JPH05103765A - Hyperbaric oxygen therapy device - Google Patents

Abstract

PURPOSE:To enable blood pressure measurement by means of a pulse band outside a hyperbaric oxygen therapy device by providing a pressure setting valve of special constitution or the like on the device that feeds a pressure gas to a patient having cardiac infarction in a chamber. CONSTITUTION:A pulse band 3 is put on a patient A in a chamber 1 to which pressurizing gas G is fed by means of a pressure controller 2, and its rubber bag internal pressure is indicated by means of a pressure indicator 4 that is provided inside the chamber 1 and whose indication can be seen directly from the outside. When a pressure gas G is introduced from the gas inlet 7a of a pressure setting valve 7 and a setting spring 7b is push-pressed by operating a pressure operater, gas pressure which is from a gas outlet 7i and is the internal pressure of the chamber 1 adding setting pressure that is determined by push-pressing, is applied to the rubber bag. Accordingly, even though internal pressure is changed, the blood pressure of the patient A can be measured by confirming Korotkoff Sounds by means of the electronic sound or the like of a blood pressure reading timing detector 5 connected outside the device and the detecting portion 3b of the pulse band 3 and reading indication by means of the pressure indicator 4 at this time.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention accommodates a patient such as myocardial infarction in a hyperbaric treatment chamber and supplies oxygen or a pressurized gas from an air supply device to the chamber.
Regarding a device provided for treatment of the patient, in particular, during the treatment, a third party accurately measures the blood pressure of the patient outside, so that the treatment can be safely performed in a high-pressure environment. ..

[0002]

2. Description of the Related Art Only a patient is accommodated in a hyperbaric therapy apparatus for one person, and the measurer cannot enter the room. Therefore, the measurer outside the device measures the blood pressure of the patient. Is desirable for safety. However, since there is no suitable means for noninvasively (noninvasively) measuring the blood pressure (brachial artery pressure) of the patient in the device, the blood pressure of the patient is not generally measured in Japan.

In the United States, in order to measure such blood pressure,
In some cases, invasive blood measurement is performed by a direct method in which a catheter connected to a blood pressure transducer is inserted into a blood vessel to convert blood pressure into an electric signal and guide the electric signal to the outside of the chamber. However, such a blood pressure measuring means is not desirable in terms of influence on the patient and operability thereof.

However, when recent imported products are inspected, it is found that blood pressure can be measured by a non-invasive indirect method instead of the direct method. However, in this type, since the patient is beaten in the chamber and the gas pressure is sent to the rubber sac, the gas pressure and the inner pressure of the chamber are simultaneously applied to the patient. Although the blood pressure can be measured when the internal pressure is maintained at a constant pressure, in a hyperbaric oxygen therapy device, when the internal pressure is being increased or reduced, it becomes impossible to measure. There is a drawback that

In addition, in some of the indirect methods up to now, in order to reduce the pressure in the rubber sac in the beat band, the gas in the rubber sac is continuously discharged from the solid orifice. In this case, it is not possible to maintain the desired constant pressure during the descent, so that the reading of the pressure indicator must be taken instantaneously, and therefore requires skill.
Moreover, high precision measurement is not possible.

Further, even in the above indirect method, an air blower is used to pressurize the inside of the rubber sac, and at the time of exhausting, the exhaust valve attached to the blower is opened / closed and the opening degree is adjusted. There are known means for controlling the descending speed and maintaining a constant pressure, but even in this case, the operation is complicated and requires skill.

Here, in the above-mentioned imported products, a microphone is used as a known unit as a detection unit for detecting pulsating sound (Korotokov sound) of blood provided in the pulse band, and it is connected to the outside of the device by an earphone or the like connected thereto. Since the person who is measuring is listening to the Korotkoff sound, the detection of the reading timing of the sphygmomanometer is unclear, and the operation requires skill.

[0008]

In view of the above-mentioned problems of the prior art, the present invention provides a specially-configured pressure setting valve outside the chamber for hyperbaric oxygen therapy when measuring the patient blood pressure by the indirect method. The gas pressure adjusted by the operation is applied to the rubber bladders in the beat band, and thus the set pressure adjusted by the pressure setting valve is controlled based on the internal pressure of the chamber by superimposing on it. And then
Thus, the first object is to enable measurement of blood pressure even when the pressure inside the chamber is not kept constant and pressure changes due to depressurization.

