%0 Generic %A Krynauw, Hugo %A Buescher, Jannik %A Koehne, Josepha %A Verrijt, Loes %A Limbert, Georges %A Davies, Neil Hamer %A Bezuidenhout, Deon %A Franz, Thomas %D 2019 %T Data: Tissue ingrowth markedly reduces mechanical anisotropy and stiffness in fibre direction of highly aligned electrospun polyurethane scaffolds %U https://zivahub.uct.ac.za/articles/dataset/Data_Tissue_ingrowth_markedly_reduces_mechanical_anisotropy_and_stiffness_in_fibre_direction_of_highly_aligned_electrospun_polyurethane_scaffolds/9888710 %R 10.25375/uct.9888710.v1 %2 https://zivahub.uct.ac.za/ndownloader/files/17776214 %K Electrospinning %K Elastic modulus %K stiffness %K Tissue engineering %K In Vivo Studies %K vascular prosthesis %K Subcutaneous %K Biological Engineering %K Biophysics %K Regenerative Medicine (incl. Stem Cells and Tissue Engineering) %K Biomaterials %K Polymers and Plastics %X The provided material represents the data for fibre diameter, fibre alignment, tissue ingrowth and mechanical properties of an tissue-engineering electrospun polymeric scaffold related to the article Krynauw H, Buescher J, Koehne J, Verrijt L, Limbert G, Davies NH, Bezuidenhout D, Franz T, Tissue ingrowth markedly reduces mechanical anisotropy and stiffness in fibre direction of highly aligned electrospun polyurethane scaffolds. bioRxiv, 2019: 779942.
%I University of Cape Town