Literature DB >> 11451047

Hydrodynamic damage to animal cells.

Y Chisti1.   

Abstract

Animal cells are affected by hydrodynamic forces that occur in culture vessel, transfer piping, and recovery operations such as microfiltration. Depending on the type, intensity, and duration of the force, and the specifics of the cell, the force may induce various kinds of responses in the subject cells. Both biochemical and physiological responses are observed, including apoptosis and purely mechanical destruction of the cell. This review examines the kinds of hydrodynamic forces encountered in bioprocessing equipment and the impact of those forces on cells. Methods are given for quantifying the magnitude of the specific forces, and the response thresholds are noted for the common types of cells cultured in free suspension, supported on microcarriers, and anchored to stationary surfaces.

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Year:  2001        PMID: 11451047     DOI: 10.1080/20013891081692

Source DB:  PubMed          Journal:  Crit Rev Biotechnol        ISSN: 0738-8551            Impact factor:   8.429


  36 in total

1.  The sensitivity of human mesenchymal stem cells to vibration and cold storage conditions representative of cold transportation.

Authors:  N I Nikolaev; Y Liu; H Hussein; D J Williams
Journal:  J R Soc Interface       Date:  2012-05-23       Impact factor: 4.118

2.  Slow turning lateral vessel bioreactor improves embryoid body formation and cardiogenic differentiation of mouse embryonic stem cells.

Authors:  Sasitorn Rungarunlert; Nuttha Klincumhom; Theerawat Tharasanit; Mongkol Techakumphu; Melinda K Pirity; Andras Dinnyes
Journal:  Cell Reprogram       Date:  2013-09-10       Impact factor: 1.987

Review 3.  Living with heterogeneities in bioreactors: understanding the effects of environmental gradients on cells.

Authors:  Alvaro R Lara; Enrique Galindo; Octavio T Ramírez; Laura A Palomares
Journal:  Mol Biotechnol       Date:  2006-11       Impact factor: 2.695

4.  Production of a self-activating CBM-factor X fusion protein in a stable transformed Sf9 insect cell line using high cell density perfusion culture.

Authors:  Volker M Gorenflo; Tom A Pfeifer; Gary Lesnicki; Emily M Kwan; Thomas A Grigliatti; Douglas G Kilburn; James M Piret
Journal:  Cytotechnology       Date:  2004-03       Impact factor: 2.058

Review 5.  Engineering Strategies for the Formation of Embryoid Bodies from Human Pluripotent Stem Cells.

Authors:  Giuseppe Pettinato; Xuejun Wen; Ning Zhang
Journal:  Stem Cells Dev       Date:  2015-06-02       Impact factor: 3.272

6.  Embryoid body formation from embryonic and induced pluripotent stem cells: Benefits of bioreactors.

Authors:  Sasitorn Rungarunlert; Mongkol Techakumphu; Melinda K Pirity; Andras Dinnyes
Journal:  World J Stem Cells       Date:  2009-12-31       Impact factor: 5.326

7.  A microfluidic device enabling high-efficiency single cell trapping.

Authors:  D Jin; B Deng; J X Li; W Cai; L Tu; J Chen; Q Wu; W H Wang
Journal:  Biomicrofluidics       Date:  2015-01-07       Impact factor: 2.800

Review 8.  Harnessing stem cells and biomaterials to promote neural repair.

Authors:  K F Bruggeman; N Moriarty; E Dowd; D R Nisbet; C L Parish
Journal:  Br J Pharmacol       Date:  2018-12-21       Impact factor: 8.739

9.  Applying shear stress to endothelial cells in a new perfusion chamber: hydrodynamic analysis.

Authors:  Fatemeh Anisi; Nasim Salehi-Nik; Ghassem Amoabediny; Behdad Pouran; Nooshin Haghighipour; Behrouz Zandieh-Doulabi
Journal:  J Artif Organs       Date:  2014-09-12       Impact factor: 1.731

10.  Albumin and mammalian cell culture: implications for biotechnology applications.

Authors:  Geoffrey L Francis
Journal:  Cytotechnology       Date:  2010-04-06       Impact factor: 2.058
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