RU2734442C2 - Device for treating infected and purulent wounds - Google Patents

Abstract

FIELD: medical equipment.SUBSTANCE: invention refers to an apparatus for treating infected and purulent wounds. Device contains a housing, on the front side of which there is a touch screen, which is a control device of the device. Inside housing there is control board connected to instrument control device, diaphragm vacuum pump, configured to remove air and/or fluid from the wound and connected to a control board, a pressure sensor in the wound area and an electromagnetic valve configured to supply air into the wound region. Device comprises an accumulator connected to all power consuming elements of the device. Device is configured to perform three operating modes. In the first mode, the pressure sensor controls the negative pressure level and when pressure reaches 100 mm Hg generates signal to control board to disconnect pump. After that, pump is switched off, and pressure in drain tube drops, after reaching negative pressure below 10 mm Hg from preset pressure sensor generates signal to control board to switch on vacuum pump in order to repeatedly achieve specified level of negative pressure. At the first mode the cycle is repeated. In the second mode, the pressure sensor controls the level of negative pressure and when the specified upper level reaches 100 mm Hg generates signal to control board to disconnect pump. After that, the pump is switched off, and the pressure in the drainage drops. After reaching negative pressure below 10 mm Hg from preset pressure sensor generates signal to control board to switch on vacuum pump in order to repeatedly reach preset level. At that, the upper pressure cycle execution time counter is started. After time of upper level of negative pressure, signal is sent to control board and negative pressure in system is reset to atmospheric value. Then the cycle of the lower negative pressure level is started, the vacuum pump generates negative pressure to the upper level in the system, in parallel, the pressure sensor controls the level of negative pressure and when the specified lower level reaches 50 mm Hg generates signal to control board to disconnect pump. After that, the pump is switched off, and the pressure in the drainage drops. After reaching negative pressure below 10 mm Hg from preset pressure sensor generates signal to control board to switch on vacuum pump in order to repeatedly reach preset level, wherein the lower pressure cycle time counter is switched on. When the lower level of negative pressure expires, a signal is sent to the control board and negative pressure in the system is reset to atmospheric pressure. Cycle in second mode is repeated. At the third mode, the pressure sensor controls the level of negative pressure and when the preset level reaches 100 mm Hg generates signal, supplied to control board to disconnect pump. After that, the pump is switched off, and the pressure in the drainage drops. After reaching negative pressure below 10 mm Hg from a given pressure sensor transmits control signal to control board about necessity to switch on vacuum pump in order to repeatedly reach preset level, wherein the time counter is started. After time of negative pressure vacuum phase control signal is sent to control board and negative pressure in system is reset to atmospheric value, and starting the installation phase. Drug solution is delivered to the preset level; after that, the solution exposure phase is started when the therapeutic solution has a therapeutic effect on the wound. After that vacuum phase is repeatedly started, and cycle in the third mode is repeated.EFFECT: technical result is creation of automated device suitable for operation in three modes.1 cl

Description

The invention relates to the field of medical technology, namely, to devices for the treatment of purulent and necrotic wounds.

It is known (RU, patent 174957, publ. 11/13/2017) a device for vacuum drainage of wounds using alternating negative pressure, consisting of a covering material that covers the porous patch; The covering material contains a port, and the patch is connected by means of a vacuum wire to the container for collecting the wound discharge through the port, and the vacuum source is connected to the container by means of a vacuum wire, and the pad has a corrugated surface in its lower part.

The known device works as follows. To carry out vacuum drainage, a porous patch is installed in a pretreated wound in such a way that its corrugated surface is compressed during immersion, optimally adjusting to a specific wound defect. Then the wound is closed with a covering material, covering also intact skin areas, and the patch is connected to a container for collecting wound discharge, as well as to a vacuum source through a vacuum wire port. After which the operation proceeds to its further stage.

The disadvantages of the known device can be recognized as the impossibility of its automation, as well as the ability to work in only one mode.

It is also known (RU, patent 70627, publ. 02/10/2008) a device for vacuum therapy of purulent wounds, containing a fine-mesh porous material, a drainage system for wound discharge, an insulating film and a vacuum source, and depending on the parameters of the wound, a fine-mesh porous material with a thickness of 5 to 50 mm, the shape and dimensions of which are modeled individually according to the size of the wound, its walls and bottom.

The device works as follows. After applying a dressing to the wound, the drainage system is connected to a vacuum source. In the cavity of the container for the exudate separated from the wound, a vacuum is created. The resulting vacuum spreads to the wound area, as a result of which the exudate from the wound cavity begins to be sucked out through the foam sponge, perforations in the drainage tubes and directly drainage tubes into the container 3 for wound discharge exudate.

The disadvantages of the known device can be recognized as the impossibility of its automation, as well as the ability to work in only one mode.

