Feeling incredibly fortunate to have worked with such an amazing team! Motion Blur #Microscopy offers extreme sensitivity and high temporal resolution, perfect for studying #CellAdhesion mechanisms in controlled whole blood flow. Plus, it requires a minimal microscopy setup
Thrilled to share our new paper published today in
@NatureComms: "Motion blur microscopy: in vitro imaging of cell adhesion dynamics in whole blood flow"
Motion Blur Microscopy (MBM) integrates microfluidics and light microscopy with #AI to provide a low cost, easy to implement alternative to intravital microscopy. We use MBM for visualizing cellular interactions, adhesion, and motility in whole blood flow. MBM is generalizable to studies of various diseases, including blood disorders, cancer, thrombosis, inflammatory and autoimmune diseases. MBM provides rich datasets for theoretical modeling of cellular adhesion dynamics in complex media.
Congratulations to all authors: @utkugoreke, Ayesha Gonzales, Brandon Shipley, Madeleine Tincher, @oshin_1309, @WWulftange, @YunchengMan, @RanAnPhD, @hinczewskilab@cwru, @CaseEngineer, @CWRUartsci, @PhysicsCWRU, @CWRU_MAE
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https://t.co/zfrzpQxZyz
New Preprint! Excited to be part of this work where @utkugoreke lead a collaboration between the @UAGurkan Lab the @hinczewskilab Lab to develop a novel method of imaging adherent cells in whole blood, despite the high opacity ๐ฌ๐ฉธ
https://t.co/bep0HDd0AN
New #preprint just dropped led by @UAGurkan and @hinczewskilab.
We used SMR-TIRM to track the dynamics of a red blood cell adhering/releasing to/from a surface.
This is super cool and a great example of the interdisciplinary research @cwru@CaseEngineer@CWRUartsci!