RU76231U1 - SMALL MULTI-CHANNEL DEVICE FOR ULTRASONIC THERAPEUTIC TREATMENT OF POSTOPERATIVE CAVITIES - Google Patents

Abstract

The utility model relates to medicine, namely to ultrasound therapy and can be used in surgery for the rehabilitation of extensive postoperative cavities. A small-sized multi-channel device for ultrasonic therapeutic treatment of postoperative cavities is proposed, comprising n ultrasonic emitters suitable for placement in a human cavity and a control unit of a device having n outputs for connection with the aforementioned ultrasonic emitters, and made possible to generate ultrasonic signals with a frequency of 400-500 kHz, at Piezoceramic emitters made in the form of disks, metallized are used as ultrasonic emitters. Rowan plates are covered with a sealed, acoustically coherent layer. The control unit of the device is made with the possibility of its placement on the human body. The technical result is achieved due to more intensified drug and physical effects on tissues and cells of the internal vast postoperative human cavities by irradiating them with ultrasonic vibrations of different frequencies.

1 n.p. f.p.m .; 2 ill.

Description

The utility model relates to medicine, namely to ultrasound therapy and can be used in surgery for the rehabilitation of extensive postoperative cavities.

A device is known [RU 2248226 C2, 2005], containing an aspiration tube with side holes and, passing inside it, an irrigation tube. An irrigation tube is connected at the working end to a jet nozzle, which is a hollow collapsible cylinder with holes having an ultrasonic emitter inside with a conductor to an ultrasonic frequency generator. The emitter with a conductor is configured to introduce ultrasonic vibrations into the antiseptic solution.

The described device does not allow for scoring of the entire abdominal cavity and to produce a change in the generated ultrasound frequency in the region of natural resonant frequencies of piezoceramic emitters - which contributes to a more intense penetration of drugs.

A device for treating purulent abdominal wounds with ultrasound [RU 2003362 C1, 1993], comprising an ultrasonic oscillation generator and an emitter made in the form of a flexible module consisting of a set of ceramic washers placed in a polyamide tube. The device is selected as a prototype.

The above device does not allow wide simultaneous irradiation of several areas of extensive postoperative cavities, which limits the impact of ultrasound.

The objective of the utility model is to develop ultrasonic devices for the effective sounding by ultrasonic vibrations of extensive postoperative cavities for the required time, for example, the chest, abdominal cavity, and postoperative cavities of other localization.

Improving the therapeutic effect is achieved due to a more intensified medicinal and physical effect on tissues and cells of human internal cavities by irradiating them with ultrasonic vibrations of various frequencies.

The problem is achieved by the fact that a small multi-channel device for ultrasonic therapeutic treatment of postoperative cavities is proposed.

What is new is that it contains n ultrasonic emitters suitable for placement in a human cavity and a control unit of a device having n outputs for connecting to the aforementioned ultrasonic emitters.

In addition, piezoceramic emitters made in the form of disks, metallized plates of which are covered with a sealed, acoustically matched layer, are used as ultrasonic emitters.

In addition, the device control unit includes an ultrasonic signal carrier frequency generating unit and a carrier frequency scanning control unit, an ultrasonic signal power amplifier and a radiation power control unit, a power splitter having n output channels, a radiation indication unit having n input and n output channels, a battery-powered power supply, wherein the power supply is connected to a carrier frequency generating unit and a power amplifier, the output of the power amplifier is connected to an input branch la, and its n outputs connected to respective inputs of n emission display unit, which outputs are connected to respective n ultrasonic transducers.

In addition, the ultrasonic emitters are connected to the control unit of the device using a pair of long conductors located inside the silicone catheters electrically connecting the ultrasonic emitters with n output channels of the control unit of the device.

In addition, in addition, in the control unit of the device on its front panel there are: LED emitters showing the presence of ultrasonic radiation in each n channel, indicators of the radiation power level, power mode switch; and batteries inside the control unit housing.

In addition, the device may further comprise a charging unit for charging the batteries located in the control unit of the device, made in the form of a network adapter.

In addition, the control unit is arranged to be placed on the human body.

In addition, the control unit is configured to generate ultrasonic signals with a frequency of 400-500 kHz.

According to most authors, the main link in the complex treatment of acute diffuse peritonitis is the rehabilitation of the abdominal cavity. Various methods exist and are introduced into clinical practice, but even the most thorough intraoperative treatment does not allow to achieve complete sterility of the peritoneum [1, 2, 3, 6].

From the 60-70s of the 20th century, ultrasound began to be used to sanitize purulent-necrotic cavities [4, 5]. For the treatment of inflamed peritoneum and mechanical removal of necrotic masses, low-frequency ultrasound (26.5 kHz) and medium-frequency ultrasound (300 kHz) were used, scoring was performed in an antiseptic medium. Stationary devices were used to generate ultrasonic waves. The authors noted that as a result of the use of low- and mid-frequency ultrasound, a persistent bactericidal effect was noted. The negative points of the above mentioned scoring devices are the short duration of exposure, the presence of a bulky stationary generator with a power supply. Thus, despite attempts to use various stationary devices for ultrasonic sanitation of the abdominal cavity with diffuse purulent peritonitis, a number of questions remain open. To improve the technique, it is necessary to develop new methods and devices for voicing the abdominal cavity in the complex treatment of patients with peritonitis.

