BiomimX ,uBEAT 3D细胞构建体机械刺激系统

uBEAT uBeat专li技术为3D细胞构建体提供了受控且可调的机械刺激。 uBeat在您的体外模型中集成了原始的机械微环境，从而以qian所未有的度再现了人体器官的功能。 uBeat技术提供的机械刺激可调节和定制，以适应不同的器官模型。通过更改设计的几个几何特征，可以实现单轴应变和/或有限的压缩。 uBeat-在微尺度上控制机械刺激的*方法单轴应变uBeat技术允许对微尺度平台内的3D细胞构造施加受控，均匀和单轴应变密闭压缩uBeat技术允许对3D应用受控，纯净和受限的压缩微型平台3D细胞培养中的细胞构建物BiomimX的平台允许生成和培养微型3D细胞培养模型。得益于用户友好的播种过程，就像将细胞播种到标准培养板中一样容易，可以在BiomimX的平台上获得3D细胞构建体。我们的平台可与任何类型的电池，任何水凝胶预聚物兼容，并易于与标准实验室设备关联。芯片上的中到高通量有机体BiomimX开发了*的中通量技术，将多个*独立播种的培养室整合在一起，一步到位。中通量技术非常适合在单个设备中测试分子的剂量依赖性响应，而对细胞和试剂的浪费极少。

uBEAT

uBeat patented technology provides 3D cell constructs with a controlled and tunable mechanical stimulation. uBeat integrates the native mechanical microenvironment in your in vitro models, allowing to recapitulate human organs’ function with an unprecedented level of precision and accuracy.

The mechanical stimulation provided by uBeat technology is tunable and customizable to fit different organ models. By changing few geometrical features of the design, uniaxial strain and/or confined compression can be achieved.

uBeat - the best way to control mechanical stimulation at the microscale

Uniaxial strain

uBeat technology allows to apply a controlled, uniform and uniaxial strain to 3D cell constructs within a microscaled platform

Confined compression

uBeat technology allows to apply a controlled, pure and confined compression to 3D cell constructs within a microscaled platform

3D CELL CULTURE

BiomimX's platform allows for the generation and culturing of miniaturized 3D cell culture models. Thanks to a user-friendly seeding procedure, as easy as seeding your cells in a standard culture plate, 3D cell constructs can be obtained within BiomimX's platform. Our platform is compatible with any cell type, any hydrogel pre-polymer and easily associated with standard lab equipment.

MID- TO HIGH- THROUGHPUT ORGANS ON CHIP

BiomimX developed a unique mid-throughput technology, integrating multiple, completely independent culture chambers seeded all in one step. Mid-throughput technology is ideal for testing the dose-dependent response of  molecules in a single device, with minimal waste of cells and reagents.