uBEAT uBeat專li技術為3D細胞構建體提供了受控且可調的機械刺激。 uBeat在您的體外模型中集成了原始的機械微環境，從而以qian所未有的度再現了人體器官的功能。 uBeat技術提供的機械刺激可調節和定制，以適應不同的器官模型。通過更改設計的幾個幾何特征，可以實現單軸應變和/或有限的壓縮。 uBeat-在微尺度上控制機械刺激的*方法單軸應變uBeat技術允許對微尺度平臺內的3D細胞構造施加受控，均勻和單軸應變密閉壓縮uBeat技術允許對3D應用受控，純凈和受限的壓縮微型平臺3D細胞培養中的細胞構建物BiomimX的平臺允許生成和培養微型3D細胞培養模型。得益于用戶友好的播種過程，就像將細胞播種到標準培養板中一樣容易，可以在BiomimX的平臺上獲得3D細胞構建體。我們的平臺可與任何類型的電池，任何水凝膠預聚物兼容，并易于與標準實驗室設備關聯。芯片上的中到高通量有機體BiomimX開發了*的中通量技術，將多個*獨立播種的培養室整合在一起，一步到位。中通量技術非常適合在單個設備中測試分子的劑量依賴性響應，而對細胞和試劑的浪費極少。

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.