The invention provides a small-sized multi-channel device that allows continuous ultrasonic sanitation of extensive postoperative cavities through the use of the nth number of the same type of ultrasonic emitters located in different areas of the human cavity. In this case, ultrasonic emitters are suitable for placement for a long time in the human cavity. Piezoceramic ultrasonic emitters (UI1, UI2 .... UIn) have metallized plates covered with a sealed, acoustically matched layer. The plates are electrically connected by a pair of conductors located inside the silicone catheters with the electronic part of the control unit of the device. The control unit contains: LED emitters showing the presence of ultrasonic radiation in this channel; radiation power level indicator; power level switch. Charging the batteries located inside the control unit is carried out by the network remote charger adapter.

The invention is illustrated in graphic materials.

Figure 1 presents a block diagram of a stationary multi-channel device for ultrasonic sanitation of the internal cavities of the human body.

Figure 2 presents a schematic view of a stationary multi-channel device for ultrasonic sanitation of the internal cavities of the human body.

A small multi-channel device for ultrasonic therapeutic treatment of postoperative cavities (Fig. 1) consists of a control unit of device 1 and ultrasonic emitters 2 (UI1-UIn) made in the form of disks with a diameter of 20 mm and a thickness of 5 mm made of piezoelectric ceramics of the TsTBS-8 brand, which connected to the control unit using electrical conductors placed in a silicone catheter 3. The control unit 1 of the device contains a microprocessor unit for generating ultrasonic signals in the range of 400-500 kHz - the formation unit carrier frequency 4 (Fig.2.). Frequency tuning in this range is performed using the scanning control unit 5. The ultrasonic signals are amplified by a power amplifier 6. The radiation power is changed by the power control unit 7. The power splitter provides the distribution of ultrasonic signals to different piezoceramic emitters 8. The presence of ultrasonic radiation on each The MI provides an indication unit 9. The electronic part of the device is powered by a power supply 10 on the battery ba areyah AA capacity not less than 1500 mA / h. Periodic charging of the batteries provides a charger - AC adapter 11.

The device operates as follows.

Ultrasonic irradiation of human internal cavities in a wide area is carried out using ultrasonic emitters 2 (UI1-UIn) (figure 1), which are located evenly in problem areas where ultrasound therapy is required. The small size and weight of the control unit of the device 1 allows you to ensure its location on the human body fixing it with adhesive plaster. The flexible silicone catheters with conductors 3 are withdrawn from the abdominal cavity to the control unit of the device 1 through a drainage tube (not shown) inserted into the postoperative incision.

Before using the device, the batteries are charged in the power supply unit 10 (Fig. 1). Charging is carried out using a remote power adapter 11. The LED indicator in the power supply 10 indicates a full charge of the batteries. After turning on the device, the carrier frequency generating unit 4 generates ultrasonic signals with a frequency of 400-500 kHz. Frequency change in the specified range is controlled from the frequency scanning control unit

5. The control signals from block 5 provide a change in the carrier frequency from 400 kHz to 500 kHz with a period of change of 10 Hz. Changing the carrier frequency in the range from 400 to 500 kHz makes it possible to guarantee the formation of ultrasonic signals in the region of natural resonant frequencies of the piezoceramic emitters 2, on which the greatest return of ultrasonic radiation to the medium in which the piezoceramic emitters are located. The amplitude of the ultrasonic signals generated by block 4 is increased by a power amplifier 6. Using the radiation power control unit 7, a discrete change in the signal levels is supplied to the piezoceramic emitters 2. The power level is displayed on a 4-segment LED indicator, which is part of the control unit 7. The ultrasonic signal supplied from the power amplifier 6 is distributed by a power splitter 8 into n channels, depending on the number of piezoceramic used Sgiach emitters 2. As power splitter can use a high frequency transformer with n - the number of secondary windings. Indication of ultrasonic radiation carried out by piezoceramic emitters 2, is provided using the display unit 9 (figure 2), which includes LED indicators that are lit when there is current in the radiation circuit of ultrasonic signals in each of n channels. The connection of each n channel of the display unit 9 with the corresponding piezoceramic emitter UIn is carried out by two thin stranded conductors placed in a silicone catheter 3.

The effect of ultrasonic radiation of the proposed device with one ultrasonic emitter UI on the organs of the chest and abdominal cavity is investigated. The purpose of the study: to find out whether this device has any harmful effect on internal organs. The study was conducted on 20 white rats weighing 200-220 grams of a male. Under sterile conditions, under ether anesthesia, the animals underwent laparotomy. AI was placed in the free abdominal cavity, the wound of the anterior abdominal wall was sutured in layers. The MI was in the abdominal cavity from 1 day to 21 days. Animals were withdrawn from the experiment on days 1, 3, 5, 7, and 21 by decapitation. A morphological study of the lungs, liver, spleen, large and small intestines, and kidneys was performed. According to histology, on the 1st, 3rd, 5th, 7th and 21st days of the MI in the chest and abdominal cavity, pathological changes from the internal organs were not detected. Based on the research, we can conclude that the MD does not have a harmful effect.

