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of 6
pro vyhledávání: '"Agnes Nagy-Mehesz"'
Autor:
Vince Beachley, Vladimir Kasyanov, Agnes Nagy-Mehesz, Russell Norris, Iveta Ozolanta, Martins Kalejs, Peteris Stradins, Leandra Baptista, Karina da Silva, Jose Grainjero, Xuejun Wen, Vladimir Mironov
Publikováno v:
Journal of Tissue Engineering, Vol 5 (2014)
Effective cell invasion into thick electrospun biomimetic scaffolds is an unsolved problem. One possible strategy to biofabricate tissue constructs of desirable thickness and material properties without the need for cell invasion is to use thin (
Externí odkaz:
https://doaj.org/article/b65fd9c80e064c07a9ef87081e0fa17b
Autor:
Zoltan Hajdu, Agnes Nagy Mehesz
Publikováno v:
Circulation Research. 121
Tissue engineered heart valve constructs (TEHVCs) are thought to be the solution for the increasing needs of heart valve replacements. Using decellularized xenograft valve matrices reseeded with autologous cells seems to fulfill the demands for durab
Publikováno v:
Annals of Biomedical Engineering. 42:1049-1061
Work described herein characterizes tissues formed using scaffold-free, non-adherent systems and investigates their utility in modular approaches to tissue engineering. Immunofluorescence analysis revealed that all tissues formed using scaffold-free,
Autor:
Zoltan Hajdu, Albert Hagège, Agnes Nagy Mehesz, Annemarieke de Vlaming, Kimberly Sauls, Adrian H. Chester, Susan A. Slaugenhaupt, Roger R. Markwald, Robert A. Levine, Richard P. Visconti, Russell A. Norris
Publikováno v:
Differentiation. 84:103-116
Atrioventricular valve development commences with an EMT event whereby endocardial cells transform into mesenchyme. The molecular events that induce this phenotypic change are well understood and include many growth factors, signaling components, and
Autor:
Agnes Nagy Mehesz, Roger R. Markwald, Zoltan Hajdu, Richard P. Visconti, Russell A. Norris, Vladimir Mironov
Publikováno v:
Journal of Tissue Engineering and Regenerative Medicine. 4:659-664
Organ printing or computer-aided robotic layer-by-layer additive biofabrication of thick three-dimensional (3D) living tissue constructs employing self-assembling tissue spheroids is a rapidly evolving alternative to classic solid scaffold-based appr
Autor:
Jose Grainjero, Xuejun Wen, Agnes Nagy-Mehesz, Vincent Beachley, Peteris Stradins, Karina da Silva, Martins Kalejs, Russell A. Norris, Iveta Ozolanta, Vladimir Kasyanov, Vladimir Mironov, Leandra Santos Baptista
Publikováno v:
Journal of Tissue Engineering
Journal of Tissue Engineering, Vol 5 (2014)
Journal of Tissue Engineering, Vol 5 (2014)
Effective cell invasion into thick electrospun biomimetic scaffolds is an unsolved problem. One possible strategy to biofabricate tissue constructs of desirable thickness and material properties without the need for cell invasion is to use thin (