RU195366U1 - A device for the isolation of stromal-vascular fraction cells from adipose tissue for their subsequent use in regenerative medicine - Google Patents

Abstract

The proposed device relates to devices for cell technology and is intended for the purification and processing of adipose tissue with subsequent isolation of stromal-vascular fraction cells (UHF) from it for use in regenerative medicine. The technical result of the utility model is high-quality cleaning and processing of adipose tissue in a closed system with subsequent isolation of cells of the stromal-vascular fraction of adipose tissue, and SVFzht is characterized by a high yield of regenerative cells, as well as the absence of of fat cells and stroma. The technical task is achieved through the use of a device consisting of 2 main containers and a 1000 ml drain container, connected via a “lock-lock” port with a trunk system, characterized in that the first 500 ml container is designed for washing adipose tissue from blood and oil shaped elements, the second 500 ml container is designed for enzymatic treatment of adipose tissue, and the fermentation container narrows down and goes into the highway with built-in ltrami, at the end of which there is a Luer port.

Description

The proposed device relates to medicine and biotechnology, namely to regenerative medicine and cell technology, and can be used for cleaning and treating adipose tissue obtained during the adipose tissue collection procedure, for further use of stromal-vascular fraction cells extracted from it in the restoration of damaged organs and tissues.

Adipose tissue in the human body is a type of connective tissue. The basis of its structure is fat cells (adipocytes). Adipocytes are located between the collagen, elastin, reticular fibers, blood capillaries, nerve fibers and other cells that perform protective and regenerative functions. All adipose tissue cells except adipocytes are united by the common name stromal-vascular fraction.

The stromal-vascular fraction (SVF) is a multicomponent cell product where one of the dominant and best-studied cell populations is MMSC [Zuk P.A., Zhu M., Ashjian P. Human adipose tissue is a source of multipotent stem cells. Mol Biol Cell. 2002; 13: 4279-4295]. SVF refers to cell products that do not require cultivation, that is, the collection of biological material, its processing, obtaining SVF and its clinical use are possible within the framework of a single surgical intervention.

The selection of SVF from adipose tissue is carried out in several stages: washing the adipose tissue, its fermentation, filtration and centrifugation. All these stages are performed sequentially and require the presence of work skills and the utmost care of the performer.

There is a method of treating adipose tissue with cells, where stem cells are extracted from adipose tissue using the manual method (Bansal, N.N. et al. Intra-articular injection in the knee of adipose derived stromal cells (stromal vascular fraction) and platelet rich plasma for osteoarthritis. J Transl Med. 2017. Jun 19, 15 (1): 141). This method is based on the enzymatic treatment of 100 ml of adipose tissue, taken by syringe tumecent liposuction, and the enzymatic treatment is carried out with a collagenase solution during incubation on a shaker for 30 minutes at a temperature of 37 ° C, followed by washing, filtration through pores of 100 μm and centrifugation. The disadvantages of this method are the presence of the "human factor", high time and material costs, the risk of impaired sterility and contamination of the biomaterial.

A device for washing adipose tissue is also known (Mestak O et al. Centrifugation versus PureGraft for fatgrafting to the breast after breast-conserving therapy. World J Surg Oncol. 2014 Jun 5; 12: 178. Doi: 10.1186 / 1477-7819-12- 178), which is a closed system for washing adipose tissue obtained as a result of liposuction. The system is a PureGraft bag of various volumes for washing up grease, a Waste Bag for collecting waste materials with a capacity of 1.5 l with connecting tubes, and additional consumables (set of supply tubes with a cannula Syringe adapter with Luer tip, adapter for Toomey syringe). The PureGraft bag consists of two chambers separated by a filter plate. In the process of washing adipose tissue, blood, oil and destroyed cells go into the Waste Bag for waste collection, and the washed adipose tissue remains in the PureGraft bag, which is then used to isolate stem cells or for use in plastic surgery. The device allows to obtain the most purified adipose tissue in a closed system, however, the further isolation of the stromal-vascular fraction occurs manually, as described previously.

The closest in technical essence to the proposed device is a device for fractionation of adipose tissue and isolation of stromal-vascular fraction from it for use in regenerative medicine (RU 173796 U1), which is a closed sealed system in the form of a transparent cone-shaped container with a lid of 300-500 ml , with an external volume calibration and a system of internal parietal canals, the container being separated by at least one strainer adjacent flush to the interface measures, and two chambers - a working chamber for processing tissue with a parabolic bottom without sharp corners in the working space and a chamber for concentrating cells, and the chamber for concentrating cells has a volume of 3-9 ml, has a keeled shape, is located at an angle of 10-45 degrees and extended along the entire length of the device. The device also has a bacteriological filter for balancing the pressure inside the system, and the bacteriological filter is located on the cover of the device. The disadvantages of this system are the presence between the chambers of only a strainer capable of passing cells into both the lower and upper chambers, which can lead to a large loss of cells as a result of their extraction. Also, when using the device during the fermentation procedure with stirring in the thermal shaker, contamination of the bacteriological filter and its clogging may occur, which will lead to an increase in pressure inside the device and disrupt its operation. In addition, this device requires a certain centrifuge suitable for a given capacity.