The bactericidal activity of UI with respect to G + and G - microorganisms was determined. The study was carried out in vitro and was carried out on a microbial suspension with a concentration of 10 ⁵ , 10 ⁶ , 10 ⁷ , 10 ⁸ CFU / ml in physiological saline, because according to bacteriological culture of patients with purulent processes, these concentrations are most common. We studied those representatives of microflora that are most often found in patients with purulent processes of various localization. The following museum strains of microorganisms were exposed to UI: Staphylococcus aureus. Streptococcus, Escherichia coli, Pseudomonas aeruginosa, Klebsiella, Enterobacter, Enterococcus, Acinetobacter, C. Albicans. The exposure was carried out for 1 day, after which sowing on solid nutrient media was performed. The results were evaluated after 1 day compared with the control group. As a result of the study, it was revealed that under the influence of UI, no growth of colonies of the following bacteria was noted: Staphylococcus aureus, Streptococcus, Escherichia coli, Klebsiella, Enterobacter, Enterococcus, Acinetobacter, C. Albicans. At the same time, the control group showed abundant growth of colonies of microorganisms. Along with this, the absence of the effect of MI on Pseudomonas aeruginosa (Pseudomonas aeruginosa) was revealed. Its abundant growth was observed both in the control group and after exposure to MD.

Thus, we can conclude that the effectiveness of UI in relation to the following microorganisms: Staphylococcus aureus. Streptococcus, Escherichia coli, Klebsiella, Enterobacter, Enterococcus, Acinetobacter, C. Albicans at a concentration of 10 ⁵ , 10 ⁶ , 10 ⁷ , 10 ⁸ MT / ml and the safety of its use in patients.

Bibliography:

1. Andreichenko V.V. The role of aerobic and non-clostridial anaerobic microflora in the occurrence and development of purulent peritonitis // Surgery News.- 2001.- Volume 12. No. 2. -S.9-13.

2. Davydov Yu.A., Larichev A.B., Volkov A.V. General purulent peritonitis // Yaroslavl: Dia-press, 2000.- 120 p.

3. Efimenko N.A., Yakovlev S.V., A modern view of antibacterial therapy of intra-abdominal infections // CONSILIUM-MEDICUM. Volume 06 / N 1/2004 State Institute for Advanced Medical Studies of the Ministry of Defense of the Russian Federation, Moscow; Moscow Medical Academy I.M.Sechenova

4. Ismayilov A.A., Kuliev R.A. Treatment of purulent-septic diseases in children using ultrasonic cavitation // Bulletin of Surgery, 1984-No.10 P.96-98

5. Filippov S.I., Kozlov K.K., Kononov A.V. The use of low-frequency ultrasound with targeted gaseous agents in acute peritonitis widespread // Surgery, 2001-No.3 P.12-14

6. Dambaev G.Ts., Gunter V.E., Mezentsev G.D., Makhnev A.V., Soloviev M.M. The use of new technologies in the treatment of peritonitis // Tomsk: ed. TPU, 1998.192 p.

Claims (8)

1. A small multi-channel device for ultrasonic therapeutic treatment of postoperative cavities, characterized in that it contains n ultrasonic emitters suitable for placement in a human cavity and a control unit of a device having n outputs for connection with the aforementioned ultrasonic emitters. 2. The device according to claim 1, characterized in that the ultrasonic emitters used piezoceramic emitters made in the form of disks, metallized plates of which are covered with a sealed, acoustically agreed layer. 3. The device according to claim 1, characterized in that the control unit of the device comprises a carrier frequency generating unit for the ultrasonic signal and a carrier frequency scanning control unit, an ultrasonic signal power amplifier and a radiation power control unit, a power splitter having n output channels, a radiation indication unit having n input and n output channels, a battery-powered power supply, the power supply being connected to a carrier frequency generating unit and a power amplifier, an output of a power amplifier connected to the input of the splitter, the splitter and n outputs connected to respective inputs of n emission display unit, which outputs are connected to respective n ultrasonic transducers. 4. The device according to claim 1, or 2, or 3, characterized in that the ultrasonic emitters are connected to the control unit of the device using a pair of long conductors located inside the silicone catheters that electrically connect the ultrasonic emitters with n outputs of the control unit of the device. 5. The device according to claim 1, characterized in that in addition to the front panel of the device control unit are located: LED emitters showing the presence of ultrasonic radiation in each n channel, indicators of the radiation power level, power mode switch and batteries inside the control unit body. 6. The device according to claim 1, characterized in that the device may further comprise a charger for charging the batteries located in the control unit of the device, made in the form of a network adapter. 7. The device according to claim 1, characterized in that the control unit of the device is made with the possibility of its placement on the human body. 8. The device according to claim 1, characterized in that the control unit of the device is configured to generate ultrasonic signals with a frequency of 400-500 kHz.