It is also known (RU, patent 70132, publ. 20.01.2008) a vacuum aspirator containing two sealed vessels, which are interconnected by means of a tube, one of which is located above the other and connected to a sealed container for collecting exudate by means of a sealed tube, and hermetically the fixed tube is connected to both sealed vessels through a tee-adapter, while the device additionally contains paired infusion tubes, which are equipped with clamps, and paired plastic infusion needles, which are equipped with air valves.

The known device works as follows. Before starting work, the connecting needle of the vacuum of the aspirator is connected to a sealed container for collecting exudate, after which the vacuum aspirator is set in the working position so that the container with the liquid is at the top. Next, the lower air valve of the infusion needle is opened, after which the upper clamp is loosened or completely opened, setting the required aspiration force. In this case, the liquid from the upper vessel begins to drop by drops into the lower one. In the absence of fluid flow into the lower vessel, the system is started by opening the upper air valve of the infusion needle for a second. If the system begins to lack air for the liquid to flow from the upper vessel to the lower one (it happens when the wound or cavity is completely tight, combined with long-term operation of the vacuum of the aspirator), the vacuum is reduced by loosening the lower clamp. After the upper vessel is completely free of fluid (after 30-120 minutes, depending on the volume of the vessels and the area of drainage), it is necessary to tighten both clamps, close the lower air valve of the infusion needle and turn the system over. Further, all actions to start the operation of the aspirator are repeated again. The vacuum aspirator can be installed on a flat surface next to the patient's bed, as well as suspended from the bed. The principle of operation of the vacuum aspirator is based on active vacuum suction of exudate from closed wounds and cavities by creating a vacuum in a sealed system for collecting exudate through its connection with the vacuum space of one of the vessels of the vacuum aspirator, which is formed due to a drop in the liquid level and an increase in the useful volume.

The disadvantages of the known device can be recognized as the impossibility of its automation, as well as the ability to work in only one mode.

The specified source of information is accepted as the closest analogue.

The technical problem solved by the development of the claimed device is to improve the instruments for vacuum therapy.

The technical result obtained by implementing the developed device consists in creating an automated device suitable for operation in three modes.

To achieve the specified technical result, it is proposed to use the developed device for the treatment of infected and purulent wounds. It contains a housing, on the front side of which a touch screen is located, which is a control device for the device, inside the housing there are a control board connected to the device control means, a diaphragm vacuum pump configured to remove air and / or liquid from the wound and connected to the control board , a pressure sensor in the wound area, and an electromagnetic valve configured to supply air to the wound area, as well as a battery connected to all power-consuming elements of the device

In some embodiments, the device may further comprise a peristaltic pump, the inlet of which is connected to a container for a medicinal solution, and the outlet is configured to deliver a medicinal solution to the wound area.

The developed device works as follows. Three work algorithms are possible.

1. Continuous mode (just negative pressure) creates a drain when the system is connected to the instrument.

Using the touch screen, set the level of negative pressure, the intensity of the rise of negative pressure and other settings. Then turn on the device by pressing the "start" button on the screen. After that, the control signal goes to the control board, and turns on the vacuum pump, which generates negative pressure (vacuum) in the system. In parallel, the pressure sensor monitors the level of negative pressure and, when a predetermined level is reached (for example, 100 mm Hg), generates a signal to the control board about the need to turn off the pump. After that, the pump is turned off, and the pressure in the drain (system) gradually decreases, after reaching a negative pressure below 10 mm Hg. from the set pressure, the sensor generates a signal to the control board about the need to turn on the vacuum pump in order to re-reach the set level of negative pressure. The cycle is repeated many times.

2. Variable mode (in the process of its implementation, the upper pressure and lower pressure are set, the alternate action of which stimulates granulation). When implementing this mode, a drain is created connected to the device. The upper level and then the lower level of negative pressure, the cycle time of the upper pressure, the cycle time of the lower pressure, the intensity of the negative pressure rise and other settings are set via the touch screen. Then turn on the device by pressing the "start" button on the screen. After that, the control signal goes to the control board, and turns on the vacuum pump, which generates negative pressure to the upper level in the system. In parallel, the pressure sensor monitors the level of negative pressure and, upon reaching a preset upper level (for example, 100 mm Hg), generates a signal to the control board about the need to turn off the pump. After that, the pump is turned off, and the pressure in the drain (system) gradually decreases, after reaching a negative pressure below 10 mm Hg. from the set pressure, the sensor generates a signal to the control board about the need to turn on the vacuum pump in order to re-reach the set level. This starts the time counter for the upper pressure cycle. When the time of the upper level of negative pressure has expired, a signal is sent to the control board and the negative pressure in the system is reset to atmospheric. The negative pressure low cycle is then started. The vacuum pump generates negative pressure up to the upper level in the system. In parallel, the pressure sensor monitors the level of negative pressure and, upon reaching a predetermined lower level (for example, 50 mm Hg), generates a signal to the control board about the need to turn off the pump. After that, the pump is turned off, and the pressure in the drain (system) gradually decreases, after reaching a negative pressure below 10 mm Hg. from the set pressure, the sensor generates a signal to the control board about the need to turn on the vacuum pump in order to re-reach the set level. At the same time, the time counter of the lower pressure cycle is turned on. When the time of the lower level of negative pressure expires, a signal is sent to the control board and the negative pressure in the system is reset to atmospheric. The cycle is repeated many times.

