SU888930A1 - Device for investigating biological particles in liquid volumes - Google Patents

Description

The invention relates to diagnostic devices, namely, devices for studying biological particles in microvolumes of a liquid, and can be used, for example, in forensic medicine to indicate immunological reactions during which a change in the average particle size occurs. The devices known in DP are for examining biological particles in a liquid, containing a source of coherent radiation, a focusing lens, a cuvette, receiving scattered radiation, and a processing unit 1. However, such devices require the use of significant volumes of the liquid under study and are not suitable for studying microvolumes. Closest to the invention is a PL device for examining biological particles in microvolumes of a liquid, containing a source of coherent radiation, a focusing lens, a cell made in the form of a capillary tube, a scattered radiation receiver and a processing unit, the optical axes of the lens and receiver radiation form a right angle r2}. However, a known device has a design complexity, difficult to operate, "associated with the use of two additional mirrors that require adjustment. The aim of the invention is to simplify the design and operation of the device. This goal is achieved by the fact that in a device for studying biological particles in microvolumes a liquid containing a source of coherent radiation, a focusing lens, a cuvette made in the type of a copying tube, a scattered radiation receiver, and a processing unit My utopian capillary tube is located at a right angle to the optical axis of the lens and obliquely to the optical axis of the scattered radiation receiver.

FIG. I schematically depicts an extension for studying biological particles in microvolumes of a liquid; in fig. 2 - the same, a view in the plan.

The device consists of a source of coherent radiation I, a focusing lens 2, a capillary tube 3, a scattered radiation receiver 4 and a processing unit 5. The capillary tube 3 is located perpendicular to the axis of the lens and tilted to the axis of the receiver 4. To fix the capillary tube; 3 obliquely relative to the axis of the receiver 4; the tube 3 is pressed against the inclined metal prism 6 by means of a rubber ring 7, ..

ycrpofiCTBO works as follows.

The test liquid is placed in the capillary tube 3 and the tube is placed in the inclined metal prism 6, where it is fixed by the ring 7, the beam from source I is focused by the lens 2 into the capillary tube 3. Since the capillary tube is perpendicular to the axis of the lens 2, the light is scattered its walls (parasitic light) co.ncentrate-. in the vicinity of the plane 8, a perpendicular capillary tube 3. The inclination of the latter relative to the axis of the receiver 4 of the scattered radiation prevents the penetration of parasitic light into it. The angle of inclination is not critical and is chosen from design considerations (in this case 45). The light scattered by biological particles hits the receiver 4, which, together with the processing unit 5, allows you to measure the intensity of the scattered light or its time correlation function and so

at the same time makes it possible to detect immunological reactions.

Considerable control over the design and operation of the device by eliminating additional elements that require adjustment, the ability to use capillary tubes manufactured by the industry, the simplicity of replacing them makes the device promising when conducting mass studies that provide an indication of immunological reactions in liquid volumes of about 10 µL or less. .

Claims (2)

1. Metrologists and measurement techniques 78 Catalog of exhibits at the exhibition M, VDNH 1978, p. 66 2. nd orobu mers 1975, v. 14, p. 419-430.