可拉伸細胞基底硬度控制培養(yǎng)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。

直徑100mm培養(yǎng)皿，總生長表面積為57cm²

●BioFlex® CellSoft標(biāo)準(zhǔn)6孔板

●腔室載玻片CellSoft

CellSoft培養(yǎng)板有很多不同的種類，如不同的硬度，不同的孔板，用于顯微觀察的腔室載玻片（圓形多孔板），共價包被CollagenI或其他蛋白，可對細胞進行靜態(tài)或動態(tài)牽拉應(yīng)力刺激。更重要的一點，新型的CellSoft培養(yǎng)板可以反復(fù)酶消化和再接種細胞，蛋白包被的表面可以重復(fù)使用多達三次。

niche。●彈性模量范圍1-80kPa

●BioFlex® CellSoft標(biāo)準(zhǔn)6孔板

●腔室載玻片CellSoft

Amino,

Elastin,

and Laminin (YIGSR)
and untreated （未處理）

納米圖案化牽張、壓縮培養(yǎng)表面提供細胞微環(huán)境，模仿天然細胞外基質(zhì)的對齊結(jié)構(gòu)，促進細胞結(jié)構(gòu)和功能發(fā)展。

納米圖案化牽張、壓縮培養(yǎng)表面提供細胞微環(huán)境，模仿天然細胞外基質(zhì)的對齊結(jié)構(gòu)，促進細胞結(jié)構(gòu)和功能發(fā)展。

• PUBLICATIONS

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• 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

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

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

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

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• 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

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

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• 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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[26] C. R.Justus, N. Leffler, M. Ruiz-Echevarria, and L. V Yang, “In vitro cell migrationand invasion assays.," J. Vis. Exp., vol. 752, no. 88, p. e51046,2014.

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[33] S. M.McFaul, B. K. Lin, and H. Ma, “Cell separation based on size and deformabilityusing microfluidic funnel ratchets," Lab Chip, vol. 12, no. 13, pp.2369–2376, 2012.

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[34] S. C. Hur,N. K. Henderson-MacLennan, E. R. B. McCabe, and D. Di Carlo,“Deformability-based cell classification and enrichment using inertialmicrofluidics.," Lab Chip, vol. 11, no. 5, pp. 912–920, 2011.

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[35] H. W. Hou,Q. S. Li, G. Y. H. Lee, A. P. Kumar, C. N. Ong, and C. T. Lim, “Deformabilitystudy of breast cancer cells using microfluidics," Biomed. Microdevices,vol. 11, no. 3, pp. 557–564, 2009.

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