RU2026031C1 - Method for electric effect on biological object in pressure chamber and device for its realization - Google Patents

Abstract

FIELD: medicine. SUBSTANCE: localization of zone of bioelectrode effect in which electrodes and pick-ups are located mounted on patient who is in oxygen pressure chamber. For this purpose zone of action and electrode location is covered by gas-proof envelope in which cavity a little gas volume is blown constant of gases entering in breathing mixtures with a little oxygen content or without it including, for instance, gas which patient breathes out. In consequence there is possibility to increase oxygen concentration in location zone of electrodes and electric elements up to fire safe level. Device is made in the form of tubular housing having front packing seal which enables to pass a little gas quantity. Housing cavity is coupled with gas source, for instance, made in the form bottle or mouthpiece for expiration. This guarantees constant inlet of fire safe gas in zone of electrode location. EFFECT: improved reliability. 8 cl, formulae, 4 dwg

Description

 The invention relates to medicine, and more specifically to means for recording biopotentials and bioelectrode effects on the human body in a pressure chamber with an oxygen atmosphere, mainly with high pressure.

 A number of methods and means are known to increase the safety of electrical measurements and impacts in pressure chambers with an oxygen atmosphere, most of which are reduced mainly to lowering electrical parameters to the minimum permissible limits, and according to the most explosion-proof version, the devices are placed in a separate airtight compartment filled with ordinary air (automatic St. and USSR patent N 293608, 331519, 1155245, CL A 61 G 10/02).

 A disadvantage of the known methods and means is the need for open application of electrodes under voltage in the oxygen atmosphere of the pressure chamber, for example, when applied to the patient’s body, and the impossibility of their complete sealing in connection with this.

 As a prototype of the proposed method can be considered, for example, conventional methods of recording and recording electroencephalograms, pulsograms, rhythmospirograms carried out in a pressure chamber and consisting in applying open electrodes to the patient’s body and applying electric voltage to them (ed. St. N 254026, class A 61 G 10/02, 1969).

 As a prototype of the device, a bioelectrode block can be considered, containing electroencephalograms with current-conducting wires located on the patient’s body and connected to the transducer, and fasteners (ed. St. N 254026, class A 61 G 10/02, 1969) .

 A common drawback of these methods and means is the lack of explosion safety in the conditions of pressure chambers with an oxygen atmosphere.

 The purpose of these inventions is to increase the explosion and fire safety in the conditions of pressure chambers with an oxygen atmosphere and, in addition, as applied to the device, to increase the ease of use.

 In the proposed method, this goal is achieved by the fact that when it is implemented, a gas-tight shell is arranged over the electrodes, overlapping the perimeter of the area of their location on the body and a constant flow of a gaseous medium depleted of oxygen from the composition of gases used for breathing mixtures is produced in the formed cavity, and the shell placed on the patient’s body with a gap to ensure the release of excess gas. The air exhaled by the patient can be used as the gas mixture supplied to the cavity.

 The proposed device for electrical action on a biological object in a pressure chamber further comprises a gas-tight casing, in the cavity of which a casing is mounted with a transducer and electrodes located on the side of the open end of the casing facing the patient, while the casing cavity is in communication with a supply of oxygen-depleted gas medium, and an elastic cuff is installed around the perimeter of the open end of the casing, which is installed with the possibility of ensuring the release of excess gas, a slot-shaped slot is made in the cuff and located along its perimeter from the side of the surface in contact with the patient’s body, and the casing is equipped with a connecting hose with a mouthpiece to allow the patient to exhale into the cavity of the casing or a cylinder with compressed gas fixed to the casing from the outside and communicated with its cavity through the throttle. In addition, it is provided that the gas medium supply source is located outside the pressure chamber and is connected to the casing cavity by means of a flexible hose hermetically passing through the pressure chamber body, while conducting elements are placed inside the hose with a gap, and an oxygen concentration measuring sensor is additionally installed in the casing cavity.

 Thus, the main features of the proposed method and device for electrically acting on a biological object is the formation of an unpressurized cavity covering the area of location of open electrodes that are energized, and due to the constant injection of oxygen-depleted gas into this region, an atmosphere different from the oxygen atmosphere of the pressure chamber is created in it.

 This allows you to avoid dangerous situations in the event of accidental electrical breakdowns and sparks in a pressure chamber, to expand the range of operating voltages, to simplify the design of electronic devices and contact tools. At the same time, a small amount of gas entering the casing does not change the atmospheric parameters in the pressure chamber, providing the usual conditions for conducting barotherapy sessions.

 Figure 1 shows a General view of one of the variants of the device for electrical impact on a biological object in a pressure chamber, cross section; in FIG. 2 is a view along arrow A in FIG. 1; figure 3 - the second and third variants of the device, a cross section; figure 4 is a fourth variant of the device, a cross section with a conditional image of the elements.

