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产地类别	进口	应用领域	环保

3D Liver canaliculi assays批发价格,该细胞组织可拉伸微电极阵列刺激与成像记录系统使研究人员能够可重复且可靠地研究生理和病理机械拉伸对生物组织电生理的影响。该系统集成：细胞拉伸设备，电生理数据采集系统；活细胞成像系统三种功能...

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3D Liver canaliculi assays批发价格

3D Liver canaliculi assays，

品牌:法国以及美国flexcell

销售欧美进口各种不同基底静态培养及不同基底力学刺激环境动态培养装置
一、法国基底刚度可调控微图案培养产品

特点：

控制细胞的3D结构和力学

细胞在平坦或微结构化的软3D环境中培养，以模仿体内条件。

基材的刚度可以从非常软（1 kPa）到非常硬（200 kPa）中选择

提供多种基材形貌（平坦，圆形孔，方形孔，凹槽等）

基于凝胶的底物已准备好用于您的细胞培养实验

由于细胞直接接种在特征的顶部（易于限制非迁移细胞），因此易于使用且易于使用

预涂ECM基质（例如纤连蛋白）

适用于任何细胞培养底物（盖玻片，培养皿，多孔板）

凝胶的光学透明性使这些底物与高分辨率光学显微镜系统兼容

可拉伸细胞基底硬度控制培养皿（CellSoft 100mm Round Dishes）
Cells sense soft! CellSoft offers softer substrates to match the material properties of tissue niches to better meet the needs of biological laboratories wanting to grow their cells on native stiffness。

直径100mm培养皿，总生长表面积为57cm²

●BioFlex® CellSoft标准6孔板
●腔室载玻片CellSoft
CellSoft培养板有很多不同的种类，如不同的硬度，不同的孔板，用于显微观察的腔室载玻片（圆形多孔板），共价包被CollagenI或其他蛋白，可对细胞进行静态或动态牵拉应力刺激。更重要的一点，新型的CellSoft培养板可以反复消化和再接种细胞，蛋白包被的表面可以重复使用多达三次。
niche。●弹性模量范围1-80kPa
●BioFlex® CellSoft标准6孔板
●腔室载玻片CellSoft
Amino,
Elastin,
and Laminin (YIGSR)
and untreated （未处理）

纳米图案化牵张、压缩培养表面提供细胞微环境，模仿天然细胞外基质的对齐结构，促进细胞结构和功能发展。
纳米图案化牵张、压缩培养表面提供细胞微环境，模仿天然细胞外基质的对齐结构，促进细胞结构和功能发展。
PUBLICATIONS

Confinement and Low Adhesion Induce Fast Amoeboid Migration of Slow Mesenchymal Cells
Y.-J. Liu, M. Piel, Cell, et al., 2015 160(4), 659-672

Actin flows induce a universal coupling between cell speed and cell persistence
P. Maiuri, R. Voituriez, et al., Cell, 2015 161(2), 374–386

Geometric friction directs cell migration
M. Le Berre, M. Piel, et al., Physical Review Letter 2013 111, 198101

Mitotic rounding alters cell geometry to ensure efficient spindle assembly
O. M. Lancaster, B. Baum, et al., Developmental Cell, 2013 25(3), 270-283

Fine Control of Nuclear Confinement Identifies a Threshold Deformation leading to Lamina Rupture and Induction of Specific Genes
M. Le Berre, J. Aubertin, M. Piel, Integrative Biology, 2012 4 (11), 1406-1414

Exploring the Function of Cell Shape and Size during Mitosis
C. Cadart, H. K. Matthews, et al., Developmental Cell, 2014 29(2), 159-169

Methods for Two-Dimensional Cell Confinement
M. Le Berre, M. Piel, et al., 2014, Micropatterning in Cell Biology Part C, Methods in cell biology, 121, 213-29

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3D Liver canaliculi assays批发价格