Next, according to the present invention, when the pressure is reduced in the rubber sac of the beat band, the pressure reduction speed can be arbitrarily adjusted by the operation speed of the set actuator in the pressure setting valve. At the same time, by stopping the operation of the set actuator, the pressure at that time can be automatically maintained, and it is possible to easily and highly accurately read the instruction of the pressure indicator in the constant pressure state. In addition, the second purpose is to ensure the safety as long as the operation of the setting actuator is controlled without causing an unintended excessive pressurization. Is.

Also in the detection unit attached to the beat band, Korotkoff sound generated by blood circulation in the blood vessel is taken out as an electric signal, and the Korotkoff sound is generated by an electronic sound or the like by the blood pressure reading timing detection device outside the device. The third object is to make it possible to detect the blood pressure clearly and to enable correct blood pressure measurement without requiring skill.

Further, in the present invention, consideration is added to the pressure indicator for displaying the blood pressure. That is, if a general pressure gauge is used and it is installed outside the device, the indication will show the value of the blood pressure plus the internal pressure of the chamber, and measurement will not be possible, so try to avoid this. If so, it is possible to use a differential pressure gauge. However, in the case of the differential pressure gauge, although the differential pressure between the blood pressure and the internal pressure of the chamber, which is the environmental pressure, can be measured, the differential pressure gauge is not versatile and its structure is complicated and expensive.

Therefore, in the present invention, the pressure in the rubber sac of the beat band is visually observed from the outside of the device through the chamber by appropriately arranging the pressure indicator inside the chamber instead of performing the measurement outside the device. The fourth purpose is to enable the reading so that it can be clearly read from the outside of the apparatus even by using a general pressure gauge.

[0013]

In order to achieve the above-mentioned objects, the present invention enables a patient to enter and leave, and pressurized gas from an oxygen or air supply device is brought into a desired pressurized state by a pressure control device. A chamber for hyperbaric therapy, which is freely provided so that the heartbeat is wrapped around the patient in the chamber,
A pressure indicator which is connected to a rubber sac housed in a cloth band of the band by a communication pipe, and which is installed in the chamber so that the indicated value can be directly viewed from the outside, and is attached to the band as above. An electric signal due to the Korotkoff sound from the detection unit is inputted from the inside of the chamber to the outside by a lead wire, and a blood pressure reading timing detection device for displaying by electronic sound or the like, and pressurized gas from the oxygen or air supply device , Having a secondary side chamber that flows into the primary side chamber from the gas inlet and into which the pressurized gas flows by opening the movable valve, and communicates the gas outlet of the secondary side chamber with the rubber band of the beat band,
An airtight chamber adjacent to the secondary chamber via the diaphragm assembly is provided with a pressure setting valve communicating with the inside of the chamber and applying back gas pressure to the diaphragm assembly. By operating the actuator, in addition to the back gas pressure to the diaphragm assembly, a desired pressing force by the setting spring in the airtight chamber is applied so that it can be adjusted. By opening the movable valve so as to be freely movable back and forth, a gas pressure of a desired set value corresponding to the above-mentioned pressing pressure superimposed on the back gas pressure is applied from the secondary side chamber to the rubber band of the beat band. The present invention is intended to provide a hyperbaric oxygen therapy device characterized by the above.

[0014]

[Function] The patient enters the chamber for hyperbaric oxygen therapy,
Here, the attached beat band is wrapped around the upper arm, and pressurized gas is supplied from the oxygen or air supply device to the chamber by using a pressure control device to increase the internal pressure of the chamber to a required high atmospheric pressure. treat.

Therefore, when measuring the blood pressure of the patient, the pressurized gas from the oxygen or air supply device is
Supply from the gas inlet of the pressure setting valve to the primary side chamber. Then, while observing the indication value of the pressure indicator in the chamber, by operating the setting actuator of the pressure setting valve, the setting spring in the airtight chamber is pressed to push the diaphragm assembly toward the secondary chamber. .. Due to this pushing, the pressure in the rubber sac of the beat band communicating with the gas outlet of the secondary side chamber is gradually increased to about 160 to 200 mHg (slightly higher than the systolic (highest) blood pressure).