 The device for electrical action on a biological object is intended for installation in a pressure chamber (not shown) with an oxygen atmosphere at an excess compared to atmospheric pressure, which dramatically increases the risk of possible short circuits and discharges even of low-voltage equipment such as electrical sensors, electronic converters and other devices with open electrodes and contact elements. The considered variants of a device for electric exposure, for example, a rheograph sensor, an electrocardiograph, in general, contain a housing (base) 1 in which a transducer 2 is installed, for example, made in the form of a microcircuit or a simple voltage distributor for open electrodes 3 in contact with the patient’s body 4, as well as current-carrying leads 5 connected to a measuring or other device (not shown) with an electrical output. The device further comprises a gas-tight casing with a cavity 6, made, for example, with a rigid cover 7, to which the housing 1 of the transducer 2 is attached, and the tubular bellows shell 8 is made of plastic, on the opposite side facing the patient, the end of which has an elastic sleeve 9, for example, rubber. The device may be provided with fastening elements, for example, a fabric belt 10 (shown conditionally), covering the patient.

 To supply gas to the cavity 6 of the casing, it has an inlet pipe 11, which, for example, is connected to a gas source through a controlled gearbox (inductor) 12. In this case, various gas sources can be used, which determines the features of their connection. In the first embodiment (Fig. 1), an autonomous gas source is used, for example, in the form of a carbon dioxide cylinder 13 (for siphons), which is mounted on the cover 7 of the casing and is connected through an adjustable choke 12 to the inlet 14 with the inlet pipe 11, and the outlet 14 can be introduced into the cavity 6 of the casing and is close to the area of location of the electrodes 3. In addition to the natural minimum gaps between the sealing cuff 9 and the patient’s body 4, small through slotted channels 15 (slots) can be made in the sealing cuff for the excess gas and pressure equalization in the cavity 6 in the housing and a pressure chamber (Fig. 2). In another embodiment (FIG. 3), it is provided that air exhaled by the patient can be used as oxygen depleted gas, which is supplied through the mouthpiece 16 and the flexible hose 17 into the cavity 6 of the casing. In this case, the mouthpiece 16 may have a removable mouthpiece or connected to a breathing mask (not shown).

 In the third embodiment (FIG. 3), it is provided that a gas with a low oxygen content, for example ordinary air, is supplied from an external pressure chamber type compressor (not shown) through a hose 18.

 The hose 18 may include a pressure seal 19 installed in the pressure chamber wall 20. A feature of the hose 18 is the presence in it freely with a gap of the current-conducting conductors 5 (wires) located in it, hermetically removed from it outside the pressure chamber. At the same time, the presence of conductors 5 in the hose 18 should not impede the performance of its basic functions related to the supply of air to the electrodes 3, which is ensured by the gap size.

 To install the electrodes on the hands and feet of the patient, the casing can be formed by a tubular elastic sheath 8 with two end elastic cuffs 9 or made by the type of gloves (shown conditionally). Oxygen-depleted air or other gas is supplied into the casing similarly to other options through a flexible hose 21, and the electrodes 3 can be mounted on a bracelet 22 with a current lead 23 (such as a watch strap, Fig. 4).

 The device operates as follows.

 Before the start of the baroseance, the pressure chamber and the corresponding medical equipment are prepared for work. The patient is located on the moving platform of the pressure chamber and the corresponding bioelectrode blocks are installed and fixed on it: for example, an ECG sensor with open contact electrodes 3 connected to the main device outside the pressure chamber. So, in option 1, the electrode block with the housing 1, the shell 8, the cover 7, on which the can of gas 13 is fixed, is installed on the chest of the patient’s body 4, fixing it additionally with a belt 10. In this case, the electrodes 3 are in contact with the patient’s body 4 due to the mass of the block and the can 13, and also, due to the light pressure of the belt 10, for example, with elastic elements in it. The monitoring of the pressing of the electrodes can be done in hardware when setting up the device. The gaps between the cuff 9 and the patient’s body 3 are automatically formed due to microroughness and hairline, as well as due to the implementation of the channels 15 in the cuff 9. Immediately before the start of the session, the throttle 12 is opened and through the micro-hole in it the gas from the cylinder 13 starts with a minimum flow rate a certain size of the channel of the throttle 12 and the pressure in the can 13, enter the cavity 6 of the casing, creating a mixed medium in it and displacing the air previously in it through the channels 15. After turning on the throttle 12, the platform with the patient slide They’ll enter the pressure chamber and begin the session, supplying oxygen to it.

