A new approach for studying flow past transcatheter aortic valves includes turbulence and shear stress quantities that could help validate new cardiovascular device designs @ETH_en@Unispital_USZ@snsf_ch@Medtronic@BMESociety@SpringerNature
https://t.co/sDrc0A6wRl
A Princeton-led team of scientists and citizen scientists has made a massive step toward understanding the human brain by building a neuron-by-neuron and synapse-by-synapse roadmap through the brain of an adult fruit fly. 🧠
Mineralization in explanted bioprosthetic valves in relation to hemodynamic forces - an interdisciplinary study by E. Tsolaki @empa_ch@ETH and P. Corso @unibe (shared first authors) https://t.co/0lu8bTXiLQ
What is the role of bioprosthetic aortic valve design on hemodynamics?
See the new articles by @pascal_corso:
Part I: Flow configuration and vortex dynamics
https://t.co/dPnoDBFV3d
Part II: Spectral analysis and anisotropy
https://t.co/AtJcsyJxEe
Professor Inge Herrmann: Multiscale multimodal characterization and simulation of structural alterations in failed bioprosthetic heart valves @IngeKHerrmann@Empa_CH@ETH_en@LondonNanotech https://t.co/YQGWgSbxgp