RU178264U1 - DEVICE FOR CARRYING OUT ANESTHESIOLOGICAL ASSISTANCE TO SMALL LABORATORY ANIMALS - Google Patents

Abstract

The utility model relates to experimental medicine and veterinary medicine, and can be used for anesthesia in small laboratory animals during various experiments. An anesthesia device for small laboratory animals, including an electric motor connected to a mechanical drive installed to apply pressure to the respiratory bag, and inspiratory and expiratory contours for supplying the flow of the respiratory mixture to the laboratory animal and removing expired air from it, while the inspiration circuit There is a module for inhalation anesthesia connected through a safety valve with a breathing bag, and an endotracheal tube for introducing a small laboratory animal into the trachea, the exhalation circuit through the tee is connected to the endotracheal tube, and the electric motor is frequency adjustable to control the frequency of pressure on the respiratory bag.

Description

Device for conducting anesthesia for small laboratory animals

The utility model relates to experimental medicine and veterinary medicine; it can be used for anesthesia in small laboratory animals during various experiments.

In practice, it is widely known that anesthesia is performed on an animal (rat) by direct contact of a cotton-gauze swab soaked in a volatile anesthetic with the animal's face.

It is also known a device containing a housing for an inhalation anesthetic, while the base of the mask is equipped with a handle for its installation in its original position, which also allows you to easily move the mask to a certain distance from the head of the experimental animal (rat) in case of weakened breathing and adjust the concentration of the inhaled anesthetic during respirable mixture. The mask body is made of a metal frame covered with a transparent material for visual observation of the test animal, for example, polyethylene [10].

The disadvantages of this method are the high consumption of anesthetic substance, difficulties in changing the depth of inhalation anesthesia and the inability to perform forced ventilation with complete muscle relaxation in these experimental animals.

The closest model is a device consisting of an inlet tube, a clip-clamp and a needle. The device additionally contains a narcotic mask of a cylindrical shape made of a transparent material, and its diameter should be at least 14 mm and a depth of at least 40 mm [5].

The task that the device we are representing is aimed at is the creation of an anesthesia device, simple in design, for inhalation anesthesia in small laboratory animals in the mode of mechanical controlled ventilation of the lungs through an endotracheal tube, similar in principle to mechanical ventilation devices in humans.

The problem is solved by creating the following utility model. A self-expanding breathing bag (Pylon type) (1) with a safety valve (2) operating at a peak pressure of 30 cm of water is fixed on a rigid base. Art. A piston (7) is in direct contact with it, periodically exerting pressure on it under the action of an electric motor (6) operating with a clearly defined pressure frequency. This frequency has the ability to be adjusted by turning the knob on the motor housing. AnaConDa module for inhalation anesthesia is attached to the respiratory bag (5), which works on the principle of continuous administration of anesthetic (isoflurane, sevoflurane) to a special evaporation membrane through a syringe dispenser at a given speed, which can be changed to achieve different levels of anesthesia.

The AnaConDa inhalation anesthesia module is a standard module for use for sedation of patients with gaseous anesthetics isoflurane and single-use sevoflurane, as it contains a certified membrane device for vaporizing only these gaseous anesthetics with a certain boiling point and initially in a sealed vial in a liquid state. Using this module with other gaseous anesthetics is not recommended by the manufacturer, as it can lead to unpredictable effects.

дюйма требуемой длины (3). Выдох осуществляется пассивно через контур выдоха, отходящий от интубационной трубки и контура вдоха через тройник.This device is connected to an endotracheal tube (4) located in the larynx of a laboratory animal through a PVC pipe with a diameter

inches of required length (3). The exhalation is carried out passively through the exhalation circuit extending from the endotracheal tube and the inspiratory circuit through the tee.

The length of the exhalation circuit may vary depending on the conditions and rate of administration of the anesthetic. Experimentally, a correspondence was drawn between the rate of supply of the anesthetic to the anesthesia module with various depths of anesthesia depending on the weight and type of animal.

When used on small laboratory animals, indoor pollution with gaseous anesthesia products is minimal and does not affect the experimenter. If necessary, it is possible to extend the exhalation circuit to a distance beyond the laboratory limit or to connect active aspiration with minimal discharge to eliminate gaseous anesthesia products.

The figure 1 shows a diagram of a device.

The device contains an electric motor with a mechanical drive (6), a standard breathing bag (1) with a safety valve (2), a module for inhalation anesthesia (5).