At this time, the internal pressure of the chamber is applied to the airtight chamber, and the internal pressure of the chamber is also applied to the secondary side chamber adjacently provided via the diaphragm assembly via the rubber band of the beat band. Since it is added, the pressure corresponding to the pressing force of the setting spring due to the operation of the setting operator is applied to the rubber bag, and the pressure is indicated to the pressure indicator. Therefore, even if the internal pressure of the chamber changes due to a decrease or increase in pressure during treatment,
The pressures of the airtight chamber and the secondary side chamber change at the same time, and even in such a case, the blood pressure can be measured by the pressure in the rubber sac.

Next, by gradually moving the above-mentioned setting actuator in reverse, the pressing force by the setting spring is weakened, the pressure inside the rubber sac decreases, and the Korotkoff sound is detected by the detector. Then, the blood pressure reading timing detection device displays an electronic sound or an LED blinks. At this time, the operation of the set actuator is once stopped to stop the decompression, and the instruction on the pressure indicator is given here. If read, the systolic blood pressure can be measured.

Further, the pressure of the rubber vesicle is gradually reduced again by the pressure setting valve, and when the electronic sounding due to the Korotkoff sound disappears, the pressure reduction is stopped and the pressure indicator at this time is displayed. The diastolic (minimum) blood pressure will be measured by reading the instructions given by the device.

[0019]

The present invention will be described in detail with reference to the illustrated embodiments.
As shown in FIG. 1, reference numeral 1 denotes a chamber of a known hyperbaric oxygen treatment apparatus which allows a patient A to come in and out and to see through the inside. The pressurized gas G from an oxygen or air supply device (not shown) can be adjusted to a desired pressure and supplied by the pressure control device 2 installed at 1. Here, reference numerals 2a and 2b respectively denote a feed pipe and a feed pipe for the pressurized gas G, and 2c and 2d denote a discharge pipe and a discharge pipe for releasing the internal pressure of the chamber 1 to the outside.

Next, in order to measure the blood pressure of the patient, a known beat band 3 (manchette) is provided in the chamber 1, and a rubber tube or the like communicating with a rubber sac (not shown) of the beat band 3 is provided. The connecting pipe 3a according to the above is also provided with a pressure indicator 4 (manometer) which is internally provided in the chamber 1, and is arranged so that the indication of the pressure indicator 4 can be seen directly from the outside of the device through the chamber 1. is there.

Here, in order to measure the brachial artery pressure of the patient A, the pulsating band 3 is to detect a Korotkoff sound, a cloth band that can be wound around the brachial region, a rubber band housed in the band. And a detection unit 3b capable of
As the pressure indicator 4 described above, a mercury type or an aneroid type may be used in order to measure the pressure in the rubber sac, but the aneroid type is preferable in consideration of contamination in the chamber 1, and in practice, By mounting the pressure indicator 4 near the pressure resistant window of the chamber 1 or inside the transparent pressure resistant wall, it is possible to read the instruction as described above.

Next, outside the device, a blood pressure reading timing detection device 5 is provided, and a lead wire 5a connected to this device is provided.
Is air-tightly penetrated through the chamber 1 and is connected to the above-described detection unit 3b of the beat band 3, whereby an electric signal from the detection unit 3b that detects the Korotkoff sound is input to the blood pressure reading timing detection device 5. Then, an electronic sound synchronized with the pulse is emitted, and an LED is blinked.

Here, it is preferable to use a piezoelectric element as the detecting section 3b, and one or both of the electronic sound and the light emission of the LED is displayed by increasing the width after removing noise by a noise filter. Therefore, it is desirable to use a dry battery (006P, 9V, one) as a power source so as to improve portability and electrical safety.

Further, a pressure setting valve 7 is provided outside the apparatus so that the pressurized gas G can be supplied from the inlet pipe 2b through the stop valve 6 to the gas inlet 7a by the branch pipe 2a '.
The pressure setting valve 7 will be described in detail later with reference to FIG. 2, but as schematically shown in FIG. 1, a closed chamber 7 having the setting spring 7b and the diaphragm assembly 7c is provided.
d is communicated with the chamber 1 by a back pressure pipe 7e.

