RU2613787C1 - Device for small laboratory animals purposeful activity research - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: device for small laboratory animals purposeful activity research includes a labyrinth and a control computer. The research labyrinth is equipped with electrified conductive flooring and optical stimuli, and is made with the starting compartment, equipped with a hinged transparent door and radial compartments. Radial compartments are formed opposite to the starting compartment at equal angles to each other, providing visual perception of any of the available optical stimuli placed in radial compartments. The number of radial compartments exceeds two. The control computer is configured to randomly select one of the radial compartments and issue a command to switch it to an optical stimulus, as well as commands to supply current to the electrified floors in the remaining radial compartments and to unlock the transparent door of the starting compartment.

EFFECT: reduced time of a conditioned reflex to avoid the punishment of in case of the right action.

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Description

The invention relates to the field of biology and can be used to study the conditioned reflex activity of small laboratory animals.

A device for studying the higher nervous activity of animals is known, which is a camera made in the form of concentric inner and outer hollow cylinders connected by compartments with hinged doors and removable transparent partitions [USSR copyright certificate No. 1410942]. The inner cylinder has an electrode floor, and the outer one is equipped with light sources (incandescent lamps). The device operates as follows. In the training cycle, the animal moves freely from the inner cylinder to the outer cylinder through the compartments. If this does not happen, the biological object is exposed to electric current supplied to the electrode floor, which forces it to carry out the indicated movement, after which the animal is removed and placed in the inner cylinder.

In the study of higher nervous activity, light sources are used. After turning on all incandescent lamps, the time is fixed during which the animal reacts to this stimulus and makes an attempt to transfer from the inner cylinder.

Another variant of the device’s functioning is designed to study the animal’s ability to perform a task with a choice, namely, that the bioobject must open the door of that compartment, opposite which the light source is turned on.

The disadvantage of this device is that the laboratory animal is not able to see all the light sources at the same time, in particular those to which it is turned with its tail, which complicates the fulfillment of the conditioned reflex.

A device is known as a “shuttle chamber", designed to study in experimental animals the reaction of active avoidance [Zorina Z.A., Poletaeva I.I. Zoopsychology. Elementary thinking of animals: Textbook - M .: Aspect Press, 2007, p. 74]. The shuttle camera is a box divided by a partition into two compartments. The partition has an opening for moving the animal. Both compartments are equipped with conductive floors. In addition, the shuttle camera has a source of optical or acoustic radiation, which is used to supply a conditional signal to the experimental animal.

The bioobject is placed in one of the compartments. First, a conditional signal is turned on, after which a current is applied to the conductive floor in the compartment where the animal is located. To avoid pain, the biological object runs into another compartment. After a short period of time (as a rule, its duration varies, so as not to produce a conditioned reflex for the animal for a while), the current is turned on in the compartment where it had previously been run over. The conditioned reflex is considered to be fulfilled if the animal runs into the safe compartment during the action of the conditioned signal and before the current is turned on. The disadvantage of this method is that it provides for the training of bioobjects in bilateral avoidance in the absence of a permanent safe zone in the chamber, which leads to a significant rejection and lengthening of the training time. In addition, this method does not exclude the possibility of spontaneous movement of the animal through the chamber, since it can anticipate the appearance of a conditional signal and begin to move to the opposite compartment in order to avoid possible punishment in the form of an electric current.

A device is known for the development and study of conditioned reflexes in animals [USSR copyright certificate No. 1576163]. The device is a maze consisting of a central platform connected to compartments that are located in a horizontal plane at equal angles to each other. The compartments are equipped with incandescent lamps for visual irritation. At the top of the labyrinth there is a sound stimulus-speaker. In addition, the compartments and the central platform have a conductive floor. The device is equipped with a computer that controls the flow of stimuli, and also fixes the movements of the animal through the maze.

The test animal is placed in one of the compartments of the maze. A conditioned signal in the form of an optical stimulus is supplied to the compartment where the animal is not located. At the same time, a sound stimulus may be given. The animal must move into the lit compartment.

After that, the compartment where the animal has moved has become the "starting".

In the process of functioning of the device, a periodic supply of stimuli to various compartments is carried out at certain intervals of time. In this case, the conductive floor is used only in those compartments where incandescent lamps are not turned on. Using a computer fully automates the research process.

This device is selected as a prototype. Its main disadvantage is the difficulty in providing the same conditions for the experimental animals to fulfill the conditioned reflex with an increase in the number of compartments. Moreover, the most favorable conditions are realized when the number of compartments is 3 and they are connected to the central platform at an angle of 120 degrees to each other. Thus, the research labyrinth adopts a Y-shaped structure. However, such a structure of the labyrinth is limited only by two possible directions of motion of the experimental biological object. This suggests the possibility of its spontaneous movement through the maze.

