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Artificial Cells, Blood Substitutes, and Biotechnology Volume 35, 2007 - Issue 6
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Original

Enhanced Oxygen Delivery to Primary Hepatocytes within a Hollow Fiber Bioreactor Facilitated via Hemoglobin-Based Oxygen Carriers

Jesse P. Sullivan Department of Chemical and Biomolecular Engineering, University of Notre Dame, Notre Dame, IN, USA
,
Jason E. Gordon Department of Chemical and Biomolecular Engineering, University of Notre Dame, Notre Dame, IN, USA
,
Therese Bou-Akl Department of Chemical Engineering and Materials Science, Wayne State University, Detroit, MI, USA
,
Howard W. T. Matthew Department of Chemical Engineering and Materials Science, Wayne State University, Detroit, MI, USA
&
Andre F. Palmer Department of Chemical and Biomolecular Engineering, The Ohio State University, Columbus, OH, USACorrespondence[email protected]
Pages 585-606 | Published online: 11 Jul 2009

REFERENCES

  • Simon, L., Karim, M.N. (2001). Identification and control of dissolved oxygen in hybridoma cell culture in a shear sensitive environment. Biotechnology Progress 17(4): 634–642.
  • Patzer, J.F. (2004). Oxygen consumption in a hollow fiber bioartificial liver-revisited. Artificial Organs 28(1): 83–98.
  • Gebhardt, R. (1992). Metabolic zonation of the liver-regulation and implications for liver-function. Pharmacology & Therapeutics 53(3): 275–354.
  • Leary, T.S. , et al. (2002). Measurement of liver tissue oxygenation after orthotopic liver transplantation using a multiparameter sensor – A pilot study. Anaesthesia 57(11): 1128–1133.
  • Dardzinski, B.J., Sotak, C.H. (1994). Rapid tissue oxygen-tension mapping using F-19 inversion-recovery echo-planar imaging of perfluoro-15-crown-5-ether. Magnetic Resonance in Medicine 32(1): 88–97.
  • Tallgren, M. , et al. (1999). Hepatic and splanchnic oxygenation during liver transplantation. Critical Care Medicine 27(11): 2383–2388.
  • Allen, J.W., Hassanein, T. Bhatia, S.N. (2001). Advances in bioartificial liver devices. Hepatology 34(3): 447–455.
  • Morsiani, E. , et al. (2001). Long-term expression of highly differentiated functions by isolated porcine hepatocytes perfused in a radial-flow bioreactor. Artificial Organs 25(9): 740–748.
  • Nyberg, S.L. , et al. (1994). Primary hepatocytes outperform Hep G2 cells as the source of biotransformation functions in a bioartificial liver. Annals of Surgery 220(1): 59–67.
  • Sullivan, J.P., Gordon, J.E., Palmer, A.F. (2006). Simulation of oxygen carrier mediated oxygen transport to C3A hepatoma cells housed within a hollow fiber bioreactor. Biotechnology and Bioengineering 93(2): 306–317.
  • Krogh, A. (1919). The number and distribution of capillaries in muscles with calculations of the oxygen pressurehead necessary for supplying the tissue. Journal of Physiology 52: 409–415.
  • Buerk, D.G., Saidel, G.M. (1978). A comparison of two nonclassical models for oxygen consumption in brain and liver tissue. Advanced Experimental Medical Biology 94: 225–232.
  • Hay, P.D. , et al. (2000). Oxygen transfer in a diffusion-limited hollow fiber bioartificial liver. Artificial Organs 24(4): 278–288.
  • Shi, Y., Sardonini, C.A., Goffe, R.A. (1998). The use of oxygen carriers for increasing the production of monoclonal antibodies from hollow fibre bioreactors. Research in Immunology 149(6): 576–587.
  • Jones, J.A. (1995). Red-blood-cell substitutes - current status. British Journal of Anaesthesia 74(6): 697–703.
  • Faivre, B. , et al. (1998). Hemoglobin autooxidation/oxidation mechanisms and methemoglobin prevention or reduction processes in the bloodstream – Literature review and outline of autooxidation reaction. Artificial Cells Blood Substitutes and Immobilization Biotechnology 26(1): 17–26.
  • Everse, J., Hsia, N. (1997). The toxicities of native and modified hemoglobins. Free Radical Biology and Medicine 22(6): 1075–1099.
  • Seglen, P. (1976). Preparation of isolated rat liver cells. Methods in Cell Biology 13: 29–83.
  • Dunn, J.C.Y., Tompkins, R.G., Yarmush, M.L. (1991). Long-term in vitro function of adult hepatocytes in a collagen sandwich configuration. Biotechnology Progress 7(3): 237–245.
