1. Radial Flow Perfusion Enables Real-Time Profiling of Cellular Metabolism at Low Oxygen Levels with Hyperpolarized 13C NMR Spectroscopy
- Author
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Enri Profka, Rahim R. Rizi, Anthony A. Mancuso, Stephen Kadlecek, Ryan M. Kiefer, Michael Noji, Mehrdad Pourfathi, Terence P. Gade, Charles N. Weber, Sarmad Siddiqui, and Austin R. Pantel
- Subjects
cell immobilization ,Chemistry ,Endocrinology, Diabetes and Metabolism ,Oxygen transport ,NMR tube ,chemistry.chemical_element ,Nuclear magnetic resonance spectroscopy ,Metabolism ,Microbiology ,Biochemistry ,Oxygen ,QR1-502 ,perfusion ,microcarriers ,NMR spectroscopy ,radial flow ,oxygen transport ,Bioreactor ,Biophysics ,Radial flow ,DNP ,hyperpolarized 13C ,Molecular Biology ,Perfusion - Abstract
In this study, we describe new methods for studying cancer cell metabolism with hyperpolarized 13C magnetic resonance spectroscopy (HP 13C MRS) that will enable quantitative studies at low oxygen concentrations. Cultured hepatocellular carcinoma cells were grown on the surfaces of non-porous microcarriers inside an NMR spectrometer. They were perfused radially from a central distributer in a modified NMR tube (bioreactor). The oxygen level of the perfusate was continuously monitored and controlled externally. Hyperpolarized substrates were injected continuously into the perfusate stream with a newly designed system that prevented oxygen and temperature perturbations in the bioreactor. Computational and experimental results demonstrated that cell mass oxygen profiles with radial flow were much more uniform than with conventional axial flow. Further, the metabolism of HP [1-13C]pyruvate was markedly different between the two flow configurations, demonstrating the importance of avoiding large oxygen gradients in cell perfusion experiments.
- Published
- 2021
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