Primary side chamber 7f communicating with the gas inlet 7a
The secondary side chamber 7g adjacent thereto can communicate with each other by opening the movable valve 7h that cooperates with the diaphragm assembly 7c, and the gas outlet 7i of the secondary side chamber 7g is
The pressurizing pipe 7j communicates with the rubber band of the beat band 3. In the figure, 8 is an emergency exhaust valve provided in the exhaust pipe 7j branched from the pressurizing pipe 7j, and 9 is a check valve provided in the chamber 1, which is also introduced into the pressurizing pipe 7j. They are connected by a pipe 9a, and 10 in the figure shows an internal pressure gauge of the chamber 1 attached to the back pressure pipe 7e.

The pressure setting valve 7 will now be described in detail with reference to FIG. 2, which has a structure similar to a general-purpose secondary pressure adjusting valve, but has a bonnet attached to a predetermined mounting point 11. The diaphragm assembly 7c is sandwiched between 7k and a lower body 7l,
The airtight chamber 7d is adjacent to the bonnet 7k side, and the primary side chamber 7f and the secondary side chamber 7g are adjacent to the body 7l side.

On the upper side of the airtight chamber 7d, a setting actuator 7m made of a knob is inserted through a O-ring 7n in a retaining state so as to be rotatable, and a push seat which is screwed to be vertically movable by the rotation. The above-mentioned setting spring 7b which can be pressed by the plate 7o is the diaphragm assembly 7 described above.
Since the back pressure pipe 7e is connected to the back pressure connection port 7p which is mounted on the c and is opened on the bonnet 7k and communicates with the airtight chamber 7d, the inner pressure of the chamber 1 is transferred to the airtight chamber 7d. It is applied as pressure.

A primary side chamber 7f communicating with the gas inlet 7a is provided on the left side in the figure on the side of the body 7l, and from the right side thereof to directly below the diaphragm assembly 7c via the communicating port 7q. The secondary chamber 7g has been provided, and further, the movable valve 7h is vertically installed so as to be movable up and down on the axis of the body 7l so as to be pushed down by pushing the diaphragm assembly 7c. ing.

This movable valve 7h has its valve seat 7
Since h'is separated and contacted downward from the valve opening 7r, the primary side chamber 7
When f and the secondary side chamber 7g are brought into communication with each other and the diaphragm assembly 7c moves upward, the movable valve 7h is also moved back by the valve spring 7s interposed at the lower end of the movable valve 7h. Valve seat 7 above
h'is configured to close the valve port 7r. In the figure, 7t and 7u are packings for the movable valve, and 7v is the movable valve 7.
The bearing vacant space 7w and the secondary side chamber 7 to enable the vertical movement of h.
It shows an air passage communicating with g.

Therefore, the stop valve 6 is normally closed, and when the blood pressure is to be measured, the stop valve 6 is opened to allow the pressure gas G to flow from the gas inlet 7a of the pressure setting valve 7 to the primary side chamber 7f.
Influx into. In the present invention, even if the rubber sac is pressurized by an air balloon or a pressure pump as in the blood pressure measurement under atmospheric pressure that is usually performed, the rubber sac inside the chamber 1 is applied from outside the device. As for the pressure, the pressurizing force becomes insufficient and it becomes unusable, while the pressurized gas from the oxygen or air supply device is supplied as described above.
A sufficient pressure can be applied.

Here, in the pressure setting valve 7 that receives the supply of the pressure gas G, the setting actuator 7m is fully loosened, that is, the setting spring 7b is in the free state, and the spring concerned. When the reaction force by 7b is zero, the internal pressure of the chamber 1 is the airtight chamber 7 of the pressure setting valve 7.
d acts as a back gas pressure, and as a result, the pressure of the secondary side chamber 7g is controlled to be equal to the internal pressure of the chamber 1.

