Ben Cosgrove: Difference between revisions
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'''Ben Cosgrove''' [http:// | '''Ben Cosgrove''' [http://www.stanford.edu/~cosgrove/cosgrove_cv.pdf CV] [mailto:cosgrove@stanford.edu email] [http://www.epernicus.com/bc Epernicus] | ||
Ph.D. | Ph.D., Bioengineering, Department of Biological Engineering, M.I.T. | ||
''Current affiliation:'' | |||
Postdoctoral Fellow, Molecular Imaging Program at Stanford, Stanford University School of Medicine | |||
''Research Advisors:'' | |||
''Ph.D. Research Advisors:'' | |||
* Linda Griffith [http://web.mit.edu/lgglab/ webpage] | * Linda Griffith [http://web.mit.edu/lgglab/ webpage] | ||
* Doug Lauffenburger [http://lauffenburger.openwetware.org/ | * Doug Lauffenburger [http://web.mit.edu/dallab/index.html webpage] [http://lauffenburger.openwetware.org/ lab wiki] | ||
''Ph.D. Research Summary:'' | |||
"Quantitative Analysis of Cytokine-Induced Hepatocyte Proliferation, Apoptosis, and Toxicity" | |||
Many therapeutic approaches, including viral gene therapy agents and small molecule pharmaceutical compounds, are confounded by liver toxicity due to, in part, synergistic relationships with inflammatory stimuli in eliciting hepatocyte toxicity and/or death. My work focuses quantitatively measuring and modeling how hepatocytes regulate, through the activities of intracellular and extracellular signaling networks, cell behavioral responses following cytokine stimulation in the presence of viral gene therapy agents or small molecule drugs in physiologically relevant ''in vitro'' cell models. | |||
Initially, I examined the role of the inflammatory cytokine tumor necrosis factor-α (TNF), which regulates both hepatocyte proliferation and apoptosis ''in vivo''. I showed that TNF stimulates hepatocyte proliferation and (adenoviral vector infection-sensitized) apoptosis ''in vitro'' through a time-varying autocrine cascade involving the growth factor TGF-α and the cytokines IL-1α/β and IL-1ra. I demonstrated that the inducible TGF-α–IL-1α/β–IL-1ra autocrine cascade regulates hepatocyte responses to TNF in a self-antagonizing manner by modulating multiple signaling pathways, including Akt, ERK, JNK, p38, and IKK–NF-κB, downstream of TNFR that both positively and negatively regulate hepatocyte proliferation and apoptosis. | |||
Currently, I am developing ''in vitro'' models of idiosyncratic drug hepatotoxicity by examining the interactions between multiple pharmaceutical compounds and inflammatory cytokines. In this work, I aim to elucidate how certain idiosyncratic hepatotoxic drugs exhibit synergistic toxicity relationships with inflammatory cytokines by collecting systems-level intracellular signaling data and phenotypic cellular toxicity data. This data set has been used to develop data-driven signaling-outcome models through partial least squares regression (PLSR) approaches to identify and predict key signaling activities that regulate a diverse set of hepatocyte toxicity phenotypes and to inform future therapeutic strategies. | |||
''Publications:'' | |||
[1] Cosgrove BD, Griffith LG, Lauffenburger DA. Fusing tissue engineering and systems biology toward fulfilling their promise. ''Cellular and Molecular Bioengineering'' 1:33-41, 2008. [http://dx.doi.org/10.1007/s12195-008-0007-9 DOI]. | |||
[2] Cosgrove BD, Cheng C, Pritchard JR, Stolz DB, Lauffenburger DA, Griffith LG. An inducible autocrine cascade regulates rat hepatocyte proliferation and apoptosis responses to tumor necrosis factor-α. ''Hepatology'' 48(1):276-288, 2008. [http://dx.doi.org/10.1002/hep.22335 DOI]. | |||
''Honors:'' | |||
* ''2008'' Ben Trump Award, Aspen Cancer Conference | |||
* ''2008'' Graduate Student Research Award, Biomedical Engineering Society | |||
* ''2003-2006'' Whitaker Foundation Graduate Fellowship in Biomedical Engineering | |||