If the number of compartments is 4, then the labyrinth acquires a cruciform structure (the angle between the compartments is 90 degrees). In this case, the test animal has the opportunity to perceive directly the optical stimulus itself only if the lamp is in the exact opposite compartment. Otherwise, being at the starting position, it will be able to observe only reflected light from the lamp in the area of the central platform. Then, to fulfill the conditioned reflex, the biological object will first need to move to the central platform and only after that determine the direction of further movement. As a result, the time required to complete the conditioned reflex will significantly increase for the test animals, and the tasks of moving to the opposite and to the side compartments will be unequal.

An increase in the number of research labyrinth compartments leads to a further complication of the perception of optical stimuli by a bioobject.

In addition, for any number of compartments, a biological object (for example, a laboratory rat) moves in the direction of the incandescent lamp head forward and in order to see an optical stimulus (or light from an optical stimulus) in another part of the labyrinth, it needs to rotate 180 degrees, which will also lead to a significant increase in the execution time of the conditioned reflex. As a result of this, with full automation of research, punishment of the animal by electric shock may occur even when it performs the correct action, which will contribute to the stress of the biological object and subsequent culling.

The task at hand is to develop a device that eliminates the lack of a prototype.

The technical result, the solution of which the invention is directed, is to develop a device that provides research on the targeted activity of a biological object and eliminates the disadvantages of the prototype.

The achievement of the technical result is ensured by the fact that in the known device for the development and study of conditioned reflexes in animals, containing a research labyrinth, equipped

electrically conductive floors and optical stimuli, and a control computer, according to the invention, the research labyrinth is made with a start compartment equipped with a hinged transparent door and radial compartments, while opposite the start compartment there are made radial compartments at equal angles to each other, providing visual perception to animals of any of available optical stimuli, and the number of radial compartments is more than two.

The device operates as follows. The investigated biological object (white laboratory rat) is placed in the starting compartment. A conditional signal for an experimental animal is the inclusion of an optical stimulus (lamp) in one of the radial compartments. At the same time, in other radial compartments, in addition to the compartment with an optical stimulus involved, current is supplied to electrified floors, realizing the principle “where there is light, there is no current”. If there is no reaction from the bioobject to the optical stimulus for a certain period of time, current is supplied to the electrified floor of the launch compartment, which forces the animal to leave it. After the biological object is moved to the “correct” radial compartment, the electrified floors in the installation are de-energized, and the experimental biological object is taken out of the radial compartment by the experimenter and moved to the starting compartment.

The lamp is turned on and current is supplied to the electrified floors in the radial compartments automatically using a computer, which eliminates any sequence of stimuli being fed into the radial compartments and allows introducing a heuristic component into the animal’s actions and minimizing the possibility of a spontaneous transition.

In support of the criterion of "industrial applicability" consider an example of a specific implementation of the device.

In FIG. 1 shows a device for studying the targeted activity of small laboratory animals.

In FIG. one:

1 - starting compartment;

2 - radial compartments;

3 - electrified conductive floor;

4 - optical stimuli (lamps);

5 - displacement sensors;

6 - articulated transparent door of the launch compartment;

7 - control computer.

In the initial state, the lamps in the radial compartments are extinguished, the electrified floors are de-energized, and the door of the start compartment is locked.

The cycle of the device is as follows. The studied biological object (a white laboratory rat) is placed in the starting compartment 1. The host computer 7 randomly selects one of the radial compartments 2 and gives a command to turn on the optical stimulus (lamp) 4 in it, in the remaining radial compartments to supply current to the electrified floors 3, as well as unlocking the transparent door of the starting compartment 6. In case of failure of the bioobject to leave the starting compartment after a certain period of time, the computer 7 gives a command to supply current to the electrically conductive floor of the starting compartment, which causes the animal to move into one of the radial compartments. The movement of the biological object from the starting compartment 1 to the radial compartment with the optical stimulus 4 turned on is detected by the sensors 5. After moving, the investigated biological object is removed by the experimenter from the radial compartment.

Next, the device is returned to its original state, after which the cycle of its operation is repeated.

Claims (1)

A device for researching the targeted activity of small laboratory animals, containing a research labyrinth, equipped with electrified conductive floors and optical stimuli and a control computer, characterized in that the research labyrinth is made with a launch compartment equipped with a hinged transparent door and radial compartments, while opposite the launch compartment radial compartments at equal angles to each other, providing visual perception of the abdomen any of the available optical stimuli located in the radial compartments, and the number of radial compartments is more than two, and the control computer is configured to randomly select one of the radial compartments and give a command to turn on the optical stimulus, as well as commands to supply current to electrified floors in the remaining radial compartments and to unlock the transparent door of the starting compartment.

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