient or person being examined P is shown lying supine on a bed 10 with 8 and 8. The recording mattress 11 comprises two metal plate-like sensing electrodes 12a, 12b of the same size and shape or a similar metal mesh, rod or grid acting as an antenna. An insulating plate 13' is sandwiched between the sensing electrodes 12a, 12b.
2b, and also as a mechanical support so that the sensing electrodes 12a, 12b can be in the form of relatively thin films attached to the surface of the insulating plate 13'.

The metal plates or sensing electrodes 12a, 12b are connected by insulated conductors 14 to a preamplifier 17, which is a prior art differential amplifier of the type used in ECG technology characterized by a high input impedance. be able to. As shown in FIG. 1, amplifier 17 is connected to a monitoring and recording device by an insulated cable.

There is an active layer immediately above the sensing electrode.
29 are provided. The active layer includes layer members 29a and 29 made of two insulating members having different dielectric constants.
It is composed of b. A suitable material is plastic. As shown, the layer members are in contact with each other and their contact surfaces are movable relative to each other while remaining in contact. Layer member 2
The contact surface of 9a has a large number of air-filled vesicles and constitutes a "friction reducing element" for facilitating movement relative to the contact surface of layer member 29b.

When the body of the subject on the bed moves, forces are transmitted to the active layer, causing a relative displacement between the contact surfaces of the layer members, thereby causing a change in the charge distribution within the active layer, which sensed by the antenna.

The active layer 29 and sensing electrode 12 are inserted into a shield 30 made of a conductive flexible material that is connected to the ground terminal of the amplifier 17. In practice, the shield 30 can be made of a plastic film bag that is metallized on the outside. The sensing electrode also has metal films 12a on both sides,
Since it can be made from the plastic film 13 provided with 12b, the recording pintress can be folded thinly.

The mode of operation of the above-mentioned recording pintress is as follows. Movements of the patient's body are transmitted via the foamed plastic mattress 28 to the active layer 29, where the insulating materials 29a, 29b of different dielectric constants are moved relative to each other so that their contact points change. It will be done. It is well known that this results in surface charges of different signs on the insulating materials 29a, 29b. These surface charges constitute an electrical dipole (or dipole) whose electric field is transmitted to a sensing electrode, and the signal obtained by the sensing electrode is recorded by an amplifier. The recorded signal corresponds to the patient's movement since the orientation and number of dipoles, and therefore also their electric field, change with the patient's movement. On the other hand, the metal surface of the shield 30 and the antenna plate 12a,
12b forms a capacitor between them, and since the active layer 29 is made of an elastic material, when the capacitance of the capacitor made of metal plates on both sides of the active layer changes, the voltage of these capacitors changes. do.

Based on the above, the recording mattress of the present invention can have the following structure (FIG. 1B).

The sensing electrodes 12a, 12b are arranged with an active layer 29 above them, and the sensing electrodes and the active layer are enclosed within a continuous shield 30 that is internally insulative and coated with a conductive material. It will be done.
The structure thus obtained operates in the following manner.

As mentioned above, the sensing electrode is composed of two mutually insulated conductive metal plates, that is, the sensing electrodes 12a, 12.
These metal plates cooperate to form a capacitor C. The conductive shield 30 then cooperates with the metal plate 12b to form a capacitor _C2 ,
It also works together with the metal plate 12a to form a capacitor _C1 . Capacitors C ₁ and C ₂ have different capacitances, and due to the above-described structure, capacitor C ₂ has a larger capacitance than capacitor C ₁ . A foamed plastic 28 is placed on such a structure, on which the patient P lies. Movements of the patient are transmitted through the foamed plastic 28 to the underlying structure, and therefore, first of all, since the insulating layer 29 is composed of a highly elastic material, the capacitor C ₁
The capacitance of varies. Furthermore, patient movement creates a static charge on the active layer and locally changes the charge.

In the case of 1B, the capacitor C ₁ can be charged by an external voltage source, or a material can be used in which the active layer 29 is permanently charged.

Due to the factors mentioned above, the voltage on capacitor C ₁ changes first, and these voltage changes are transferred to the sensing electrode and the capacitor C formed thereby.

The structure described above particularly provides the following advantages.

The sensing electrodes 12a, 12b, which act as sensing electrodes and are to be coupled to the input terminals of the amplifier, are symmetrical with respect to the external interfering electric field, but the active layer 29
The change in charge that occurs is asymmetric.
Shield 30 acts as a shield against external interfering electric fields and transmits changes in charge caused by movement to sensing electrode 12 . shield 3
0 is the ground terminal of the amplifier 17, that is, the potential "protection"
Connected to the terminal.

FIG. 2 shows a hospital monitoring and control system to which the device of the invention is applied. This system includes a patient room 20, in which beds 10a, 10b, 10c, etc., equipped with the aforementioned sensing electrodes are placed, and these sensing electrodes are connected to an amplifier 1 by cable.
7a, 17b, 17c etc., these sensing electrodes are then connected to shielded cables 18a, 18
b, 18c are connected to the monitoring and recording device 19. Since it is often unavoidable to locate the patient room 20 at a great distance from the control room 27, it is necessary to use a special electrical transmission system between these rooms, which system includes modulation, e.g. time sharing principles. used. Such systems are known per se in the art and therefore a detailed description thereof is omitted. FIG. 2 shows devices belonging to this system, namely a line driver, a multiplier 22 and a line receiver 23.

