PL73614Y1 - Stand for separating tumour cells - Google Patents

Abstract

A station for separating cancer cells, characterized in that it comprises an incubator (1) having a chamber in which a screening device (2) is placed, slidably mounted on a base (2g), in the ceiling part of the incubator (1) there is a passage opening (1a) located in the axis of symmetry of the screening device (2), where a plug (1b) with two holes (1c) is slidably fitted into the passage opening (1a), through which two conduits (1d) are supplied to the screening device (2) through its cover with holes (2h), which are connected to a supply pump (3), which is a double-syringe infusion pump.

Description

Description of the design The subject of the design is a stand for separating cancer cells. The design belongs to the field of mechanical engineering and biomedical engineering. The design solves a technical problem of separating cancer cells. There is a known Polish utility design W27436, which is a screening device for detecting and isolating circulating cancer cells. The design includes a flooding container and a precipitation container and pressure pumps. The lower part of the flooding container and the upper part of the precipitation container are connected to each other by a threaded sleeve of the flooding container and a threaded sleeve of the precipitation container, which contains a molecular sieve located between the lower part of the flooding container and the upper part of the precipitation container. The pressure pump of the flooding container is connected to the flooding container by means of a pressure pipe. The pressure line is connected to the upper part of the flood tank by means of a flood tank cap connector placed in the upper cover screwed onto the upper part of the flood tank with an intermediary element in the form of a sealing washer. The pressure pump of the flood tank is connected to the precipitation tank by means of a pressure line. The pressure line is connected to the precipitation tank by means of a cap connector of the precipitation tank. A method for collecting cells is known from the European patent application specification A2. The solution has two filters in the form of grids with rectangular mesh geometry. A method and devices for microfiltration and cell separation are known from the American patent application specification US 2009/0188864 A1. This solution is also based on meshes with a honeycomb structure with holes. A difficulty in making microfilters is their technologically complicated production process. The aim of the model is to develop a new design solution enabling the separation of cancer cells, especially circulating cancer cells. In the solution according to the model, the heater maintains a constant set sieving temperature, a sieving column with a microsieve is placed in the heater chamber and a pump is connected to unclog the flow in the event of the microsieve being blocked. The model also includes a two-syringe infusion pump, which is used to feed the sieved portion of blood to the sieving columns using flexible tubes. Two syringes are mounted on the pump, one for blood, the other for diluting the blood with a physiological fluid. In the case of using a solution for isolating cancer cells, screening and isolating cancer cells can be carried out using a combined microsieve consisting of three individual microsieves (there may be three with identical or different openings, e.g. 12, 8 and 5 µm). Isolation on a combined microsieve is more effective in terms of screening efficiency and can reach 98%. The essence of the model is a station for separating cancer cells containing a heater with a chamber in which a screening device is placed, mounted slidably on a base, in the ceiling part of the heater there is a through hole located in the axis of symmetry of the screening device, where a plug with two holes is slidably fitted into the through hole, through which two cables are led to the screening device through its cover with holes, which are connected to the supply pump, which is a two-syringe infusion pump. The screening device consists of a cylindrical flooding container and a cylindrical precipitation container placed under it, where between the containers a grid with micro-sieves is mechanically attached to both containers. The screening device is equipped with a hand pump connected from the side to the precipitation tank by means of a pressure pipe, which is connected to the precipitation tank by means of a tank coupling. The lower part of the flood tank and the upper part of the precipitation tank are connected to each other by means of a threaded sleeve of the flood tank and a threaded sleeve of the precipitation tank. This sleeve contains grates inside, where directly on each of them a micro-sieve is placed, screwed in in such a way that they are located between the lower part of the flood tank and the upper part of the precipitation tank. The station for separation of biological particles is shown in Fig. 1, which shows a side cross-sectional view of the station. The station for separation of biological particles in a preferred embodiment comprises a screening device (2) consisting of a flooding container (2a) of cylindrical shape and internal diameter of 19 mm with a capacity of 30 ml, made of polyoxymethylene, and a precipitation container (2b) of cylindrical shape and internal diameter of 20 mm with a capacity of 60 ml, made of polyoxymethylene, placed underneath, wherein a grid (2c) with three micro-sieves (2d) is mechanically attached between the containers (2a and 2b) by means of a threaded connection to both containers. The holes in the meshes of each micro-sieve (2d) have a diameter of 8 µm with a spacing of 50 µm. The total sieve surface is 226.8 mm 2 , the surface of the flow meshes is 4.1 mm 2 , the number of meshes is 80,000. The screening device (2) is equipped with a hand pump (2e) connected from the side to the precipitation tank (2b) by means of a pressure pipe (2f) made of a flexible hose. The pressure pipe (2f) is connected to the precipitation tank (2b) by means of a coupling connector of the precipitation tank. The lower part of the flood tank (2a) and the upper part of the precipitation tank (2b) are connected to each other by means of threaded connections through sleeves. This sleeve contains three grates (2c) inside, where directly on each of them a micro-sieve (2d) is placed, positioned in such a way that they are located between the lower part of the flood tank (2a) and the upper part of the precipitation tank (2b). In addition, the station contains an incubator (1) with a maximum heating temperature of 50°C with forced air circulation. The incubator has a chamber with a capacity of 75 l. A screening device (2) with a pressure pipe (2f) led to the upper part of the precipitation tank (2b) is placed in the chamber. The screening device (2) is slidably mounted on a base (2g). In the ceiling part of the incubator (1) there is a through hole (1a) with a diameter of 30 mm located in the axis of symmetry of the containers (2a and 2b), where a plug (1b) with two holes (1c) with a diameter of 8 mm each is slidably fitted into the through hole (1a). Two lines (1d) made of transparent flexible material are led through the holes (1c) to the screening device (1) through its cover with holes (2h), which are connected to the supply pump (3), which is a two-syringe infusion pump. Each of the syringes has a capacity of 20 ml. One of the syringes is intended for biological particles and the other for physiological fluid. PL PL PL PL PL PL

Claims (1)

Protective disclaimer 1. A station for separating cancer cells, characterized in that it comprises an incubator (1) having a chamber in which a screening device (2) is placed, slidably mounted on a base (2g), in the ceiling part of the incubator (1) there is a passage opening (1a) located in the axis of symmetry of the screening device (2), where a plug (1b) with two holes (1c) is slidably fitted into the passage opening (1a), through which two lines (1d) are supplied to the screening device (2) through its cover with holes (2h), which are connected to a supply pump (3), which is a two-syringe infusion pump, furthermore the screening device (2) consists of a flooding tank (2a) of cylindrical shape and a precipitation tank (2b) of cylindrical shape placed underneath it, cylindrical shape, where at least one grate (2c) with micro-screens (2d) is mechanically attached to both of the screens between the containers (2a and 2b), the screening device (2) is equipped with a hand pump (2e) connected from the side to the precipitation tank (2b) by means of a pressure pipe (2f), which is connected to the precipitation tank (2b) by means of a coupling connector of the precipitation tank, the lower part of the flood tank (2a) and the upper part of the precipitation tank (2b) are connected to each other by means of a threaded sleeve of the flood tank (2a) and a threaded sleeve of the precipitation tank (2b), this sleeve contains grates (2c) inside, where a micro-screen (2d) is placed directly on each of them, screwed in such a way in such a way that they are located between the lower part of the flood tank (2a) and the upper part of the precipitation tank (2b). Figure