Dispersible oxygen microsensors map oxygen gradients in three-dimensional cell cultures

Sasha Cai Lesher-Pérez; Ge Ah Kim; Chuan Hsien Kuo; Brendan M. Leung; Sanda Mong; Taisuke Kojima; Christopher Moraes; M. D. Thouless; Gary D. Luker; Shuichi Takayama

doi:10.1039/c7bm00119c

Dispersible oxygen microsensors map oxygen gradients in three-dimensional cell cultures

Sasha Cai Lesher-Pérez, Ge Ah Kim, Chuan Hsien Kuo, Brendan M. Leung, Sanda Mong, Taisuke Kojima, Christopher Moraes, M. D. Thouless, Gary D. Luker, Shuichi Takayama

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47 Citas (Scopus)

Resumen

Phase fluorimetry, unlike the more commonly used intensity-based measurement, is not affected by differences in light paths from culture vessels or by optical attenuation through dense 3D cell cultures and hydrogels thereby minimizing dependence on signal intensity for accurate measurements. This work describes the use of phase fluorimetry on oxygen-sensor microbeads to perform oxygen measurements in different microtissue culture environments. In one example, cell spheroids were observed to deplete oxygen from the cell-culture medium filling the bottom of conventional microwells within minutes, whereas oxygen concentrations remained close to ambient levels for several days in hanging-drop cultures. By dispersing multiple oxygen microsensors in cell-laden hydrogels, we also mapped cell-generated oxygen gradients. The spatial oxygen mapping was sufficiently precise to enable the use of computational models of oxygen diffusion and uptake to give estimates of the cellular oxygen uptake rate and the half-saturation constant. The results show the importance of integrated design and analysis of 3D cell cultures from both biomaterial and oxygen supply aspects. While this paper specifically tests spheroids and cell-laden gel cultures, the described methods should be useful for measuring pericellular oxygen concentrations in a variety of biomaterials and culture formats.

Idioma original	English
Páginas (desde-hasta)	2106-2113
Número de páginas	8
Publicación	Biomaterials Science
Volumen	5
N.º	10
DOI	https://doi.org/10.1039/c7bm00119c
Estado	Published - oct. 2017
Publicado de forma externa	Sí

Nota bibliográfica

Funding Information:
This material is based upon work supported by the NIH (CA170198, AI116482) and the Defense Threat Reduction Agency (DTRA) and Space and Naval Warfare Command Pacific (SSC PACIFIC) under Contract no. N66001-13-C-2027 INteGrated Organoid Testing System (INGOTS), Wake Forest University. Support for some of the early developments of the microspheres was provided by NSF (CMMI-0700232). Any opinions, findings and conclusions or recommendations expressed in this material are those of the author(s) and do not necessarily reflect the views of the DTRA and SSC PACIFIC. SCLP was supported by an NSF Graduate Research Fellowship Program (DGE 1256260; ID: 2011101670) and the NIH Cellular Biotechnology Training Program (NIH GM008353). CM was supported by a Banting postdoctoral fellowship from the Natural Sciences and Engineering Research Council of Canada. TK is thankful for the Yoshida Scholarship. The authors would also like to thank Dr Joseph M. Labuz for useful discussion and thoughtful input, Priyan Weerappuli for help with MATLAB image processing, and Usha Kadiyala from J. Scott VanEpps lab (University of Michigan) and Prof. Joe Lo lab (University of Michigan) for the commercial O2 sensor measurements.

Publisher Copyright:
©2017 The Royal Society of Chemistry.

ASJC Scopus Subject Areas

Biomedical Engineering
General Materials Science

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title = "Dispersible oxygen microsensors map oxygen gradients in three-dimensional cell cultures",

abstract = "Phase fluorimetry, unlike the more commonly used intensity-based measurement, is not affected by differences in light paths from culture vessels or by optical attenuation through dense 3D cell cultures and hydrogels thereby minimizing dependence on signal intensity for accurate measurements. This work describes the use of phase fluorimetry on oxygen-sensor microbeads to perform oxygen measurements in different microtissue culture environments. In one example, cell spheroids were observed to deplete oxygen from the cell-culture medium filling the bottom of conventional microwells within minutes, whereas oxygen concentrations remained close to ambient levels for several days in hanging-drop cultures. By dispersing multiple oxygen microsensors in cell-laden hydrogels, we also mapped cell-generated oxygen gradients. The spatial oxygen mapping was sufficiently precise to enable the use of computational models of oxygen diffusion and uptake to give estimates of the cellular oxygen uptake rate and the half-saturation constant. The results show the importance of integrated design and analysis of 3D cell cultures from both biomaterial and oxygen supply aspects. While this paper specifically tests spheroids and cell-laden gel cultures, the described methods should be useful for measuring pericellular oxygen concentrations in a variety of biomaterials and culture formats.",

