RU178083U1 - DEVICE FOR RESEARCH OF THE PROCESS OF BIOFERMA - Google Patents

Abstract

The utility model relates to modern devices for studying biofilms, is intended for microscopic (visual) studies of the life cycle of biofilms formed by various communities of microorganisms on various materials and in different environments under the controlled influence of temperature, lighting, the speed of movement of the liquid medium, the composition of the gas phase. for studying the biofouling process, comprising a housing of a flowing biological cell with a recess, while the horizontal channels with screwed fittings, a cover with an opening corresponding to the shape of the recess is installed in the upper part of the housing, and a cover glass is installed between the case and the cover, while the device is sealed with an elastic seal, and a chamber is formed between the cover glass and the bottom of the housing recess, at the bottom of which is placed a plate of the test material located in a liquid flowing or stationary medium, while the device is installed between two containers connected by flexible tubes to pieces erami. Characterized in that the housing and the cover are made of a transparent polymer material. Characterized in that the clearance between the cover glass and the plate for applying the test material does not exceed 0.7 mm Characterized in that the channels for supplying and discharging a liquid medium are equipped with locking mechanisms. Characterized in that for a visual assessment of the process, it is not necessary to disassemble the cell and remove the plate of the test material, the coverslip.

Description

The utility model relates to modern instruments for studying biofilms, is intended for microscopic (visual) studies of the life cycle of biofilms formed by various communities of microorganisms on various materials and in different environments under the controlled influence of temperature, lighting, the speed of movement of the liquid medium, and the composition of the gas phase.

A device is known (RF Patent 2559546), which includes a container equipped with a spring-like device made of soft wire twisted in the form of 10 turns, at an angle of at least 10-12 ° to the vertical axis, with a diameter of 17 mm. The spring-like device has two shoulders with a length of 70 mm for placement inside the container and its removal from it, the device is configured to be installed between turns of coverslips with a size of 20 × 20 × 0.6 mm. The functions of the device are to create a biofilm on coverslips. The coverslips are placed between the turns of the spring-like device inside the container. The container is filled with experimental medium, a suspension of cholera vibrios is added to the container and incubated at a final concentration of cholera vibrios in n × 10 ⁸ CFU / ml with a minimum sensitivity threshold of 0.1 CFU / ml at room temperature.

The disadvantage of this analogue is the limited use of the device and the inability to use in relation to the flow circulation system, the inability to install coverslips in the duct.

The closest in technical essence and the achieved result is an invention that relates to medicine, in particular, to laboratory diagnostics. A device for studying biological material, comprising a body, a cover, a sealing washer and a porous gasket with a polymer membrane for applying the test material, the porous gasket being fixed between the body and the cover, and recesses are made in the body and in the cover, forming the volume in which the plate is placed, and a channel is made in the housing, communicating with the volume for supplying a liquid medium. The device allows to increase the accuracy of the study of biological material. A biological sample is collected, filtered, stained and microscopic of the obtained precipitate, and suspension is taken after the sampling, the filtering is carried out using a transparent polymer porous membrane, and the sediment is microscopied to its entire depth directly on the membrane. The described device for implementing the method (RF Patent 2213965) is taken as a prototype.

The disadvantage of the prototype is the inability to conduct microscopy in real time during various stages of growth and development of biofilms with the ability to assess the degree of biofouling, the need to disassemble the device for assessment, as well as the inability to observe the growth and development of biofouling in the absence of a duct and during the formation of biofouling on the surface of various materials.

The objective of the utility model is to create a device that allows you to study all phases of the biofouling life cycle (lag phase, stage of exponential growth, stabilization, dying off) formed on various materials, in the duct or in the absence of duct, in contact with a gaseous medium of various degrees of seeding in real time.

The stated technical problem is solved in a utility model that includes a flow cell made of a transparent material (plexiglass, polycarbonate) with a chamber inside, equipped with fittings, sealed with an elastic seal and a cover glass sealed with a transparent cover, while the plates of the studied material are placed on the bottom of the chamber located in a liquid flowing or stationary medium, which is placed in one of two vessels connected by flexible tubes to the fittings of the cell and alternately placed above and below below the cell fixing level to create a medium flow, or at the same level with the cell to stop the medium flowing through the working chamber of the cell. The cell can be connected to a flow system containing a container or pipeline with the medium to be studied, a tripod, a flow regulator, connecting tubes with clamps, a biological flow cell, and a receiving tank.

The technical result is to improve the quality and convenience of microbiological research by providing the possibility of visual examination of the life cycle of biofilms and the process of fouling by various communities of microorganisms on various materials in different environments without the need to disassemble the device under the conditions of controlled exposure to lighting temperature, speed of movement of the liquid medium, gas composition phase.

