CN110530780A - A kind of cell hyperbaric chamber being equipped on microscopic system - Google Patents

Abstract

The invention relates to a cell hyperbaric chamber mounted on a microscope system, which is characterized in that it includes a hyperbaric chamber, a cabin body base, a pressure relief pipeline and a stable holder; by setting the hyperbaric chamber with a visual structure on the microscope stage The structure can directly form a high-pressure environment for cells on the microscope stage, and directly observe the cells in a high-pressure environment; avoid taking out cells from a high-pressure environment, causing cells to change rapidly under high-pressure conditions, resulting in captured physiological The signal is a matter of time delay; the hyperbaric cabin is compressed by setting a stable holder and a guide column structure on the base of the cabin, which is convenient for quick positioning, installation and disassembly; a guide seat is set on the bottom end cover, and the guide The contact between the seat structure and the guide column effectively prevents the alignment deviation between the limit guide hole and the guide column, and also avoids the direct contact between the limit guide column and the limit guide plate to effectively protect the upper limit guide plate of the bottom cover.

Description

A cell hyperbaric chamber mounted on a microscope system

technical field

The invention relates to the technical field of hyperbaric chambers, in particular to a cell hyperbaric chamber mounted on a microscope system.

Background technique

In recent years, with the country's increasing emphasis on ocean development, diving activities are increasing, and research on the effects of high pressure on human physiological functions, such as inert gas anesthesia, hypertensive neurological syndrome and hyperbaric oxygen exposure, has become the focus of attention. However, there are still many technical difficulties in research in this field. For example, if we want to observe the influence of high pressure on cultured cells and tissues, we first need to place cultured cells or tissues in a dedicated hyperbaric chamber or workstation for high pressure exposure. After the exposure is over, it needs to be taken out after a period of decompression, and then quickly placed under a microscope to observe the changes in various indicators. Because some functions of cells change rapidly under high-pressure conditions, and these changes are very fast after leaving the high-pressure environment. disappears quickly, so the physiological signals captured by existing methods are time-delayed or even wrong, and these defects will mislead the experiment.

At present, there is no such device that can overcome the above-mentioned problems, but using our equipment that can be mounted on the microscope stage and can be dynamically observed by the microscope can fundamentally solve the above-mentioned problems. This device can provide cultured tissues or cells with A deep-sea pressure environment can realize long-term dynamic observation of various indicators of cultured tissues and cells under high-pressure exposure with a microscope, which improves the accuracy of scientific research data.

Contents of the invention

In view of this, the object of the present invention is to provide a cell hyperbaric chamber mounted on a microscope system, which can improve the accuracy of cell observation in a high pressure environment.

In order to solve the above technical problems, the present invention provides a cell hyperbaric chamber mounted on a microscope system, the cell hyperbaric chamber is mounted on the stage of the microscope system, and is characterized in that it includes a hyperbaric chamber, a chamber base, a pressure relief Pipe and stabilizing grippers;

The hyperbaric chamber includes a hyperbaric chamber body, a top cover plate, a top observation window, a bottom cover plate and a bottom observation window; the hyperbaric chamber body is a columnar structure and a cylinder for accommodating culture fluid and glass slides is provided in the hyperbaric chamber body. chamber, the cylindrical chamber connects the two ends of the hyperbaric cabin; the side of the hyperbaric cabin is provided with an air inlet and an exhaust port; the top cover and the bottom cover respectively connect the Said top observation window and said bottom observation window are compressed on both ends of the hyperbaric cabin body;

There are several positioning holes on the base of the cabin, and the positioning holes lock the base of the cabin on the stage of the microscope system through bolts to follow the movement of the stage; The guide column matched with the bottom end of the tank, the guide column is a stepped shaft structure; the edge of the bottom cover plate of the hyperbaric cabin is provided with a limit guide plate and a limit guide hole is opened on the limit guide plate, and the limit guide The hole cooperates with the stepped surface of the guide column on the cabin base to realize the position-limiting guidance of the hyperbaric cabin, and the stepped shaft-type guide column structure forms a light-transmitting gap between the cabin base and the bottom end of the hyperbaric cabin;

The pressure relief pipeline is connected to the exhaust port of the high pressure cabin, and the pressure relief pipeline is provided with a pressure relief valve and a pressure monitoring gauge;

The stable holder is arranged on the base of the cabin body and is located around the bottom of the hyperbaric cabin and pressed against the stepped surface of the guide column on the base of the cabin body.

Further, the stable holder includes a fixed base, a hinged base, a compression handle and a compression block; the fixed base is vertically arranged on the cabin base and distributed around the hyperbaric cabin; the hinged base is set On the top of the fixed base, the pressing handle and the pressing block are arranged perpendicular to each other to form an L-shaped structure, one end of the pressing handle is hinged on the hinged base, and the pressing block is pressed to the limit by rotating the pressing handle guide plate.

Further, a limit guide seat is provided in the limit guide hole on the limit guide plate; the limit guide seat is a pair of coaxially arranged cylindrical barrel structures, and one of the cylinders of the limit guide seat The cylinder structure is embedded in the limit guide hole, and the other cylinder structure of the limit guide seat is pressed on the lower surface of the limit guide plate; the limit guide column is embedded in the limit guide seat.

