| 1 |
Improvement of short-term hypothermic preservation of microencapsulated hepatocytes
Lu J, Zhang YH, Zhu DH, Wang J, Ye C, Zhang XQ, Cao HC, Li LJ
Biotechnology Letters, 38(6), 909, 2016 |
| 2 |
Low temperature cell pausing: an alternative short-term preservation method for use in cell therapies including stem cell applications
Robinson NJ, Picken A, Coopman K
Biotechnology Letters, 36(2), 201, 2014 |
| 3 |
Di-rhamnolipids improve effect of trehalose on both hypothermic preservation and cryopreservation of rat hepatocytes
Jiang LF, Shen C, Dai J, Meng Q
Applied Microbiology and Biotechnology, 97(10), 4553, 2013 |
| 4 |
Differential response in downstream processing of CHO cells grown under mild hypothermic conditions
Tait AS, Tarrant RDR, Velez-Suberbie ML, Spencer DIR, Bracewell DG
Biotechnology Progress, 29(3), 688, 2013 |
| 5 |
Enhancement of monoclonal antibody productivity by promoting active hypothermic growth in hybridoma cells
Chong SL, Mou DG, Lim SH, Ali AM, Tey BT
Journal of Chemical Technology and Biotechnology, 84(11), 1674, 2009 |
| 6 |
Cardiac proteasome dysfunction during cold ischemic storage and reperfusion in a murine heart transplantation model
Majetschak M, Patel MB, Sorell LT, Liotta C, Li S, Pham SM
Biochemical and Biophysical Research Communications, 365(4), 882, 2008 |
| 7 |
High yields of monomeric recombinant beta-interferon from macroporous microcarrier cultures under hypothermic conditions
Tharmalingam T, Sunley K, Butler M
Biotechnology Progress, 24(4), 832, 2008 |
| 8 |
CHO cells adapted to hypothermic growth produce high yields of recombinant beta-interferon
Sunley K, Tharmalingam T, Butler M
Biotechnology Progress, 24(4), 898, 2008 |
| 9 |
Synergistic effect of cold mannitol and Na+/Ca2+ exchange blocker on blood-brain barrier opening
Ikeda M, Bhattacharjee AK, Kondoh T, Nagashima T, Tamaki N
Biochemical and Biophysical Research Communications, 291(3), 669, 2002 |