A device for studying the biofouling process is intended for microscopic (visual) studies of the life cycle of biofilms formed by various communities of microorganisms on various materials and in different environments under the conditions of controlled exposure to temperature, lighting, the speed of movement of the liquid medium, and the composition of the gas phase.

The utility model is illustrated in the drawing.

In FIG. 1 - flow biological cell (section), in FIG. 2 - flow biological cell (top view), in FIG. 3 is an example of connection.

The device includes a body of a flowing biological cell 1 made of transparent material (plexiglass) with a recess, while in the case there are horizontal channels 2 with screwed fittings 3, in the upper part of the case there is a cover 4 made of transparent material with an opening corresponding to the shape of the recess, a cover glass 5 is installed between the housing and the cover, while the device is sealed with an elastic seal 6, while a chamber is formed between the cover glass and the bottom of the recess of the housing, at the bottom of which the plate of the test material 7 located in a liquid flowing or stationary medium is placed, while the device is installed between two containers 8, 9 connected by flexible tubes with fittings 10, while the device is equipped with shut-off mechanisms (not shown in the figures) that regulate the flow through channels 2 .

The device consists of the following main parts: a tripod 11 for attaching the working (loading) 8 and receiving 9 containers and a device for studying the biofouling process (biological flow cell 12), connected with fittings 3. The upper working (loading) container filled with natural water or by artificial insemination by microflora, connected through a medical dropper with a polyvinyl chloride tube with a clamp (not shown in the figure) with a biological cell. The biological cell is a detachable case made of a transparent material (polymethylmethacrylate - PMMA), between the flanges of which there is a cylindrical hollow flow chamber equipped with fittings brought to the cell body. The diameter of the chamber is determined by the size of the coverslip sealed in its upper part by means of an elastic seal in the chamber body. The clearance between the coverslip and the plate of the test material at the bottom of the chamber does not exceed 0.7 mm. Thus, a flat cylindrical gap with transparent walls is formed between the bottom and the coverslip of the chamber, through which the test liquid flows, containing microorganisms that can form biofilms. The flow rate is set using a medical clamp on the supply tube with a dropper connecting the working (loading) tank located above the cell with a fitting on the cell body. Another fitting of the cell with the same tube with a dropper is connected to a receiving tank located at a level below the cell. When liquid flows from the upper tank to the lower, a slow-flow zone with good lighting is created in the cell, which creates favorable conditions for the growth and development of biofilms. At the end of the fluid flow from the upper (working or loading) tank to the lower (receiving) tank, they should be interchanged. Accordingly, the receiving capacity in the new cycle will receive the name of the working or loading, and the capacity, which will occupy the lowest position in the device, will receive the name of the receiving in the new cycle. It is possible to observe the life cycle of the origin and development of biofilms in real time using microscopes of various classes and types through the coverslip of the cell of a flowing biological cell. Studies can be carried out not only with a constant flow of fluid through the cell, but also in the absence of one, which allows you to observe changes in the structure of the biofilm associated with a lack of nutrients and oxygen. The device allows the study of biofilms formed by cultures artificially introduced into the aquatic environment without the risk of penetration into the system of microorganisms from the surrounding air. For such studies, it is necessary to use a set of tubes with droppers equipped with air filters. The presence of such filters does not allow microorganisms from the air to penetrate into the studied biofilm cultivation system. The device also allows you to study biofilms formed by microorganisms from the air in a certain room, for example, a hospital, a house, a barn, etc. For this kind of research, the device is placed in a room whose air environment needs to be investigated, the loading tank at the beginning of the research is filled with a sterile aqueous medium of a certain chemical composition, into which air enters during cycles of changing the position of containers through droppers, devoid of air filters. This device can easily be converted completely into a flow measuring system. To do this, instead of the loading capacity, the source of the aqueous medium can be the volume of process water or solution from which the aqueous medium can be supplied to the inlet fitting of the cell with a given speed using a peristaltic pump (not shown) for an arbitrarily long time interval.

Claims (2)

1. A device for studying the biofouling process, containing a flowing biological cell having a body with a recess and a cover, horizontal channels for supplying and discharging a liquid medium are made in the body, characterized in that the fittings are screwed into the channels for connection via flexible tubes with clamps of the flowing biological cell to the upper working and lower receiving tanks mounted on a tripod, while the flowing biological cell is placed on a tripod between the upper working and lower receiving tanks, the case and the covers flow biological cells are made of transparent polymeric material, a hole is made in the lid corresponding to the shape of the recess, a cover glass is sealed between the case and the cover by means of an elastic seal to form a chamber between the bottom of the recess and the cover glass of the chamber with the possibility of placing a plate of the material under study in the bottom of the chamber liquid medium, and so that the gap between the coverslip and the wafer does not exceed 0.7 mm. 2. A device for studying the biofouling process according to claim 1, characterized in that the channels for supplying and discharging a liquid medium can be equipped with locking mechanisms.

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