  • Kay, J.M., Nedderman, R.M. (1985). Fluid Mechanics and Transfer Processes, Cambridge University Press: Cambridge, UK.
  • Sullivan, J.P., Palmer, A.F. (2006). Targeted oxygen delivery within hepatic hollow fiber bioreactors via supplementation of hemoglobin-based oxygen carriers. Biotechnology Progress 22(5): 1374–1387.
  • Renkin, E.M. (1954). Filtration, diffusion, and molecular seiving through porous cellulose membranes. Journal of General Physiology 38: 225–243.
  • Foy, B.D. , et al. (1994). A device to measure the oxygen-uptake rate of attached cells – importance in bioartificial organ design. Cell Transplantation 3(6): 515–527.
  • Bird, R.B., Stewart, W.E., Lightfoot, E.N. (1960). Transport Phenomena, John Wiley and Sons: New York, p. 780.
  • Moll, W. (1968). The influence of hemoglobin diffusion on oxygen uptake and release by red cells. Respiratory Physiology 6(1): 1–15.
  • Yap, E., Hellums, J. (1987). Use of adiar four-step kinetics in mathematical simulation of oxygen transport in the microcirculation. Advanced Experimental Medical Biology 215: 193.
  • Federspiel, W.J., Popel, A.S. (1986). A theoretical-analysis of the effect of the particulate nature of blood on oxygen release in capillaries. Microvascular Research 32(2): 164–189.
  • Hay, P.D., Veitch, A.R., Gaylor, J.D.S. (2001). Oxygen transfer in a convection-enhanced hollow fiber bioartificial liver. Artificial Organs 25(2): 119–130.
  • Piret, J.M., Cooney, C.L. (1991). Model of oxygen-transport limitations in hollow fiber bioreactors. Biotechnology and Bioengineering 37(1): 80–92.
  • Katayama, S. , et al. (2001). Size-dependent in vivo growth potential of adult rat hepatocytes. American Journal of Pathology 158(1): 97–105.
  • Gordon, J., Dare, M., Palmer, A. (2005). Engineering select physical properties of cross-linked red blood cells and a simple a priori estimation of their efficacy as an oxygen delivery vehicle within the context of a hepatic hollow fiber bioreactor. Biotechnology Progress 21: 1700–1707.
  • Shatford, R.A. , et al. (1992). Hepatocyte function in a hollow fiber bioreactor – a potential bioartificial liver. The Journal of Surgincal Research 53(6): 549–557.
  • Nyberg, S.L. , et al. (1993). Extracorporeal application of a gel-entrapment, bioartificial liver - demonstration of drug-metabolism and other biochemical functions. Cell Transplantation 2(6): 441–452.
  • Kamlot, A. , et al. (1996). Review: Artificial liver support systems. Biotechnology and Bioengineering 50(4): 382–391.
  • Tsiaoussis, J. , et al. (2001). Which hepatocyte will it be? Hepatocyte choice for bioartificial liver support systems. Liver Transplantation 7(1): 2–10.
  • Scotto, J., Opolon, P., Eteve, J. (1973). Liver biopsy and prognosis in acute liver failure. Gut. 14: 927–933.
  • Tilles, A.W. , et al. (2001). Effects of oxygenation and flow on the viability and function of rat hepatocytes cocultured in a microchannel flat-plate bioreactor. Biotechnology and Bioengineering 73(5): 379–389.
  • Tanaka, Y. , et al. (2006). Evaluation of effects of shear stress on hepatocytes by a microchip based system. Measurement Science Technology 17: 3167–3170.
  • Fournier, R.L. (1999). Basic Transport Phenomena in Biomedical Engineering, Taylor & Francis: Philadelphia, p. 90.
  • Emery, A.N., Jan, D.C.H., Alrubeai, M. (1995). Oxygenation of intensive cell-culture system. Applied Microbiology and Biotechnology 43(6): 1028–1033.
  • Maeda, T. , et al. (2000). Preclinical evaluation of a hollow fiber silicone membrane oxygenator for extracorporeal membrane oxygenator application. ASAIO Journal 46(4): 426–430.
  • Freitas, R.A., Jr. (1999). Nanomedicine, Volume I: Basic Capabilities, Landes Bioscience: Georgetown, TX.
  • Gibson, Q. (1970). The reaction of oxygen with hemoglobin and the kinetic basis of the effect of salt on binding of oxygen. The Journal of Biological Chemistry 245(13): 3285–3288.
  • Popel, A.S. (1989). Theory of oxygen-transport to tissue. Critical Reviews in Biomedical Engineering 17(3): 257–321.
  • McCarthy, M.R. (2001). The role of facilitated diffusion in oxygen transport by cell-free hemoglobins: Implications for the design of hemoglobin-based oxygen carriers. Biophysical Chemistry 92(1–2): 117.

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