![]() Staiger MP et al (2006) Magnesium and its alloys as orthopedic biomaterials: a review. Hollister SJ (2005) Porous scaffold design for tissue engineering. ![]() In: Regenerative medicine and tissue engineering-cells and biomaterials. Disponível em: ://WOS:000222465100019 >Ĭhang HI, Wang Y (2011) Cell responses to surface and architecture of tissue engineering scaffolds. Liu XH, Ma PX (2004) Polymeric scaffolds for bone tissue engineering. Disponível em: ://WOS:000376480500005 >ĭhandayuthapani B et al (2011) Polymeric scaffolds in tissue engineering application: a review. Xing RT et al (2016) An injectable self-assembling collagen-gold hybrid hydrogel for combinatorial antitumor photothermal/photodynamic therapy. Zhao X et al (2017) Antibacterial anti-oxidant electroactive injectable hydrogel as self-healing wound dressing with hemostasis and adhesiveness for cutaneous wound healing. Disponível em: ://WOS:000402514600001 >ĭutta RC, Dutta AK (2009) Cell-interactive 3D-scaffold advances and applications. Lachman N et al (2017) Synthesis of polymer bead nano-necklaces on aligned carbon nanotube scaffolds. Singh N et al (2016) Chitin and carbon nanotube composites as biocompatible scaffolds for neuron growth. Neufurth M et al (2017) 3D printing of hybrid biomaterials for bone tissue engineering: calcium-polyphosphate microparticles encapsulated by polycaprolactone. Lee WD et al (2017) Sol gel-derived hydroxyapatite films over porous calcium polyphosphate substrates for improved tissue engineering of osteochondral-like constructs. ![]() Jakobsson A et al (2017) Three-dimensional functional human neuronal networks in uncompressed low-density electrospun fiber scaffolds. Naahidi S et al (2017) Biocompatibility of hydrogel-based scaffolds for tissue engineering applications. Poursamar SA et al (2016) The effects of crosslinkers on physical, mechanical, and cytotoxic properties of gelatin sponge prepared via in-situ gas foaming method as a tissue engineering scaffold. Kim YS et al (2019) An overview of the tissue engineering market in the United States from 2011 to 2018. In: 12th international conference of the international-society-for-scientometrics-and-informetrics, Rio de Janeiro, Brazil, 14–17 July 2009, pp 886–897 Van Eck NJ, Waltman L (2009) VOSviewer: a computer program for bibliometric mapping. ISSN 1536-0644Ĭross LM et al (2016) Nanoengineered biomaterials for repair and regeneration of orthopedic tissue interfaces. Disponível em: ://WOS:000167221200001 >īarnett JR, Pomeroy GC (2007) Use of platelet-rich plasma and bone marrow-derived mesenchymal stem cells in foot and ankle surgery. Pract Pain Manage 8(1):11–26Īgrawal CM, Ray RB (2001) Biodegradable polymeric scaffolds for musculoskeletal tissue engineering. ![]() Disponível em: ://WOS:A1993LB79100031 >Ĭrane D, Everts P (2008) Platelet rich plasma (PRP) matrix grafts. Langer R, Vacanti JP (1993) Tissue engineering. Based on a bibliometric study covering the last three decades of scientific research in scaffolds, this review will address the existing types of scaffolds (solid and fluid) the necessary scaffold properties for adequate tissue regeneration, such as biocompatibility and adequate mechanical properties the materials that can be used to manufacture the scaffold, from metals to natural and synthetic polymers scaffold fabrication techniques, considering their advantages and disadvantages and which are the main selection criteria and finally, the methods of scaffold characterization, such as chemical, morphological, mechanical, and biological. Tissue engineering is mainly based on obtaining biodegradable three-dimensional (3D) scaffolds. Given the constant lack of donors for organ transplantation, tissue engineering has been considered a very important tool for regenerative medicine to overcome the limitations of conventional treatments.
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