Jiatian Chen, Yingwei Fan, Guozhao Dong et Huaijuan Zhou, « Designing biomimetic scaffolds for skin tissue engineering », Biomaterials Science, vol. 11, no 9, , p. 3051–3076 (ISSN2047-4849, PMID36970875, DOI10.1039/d3bm00046j, lire en ligne, consulté le )
(en) I. Klabukov, T. Tenchurin, A. Shepelev et D. Baranovskii, « Biomechanical Behaviors and Degradation Properties of Multilayered Polymer Scaffolds: The Phase Space Method for Bile Duct Design and Bioengineering », Biomedicines, vol. 11, no 3, , p. 745 (ISSN2227-9059, PMID36979723, PMCIDPMC10044742, DOI10.3390/biomedicines11030745, lire en ligne, consulté le )
(en) F. Oberpenning, J. Meng, J. J. Yoo et A. Atala, « De novo reconstitution of a functional mammalian urinary bladder by tissue engineering », Nature Biotechnology, vol. 17, no 2, , p. 149–155 (ISSN1087-0156, PMID10052350, DOI10.1038/6146, lire en ligne, consulté le )
(en) D. Baranovskii, J. Demner, S. Nürnberger et A. Lyundup, « Engineering of Tracheal Grafts Based on Recellularization of Laser-Engraved Human Airway Cartilage Substrates », Cartilage, vol. 13, no 1, , p. 19476035221075951 (ISSN1947-6043, PMID35189712, PMCID9137320, DOI10.1177/19476035221075951, lire en ligne, consulté le )
Nicolas L'Heureux, Todd N. McAllister et Luis M. de la Fuente, « Tissue-engineered blood vessel for adult arterial revascularization », The New England Journal of Medicine, vol. 357, no 14, , p. 1451–1453 (ISSN1533-4406, PMID17914054, DOI10.1056/NEJMc071536, lire en ligne, consulté le )
Jiatian Chen, Yingwei Fan, Guozhao Dong et Huaijuan Zhou, « Designing biomimetic scaffolds for skin tissue engineering », Biomaterials Science, vol. 11, no 9, , p. 3051–3076 (ISSN2047-4849, PMID36970875, DOI10.1039/d3bm00046j, lire en ligne, consulté le )
(en) I. Klabukov, T. Tenchurin, A. Shepelev et D. Baranovskii, « Biomechanical Behaviors and Degradation Properties of Multilayered Polymer Scaffolds: The Phase Space Method for Bile Duct Design and Bioengineering », Biomedicines, vol. 11, no 3, , p. 745 (ISSN2227-9059, PMID36979723, PMCIDPMC10044742, DOI10.3390/biomedicines11030745, lire en ligne, consulté le )
(en) F. Oberpenning, J. Meng, J. J. Yoo et A. Atala, « De novo reconstitution of a functional mammalian urinary bladder by tissue engineering », Nature Biotechnology, vol. 17, no 2, , p. 149–155 (ISSN1087-0156, PMID10052350, DOI10.1038/6146, lire en ligne, consulté le )
(en) D. Baranovskii, J. Demner, S. Nürnberger et A. Lyundup, « Engineering of Tracheal Grafts Based on Recellularization of Laser-Engraved Human Airway Cartilage Substrates », Cartilage, vol. 13, no 1, , p. 19476035221075951 (ISSN1947-6043, PMID35189712, PMCID9137320, DOI10.1177/19476035221075951, lire en ligne, consulté le )
Nicolas L'Heureux, Todd N. McAllister et Luis M. de la Fuente, « Tissue-engineered blood vessel for adult arterial revascularization », The New England Journal of Medicine, vol. 357, no 14, , p. 1451–1453 (ISSN1533-4406, PMID17914054, DOI10.1056/NEJMc071536, lire en ligne, consulté le )
nih.gov
ncbi.nlm.nih.gov
