Michael J. Betenbaugh
Affiliations: | Johns Hopkins University, Baltimore, MD |
Area:
Chemical Engineering, BiochemistryWebsite:
https://engineering.jhu.edu/chembe/faculty/michael-j-betenbaugh/Google:
"Michael J Betenbaugh"Bio:
Mean distance: 2341.94
Parents
Sign in to add mentor| Prasad Dhurjati | grad student | 1988 | University of Delaware (E-Tree) | |
| (Effects of plasmid copy number and recombinant gene expression of Escherichia coli.) | ||||
Children
Sign in to add trainee| Shawn M. Lawrence | grad student | 2001 | Johns Hopkins |
| Bruno Figueroa | grad student | 2002 | Johns Hopkins |
| Tina M. Sauerwald | grad student | 2002 | Johns Hopkins |
| Jullian Jones | grad student | 2005 | Johns Hopkins |
| Karthik Viswanathan | grad student | 2005 | Johns Hopkins |
| Nilou Arden | grad student | 2006 | Johns Hopkins |
| Pratik Jaluria | grad student | 2007 | Johns Hopkins |
| Someet Narang | grad student | 2008 | Johns Hopkins |
| Tarangsri (Toey) Nivitchanyong | grad student | 2008 | Johns Hopkins |
| Michael P. Gillmeister | grad student | 2009 | Johns Hopkins |
| Brian S. Majors | grad student | 2009 | Johns Hopkins |
| Chia H. Chu | grad student | 2010 | Johns Hopkins |
| Deniz Baycin Hizal | grad student | 2011 | Johns Hopkins |
| Fenghao Chen | grad student | 2011 | Johns Hopkins |
| Matthew P. Zustiak | grad student | 2012 | Johns Hopkins |
| Aliaksandr Druz | grad student | 2013 | Johns Hopkins |
| Xiao Liu | grad student | 2017-2019 | Johns Hopkins (BME Tree) |
BETA: Related publications
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Publications
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| Geada I, Roldão A, Betenbaugh MJ, et al. (2023) Advanced cell technologies: Making protein, cell, and gene therapies a reality. Biotechnology and Bioengineering |
| Sacco SA, McAtee Pereira AG, Trenary I, et al. (2023) Overexpression of peroxisome proliferator-activated receptor γ co-activator-1⍺ (PGC-1⍺) in Chinese hamster ovary cells increases oxidative metabolism and IgG productivity. Metabolic Engineering |
| Dhara VG, Kumar S, DeVine L, et al. (2023) Cottonseed hydrolysate supplementation alters metabolic and proteomics responses in Chinese Hamster Ovary cell cultures. Biotechnology Journal. e2200243 |
| Chen Y, Betenbaugh MJ. (2023) Reconstruction of reverse transsulfuration pathway enables cysteine biosynthesis and enhances resilience to oxidative stress in Chinese Hamster Ovary cells. Metabolic Engineering |
| Cordova LT, Dahodwala H, Elliott KS, et al. (2022) Generation of reference cell lines, media, and a process platform for CHO cell biomanufacturing. Biotechnology and Bioengineering |
| Kumar S, Kumar A, Huhn S, et al. (2022) A Proteomics Approach to Decipher a Sticky CHO Situation. Biotechnology and Bioengineering |
| Sacco SA, Tuckowski AM, Trenary I, et al. (2022) Attenuation of glutamine synthetase selection marker improves product titer and reduces glutamine overflow in Chinese hamster ovary cells. Biotechnology and Bioengineering |
| Demirhan D, Kumar A, Zhu J, et al. (2022) Comparative systeomics to elucidate physiological differences between CHO and SP2/0 cell lines. Scientific Reports. 12: 3280 |
| McFarland KS, Zhu J, Sinharoy P, et al. (2022) Engineering redox sensors into CHO cells enables near-real-time quantification of intracellular redox in bioprocesses. Biotechnology and Bioengineering |
| Chen Y, Liu X, Anderson JY, et al. (2021) A genome-scale nutrient minimization forecast algorithm for controlling essential amino acid levels in CHO cell cultures. Biotechnology and Bioengineering |