Cell Migration in 1D and 2D Nanofiber Microenvironments

RT @NCIPhySci: .@DavidOddeLab @UMNCSE #PSON & collaborators @VTEngineering found that cells move faster in 1D vs. 2D geometries & a motor-c…

RT @NCIPhySci: .@DavidOddeLab @UMNCSE #PSON & collaborators @VTEngineering found that cells move faster in 1D vs. 2D geometries & a motor-c…

.@DavidOddeLab @UMNCSE #PSON & collaborators @VTEngineering found that cells move faster in 1D vs. 2D geometries & a motor-clutch based model could simulate #cellmigration in different environments @ https://t.co/2ylPmZJuVI. https://t.co/zob8PICbuH

RT @ABMEjournal: Fantastic cover art for the March issue. Cell migration is influenced by fiber geometry and can be simulated with a motor…

Fantastic cover art for the March issue. Cell migration is influenced by fiber geometry and can be simulated with a motor-clutch based model @Amrinder_Nain @DavidOddeLab @UMNews @BEAMvt @VTEngineering @BMESociety @SpringerNature https://t.co/pffwswL8jc h

RT @NCIPhySci: Researchers in @DavidOddeLab @UMNCSE #PSON & @VTEngineering found that cell migration in fibrotic environments can be explai…

RT @NCIPhySci: Researchers in @DavidOddeLab @UMNCSE #PSON & @VTEngineering found that cell migration in fibrotic environments can be explai…

RT @NCIPhySci: Researchers in @DavidOddeLab @UMNCSE #PSON & @VTEngineering found that cell migration in fibrotic environments can be explai…

RT @NCIPhySci: Researchers in @DavidOddeLab @UMNCSE #PSON & @VTEngineering found that cell migration in fibrotic environments can be explai…

Researchers in @DavidOddeLab @UMNCSE #PSON & @VTEngineering found that cell migration in fibrotic environments can be explained by a motor-clutch mechanism using integrated modeling & experimental analysis @ https://t.co/UvCttv1iuV https://t.co/c1l

Cells on the (nano)wire - Horacio’s paper on glioma migration in nanofiber environments with @Amrinder_Nain is now online in Annals of BME! @BMESociety https://t.co/WAoMqB8tCT