* ''1999-2003'' National Merit Scholarship | |||
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* MIT Biotechnology Process Engineering center [http://web.mit.edu/bpec/ webpage] | * MIT Biotechnology Process Engineering center [http://web.mit.edu/bpec/ webpage] | ||
* MIT Center for Cell Decision Processes [http://cdp.mit.edu/ webpage] [http://cdpwiki.mit.edu/ internal wiki] | * MIT Center for Cell Decision Processes [http://cdp.mit.edu/ webpage] [http://cdpwiki.mit.edu/ internal wiki] | ||
''Funding:'' | ''Funding:'' | ||
* Whitaker Foundation Graduate Research Fellowship [http://www.whitaker.org/grants/fellanc.html webpage] | * Whitaker Foundation Graduate Research Fellowship [http://www.whitaker.org/grants/fellanc.html webpage] | ||
* MIT-Pfizer Hepatoxicity Signaling Collaboration [http://www.pfizerdtc.com/ webpage] | * MIT-Pfizer Hepatoxicity Signaling Collaboration [http://www.pfizerdtc.com/ webpage] [https://hepwiki.mit.edu/wiki/index.php/Main_Page internal wiki] | ||
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Latest revision as of 12:19, 17 February 2009
 Ben Cosgrove CV email Epernicus Ph.D., Bioengineering, Department of Biological Engineering, M.I.T.
Postdoctoral Fellow, Molecular Imaging Program at Stanford, Stanford University School of Medicine
"Quantitative Analysis of Cytokine-Induced Hepatocyte Proliferation, Apoptosis, and Toxicity" Many therapeutic approaches, including viral gene therapy agents and small molecule pharmaceutical compounds, are confounded by liver toxicity due to, in part, synergistic relationships with inflammatory stimuli in eliciting hepatocyte toxicity and/or death. My work focuses quantitatively measuring and modeling how hepatocytes regulate, through the activities of intracellular and extracellular signaling networks, cell behavioral responses following cytokine stimulation in the presence of viral gene therapy agents or small molecule drugs in physiologically relevant in vitro cell models. Initially, I examined the role of the inflammatory cytokine tumor necrosis factor-α (TNF), which regulates both hepatocyte proliferation and apoptosis in vivo. I showed that TNF stimulates hepatocyte proliferation and (adenoviral vector infection-sensitized) apoptosis in vitro through a time-varying autocrine cascade involving the growth factor TGF-α and the cytokines IL-1α/β and IL-1ra. I demonstrated that the inducible TGF-α–IL-1α/β–IL-1ra autocrine cascade regulates hepatocyte responses to TNF in a self-antagonizing manner by modulating multiple signaling pathways, including Akt, ERK, JNK, p38, and IKK–NF-κB, downstream of TNFR that both positively and negatively regulate hepatocyte proliferation and apoptosis. Currently, I am developing in vitro models of idiosyncratic drug hepatotoxicity by examining the interactions between multiple pharmaceutical compounds and inflammatory cytokines. In this work, I aim to elucidate how certain idiosyncratic hepatotoxic drugs exhibit synergistic toxicity relationships with inflammatory cytokines by collecting systems-level intracellular signaling data and phenotypic cellular toxicity data. This data set has been used to develop data-driven signaling-outcome models through partial least squares regression (PLSR) approaches to identify and predict key signaling activities that regulate a diverse set of hepatocyte toxicity phenotypes and to inform future therapeutic strategies.
[1] Cosgrove BD, Griffith LG, Lauffenburger DA. Fusing tissue engineering and systems biology toward fulfilling their promise. Cellular and Molecular Bioengineering 1:33-41, 2008. DOI. [2] Cosgrove BD, Cheng C, Pritchard JR, Stolz DB, Lauffenburger DA, Griffith LG. An inducible autocrine cascade regulates rat hepatocyte proliferation and apoptosis responses to tumor necrosis factor-α. Hepatology 48(1):276-288, 2008. DOI.
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