TY - JOUR
T1 - Microfluidics as a new tool in radiation biology
AU - Lacombe, Jerome
AU - Phillips, Shanna Leslie
AU - Zenhausern, Frederic
N1 - Funding Information: The authors received financial support from the following sponsors: FZ was supported by the Center for High-Throughput Minimally-Invasive Radiation Biodosimetry ( National Institute of Allergy and Infectious Diseases Grant U19 AI067773 ); JL received a fellowship from ARC (File No. SAE20140600948 ); SP received a 2015 scholarship from the Helios Education Foundation in Arizona . Publisher Copyright: © 2015 Elsevier Ireland Ltd.
PY - 2016/2/28
Y1 - 2016/2/28
N2 - Ionizing radiations interact with molecules at the cellular and molecular levels leading to several biochemical modifications that may be responsible for biological effects on tissue or whole organisms. The study of these changes is difficult because of the complexity of the biological response(s) to radiations and the lack of reliable models able to mimic the whole molecular phenomenon and different communications between the various cell networks, from the cell activation to the macroscopic effect at the tissue or organismal level. Microfluidics, the science and technology of systems that can handle small amounts of fluids in confined and controlled environment, has been an emerging field for several years. Some microfluidic devices, even at early stages of development, may already help radiobiological research by proposing new approaches to study cellular, tissue and total-body behavior upon irradiation. These devices may also be used in clinical biodosimetry since microfluidic technology is frequently developed for integrating complex bioassay chemistries into automated user-friendly, reproducible and sensitive analyses. In this review, we discuss the use, numerous advantages, and possible future of microfluidic technology in the field of radiobiology. We will also examine the disadvantages and required improvements for microfluidics to be fully practical in radiation research and to become an enabling tool for radiobiologists and radiation oncologists.
AB - Ionizing radiations interact with molecules at the cellular and molecular levels leading to several biochemical modifications that may be responsible for biological effects on tissue or whole organisms. The study of these changes is difficult because of the complexity of the biological response(s) to radiations and the lack of reliable models able to mimic the whole molecular phenomenon and different communications between the various cell networks, from the cell activation to the macroscopic effect at the tissue or organismal level. Microfluidics, the science and technology of systems that can handle small amounts of fluids in confined and controlled environment, has been an emerging field for several years. Some microfluidic devices, even at early stages of development, may already help radiobiological research by proposing new approaches to study cellular, tissue and total-body behavior upon irradiation. These devices may also be used in clinical biodosimetry since microfluidic technology is frequently developed for integrating complex bioassay chemistries into automated user-friendly, reproducible and sensitive analyses. In this review, we discuss the use, numerous advantages, and possible future of microfluidic technology in the field of radiobiology. We will also examine the disadvantages and required improvements for microfluidics to be fully practical in radiation research and to become an enabling tool for radiobiologists and radiation oncologists.
KW - Biodosimetry markers
KW - Cancer
KW - Microfluidics
KW - Organ-on-a-chip
KW - Radiation research
KW - Radiobiological models
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U2 - 10.1016/j.canlet.2015.11.033
DO - 10.1016/j.canlet.2015.11.033
M3 - Review article
C2 - 26704304
SN - 0304-3835
VL - 371
SP - 292
EP - 300
JO - Cancer Letters
JF - Cancer Letters
IS - 2
ER -