Further, the top observation window and the bottom observation window are both blue-coated glass structures.

Further, the edge of the top cover plate and the edge of the bottom cover plate are provided with bolt holes, and the top cover plate and the bottom cover plate are respectively locked on the bulkhead of the hyperbaric cabin by bolts, the top cover plate and O-rings are provided at the contact points between the bottom cover plate and the end of the hyperbaric cabin.

Compared with the prior art, the present invention has the following technical effects:

1) In the present invention, by setting a hyperbaric chamber structure with a visualized structure on the microscope stage, a high-pressure environment for cells can be formed directly on the microscope stage, and cells can be dynamically observed directly in the high-pressure environment; Taking out cells under high-pressure environment will cause some functions of cells to change rapidly under high-pressure conditions, resulting in delayed or even wrong situations in the captured physiological signals.

2) In the present invention, the hyperbaric cabin is compressed by setting a stable gripper and a guide column structure on the cabin base, which is convenient for quick positioning, installation and disassembly; a guide seat is provided on the bottom end cover plate, and a guide seat structure is adopted The contact with the guide column effectively prevents the alignment deviation between the limit guide hole and the guide column, and also avoids the direct contact between the limit guide column and the limit guide plate to effectively protect the upper limit guide plate of the bottom cover.

Description of drawings

FIG. 1 is a top view structure diagram of a cell hyperbaric chamber mounted on a microscope system according to the present invention.

Fig. 2 is a side view structural schematic diagram of a cell hyperbaric chamber pair mounted on a microscope system according to the present invention.

Reference signs: 1. Hyperbaric cabin; 11. Hyperbaric cabin body; 12. Top cover plate; 13. Top observation window; 14. Bottom cover plate; 15. Bottom observation window; 2. Cabin base; 21. Guide column; 22. Limit guide plate; 23. Limit guide seat; 3. Pressure relief pipe; 31. Pressure relief valve; 32. Pressure monitoring gauge; 4. Stable holder; 41. Fixed base; 42. Hinged base; 43. Compression handle; 44. Compression block.

Detailed ways

In order to further understand the present invention, the preferred embodiments of the present invention are described below in conjunction with the examples, but it should be understood that these descriptions are only to further illustrate the features and advantages of the present invention, rather than limiting the claims of the present invention.

A cell hyperbaric chamber mounted on a microscope system as shown in Figures 1 and 2, the hyperbaric chamber is mounted on the stage of the microscope system; including a hyperbaric chamber 1, a cabin base 2, a pressure relief pipe 3 and a stable clamp device 4.

Hyperbaric chamber 1 comprises hyperbaric chamber body 11, top cover plate 12, top observation window 13, bottom cover plate 14 and bottom observation window 15; The cylindrical chamber of the glass slide, the cylindrical chamber conducts the two ends of the hyperbaric cabin body 11; the side of the hyperbaric cabin body 11 is provided with an air inlet and an exhaust port; the top cover plate 12 and the bottom cover plate 14 respectively The top observation window 13 and the bottom observation window 15 are pressed tightly on the two ends of the hyperbaric cabin body 11; the top observation window 13 and the bottom observation window 14 are all blue-coated glass structures; the edge of the top cover plate 12 and the bottom cover plate 14 Bolt holes are provided on the edges, and the top cover plate 12 and the bottom cover plate 14 are respectively locked on the bulkhead of the hyperbaric cabin body 11 by bolts. O-rings are provided at the contact points.

A number of positioning holes are opened on the base of the cabin body 2, and the positioning holes lock the base of the cabin body 2 on the stage of the microscope system to follow the movement of the stage through bolts; The guide column 21, the guide column 21 is a stepped shaft structure; the edge on the bottom cover plate 14 of the hyperbaric cabin 1 is provided with a limit guide plate 22 and a limit guide hole is opened on the limit guide plate 22, and the limit guide hole and the cabin body The stepped surface of the guide column 21 on the base 2 cooperates to realize the position-limiting guidance of the hyperbaric cabin 1, and the stepped shaft-type guide column 21 structure forms a light-transmitting gap between the cabin base 2 and the bottom end of the hyperbaric cabin 1; the position-limiting guide A limit guide seat 23 is arranged in the limit guide hole on the plate 22; the limit guide seat 23 is a pair of cylindrical barrel structures coaxially arranged, and one of the cylindrical barrel structures of the limit guide seat 23 is embedded in the limit In the position guide hole, another cylindrical structure of the limit guide seat 23 is pressed against the lower surface of the limit guide plate 22; the limit guide column 21 is embedded in the limit guide seat 23.

The pressure relief pipeline 3 is connected to the exhaust port of the high pressure cabin, and the pressure relief pipeline 3 is provided with a pressure relief valve 31 and a pressure monitoring gauge 32 .

