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Mimicking blood and lymphatic vasculatures using microfluidic systems.

Eva HallKailee MendiolaN Keilany LightseyDonny Hanjaya-Putra
Published in: Biomicrofluidics (2024)
The role of the circulatory system, containing the blood and lymphatic vasculatures, within the body, has become increasingly focused on by researchers as dysfunction of either of the systems has been linked to serious complications and disease. Currently, in vivo models are unable to provide the sufficient monitoring and level of manipulation needed to characterize the fluidic dynamics of the microcirculation in blood and lymphatic vessels; thus in vitro models have been pursued as an alternative model. Microfluidic devices have the required properties to provide a physiologically relevant circulatory system model for research as well as the experimental tools to conduct more advanced research analyses of microcirculation flow. In this review paper, the physiological behavior of fluid flow and electrical communication within the endothelial cells of the systems are detailed and discussed to highlight their complexities. Cell co-culturing methods and other relevant organ-on-a-chip devices will be evaluated to demonstrate the feasibility and relevance of the in vitro microfluidic model. Microfluidic systems will be determined as a noteworthy model that can display physiologically relevant flow of the cardiovascular and lymphatic systems, which will enable researchers to investigate the systems' prevalence in diseases and identify potential therapeutics.
Keyphrases
  • single cell
  • high throughput
  • circulating tumor cells
  • lymph node
  • endothelial cells
  • risk factors
  • oxidative stress
  • risk assessment
  • bone marrow
  • mesenchymal stem cells
  • label free