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Biologiczne tusze do drukowania 3D narządów i tkanek
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Abstrakty
Biodrukowanie 3D jest technologią wykazującą duży potencjał w medycynie regeneracyjnej. Technologia umożliwia wytworzenie trójwymiarowych funkcjonalnych tkanek i sztucznych narządów w oparciu o odpowiednie tusze biologiczne. Przegląd dostarcza informacji o biotuszach stosowanych w technologii biodruku 3D. W najnowszych doniesieniach literaturowych uwzględniano podział biotuszy ze względu na ich zastosowanie w wytwarzaniu konkretnych tkanek i narządów. Główną uwagę zwrócono na biotusze przeznaczone do regeneracji tkanki chrzęstnej, kostnej oraz nerwowej. Ponadto zaprezentowano także najnowsze badania prowadzone w kierunku opracowania biotuszy stosowanych w odbudowie skóry, naczyń krwionośnych, a także wątroby. Słowa kluczowe: inżynieria tkankowa, biodrukowanie.
3D bioprinting is a technology which shows great potential in regenerative medicine. The technology enables the fabrication of 3D functional tissue and artificial organs based on suitable biological inks. This review provides information about the bioinks used in 3D bioprinting technology. Recent literature reports have considered the division of bioinks based on their application in the fabrication of specific tissues and organs. The main attention has been paid to bioinks designed for regeneration of cartilage, bone and nerve tissue. Moreover, the newest research on bioinks for skin, blood vessels and liver regeneration have been presented.
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Tom
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24--32
Opis fizyczny
Bibliogr. 88 poz., rys., tab.
Twórcy
autor
- Katedra Inżynierii Materiałowej, Wydział Inżynierii Materiałowej i Fizyki, Politechnika Krakowska, ul. Jana Pawła II 37, 31-864 Kraków
autor
- Katedra Inżynierii Materiałowej, Wydział Inżynierii Materiałowej i Fizyki, Politechnika Krakowska, ul. Jana Pawła II 37, 31-864 Kraków
Bibliografia
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- [33] Zhang Y., Yu Y., Akkouch A., Dababneh A., Dolati F., Ozbolat I.T.: In vitro study of directly bioprinted perfusable vasculature conduits. Biomaterials Science 3 (1) (2015) 134–143.
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- [35] Gao Q., He Y., Zhong Fu J., Liu A., Ma L.: Coaxial nozzle-assisted 3D bioprinting with built-in microchannels for nutrients delivery. Biomaterials 61 (2015) 203–215.
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- [40] Poldervaart M.T., Gremmels H., Van Deventer K., Fledderus J.O., Oner F.C., Verhaar M.C., Dhert W.J.A., Alblas J.: Prolonged presence of VEGF promotes vascularization in 3D bioprinted scaffolds with defined architecture. Journal of Controlled Release 184 (1) (2014) 58–66.
- [41] Gruene M., Pflaum M., Hess C., Diamantouros S., Schlie S., Deiwick A., Koch L., Wilhelmi M., Jockenhoevel S., Haverich A., Chichkov B.: Laser printing of three-dimensional multicellular arrays for studies of cell-cell and cell-environment interactions. Tissue Engineering – Part C: Methods 17 (10) (2011) 973–982.
- [42] Skardal A., Zhang J., Prestwich G.D.: Bioprinting vessel-like constructs using hyaluronan hydrogels crosslinked with tetrahedral polyethylene glycol tetracrylates. Biomaterials 31 (24) (2010) 6173–6181.
- [43] Prestwich G.D., Skardal A., Zhang J., McCoard L., Oottamasathien S.: Dynamically crosslinked gold nanoparticle-hyaluronan hydrogels. Advanced Materials 22 (42) (2010) 4736–4740.
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- [45] Rodero M.P., Khosrotehrani K.: Skin wound healing modulation by macrophages. International Journal of Clinical and Pxperimental pathology 7 (3) (2010) 643–653.
- [46] Kandiyali R., Thom H., Young A.E., Greenwood R., Welton N.J.: Cost-effectiveness and value of information analysis of a low-friction environment following skin graft in patients with burn injury. Pilot and Feasibility Studies 6 (1) (2020) 1–9.
- [47] Shimizu R., Kishi K.: Skin grafts. Hindawi Publishing Corporation 2012 (2011) 1–5.
- [48] Daikuara L.Y., Yue Z., Skropeta D., Wallace G.G.: In vitro characterisation of 3D printed platelet lysate-based bioink for potential application in skin tissue engineering. Acta Biomaterialia 123 (2021) 286–297.
- [49] Shi Y., Xing T.L., Zhang H.B., Yin R.X., Yang S.M., Wei J., Zhang W.J.: Tyrosinase-doped bioink for 3D bioprinting of living skin constructs. Biomedical Materials (Bristol) 13 (3) (2018).
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- [51] Michael S., Sorg H., Peck C.T., Koch L., Deiwick A., Chichkov B., Vogt P.M., Reimers K.: Tissue engineered skin substitutes created by laser-assisted bioprinting form skin-like structures in the dorsal skin fold chamber in mice. PLoS ONE 8 (3) (2013).
- [52] Lee V., Singh G., Trasatti J.P., Bjornsson C., Xu X., Tran T.N., Yoo S.S., Dai G., Karande P.: Design and fabrication of human skin by three-dimensional bioprinting. Tissue Engineering – Part C: Methods 20 (6) (2014) 473–484.
- [53] Lee S.J., Lee J.H., Park J., Kim W.D., Park S.A.: Fabrication of 3D printing scaffold with porcine skin decellularized bio-ink for soft tissue engineering. Materials 13 (16) (2020) 1–9.
- [54] Pourchet L.J., Thepot A., Albouy M., Courtial E.J., Boher A., Blum L.J., Marquette C.A.: Human skin 3D bioprinting using scaffold-free approach. Advanced Healthcare Materials 6 (4) (2017) 1–8.
- [55] Desanlis A., Albouy M., Rousselle P., Thépot A., Dos Santos M., Auxenfans C., Marquette C.: Validation of an implantable bioink using mechanical extraction of human skin cells. First steps to a 3D bioprinting treatment of deep second degree burn. Journal of Tissue Engineering and Regenerative Medicine 15 (1) (2021) 37–48.
- [56] Zidarič T., Milojević M., Gradišnik L., Kleinschek K.S., Maver U., Maver T.: Polysaccharide-based bioink formulation for 3D bioprinting of an in vitro model of the human dermis. Nanomaterials 10 (4) (2020) 1–19.
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- [60] Zhang J., Yun S., Karami A., Jing B., Zannettino A., Du Y., Zhang H.: 3D printing of a thermosensitive hydrogel for skin tissue engineering. A proof of concept study. Bioprinting 19 (2020) 00089.
- [61] Koyama Y., Brenner D.A.: Liver inflammation and fibrosis. Journal of Clinical Investigation 127 (1) (2017) 55–64.
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- [63] Rana A., Godfre E.: Outcomes in solid-organ transplantation. Texas Heart Institute Journal 46 (1) (2019) 75–76.
- [64] Mazzocchi A., Devarasetty M., Huntwork R., Sokre S., Skardal A.: Optimization of collagen type I-hyaluronan hybrid bioink for 3D bioprinted liver microenvironments. International Society for Biofabrication (2018) 11–14.
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Uwagi
Opracowanie rekordu ze środków MNiSW, umowa Nr 461252 w ramach programu "Społeczna odpowiedzialność nauki" - moduł: Popularyzacja nauki i promocja sportu (2021).
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-30cf1802-0bfb-4f66-adc4-386275e90cc9