Jiatian Chen, Yingwei Fan, Guozhao Dong et Huaijuan Zhou, « Designing biomimetic scaffolds for skin tissue engineering », Biomaterials Science, vol. 11, no 9, , p. 3051–3076 (ISSN2047-4849, PMID36970875, DOI10.1039/d3bm00046j, lire en ligne, consulté le )
(en) I. Klabukov, T. Tenchurin, A. Shepelev et D. Baranovskii, « Biomechanical Behaviors and Degradation Properties of Multilayered Polymer Scaffolds: The Phase Space Method for Bile Duct Design and Bioengineering », Biomedicines, vol. 11, no 3, , p. 745 (ISSN2227-9059, PMID36979723, PMCIDPMC10044742, DOI10.3390/biomedicines11030745, lire en ligne, consulté le )
(en) F. Oberpenning, J. Meng, J. J. Yoo et A. Atala, « De novo reconstitution of a functional mammalian urinary bladder by tissue engineering », Nature Biotechnology, vol. 17, no 2, , p. 149–155 (ISSN1087-0156, PMID10052350, DOI10.1038/6146, lire en ligne, consulté le )
(en) D. Baranovskii, J. Demner, S. Nürnberger et A. Lyundup, « Engineering of Tracheal Grafts Based on Recellularization of Laser-Engraved Human Airway Cartilage Substrates », Cartilage, vol. 13, no 1, , p. 19476035221075951 (ISSN1947-6043, PMID35189712, PMCID9137320, DOI10.1177/19476035221075951, lire en ligne, consulté le )
Nicolas L'Heureux, Todd N. McAllister et Luis M. de la Fuente, « Tissue-engineered blood vessel for adult arterial revascularization », The New England Journal of Medicine, vol. 357, no 14, , p. 1451–1453 (ISSN1533-4406, PMID17914054, DOI10.1056/NEJMc071536, lire en ligne, consulté le )
pubmed.ncbi.nlm.nih.gov
Jiatian Chen, Yingwei Fan, Guozhao Dong et Huaijuan Zhou, « Designing biomimetic scaffolds for skin tissue engineering », Biomaterials Science, vol. 11, no 9, , p. 3051–3076 (ISSN2047-4849, PMID36970875, DOI10.1039/d3bm00046j, lire en ligne, consulté le )
(en) I. Klabukov, T. Tenchurin, A. Shepelev et D. Baranovskii, « Biomechanical Behaviors and Degradation Properties of Multilayered Polymer Scaffolds: The Phase Space Method for Bile Duct Design and Bioengineering », Biomedicines, vol. 11, no 3, , p. 745 (ISSN2227-9059, PMID36979723, PMCIDPMC10044742, DOI10.3390/biomedicines11030745, lire en ligne, consulté le )
(en) F. Oberpenning, J. Meng, J. J. Yoo et A. Atala, « De novo reconstitution of a functional mammalian urinary bladder by tissue engineering », Nature Biotechnology, vol. 17, no 2, , p. 149–155 (ISSN1087-0156, PMID10052350, DOI10.1038/6146, lire en ligne, consulté le )
(en) D. Baranovskii, J. Demner, S. Nürnberger et A. Lyundup, « Engineering of Tracheal Grafts Based on Recellularization of Laser-Engraved Human Airway Cartilage Substrates », Cartilage, vol. 13, no 1, , p. 19476035221075951 (ISSN1947-6043, PMID35189712, PMCID9137320, DOI10.1177/19476035221075951, lire en ligne, consulté le )
Nicolas L'Heureux, Todd N. McAllister et Luis M. de la Fuente, « Tissue-engineered blood vessel for adult arterial revascularization », The New England Journal of Medicine, vol. 357, no 14, , p. 1451–1453 (ISSN1533-4406, PMID17914054, DOI10.1056/NEJMc071536, lire en ligne, consulté le )
Lam, C. X. F., Mo, X. M., Teoh, S. H., & Hutmacher, D. W. (2002). Scaffold development using 3D printing with a starch-based polymer. Materials Science and Engineering: C, 20(1), 49-56. (résumé)