TY - GEN
T1 - A novel method for multiparameter physiological phenotype characterization at the single-cell level
AU - Kelbauskas, Laimonas
AU - Ashili, Shashanka
AU - Houkal, Jeff
AU - Smith, Dean
AU - Mohammadreza, Aida
AU - Lee, Kristen
AU - Kumar, Ashok
AU - Anis, Yasser
AU - Paulson, Tom
AU - Youngbull, Cody
AU - Tian, Yanqing
AU - Johnson, Roger
AU - Holl, Mark
AU - Meldrum, Deirdre
PY - 2011
Y1 - 2011
N2 - Non-genetic intercellular heterogeneity has been increasingly recognized as one of the key factors in a variety of core cellular processes including proliferation, stimulus response, carcinogenesis and drug resistance. Many diseases, including cancer, originate in a single or a few cells. Early detection and characterization of these abnormal cells can provide new insights into the pathogenesis and serve as a tool for better disease diagnosis and treatment. We report on a novel technology for multiparameter physiological phenotype characterization at the single-cell level. It is based on real-time measurements of concentrations of several metabolites by means of extracellular optical sensors in microchambers of sub-nL volume containing single cells. In its current configuration, the measurement platform features the capability to detect oxygen consumption rate and pH changes under normoxic and hypoxic conditions at the single-cell level. We have conceived, designed and developed a semi-automated method for single-cell manipulation and loading into microwells utilizing custom, high-precision fluid handling at the nanoliter scale. We present the results of a series of measurements of oxygen consumption rates (OCRs) of single human metaplastic esophageal epithelial cells. In addition, to assess the effects of cell-to-cell interactions, we have measured OCRs of two and three cells placed in a single well. The major advantages of the approach are a) multiplexed characterization of cell phenotype at the single-cell level, b) minimal invasiveness due to the distant positioning of sensors, and c) flexibility in terms of accommodating measurements of other metabolites or biomolecules of interest.
AB - Non-genetic intercellular heterogeneity has been increasingly recognized as one of the key factors in a variety of core cellular processes including proliferation, stimulus response, carcinogenesis and drug resistance. Many diseases, including cancer, originate in a single or a few cells. Early detection and characterization of these abnormal cells can provide new insights into the pathogenesis and serve as a tool for better disease diagnosis and treatment. We report on a novel technology for multiparameter physiological phenotype characterization at the single-cell level. It is based on real-time measurements of concentrations of several metabolites by means of extracellular optical sensors in microchambers of sub-nL volume containing single cells. In its current configuration, the measurement platform features the capability to detect oxygen consumption rate and pH changes under normoxic and hypoxic conditions at the single-cell level. We have conceived, designed and developed a semi-automated method for single-cell manipulation and loading into microwells utilizing custom, high-precision fluid handling at the nanoliter scale. We present the results of a series of measurements of oxygen consumption rates (OCRs) of single human metaplastic esophageal epithelial cells. In addition, to assess the effects of cell-to-cell interactions, we have measured OCRs of two and three cells placed in a single well. The major advantages of the approach are a) multiplexed characterization of cell phenotype at the single-cell level, b) minimal invasiveness due to the distant positioning of sensors, and c) flexibility in terms of accommodating measurements of other metabolites or biomolecules of interest.
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U2 - 10.1117/12.875483
DO - 10.1117/12.875483
M3 - Conference contribution
AN - SCOPUS:79954481966
SN - 9780819484390
T3 - Progress in Biomedical Optics and Imaging - Proceedings of SPIE
BT - Imaging, Manipulation, and Analysis of Biomolecules, Cells, and Tissues IX
T2 - Imaging, Manipulation, and Analysis of Biomolecules, Cells, and Tissues IX
Y2 - 22 January 2011 through 25 January 2011
ER -