3. Installation mode (vacuum cycle, solution supply, solution exposure time). Using the touch screen, the level of negative pressure and the operating time of the vacuum mode, the intensity of the negative pressure rise and other settings are set. After that, there is a transition to the stage of supplying the solution and setting the parameters of the installation mode, while also choosing the volume of the supplied liquid and the exposure time of the solution (the third phase of the cycle). In this case, the device control program provides the ability to use the "filling assistant" function, for this you need to press the appropriate button and conduct the first visually controlled solution delivery, after which the operator fixes the volume of the solution in the wound, this volume is automatically saved in the settings. The device is started by pressing the "start" button on the screen. After that, the signal goes to the control board, and starts the vacuum pump, which generates negative pressure in the system. In parallel, the pressure sensor monitors the level of negative pressure and, upon reaching a predetermined level (for example, 100 mm Hg), generates a signal to the control board about the need to turn off the pump. After that, the pump is turned off, and the pressure in the drain (system) gradually decreases, after reaching a negative pressure below 10 mm Hg. from the set pressure, the sensor gives a control signal to the control board about the need to turn on the vacuum pump in order to re-reach the set level. This starts the time counter. After the time of the vacuum phase of negative pressure has expired, a control signal is sent to the control board and the negative pressure in the system is reset to atmospheric. And the installation phase starts, the medicinal solution is supplied to a predetermined level, after which the solution exposure phase starts, when the medicinal solution has a therapeutic effect on the wound. Then the vacuum phase is restarted, and the cycle is repeated many times.

All these operations are performed automatically according to the signals generated by the control board.

Claims (2)

1. A device for the treatment of infected and purulent wounds, characterized by the fact that it contains a body on the front side of which there is a touch screen, which is a control device for the device, inside the body there are a control board connected to the device control means, a diaphragm vacuum pump made with the ability to remove air and / or fluid from the wound and connected to the control board, a pressure sensor in the wound area and an electromagnetic valve configured to supply air to the wound area, as well as a battery connected to all power-consuming elements of the device, while the device is configured performing three modes of operation, in the first mode the pressure sensor monitors the level of negative pressure and when the pressure reaches 100 mm Hg. Art. generates a signal to the control board about the need to turn off the pump, after which the pump turns off, and the pressure in the drain drops, after reaching a negative pressure below 10 mm Hg. Art. from the set pressure, the sensor generates a signal to the control board about the need to turn on the vacuum pump in order to re-reach the set level of negative pressure, while in the first mode the cycle is repeated; in the second mode, the pressure sensor monitors the level of negative pressure, and upon reaching the set upper level of 100 mm Hg. Art. generates a signal to the control board about the need to turn off the pump, after which the pump turns off, and the pressure in the drain drops, after reaching a negative pressure below 10 mm Hg. Art. From the set pressure, the sensor generates a signal to the control board about the need to turn on the vacuum pump in order to re-reach the set level, while the time counter for the upper pressure cycle starts, after the time of the upper level of negative pressure, a signal is sent to the control board and the negative pressure in the system is reset to atmospheric, then the cycle of the lower level of negative pressure starts, the vacuum pump generates negative pressure to the upper level in the system, in parallel, the pressure sensor monitors the level of negative pressure and upon reaching the preset lower level of 50 mm Hg. Art. generates a signal to the control board about the need to turn off the pump, after which the pump turns off, and the pressure in the drain drops, after reaching a negative pressure below 10 mm Hg. Art. from the set pressure, the sensor generates a signal to the control board about the need to turn on the vacuum pump in order to re-reach the set level, while the time counter of the lower pressure cycle is turned on, after the time of the lower level of negative pressure expires, a signal is sent to the control board and the negative pressure in the system is reset to atmospheric, while the cycle in the second mode is repeated; in the third mode, the pressure sensor monitors the level of negative pressure and upon reaching the set level of 100 mm Hg. Art. generates a signal to the control board about the need to turn off the pump, after which the pump turns off, and the pressure in the drain drops, after reaching a negative pressure below 10 mm Hg. Art. from the set pressure, the sensor gives a control signal to the control board about the need to turn on the vacuum pump in order to re-reach the set level, while the time counter is started, after the vacuum phase of negative pressure expires, a control signal is sent to the control board and the negative pressure in the system is reset to atmospheric, and the installation phase starts, the medicinal solution is supplied to a predetermined level, after which the exposure phase of the solution starts, when the medicinal solution has a therapeutic effect on the wound, after which the vacuum phase is restarted, and the cycle in the third mode is repeated. 2. The device according to claim. 1, characterized in that it further comprises a peristaltic pump, the inlet of which is connected to the container for the medicinal solution, and the outlet is configured to supply the medicinal solution to the wound area.