P041 Data 20190921.xlsx (49.05 kB)

Tissue ingrowth markedly reduces mechanical anisotropy and stiffness in fibre direction of highly aligned electrospun polyurethane scaffolds (data)

Version 2 2020-11-09, 07:06

Version 1 2019-09-23, 19:42

dataset

posted on 2020-11-09, 07:06 authored by Hugo Krynauw, Jannik Buescher, Josepha Koehne, Loes Verrijt, Georges Limbert, Neil Hamer Davies, Deon Bezuidenhout, Thomas FranzThomas Franz

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.

Funding

National Research Foundation, South Africa, Grant: SUR2008051000002

Inter-university Cape Heart Research Unit, South African Medical Research Council

Jahresstipendium S/08/10, Deutsche Herzstiftung

Matching Dissertation Grant, International Society of Biomechanics

History

Department/Unit

University of Cape Town

Usage metrics

Keywords

Electrospinning Elastic modulus stiffness Tissue engineering In Vivo Studies vascular prosthesis Subcutaneous Biological Engineering Biophysics Regenerative Medicine (incl. Stem Cells and Tissue Engineering)Biomaterials Polymers and Plastics

Licence

CC BY 4.0

Exports

RefWorks

BibTeX

Ref. manager

Endnote

DataCite

NLM