The technical result of the utility model is high-quality cleaning and processing of adipose tissue with the subsequent isolation of cells of the stromal-vascular fraction of adipose tissue, and HFVT is characterized by a high yield of regenerative cells, the absence of residues of adipose cells and stroma, as well as the safety and technological availability of the adipose tissue processing process.

The specified technical result is achieved through the use of a device consisting of 2 main containers and a discharge container with a volume of 1000 ml, connected via a “Luik-Lok” port with a trunk system, the first container with a volume of 500 ml intended for washing adipose tissue from shaped elements blood and oil, the second container with a volume of 500 ml is designed for enzymatic processing of adipose tissue, and the container for fermentation narrows down and goes to the highway with built-in filters, at the end of which you find tsu luer port.

The proposed device is a closed system consisting of three containers connected in series with the help of highways.

The first polymer container with rounded corners with a volume of 500 ml with an external calibration in volume is designed to wash fatty tissue from blood and oil. The container consists of two chambers - front and rear, separated by a filter mesh with a pore size of 200 microns. The container has 2 luer ports from the front and rear cameras, respectively. One port is for connecting with a discharge bag, the other is for introducing biomaterial, introducing a washing solution and moving the biomaterial into a bag for fermentation.

The second polymer container with a volume of 500 ml with applied external calibration by volume is designed for enzymatic processing of washed adipose tissue coming from the first container through the system of lines, the container for fermentation tapers down and goes into the line with built-in filters of 500 and 100 microns, at the end of which luer port is located.

The third container is designed for waste collection and is a 1000 ml polymer container connected to the first container via an integrated line.

The device has at least 5 Luer-Lock ports for connection to a trunk system or Luer syringes.

Thus, adipose tissue placed in the first container is washed from oil and blood cells, then in the second container it undergoes a fermentation process, as a result of which stromal-vascular fraction cells are released from the adipose tissue. As a result of the settling of the contents of the container after the fermentation process, the adipose tissue cells are concentrated below the narrowing of the container, while the adipose tissue remains on the surface. Further along the cell line, passing through filters of 500 and 100 microns in size for their additional purification, they are taken into a syringe for further use as intended. This mechanism of operation of the device allows to increase the efficiency of isolation of the stromal-vascular fraction without cell loss, while maintaining the simplicity and safety of work.

In FIG. 1 shows a general view of a device for cleaning and treating adipose tissue with subsequent isolation of stromal-vascular fraction cells (SVF) from it.

The essence of the utility model is illustrated by drawings, where in FIG. 1 shows a device for cleaning and treating adipose tissue with subsequent isolation of stromal-vascular fraction cells (SVF) from it, consisting of 2 main containers (1, 7) and a 1000 ml drain container (4) connected using hatch-lock ”(2, 3, 6, 8) by a system of highways (5), the first container (1) with a volume of 500 ml intended for washing adipose tissue from blood and oil, the second container with a volume of 500 ml (7) is intended for enzymatic treatment adipose tissue, and the container for fermentation tapers down and goes to the master al with built in filters of 500 (9), 100 (10) microns, which is at the end luer port (11).

An example of the method

The operation of the device is a phased process of processing adipose tissue, the output of which is a cellular product.

Adipose tissue is introduced into the container for washing (1) through the port (3). Through the same port (3), a solution for washing the tissue is introduced. Draining takes place through port (2) to the drain container (4). Then, after the washing step, the washed adipose tissue passes into the fermentation container (7) through the trunk system (5) connected to the ports (3 and 6). The enzyme is added through port (8) to the adipose tissue and the fermentation process occurs at a temperature of 37C for 30 minutes. Further, after the process of settling the contents of the container, the selected cells of the stromal-vascular fraction through the system of highways passing through filters of 500 (9) and 100 (10) μm in size and are taken into the syringe through the port (11).

As a result of the work, specialists can bring their options and features of work on this device.

Claims (1)

A device for isolating stromal-vascular fraction cells from adipose tissue, including 2 chambers, one of which is used to wash off adipose tissue, and the other is for fermentation processing and cell isolation, characterized in that each chamber is a 500 cm ³ polymer main container with external calibration in volume, the container for washing off adipose tissue is made with rounded corners and has front and rear chambers separated by a filter mesh with a pore size of 200 μm, each of which there is a luer port for dumping waste and introducing biomaterial, washing solution and moving the biomaterial into the fermentation container, and the fermentation container is made downward for concentration of the selected cells in the contracting place and passing to the highway with built-in filters 500 μm and 100 μm and luer port, while the device is equipped with a polymer container with a volume of 1000 cm ³ for waste collection, and the containers are interconnected by highways through luer ports.

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