Nerve guide conduits(NGCs),as alternatives to nerve autografts and allografts,have been widely explored as an advanced tool for the treatment of peripheral nerve injury.However,the repairing efficiency of NGCs still n...Nerve guide conduits(NGCs),as alternatives to nerve autografts and allografts,have been widely explored as an advanced tool for the treatment of peripheral nerve injury.However,the repairing efficiency of NGCs still needs significant improvements.Functional NGCs that provide a more favorable microenvironment for promoting axonal elongation and myelination are of great importance.In recent years,3D printing technologies have been widely applied in the fabrication of customized and complex constructs,exhibiting great potential for tissue engineering applications,especially for the construction of functional NGCs.In this review,we introduce the 3D printing technologies for manufacturing functional NGCs,including inkjet printing,extrusion printing,stereolithographybased printing and indirect printing.Further,we summarize the current methods and strategies for constructing functional NGCs,such as designing special conduit architectures,using appropriate materials and co-printing with different biological cues.Finally,the challenges and prospects for construction of functional NGCs are also presented.展开更多
Extensive burns and full-thickness skin wounds are difficult to repair. Autologous split-thickness skin graft (ASSG) is still used as the gold standard in the clinic. However, the shortage of donor skin tissues is a s...Extensive burns and full-thickness skin wounds are difficult to repair. Autologous split-thickness skin graft (ASSG) is still used as the gold standard in the clinic. However, the shortage of donor skin tissues is a serious problem. A potential solution to this problem is to fabricate skin constructs using biomaterial scaffolds with or without cells. Bioprinting is being applied to address the need for skin tissues suitable for transplantation, and can lead to the development of skin equivalents for wound healing therapy. Here, we summarize strategies of bioprinting and review current advances of bioprinting of skin constructs. There will be challenges on the way of 3D bioprinting for skin regeneration, but we still believe bioprinting will be potential skills for wounds healing in the foreseeable future.展开更多
基金funded by 1.3.5 project for disciplines of excellence,West China Hospital,Sichuan University(ZYJC18017,ZYYC08007)China Postdoctoral Science Foundation(2020M673229)Post-Doctor Research Project,West China Hospital,Sichuan University(2020HXBH064,2020HXBH025).
文摘Nerve guide conduits(NGCs),as alternatives to nerve autografts and allografts,have been widely explored as an advanced tool for the treatment of peripheral nerve injury.However,the repairing efficiency of NGCs still needs significant improvements.Functional NGCs that provide a more favorable microenvironment for promoting axonal elongation and myelination are of great importance.In recent years,3D printing technologies have been widely applied in the fabrication of customized and complex constructs,exhibiting great potential for tissue engineering applications,especially for the construction of functional NGCs.In this review,we introduce the 3D printing technologies for manufacturing functional NGCs,including inkjet printing,extrusion printing,stereolithographybased printing and indirect printing.Further,we summarize the current methods and strategies for constructing functional NGCs,such as designing special conduit architectures,using appropriate materials and co-printing with different biological cues.Finally,the challenges and prospects for construction of functional NGCs are also presented.
基金grants from Administration of Traditional Chinese Medicine of Sichuan(A2016N48)National Natural Science Foundation of China(81171780)+4 种基金Foundation for Distinguished Young Scientists of Sichuan Province(2016JQ0020)Project sub topics of the National 863 Project(2015AA020303)Scientific research fund for outstanding young scholars of Sichuan University(2014SCU04A12)Sichuan province science and technology support plan(2015SZ0049)Science and technology support program of Sichuan Province(2015FZ0040).
文摘Extensive burns and full-thickness skin wounds are difficult to repair. Autologous split-thickness skin graft (ASSG) is still used as the gold standard in the clinic. However, the shortage of donor skin tissues is a serious problem. A potential solution to this problem is to fabricate skin constructs using biomaterial scaffolds with or without cells. Bioprinting is being applied to address the need for skin tissues suitable for transplantation, and can lead to the development of skin equivalents for wound healing therapy. Here, we summarize strategies of bioprinting and review current advances of bioprinting of skin constructs. There will be challenges on the way of 3D bioprinting for skin regeneration, but we still believe bioprinting will be potential skills for wounds healing in the foreseeable future.
