TDCCS-3D Microgravity Simulation Control System

TDCCS-3D Microgravity Simulation Control SystemThe rotary microgravity three-dimensional cell culture system is an excellent equipment for cell culture

working principle

By rotating the cell culture container in three-dimensional space, the generated centrifugal force interacts with gravity, effectively simulating the microgravity state. Cells can grow in suspension in a rotating culture medium under low shear and low turbulence conditions, which is closer to the natural three-dimensional growth environment inside the body.

TDCCS-3D Microgravity Simulation Control Systemcompose

-Controller: It is the control core of the system, which can accurately regulate the rotation speed, direction, time and other parameters of the rotating seat.

-Rotating seat: usually placed inside the incubator, used to carry cell culture containers and achieve three-dimensional rotation of the cell culture containers.

-Cell culture containers: There are various types of biological reaction containers, universal culture dishes, culture bottles, etc., which can be selected according to experimental needs.

Product Features

-True dynamic cultivation: It can achieve dynamic cultivation of cells in three-dimensional space, making the interaction between cells and between cells and culture medium more complete.

-Low shear stress environment: During the rotation process, cells are subjected to lower shear forces, which reduces damage to cells and helps maintain their normal physiological functions and morphology.

-Adjustable parameters: Supports the adjustment of parameters such as rotational speed, steering, and microgravity simulation level to meet the requirements of different experiments for microgravity simulation level.

Application scenarios

-Cell biology research: Investigating the changes in morphology, proliferation, differentiation, gene expression, and other aspects of cells under microgravity conditions, and revealing the adaptive mechanisms of cells under different gravity conditions.

-In the field of astrobiology, as an important ground simulation tool, it provides scientific basis and data support for actual space missions by understanding the possible reactions of cells in the space environment in advance.

-Drug development: Constructing cell culture models that are more in line with the in vivo environment for screening more effective drugs, studying the changes of disease-related cells under microgravity, and providing new ideas for disease diagnosis and treatment.

-Tissue engineering and regenerative medicine: promoting intercellular interactions and signal transmission, helping to construct cell culture models that are more in line with the in vivo environment, promoting tissue formation and functional recovery.