Stable holder 4 is arranged on the cabin body base and is positioned at the bottom of hyperbaric cabin 1 and presses on the guide post step surface on cabin body base 2; Compress the handle 43 and the compression block 44; the fixed base 41 is vertically arranged on the cabin base 2 and is distributed around the hyperbaric cabin 1; the hinged base 42 is arranged on the top of the fixed base 41, and the compression handle 43 and the compression block 44 are arranged perpendicular to each other to form an L-shaped structure. One end of the compression handle 43 is hinged on the hinged base 42 , and the compression block 44 is pressed against the position-limiting guide plate 22 by rotating the compression handle 43 .

Working principle of the present invention: put into the slide glass and culture fluid that are loaded with the cell tissue to be observed in the hyperbaric cabin body 11 of hyperbaric cabin 1; Through top cover plate 12, top observation window 13, bottom cover plate 14 and bottom The observation window 15 seals the hyperbaric cabin; the sealed hyperbaric cabin 1 is installed on the cabin base 2 through the guide column 21; on the body base 2; then the overall placement on the stage of the microscope system; open the air inlet on the hyperbaric cabin 11 to feed gas for pressurization, and detect the pressure inside the hyperbaric cabin through the pressure monitoring gauge 32; when reaching the observation When the pressure is high, stop feeding the gas and observe and record relevant data; after completing the observation, open the pressure relief valve 31 and discharge the gas in the hyperbaric cabin 11 through the exhaust port on the hyperbaric cabin 11, when the hyperbaric cabin 11 is normal Open the hyperbaric chamber body 11 to take out the internal glass slides under the pressure, and pack up the relevant observation equipment to complete the entire observation process.

Those skilled in the industry should understand that the present invention is not limited by the above-mentioned embodiments. What are described in the above-mentioned embodiments and the description only illustrate the principle of the present invention. Without departing from the spirit and scope of the present invention, the present invention will also have Variations and improvements are possible, which fall within the scope of the claimed invention. The protection scope of the present invention is defined by the appended claims and their equivalents.

Claims (5)

1. A cell hyperbaric chamber mounted on a microscope system, said cell hyperbaric chamber mounted on the stage of the microscope system, characterized in that: comprising a hyperbaric chamber, a cabin base, a pressure relief pipeline and a stable holder; The hyperbaric chamber includes a hyperbaric chamber body, a top cover plate, a top observation window, a bottom cover plate and a bottom observation window; the hyperbaric chamber body is a columnar structure and a cylinder for accommodating culture fluid and glass slides is provided in the hyperbaric chamber body. chamber, the cylindrical chamber connects the two ends of the hyperbaric cabin; the side of the hyperbaric cabin is provided with an air inlet and an exhaust port; the top cover and the bottom cover respectively connect the Said top observation window and said bottom observation window are compressed on both ends of the hyperbaric cabin body; There are several positioning holes on the base of the cabin, and the positioning holes lock the base of the cabin on the stage of the microscope system through bolts to follow the movement of the stage; The guide column matched with the bottom end of the tank, the guide column is a stepped shaft structure; the edge of the bottom cover plate of the hyperbaric cabin is provided with a limit guide plate and a limit guide hole is opened on the limit guide plate, and the limit guide The hole cooperates with the stepped surface of the guide column on the cabin base to realize the position-limiting guidance of the hyperbaric cabin, and the stepped shaft-type guide column structure forms a light-transmitting gap between the cabin base and the bottom end of the hyperbaric cabin; The pressure relief pipeline is connected to the exhaust port of the high pressure cabin, and the pressure relief pipeline is provided with a pressure relief valve and a pressure monitoring gauge; The stable clamp is arranged on the base of the cabin and is located around the bottom of the hyperbaric cabin and pressed against the stepped surface of the guide column on the base of the cabin. 2. A cell hyperbaric chamber mounted on a microscope system according to claim 1, wherein the stable holder includes a fixed base, a hinged base, a compression handle and a compression block; the fixed base Vertically arranged on the base of the cabin body and distributed around the hyperbaric cabin; the hinged base is arranged on the top of the fixed base, the compression handle and the compression block are arranged perpendicular to each other to form an L-shaped structure, and the compression handle One end is hinged on the hinged base, and the pressing block is pressed against the limit guide plate by turning the pressing handle. 3. A cell hyperbaric chamber mounted on a microscope system according to claim 1, characterized in that: a limit guide seat is arranged in the limit guide hole on the limit guide plate; the limit guide seat It is a pair of coaxial cylindrical barrel structures, and one of the cylindrical barrel structures of the limit guide seat is embedded in the limit guide hole, and the other cylindrical barrel structure of the limit guide seat is pressed against the limit guide On the lower surface of the plate; the limit guide column is embedded in the limit guide seat. 4. A cell hyperbaric chamber mounted on a microscope system according to claim 1, characterized in that: the top observation window and the bottom observation window are both blue-coated glass structures. 5. A cell hyperbaric chamber mounted on a microscope system according to claim 1, characterized in that: the edges of the top cover and the bottom cover are provided with bolt holes, and the top cover and the bottom cover The plates are respectively locked on the bulkhead of the hyperbaric cabin by bolts, and O-rings are provided at the contact points between the top cover plate and the bottom cover plate and the ends of the hyperbaric cabin.