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Literature DB >> 21358040

Adipogenic differentiation of laser-printed 3D tissue grafts consisting of human adipose-derived stem cells.

M Gruene¹, M Pflaum, A Deiwick, L Koch, S Schlie, C Unger, M Wilhelmi, A Haverich, B N Chichkov.

Abstract

Laser-assisted bioprinting (LaBP) allows the realization of computer-generated 3D tissue grafts consisting of cells embedded in a hydrogel environment. In this study, human adipose-derived stem cells (hASCs) were printed in a free-scalable 3D grid pattern by means of LaBP. We demonstrate that neither the proliferation ability nor the differentiation behaviour of the stem cells was affected by the LaBP procedure. Furthermore, the 3D grafts were differentiated down the adipogenic lineage pathway for 10 days. We verify by quantitative assessments of adipogenic markers that the 3D grafts resemble cell lineages present in natural adipose tissue. Additionally, we provide the proof that even pre-differentiated hASCs could be utilized for the generation of 3D tissue grafts. These results indicate that the biofabrication of living grafts resembling their complex native origin is within reach.

Entities: Species

Mesh：

Year: 2011 PMID： 21358040 DOI： 10.1088/1758-5082/3/1/015005

Source DB: PubMed Journal: Biofabrication ISSN： 1758-5082 Impact factor: 9.954

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Cited

22 in total

1. Laser printing of three-dimensional multicellular arrays for studies of cell-cell and cell-environment interactions.

Authors: Martin Gruene; Michael Pflaum; Christian Hess; Stefanos Diamantouros; Sabrina Schlie; Andrea Deiwick; Lothar Koch; Mathias Wilhelmi; Stefan Jockenhoevel; Axel Haverich; Boris Chichkov
Journal: Tissue Eng Part C Methods Date: 2011-06-29 Impact factor: 3.056

2. Development and Characterization of a Porcine Mitral Valve Scaffold for Tissue Engineering.

Authors: M Granados; L Morticelli; S Andriopoulou; P Kalozoumis; M Pflaum; P Iablonskii; B Glasmacher; M Harder; J Hegermann; C Wrede; I Tudorache; S Cebotari; A Hilfiker; A Haverich; Sotirios Korossis
Journal: J Cardiovasc Transl Res Date: 2017-05-01 Impact factor: 4.132

3. 3D-printable self-healing and mechanically reinforced hydrogels with host-guest non-covalent interactions integrated into covalently linked networks.

Authors: Zhifang Wang; Geng An; Ye Zhu; Xuemin Liu; Yunhua Chen; Hongkai Wu; Yingjun Wang; Xuetao Shi; Chuanbin Mao
Journal: Mater Horiz Date: 2019-01-09 Impact factor: 13.266

Review 4. 3D bioprinting for engineering complex tissues.

Authors: Christian Mandrycky; Zongjie Wang; Keekyoung Kim; Deok-Ho Kim
Journal: Biotechnol Adv Date: 2015-12-23 Impact factor: 14.227

Review 5. Bioprinting for stem cell research.

Authors: Savas Tasoglu; Utkan Demirci
Journal: Trends Biotechnol Date: 2012-12-19 Impact factor: 19.536

Review 6. 3D bioprinting using stem cells.

Authors: Chin Siang Ong; Pooja Yesantharao; Chen Yu Huang; Gunnar Mattson; Joseph Boktor; Takuma Fukunishi; Huaitao Zhang; Narutoshi Hibino
Journal: Pediatr Res Date: 2017-11-01 Impact factor: 3.756

10. Tissue engineered skin substitutes created by laser-assisted bioprinting form skin-like structures in the dorsal skin fold chamber in mice.

Authors: Stefanie Michael; Heiko Sorg; Claas-Tido Peck; Lothar Koch; Andrea Deiwick; Boris Chichkov; Peter M Vogt; Kerstin Reimers
Journal: PLoS One Date: 2013-03-04 Impact factor: 3.240