From the above state, the setting spring 7b pushes down the diaphragm assembly 7c by further rotating the setting actuator 7n in the forward direction. As a result, the pressure in the secondary side chamber 7g becomes equal to that in the chamber 1. Based on the internal pressure, the set pressure determined by the pressing force of the setting spring 7b based on the operation of the setting operator 7n is superposed and controlled.
If the internal pressure of the chamber 1 fluctuates, the pressure of the secondary side chamber 7g will be synchronized with the fluctuation. In other words, it will be controlled by sliding to the internal pressure of the chamber 1.

In order to carry out the present invention, the exhaust throttle nozzle 7x is provided in the body 7l as shown in FIG. 2 so that the gas can always be discharged from the secondary side chamber 7g to the atmosphere. It is better to leave it.

That is, the exhaust throttle nozzle 7x is
By appropriately adjusting the throttle valve 7y and appropriately adjusting the amount of released gas, as is known, the movable valve 7h is in the fully closed state regardless of the presence or absence of the amount of gas used in the secondary chamber 7g. Therefore, the pressure adjustment is not ON-OFF control but continuous control. As a result, the pressure fluctuation in the secondary side chamber 7g is extremely small, and the response at the time of a sudden change in the used gas amount is good, and the movable valve 7h Even if the gas is suddenly used in the fully closed state, it is possible to prevent a large pressure drop due to the operation delay of the movable valve 7h, and also to reduce the set pressure, the pressure in the secondary side chamber 7g is reduced. Again, the desired automatic control is ensured in synchronism with the operation of the setting actuator 7m.

Therefore, in order to measure the blood pressure of the patient A by the indirect method while performing the treatment by the above-mentioned hyperbaric oxygen treatment device, the patient A puts the pulse band 3 in the chamber 1 and operates the pressure control device 2. Thus, the treatment is performed by increasing the internal pressure of the chamber 1 to the required pressure.

When measuring the blood pressure, the stop valve 6 is opened and the pressurized gas G is supplied to the pressure setting valve 7.
Setting actuator 7 while watching the instruction of pressure indicator 4 from the outside of
After positive rotation of m, the diaphragm assembly 7c is pressed by the setting spring 7b, whereby the positive rotation continues even after the primary side chamber 7f and the secondary side chamber 7g are communicated with each other, and the pressure of the secondary side chamber 7g is kept at a predetermined pressure. When the pressure is gradually increased to, the set pressure corresponding to the operation of the set actuator 7m is applied to the rubber sac of the beat zone 3 as described above, and the artery of the brachial region is compressed to stop the blood circulation.

Next, in the future, by gradually rotating the set actuator 7m in the reverse direction to decrease the pressure in the secondary side chamber 7g, the inside of the rubber sac is decompressed, and finally Korotkoff sound appears. The detection unit 3b detects this, and the blood pressure reading timing detection device 5 emits an electronic sound in synchronization with the pulse or blinks a light emitting diode to notify this, so that the measurer notifies the measurement operator 7m. The maximum blood pressure of the patient A can be measured by stopping the operation of 1 and reading the indication of the pressure indicator 4.

Next, the operation of the setting actuator 7m is restarted,
When the set pressure by the setting spring 7b is further lowered, the electronic sound due to the Korotkoff sound disappears. At this time, the depressurization is stopped, the instruction of the pressure indicator can be read, and the minimum blood pressure can be measured. Such a series of measurements will be repeated several times, but each time the measurement is completed, the setting actuator 7m is reversely rotated to release the pressing force of the setting spring 7b. , The residual pressure in the rubber sac will be released.

Even when the blood pressure measurement as described above is performed not only when the internal pressure in the chamber 1 is constant but also when the patient A is increased or decreased by the pressure control device 2, the internal pressure in the chamber 1 is changed as shown in FIG. When P ₁ changes, the pressure in the secondary chamber 7 g, that is, the pressure P ₂ in the rubber sac is controlled by being superposed on the internal pressure P ₁ , so that the correct blood pressure can be measured.

