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Microfluidic Organ-on-a-Chip: Revolutionary Platforms for Disease Comprehension and Treatment
Nuno M. Neves , Owen Gareth Davies , Shang-Chun Guo , Shi-Cong Tao , Wei Seong Toh
Existing culture systems have a limited ability to reproduce the complicated and
dynamic microenvironment of a functioning organ. To solve the issues of conventional
culture techniques, multidisciplinary researchers, involving medical doctors, stem cell
and developmental biology experts, engineers and physical scientists, have emerged
to innovate methods and devices.
A microfluidic organ-on-a-chip (μOOC) is a cell culture device, based on microfluidic
technology, which contains continuously perfused chambers with cells to simulate
organ-level physiology/pathology. The μOOC is not to build a whole living organ,
but rather to synthesize minimal functional units that recapitulate organ-/tissue-level
functions. The μOOC can be applied to study not only the convention stimulation
on cells by molecular/drugs, but also physical forces (fluid shear stress, cyclic strain
and mechanical compression), organ-specific cell-cell intercommunication, and
organ-organ coupling responses.
There is an emerging need for innovative approaches for the production, control,
analysis, and utilization of the μOOC, and even the multiple interconnected μOOC
(Human-on-a-Chip). Although the μOOC has attracted much attention and is
continuous being studied, there are still many difficult problems to be solved.
Some of the most mentioned challenges include microenvironmental (biochemical,
biophysical, biomechanical, nutrient, etc.) control, modeling tissue–tissue and multiorgan
interactions, and reducing variability (automated control, high-throughput
manipulation/analysis, integration of biosensing and etc.).
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