AI Article Synopsis
- Gas embolisms can block blood flow by forming tubular bubbles (Taylor bubbles) that obstruct microvessels, leading to ischemia.
- Researchers conducted experiments in microchannels at low Capillary numbers to observe how these bubbles affect blood flow and the behavior of red blood cells (RBCs).
- The presence of bubbles caused variations in cell-free layers (CFLs) around the bubbles, influencing local blood rheology and transport processes, which can affect bubble trapping and movement in the bloodstream.
Article Abstract
Gas embolisms can hinder blood flow and lead to occlusion of the vessels and ischemia. Bubbles in microvessels circulate as tubular bubbles (Taylor bubbles) and can be trapped, blocking the normal flow of blood. To understand how Taylor bubbles flow in microcirculation, in particular, how bubbles disturb the blood flow at the scale of blood cells, experiments were performed in microchannels at a low Capillary number. Bubbles moving with a stream of in vitro blood were filmed with the help of a high-speed camera. Cell-free layers (CFLs) were observed downstream of the bubble, near the microchannel walls and along the centerline, and their thicknesses were quantified. Upstream to the bubble, the cell concentration is higher and CFLs are less clear. While just upstream of the bubble the maximum RBC concentration happens at positions closest to the wall, downstream the maximum is in an intermediate region between the centerline and the wall. Bubbles within microchannels promote complex spatio-temporal variations of the CFL thickness along the microchannel with significant relevance for local rheology and transport processes. The phenomenon is explained by the flow pattern characteristic of low Capillary number flows. Spatio-temporal variations of blood rheology may have an important role in bubble trapping and dislodging.
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| http://dx.doi.org/10.1007/s10544-016-0138-z | DOI Listing |
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