SU1454821A1 - Apparatus for simulating taxis - Google Patents

Abstract

The invention relates to medicine, in particular to teaching aids, in particular, medical and biological physics, and can be used, for example, to demilitarize taxis and active seizure during phagocytosis. The purpose of the invention is to enable the modeling of active seizure during phagocytosis. The device comprises a vessel 1 with a cap 2 with a thickness of 10-15 mm, in which a series of holes 3 are made. In the opening 3, tip 10 can be inserted with cancpei 11. With the aid of elastic sleeve 9, tip 10 is connected to the capacity of the syringe 7 with a screw piston feed. Vessel 1 is filled with a solution of sodium chloride, in which a vertical density gradient is created so that droplets of colored aniline 12 are set approximately in the middle of the height of vessel 1. Syringe 7 is filled with ethyl alcohol, and one hole is dropped into each hole of Kryshka 2. ball 5 with through holes 6. The specific gravity of the balls is less than the specific weight of the used salt solution, so they are on the surface. 1 il. o & (L

Description

The invention relates to medicine, namely to teaching aids, in particular in medicine and biology, and can be used, for example, g to demonstrate taxis and active capture during phagocytosis.

The purpose of the invention is the ability to simulate active capture in phagocytosis.

The drawing shows a diagram of the device.

A device for modeling a taxis contains a transparent vessel 1 with a lid 2, in which a row of from -15 versts is made 3. The vessel is filled with a liquid working medium 4, which is used as a solution of sodium chloride. In the holes 3 there are placed simulators of microbes in the form of balls 5 with through-holes 20 6. The device is equipped with an injection unit of a toxic substances simulator made in the form of a syringe 7 with a dispenser 8 connected to it by an elastic tube 9 with a tip-25 nickname 10 and a cannula 11 Aniline drops 12 imitating phagocytes are placed in a salt solution.

The device operates as follows. thirty

For the experiments, the vessel 1 is filled with a solution of sodium chloride, in which a vertical density gradient is created so that aniline drops 12 are set approximately - but at the middle of the height of the vessel 1. The upper level of the solution is brought to half the thickness of the lid 2. Into the syringe 7 gaining ethyl alcohol as well. in each hole of the cover 2 is lowered by. however, the same balls 5 with through holes 6, the diameter of which is larger than the diameter of the cannula 11. In this case, the balls 5 have a small positive buoyancy. The tip 10 is inserted into the opening of the lid 2 above one of the drops of aniline 12, having previously captured the ball 5 on the cannula 11. The latter is in a stable state. Set the distance between the ball 5 (simulator of the microbe) and a drop of aniline 12 (simulator of the phagocyte) about 5-10 mm. When the dispenser knob 8 is rotated one revolution, a stream of alcohol (a simulator of toxic substances released by a microbe) is fed into a solution of sodium chloride.

When alcohol reaches the corresponding drop of aniline, at the point of contact, their surface tension decreases. The surface layer in the rest of the drop of aniline, trying to reduce its surface, will squeeze the aniline out through the area with reduced surface tension. Thus, the drop grows towards the stream of alcohol, which 10 simulates the formation of pseudopodia, and contracts on the opposite side. As a result, a drop of aniline (phagocyte) moves (makes a taxis) in the direction of the ball (microbe), and reaching the last one, envelops it and carries out active capture. Then a drop of aniline again takes a spherical shape and falls, taking the ball inside. The separation of the droplet from the tip 10 is also facilitated by the fact that aniline poorly wetts metal surfaces.

Drop 12 returns to its original position, because ball 5, due to its small size, practically does not change the average density of aniline droplets, and therefore its place is equal to. location in solution.

Then, the tip 10 is transferred to the hole opposite the other drop of aniline, and the experiment is repeated.

When the alcohol stream is directed between closely spaced aniline drops, droplets (phagocytes) touched by a jet of alcohol attack the ball (microbe), capture it, merging simultaneously into one common drop, which to some extent models the death of phagocytes in the fight against microbes.

Claims (1)

Claim A device for modeling a taxis containing a transparent vessel with a liquid working medium in which phagocyte simulators are placed in the form of aniline drops, characterized in that, in order to enable simulation of active capture during phagocytosis, it is provided with a lid with holes for the vessel, simulators of microbes in in the form of balls with a through hole and toxic substances emitted by the microbe and the site of introduction of the simulator of toxic substances, made in the form of a ball with a dispenser connected to it by an elastic tube with the ability to move in the openings of the lid with a tip’s end cannula to be placed in the through hole of the ball, the ball being made of material c. specific gravity less than the specific gravity of a solution of salt.