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note = "Funding Information: This material is based upon work supported by the NIH (CA170198, AI116482) and the Defense Threat Reduction Agency (DTRA) and Space and Naval Warfare Command Pacific (SSC PACIFIC) under Contract no. N66001-13-C-2027 INteGrated Organoid Testing System (INGOTS), Wake Forest University. Support for some of the early developments of the microspheres was provided by NSF (CMMI-0700232). Any opinions, findings and conclusions or recommendations expressed in this material are those of the author(s) and do not necessarily reflect the views of the DTRA and SSC PACIFIC. SCLP was supported by an NSF Graduate Research Fellowship Program (DGE 1256260; ID: 2011101670) and the NIH Cellular Biotechnology Training Program (NIH GM008353). CM was supported by a Banting postdoctoral fellowship from the Natural Sciences and Engineering Research Council of Canada. TK is thankful for the Yoshida Scholarship. The authors would also like to thank Dr Joseph M. Labuz for useful discussion and thoughtful input, Priyan Weerappuli for help with MATLAB image processing, and Usha Kadiyala from J. Scott VanEpps lab (University of Michigan) and Prof. Joe Lo lab (University of Michigan) for the commercial O2 sensor measurements. Publisher Copyright: {\textcopyright}2017 The Royal Society of Chemistry.",

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AU - Lesher-Pérez, Sasha Cai

AU - Kim, Ge Ah

AU - Kuo, Chuan Hsien

AU - Leung, Brendan M.

AU - Mong, Sanda

AU - Kojima, Taisuke

AU - Moraes, Christopher

AU - Thouless, M. D.

AU - Luker, Gary D.

AU - Takayama, Shuichi

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N2 - Phase fluorimetry, unlike the more commonly used intensity-based measurement, is not affected by differences in light paths from culture vessels or by optical attenuation through dense 3D cell cultures and hydrogels thereby minimizing dependence on signal intensity for accurate measurements. This work describes the use of phase fluorimetry on oxygen-sensor microbeads to perform oxygen measurements in different microtissue culture environments. In one example, cell spheroids were observed to deplete oxygen from the cell-culture medium filling the bottom of conventional microwells within minutes, whereas oxygen concentrations remained close to ambient levels for several days in hanging-drop cultures. By dispersing multiple oxygen microsensors in cell-laden hydrogels, we also mapped cell-generated oxygen gradients. The spatial oxygen mapping was sufficiently precise to enable the use of computational models of oxygen diffusion and uptake to give estimates of the cellular oxygen uptake rate and the half-saturation constant. The results show the importance of integrated design and analysis of 3D cell cultures from both biomaterial and oxygen supply aspects. While this paper specifically tests spheroids and cell-laden gel cultures, the described methods should be useful for measuring pericellular oxygen concentrations in a variety of biomaterials and culture formats.

AB - Phase fluorimetry, unlike the more commonly used intensity-based measurement, is not affected by differences in light paths from culture vessels or by optical attenuation through dense 3D cell cultures and hydrogels thereby minimizing dependence on signal intensity for accurate measurements. This work describes the use of phase fluorimetry on oxygen-sensor microbeads to perform oxygen measurements in different microtissue culture environments. In one example, cell spheroids were observed to deplete oxygen from the cell-culture medium filling the bottom of conventional microwells within minutes, whereas oxygen concentrations remained close to ambient levels for several days in hanging-drop cultures. By dispersing multiple oxygen microsensors in cell-laden hydrogels, we also mapped cell-generated oxygen gradients. The spatial oxygen mapping was sufficiently precise to enable the use of computational models of oxygen diffusion and uptake to give estimates of the cellular oxygen uptake rate and the half-saturation constant. The results show the importance of integrated design and analysis of 3D cell cultures from both biomaterial and oxygen supply aspects. While this paper specifically tests spheroids and cell-laden gel cultures, the described methods should be useful for measuring pericellular oxygen concentrations in a variety of biomaterials and culture formats.

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Dispersible oxygen microsensors map oxygen gradients in three-dimensional cell cultures

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