Here, the emergency exhaust valve 8 rapidly reduces the pressure in the rubber sac of the beat band 3 in preparation for an abnormal increase in pressure due to a failure of the pressure setting valve 7 or a sudden change in the condition of the patient A. It is preferable that the pressurizing pipe 7j can be opened to the atmosphere by a one-touch operation using a ball valve or the like, and the check valve 9 is provided with a rubber band of the beat band 3. The pressure inside the measuring circuit is
When a situation occurs such that the internal pressure falls below the internal pressure, the pressure indicator 4 and the like are provided to prevent the internal pressure from being destroyed by the internal pressure. The pressure gas in the chamber 1 will flow into the rubber sac.

[0041]

EFFECTS OF THE INVENTION Since the present invention is constructed as described above, the inside pressure of the chamber changes during the treatment by applying high pressure to the patient in the chamber for hyperbaric oxygen treatment. Even in the middle of the operation, the blood pressure measurement by the indirect method can be performed without any trouble due to the action of the pressure setting valve, which contributes greatly to the operability, optimization and safety of the treatment.

Further, since the pressure reducing speed can be freely adjusted by the operating speed of the set actuator in the pressure setting valve, and the pressure at that time can be held by stopping the operation, the value indicated by the pressure indicator is indicated. Can be easily and accurately read, and safety is ensured because more than necessary pressure is not applied to the patient, and the blood pressure reading timing detection device displays the Korotkoff sound such as electronic sound. Therefore, accurate blood pressure measurement without skill is possible.

In addition, the pressure indicator is in the chamber,
Since it is installed so that it can be read from outside the device, blood pressure can be measured without being damaged by high pressure in the chamber by using a general-purpose pressure indicator without using a differential pressure gauge. It will be possible.

[Brief description of drawings]

FIG. 1 is an explanatory diagram of a pipe configuration showing an embodiment of a hyperbaric oxygen therapy device according to the present invention.

FIG. 2 is an enlarged vertical sectional front view showing a pressure setting valve in the same apparatus of the present invention.

FIG. 3 is a graph showing the results of measuring the inner pressure of the rubber sac of the beat band used in the same apparatus by a pressure indicator, in which the change of the inner pressure with time is the inner pressure of the chamber and the pressure set by the pressure setting valve. 3 is a chart labeled as a superposition state of FIG.

[Explanation of symbols]

 1 chamber 2 pressure control device 3 beat band 3a communication pipe 3b detection unit 4 pressure indicator 5 blood pressure reading timing detection device 5a lead wire 7 pressure setting valve 7a gas inlet 7b setting spring 7c diaphragm assembly 7d airtight chamber 7f secondary chamber 7g secondary chamber Side chamber 7h Movable valve 7i Gas outlet 7m Setting operator A Patient G Pressurized gas

─────────────────────────────────────────────────── ─── Continuation of the front page (51) Int.Cl. ⁵ Identification code Internal reference number FI technical display location A61G 10/02 Z 7720-4C

Claims (1)

[Claims] 1. A hyperbaric treatment chamber which can be accessed by a patient and in which pressurized gas from an oxygen or air supply device is freely provided to a desired pressurized state by a pressure control device, and the chamber. The heartbeat band wrapped around the patient inside,
A pressure indicator which is connected to a rubber sac housed in a cloth band of the band by a communication pipe, and which is installed in the chamber so that the indicated value can be directly viewed from the outside, and is attached to the band as above. An electric signal due to the Korotkoff sound from the detection unit is inputted from the inside of the chamber to the outside by a lead wire, and a blood pressure reading timing detection device for displaying by electronic sound or the like, and pressurized gas from the oxygen or air supply device , Having a secondary side chamber that flows into the primary side chamber from the gas inlet and into which the pressurized gas flows by opening the movable valve, and communicates the gas outlet of the secondary side chamber with the rubber band of the beat band,
An airtight chamber adjacent to the secondary chamber via the diaphragm assembly is provided with a pressure setting valve communicating with the inside of the chamber and applying back gas pressure to the diaphragm assembly. By operating the actuator, in addition to the back gas pressure to the diaphragm assembly, a desired pressing force by the setting spring in the airtight chamber is applied so that it can be adjusted. By opening the movable valve so as to be freely movable back and forth, a gas pressure of a desired set value corresponding to the above-mentioned pressing pressure superimposed on the back gas pressure is applied from the secondary side chamber to the rubber band of the beat band. A hyperbaric oxygen therapy device characterized by the above.