SU1697004A1 - Device for determining microorganism motility - Google Patents

Abstract

The invention relates to the field of medicine and biology and can be used by JHO to perform biomonitoring. The purpose of the invention is to improve the accuracy of environmental assessment by continuously determining the mobility of microorganisms in a pond. For what 1. The laser radiation 1 is introduced into the light guide 2, transmitted to the flow cell 6 and passed through the receiving optical system 3, is absorbed by the absorber 4. The radiation scattered by microorganisms is collected by the receiving optical system 3, forming a dark-field image of microorganisms in the plane of the receiving end of the light-guiding cable 5, the wires of which analogs of the diaphragms, providing for the transmission of each of them at the same time the image of no more than one microorganism. The photodetector 7 transforms the light pulses into electrical ones, which are amplified by the amplifier 8 and recorded over a specific time by the recording system 9, the number of pulses recorded by the recording system 9 over a certain time is proportional to the mobility of the microorganism suspension. 1 il. . -3 ± 4g SGR-r4: G U x - - - - -wellable XJ oo

Description

The invention relates to the field of medicine and biology and can be used for biomonitoring.

The purpose of the invention is to improve the accuracy of environmental assessment by continuously determining the mobility of microorganisms in natural conditions.

The drawing shows a block diagram of the device.

The device consists of a stationary part, placed outside the reservoir on the shore, and a remote sensor placed in the reservoir.

The device contains a radiation source 1, a light guide 2, a receiving optical system 3 with an absorber 4, a receiving light guide cable 5, a flow cell b, a photo receiver 7, an amplifier 8, a system 9 for recording pulses.

The device works as follows.

The laser radiation 1 is introduced into the light guide 2 and is transmitted to the flow cell 6 and, after passing through the receiving optical system 3, is absorbed by the absorber 4. The cell design ensures unimpeded passage of microorganisms into the measurement zone due to its own mobility and at the same time reduces the speed to zero. transfer of microorganisms through the flow of water. The radiation scattered by microorganisms is collected by the receiving optical system 3, forming a dark-field image of microorganisms in the plane of the end of the receiving light-guide cable 5, whose wires are analogous to the diaphragms ensuring the transmission of images of no more than one microorganism along each of them. This is achieved by the fact that the core diameter of the cable 5 is chosen equal to the increased characteristic size of the microorganism multiplied by the increase in the receiving optical system 3 in

the plane of the cable end 5. The conductors of the cable 5 are evenly spaced around a circle with a diameter equal to the diameter of the field of view of the receiving optical system 3 multiplied by its increase in the plane of the end of the cable 5, which provides averaging information about the mobility of microorganisms over the entire field of view. The photodetector 7 transforms the light pulses into electrical ones, which are amplified by the amplifier 8 and recorded during a certain time by the registration system 9, the Number of pulses recorded by the system of the relay for a certain time, is proportional to the mobility of the microorganisms. The pulse detection system 9 is a pulse counter controlled by a timer. The counter counts the number of pulses for a certain

preset time

Claims (1)

The formula invented and s-, a device for assessing the mobility of microorganisms containing the source probing radiation, working cell, receiving optical system, including a lens and an absorber located in the rear focus of the lens, as well as a photodetector, amplifier and pulse detection system, characterized in that, in order to improve the accuracy of environmental assessment due to continuous determination of the mobility of microorganisms in natural conditions, the working cell is made flow-through and connected to the source of probing radiation by a light guide, the output end of which is located in front of the lens of the receiving optical system at a distance of not less than the working distance of the receiving optical system; the photodetector is connected with the receiving optical system by a multicore light emitting diode cable, the input end of which is located behind the absorber.