The inventive model works as follows. An electric motor (6) with a frequency set by the experimenter activates a mechanical drive (7) that exerts an adjustable pressure on the breathing bag (1). At the same time, air flows through the safety valve (2) to the AnaConDa module (5), where it is enriched with a gaseous anesthetic and enters the inspiration circuit and then through the endotracheal tube (4) to the laboratory animal. Exhalation occurs passively when the air sac relaxes through the exhalation circuit (3). The safety valve of the breathing bag prevents excessive over-inflation of the lungs of the animal. Regulation of tidal volume occurs by changing the length of the mechanical drive. Changing the respiratory rate is done by changing the frequency of rotation of the electric motor (7).

The proposed utility model was tested on 10 white mongrel male rats. An anesthetic benefit of sevoflurane was given. Introductory anesthesia was performed with sevoflurane by inhalation anesthesia. The duration of anesthesia is from 2 to 4 minutes. Due to the characteristics of the drug, tracheal intubation should not exceed more than 1-1.5 minutes, after which the animal wakes up in connection with the characteristics of the inhaled anesthetic.

The duration of anesthesia with sevoflurane through an endotracheal tube ranged from 2 to 2.5 hours. The anesthesia stage throughout was surgical, supported with the AnaConDa module. During anesthesia, the saturation of the animal was monitored, which remained all the time in the range from 92 to 99%. After the anesthetic was turned off, the time to restore spontaneous breathing and restore consciousness was from 4 to 6 minutes. All animals were successfully extubated without any negative consequences. In the long term, no negative consequences were also identified.

Literature:

1. Li J. Protective effects of sevoflurane in hepatic ischemia-reperfusion injury / Li J [and etc.] // Int J Immunopathol Pharmacol //. - 2016; 29 (2) .e doi: 10.1177 / 0394632016638346. Epub 2016 Mar 10.

2. Kellner P. Protective effects of sevoflurane in hepatic ischemia-reperfusion injury. Sevoflurane Abolishes Oxygenation Impairment in a Long-Term Rat Model of Acute Lung Injury / Kellner P [and etc.] // Anesth. Analg. - 2017. - p. 124 (1).

3. Romero A. Effects of sevoflurane on ventilator induced lung injury in a healthy lung experimental model / Romero A [and etc.] // Rev Esp Anestesiol Reanim. - 2016 .-- 63 (l). - p. 22-8. doi: 10.1016 / j.redar.2015.04.04.006. English, Spanish: 194-203.

4. Breuer T. Sevoflurane exposure prevents diaphragmatic oxidative stress during mechanical ventilation but reduces force and affects protein metabolism even during spontaneous breathing in a rat model // Anesth. Analg. - 2015.-121 (1). - p. 73-80. doi: 10.1213 / ANE.0000000000000736

5. Device for inhalation anesthesia of small laboratory animals / T.V. Pavlova [and others] // RF patent for the invention №103726.

6. Device for fixing laboratory animals in the experiment / N.A. Brusnetsov, T.N. Brusnetsova // RF patent for the invention No. 2284167.

7. Device for fixing small laboratory animals / T.U. Gafarov [et al.] // RF patent for the invention No. 2461368.

8. A device for injecting small experimental animals into anesthesia / M.Yu. Shigaev [et al.] // RF patent for invention No. 39274.

9. Zapadnyuk I.P. Laboratory animals. Dilution, maintenance, use in the experiment // Zapadnyuk I.P., Zapadnyuk V.I., Zakharia E.I. Vol. 2. - Kiev: "Vishka school." - 1974. - 304 p.

10. Tumanov mask for inhalation anesthesia in small experimental animals / E.V. Tumanov // application for a utility model of the Russian Federation No. 24097, IPC: A61M 15/00.

Claims (1)

A device for carrying out anesthesia for small laboratory animals, including an electric motor connected to a mechanical drive that is able to exert pressure on the breathing bag, and inspiratory and expiratory contours for supplying a respiratory mixture flow to the laboratory animal and exhausting exhaled air from it, while the inspiration circuit includes a module for inhalation anesthesia, connected through a safety valve with a breathing bag, and an endotracheal tube for introducing a small laboratory into the trachea ornogo animal exhalation circuit through the tee is connected to the endotracheal tube, and an electric motor configured to adjust the frequency to provide frequency regulation of exerting pressure on the breathing bag.

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