The signals obtained from the receiver 23 are directed to a signal processing means 24 having a tank circuit of 50 Hz and adjustable bands, each adjustable band being selected for a particular application, for example, for respiratory monitoring, a band
0.2 to 3 Hz, and 0.5 to 10 Hz for nighttime motion pick-ups. After passing through the signal processing circuit 24, the signal is sent to a monitoring device or recorder 2.
The monitor and recorder are both devices known in the art. The monitoring device can be an oscilloscope or any conventional recorder such as an ECG recorder. Monitor 25
An alarm device 26 is connected to the
For example, an alarm may be triggered if the patient's breathing or heart movement stops completely or if this movement is significantly different from normal.

FIG. 2 shows three signals recorded by the method according to the invention. Record a is an unfiltered signal, record b is, for example,
It represents the same signal after passing through a filter with a low frequency band in the range of 0.2 to 3 Hz, in which waves caused by respiratory movements are recorded with emphasis.
Record c represents a ballistocardiogram.

In the ballistocardiogram shown in Figure 3C, a certain level L is determined, and when the level falls below this level, a count is performed and the heart rate is measured, and when this count value falls below a predetermined value. The alarm device 26 can then be triggered.

FIG. 4 shows an electrocardiogram a obtained by an ECG device of the prior art and a recording b obtained from the same object measured by the device according to the invention.

In FIG. 5, several records generated by various movements of the patient P are reproduced. Record a represents a completely motionless state, and the periodic fluctuations seen in this record reflect the patient's heart rate and respiration. record
a ₁ is an enlarged view of record a.

Record b is a record made with the index finger. Record c is a record generated by wrist movement, record d is a record generated by ankle movement, e is a record generated by head movement, f is a record generated when the patient changes the direction of the body, and g is all records. , h is a record caused by shoulder movement, i is a record caused by knee movement, j is a record caused by muscle contraction, and k is a record caused by conversation.

[Brief explanation of the drawing]

FIG. 1 is a schematic elevational view of the device according to the invention, FIG.
The figure is a partially enlarged cross-sectional view taken along the line A-A in Figure 1, Figure 1B is a diagram showing capacitive coupling of the device of the present invention, and Figure 2 is a monitoring diagram to which the device of the present invention is applied. FIG. 3 is a block diagram of an example of a control system, in which record a shows the unfiltered signal recorded by the device of the invention, record b shows the signal caused by respiratory movements, and record c shows the cardiac signal. FIG. 4 shows a ballistic diagram, in which record a shows a record obtained by a conventional ECG device, record b shows a record obtained for the same object by the device according to the present invention, Figure 5 shows
FIG. 2 shows a recording diagram of 11 types of movements recorded by the device according to the present invention. 10a, 10b, 10c... bed, 11...
Recording pine tress, 12...Sensing electrode, 14...Insulated conductor wire, 17a, 17b, 17c...Amplifier, 1
9... Recording-monitoring device, 24... Signal processing circuit,
25... Monitor, 26... Alarm device, 28... Foamed plastic pine tress, 29... Active layer,
30...Shield, C...Capacitor.

Claims (1)

[Scope of Claims] 1. A device for monitoring epileptic seizures, tremors, breathing, heart movements, or other body movements of a test subject on a bed without directly attaching a detection means to the test subject, comprising: an active layer and a sensing electrode attached to the sensing electrode; an amplifier connected to the sensing electrode; a monitoring means connected to the amplifier; the active layer comprising at least two mutually contacting layers having different dielectric constants; When the contact surfaces between the two layer members move relative to each other due to the force applied to the active layer, the charge distribution on the contact surfaces changes. electrodes sensing the change in charge and transmitting an electrical signal to the amplifier, the transmitted signal being transmitted to monitoring means and converted into a visual, acoustic or mechanical signal; A device for monitoring the body movements of a subject on a bed, characterized by: 2. The device of claim 1, wherein the sensing electrode is placed under the mattress of the bed and consists of two mutually spaced electrically conductive members. 3. The device according to claim 2, wherein the electrically conductive member is a plate. 4. The device according to claim 2, wherein the conductive member is a net. 5. The device of claim 2, wherein the electrically conductive member is a rod. 6. The device according to claim 2, wherein the conductive member is a metallic film attached to both sides of the insulating layer. 7. The device of claim 2, wherein the active layer and sensing electrode are elastic and can be folded or rolled up. 8. The device of claim 1, wherein the active layer and sensing electrode are stacked one on top of the other to form a recording mattress. 9. A recording pintress is housed within a protective shield, the inner surface of the shield being made of an electrically insulating material and the outer surface being made of a conductive material, the protective shield being connected to a ground terminal of the amplifier. 9. A device according to claim 8, which is connected. 10 The active layer is composed of an elastic insulating layer member, the sensing electrode is composed of two conductive plates, and the active layer is between one plate of the sensing electrode and the protective shield. 10. The device according to claim 9, wherein the device is configured to constitute a capacitor. 11. Claim 1, characterized in that one layer member of the active layer is composed of a member having a large number of vesicles filled with air and in contact with the other layer member. The device according to item 1.