 During the entire session, the gas from the can 13 enters the cavity 6 of the casing maintaining its own atmosphere in it, different from the atmosphere in the pressure chamber and creating, as it were, an air cushion in it. As you work, the pressure in the can 13 drops and the flow rate decreases, which is associated with the total duration of operation of the electrode unit under voltage, which is determined in advance. Excess gas flowing through the channels 15 from the cavity 6 into the pressure chamber has practically no effect on its oxygen atmosphere due to the small volume of outflow, which is less than the total breathing volume of the patient. Thus, without affecting the overall atmosphere in the pressure chamber, it becomes possible to create your own atmosphere of air, carbon dioxide, nitrogen, and so on in the cavity 6 of the electrode 3. This eliminates the possibility of ignition in case of possible short circuits or sparks in the electrical circuits of the transducer 2 and electrodes 3 .

 In other embodiments (FIG. 3), gas is supplied to the cavity 6 of the casing from an external source or due to exhalation of the patient. And in these cases, the atmosphere of the gaseous medium in the cavity 6 is different from the oxygen atmosphere in the pressure chamber, which affects the safety of the placement of the electrodes 3. In this case, with the external gas source, the safety is increased with respect to the entire wired system, which is located in the supply hose gas is completely isolated from the surrounding oxygen environment. Such double insulation of flexible conductors eliminates the occurrence of a fire situation during kinks and other violations of their insulation.

 In the fourth embodiment, the casing is made in the form of a tubular shell or mitt, and the principle of its operation remains unchanged, the electrodes also turn out to be isolated from the surrounding oxygen medium in the pressure chamber.

Thus, the method implemented using the above device can be characterized by the following set of actions:
applying open electrodes to the body associated with an electrical device;
the location of the gas-tight casing with the output micro-holes between the patient’s body and the casing, inside of which the electrodes are located;
blowing gas into the cavity of the casing with a slight oxygen content not exceeding the composition of the normal air atmosphere;
regulation of the flow of injected gas, not exceeding the volume of respiration;
the ability to use for injection gas exhaled by the patient himself and depleted in oxygen.

 A characteristic feature of blowing is that the gas pressure in the cavity 6 of the casing is almost equal to the pressure in the pressure chamber, which is associated with the presence of channels 15, as well as the possible lifting of the shell 8 under the influence of internal pressure. The constant blowing is associated with maintaining a constant neutral atmosphere in the cavity 6 in the process of applying voltage to the electrodes 3.

 The restrictions associated with the volume of injection are determined by the fact that the composition of the atmosphere of the pressure chamber should not change compared to the usual mode and is limited by the maximum respiration parameters of the patient. It should also be noted that the introduction into cavity 6 of a gas depleted in oxygen in any case leads to a decrease in its concentration in comparison with the oxygen atmosphere of the pressure chamber.

 In conclusion, it should be noted the growing role of oxygen barotherapy for the treatment of a number of diseases and the need to comprehensively increase the safety of the use of electrical and electronic devices in pressure chambers with an oxygen atmosphere, to increase their safety.

Claims (9)

 METHOD OF ELECTRIC INFLUENCE ON A BIOLOGICAL OBJECT IN A BARCAMERA AND A DEVICE FOR ITS IMPLEMENTATION.  1. The method of electrical action on a biological object in a pressure chamber, which consists in fixing the electrodes on the patient’s body and supplying them with electrical voltage, characterized in that a gas-tight shell is placed over the electrodes, covering the perimeter of their location on the body, and a constant flow is made into the formed cavity a gas environment depleted of oxygen from the composition of the gases used for breathing mixtures, while the shell is placed on the patient’s body with a gap to ensure the release of excess gas .  2. The method according to claim 1, characterized in that the air exhaled by the patient is used as the gas mixture supplied to the cavity.  3. A device for electrical action on a biological object in a pressure chamber, containing electrodes with current-conducting wires located on the patient’s body and connected to the transducer, and fastening means, characterized in that it further comprises a gas-tight casing, in the cavity of which a housing with a transducer and electrodes is fixed, located on the side of the open end of the casing facing the patient, while the cavity of the casing is in communication with a source of supply of a gas medium depleted in oxygen, and around the perimeter An elastic cuff is located at the end of the casing, which is installed with the possibility of ensuring the exit of excess gas.  4. The device according to claim 3, characterized in that the cuff has slit-shaped slots located along its perimeter from the side of the surface in contact with the patient’s body.  5. The device according to claim 3, characterized in that the casing is equipped with a connecting hose with a mouthpiece to allow the patient to exhale into the cavity of the casing.  6. The device according to claim 3, characterized in that it is provided with a cylinder of compressed gas fixed to the casing from the outside and communicated with its cavity through the throttle.  7. The device according to claim 3, characterized in that the gas medium supply source is located outside the pressure chamber and is connected to the casing cavity by means of a flexible hose hermetically passing through the pressure chamber body, while conducting elements are placed inside the hose with a gap.  8. The device according to claim 3, characterized in that an oxygen concentration measuring sensor is additionally installed in the casing cavity.

Images