Tissue engineering is a relatively new but rapidly developing field in the medical sciences. Noncoding RNAs(ncRNAs) are functional RNA molecules without a protein-coding function; they can regulate cellular behavior a...Tissue engineering is a relatively new but rapidly developing field in the medical sciences. Noncoding RNAs(ncRNAs) are functional RNA molecules without a protein-coding function; they can regulate cellular behavior and change the biological milieu of the tissue. The application of ncRNAs in tissue engineering is starting to attract increasing attention as a means of resolving a large number of unmet healthcare needs, although ncRNA-based approaches have not yet entered clinical practice. In-depth research on the regulation and delivery of ncRNAs may improve their application in tissue engineering.The aim of this review is: to outline essential ncRNAs that are related to tissue engineering for the repair and regeneration of nerve, skin, liver, vascular system, and muscle tissue; to discuss their regulation and delivery; and to anticipate their potential therapeutic applications.展开更多
Craniomaxillofacial(CMF)reconstruction is a challenging clinical dilemma.It often necessitates skin replacement in the form of autologous graft or flap surgery,which differ from one another based on hypodermal/dermal ...Craniomaxillofacial(CMF)reconstruction is a challenging clinical dilemma.It often necessitates skin replacement in the form of autologous graft or flap surgery,which differ from one another based on hypodermal/dermal content.Unfortunately,both approaches are plagued by scarring,poor cosmesis,inadequate restoration of native anatomy and hair,alopecia,donor site morbidity,and potential for failure.Therefore,new reconstructive approaches are warranted,and tissue engineered skin represents an exciting alternative.In this study,we demonstrated the reconstruction of CMF full-thickness skin defects using intraoperative bioprinting(IOB),which enabled the repair of defects via direct bioprinting of multiple layers of skin on immunodeficient rats in a surgical setting.Using a newly formulated patient-sourced allogenic bioink consisting of both human adipose-derived extracellular matrix(adECM)and stem cells(ADSCs),skin loss was reconstructed by precise deposition of the hypodermal and dermal components under three different sets of animal studies.adECM,even at a very low concentration such as 2%or less,has shown to be bioprintable via droplet-based bioprinting and exhibited de novo adipogenic capabilities both in vitro and in vivo.Our findings demonstrate that the combinatorial delivery of adECM and ADSCs facilitated the reconstruction of three full-thickness skin defects,accomplishing near-complete wound closure within two weeks.More importantly,both hypodermal adipogenesis and downgrowth of hair follicle-like structures were achieved in this two-week time frame.Our approach illustrates the translational potential of using human-derived materials and IOB technologies for full-thickness skin loss.展开更多
Bacterial infection and the ever-increasing bacterial resistance have imposed severe threat to human health.And bacterial contamination could significantly menace the wound healing process.Considering the sophisticate...Bacterial infection and the ever-increasing bacterial resistance have imposed severe threat to human health.And bacterial contamination could significantly menace the wound healing process.Considering the sophisticated wound healing process,novel strategies for skin tissue engineering are focused on the integration of bioactive ingredients,antibacterial agents included,into biomaterials with different morphologies to improve cell behaviors and promote wound healing.However,a comprehensive review on antibacterial wound dressing to enhance wound healing has not been reported.In this review,various antibacterial biomaterials as wound dressings will be discussed.Different kinds of antibacterial agents,including antibiotics,nanoparticles(metal and metallic oxides,lightinduced antibacterial agents),cationic organic agents,and others,and their recent advances are summarized.Biomaterial selection and fabrication of biomaterials with different structures and forms,including films,hydrogel,electrospun nanofibers,sponge,foam and three-dimension(3D)printed scaffold for skin regeneration,are elaborated discussed.Current challenges and the future perspectives are presented in thismultidisciplinary field.We envision that this review will provide a general insight to the elegant design and further refinement of wound dressing.展开更多
Current advances in basic stem cell research and tissue engineering augur well for the development of improved cultured skin tissue substitutes:a class of products that is still fraught with limitations for clinical u...Current advances in basic stem cell research and tissue engineering augur well for the development of improved cultured skin tissue substitutes:a class of products that is still fraught with limitations for clinical use.Although the ability to grow autologous keratinocytes in-vitro from a small skin biopsy into sheets of stratified epithelium(within 3 to 4 weeks)helped alleviate the problem of insufficient donor site for extensive burn,many burn units still have to grapple with insufficient skin allografts which are used as intermediate wound coverage after burn excision.Alternatives offered by tissue-engineered skin dermal replacements to meet emergency demand have been used fairly successfully.Despite the availability of these commercial products,they all suffer from the same problems of extremely high cost,sub-normal skin microstructure and inconsistent engraftment,especially in full thickness burns.Clinical practice for severe burn treatment has since evolved to incorporate these tissue-engineered skin substitutes,usually as an adjunct to speed up epithelization for wound closure and/or to improve quality of life by improving the functional and cosmetic results long-term.This review seeks to bring the reader through the beginnings of skin tissue engineering,the utilization of some of the key products developed for the treatment of severe burns and the hope of harnessing stem cells to improve on current practice.展开更多
The use of polymer based composites in the treatment of skin tissue damages,has got huge attention in clinical demand,which enforced the scientists to improve the methods of biopolymer designing in order to obtain hig...The use of polymer based composites in the treatment of skin tissue damages,has got huge attention in clinical demand,which enforced the scientists to improve the methods of biopolymer designing in order to obtain highly efficient system for complete restoration of damaged tissue.In last few decades,chitosan-based biomaterials have major applications in skin tissue engineering due to its biocompatible,hemostatic,antimicrobial and biodegradable capabilities.This article overviewed the promising biological properties of chitosan and further discussed the various preparation methods involved in chitosan-based biomaterials.In addition,this review also gave a comprehensive discussion of different forms of chitosan-based biomaterials including membrane,sponge,nanofiber and hydrogel that were extensively employed in skin tissue engineering.This review will help to form a base for the advanced applications of chitosan-based biomaterials in treatment of skin tissue damages.展开更多
Skin injury is repaired through a multi-phase wound healing process of tissue granulation and re-epithelialization.Any failure in the healing process may lead to chronic non-healing wounds or abnormal scar formation.A...Skin injury is repaired through a multi-phase wound healing process of tissue granulation and re-epithelialization.Any failure in the healing process may lead to chronic non-healing wounds or abnormal scar formation.Although significant progress has been made in developing novel scaffolds and/or cell-based therapeutic strategies to promote wound healing,effective management of large chronic skin wounds remains a clinical challenge.Keratinocytes are critical to re-epithelialization and wound healing.Here,we investigated whether exogenous keratinocytes,in combination with a citrate-based scaffold,enhanced skin wound healing.We first established reversibly immortalized mouse keratinocytes(iKera),and confirmed that the iKera cells expressed keratinocyte markers,and were responsive to UVB treatment,and were non-tumorigenic.In a proof-of-principle experiment,we demonstrated that iKera cells embedded in citrate-based scaffold PPCN provided more effective re-epithelialization and cutaneous wound healing than that of either PPCN or iKera cells alone,in a mouse skin wound model.Thus,these results demonstrate that iKera cells may serve as a valuable skin epithelial source when,combining with appropriate biocompatible scaffolds,to investigate cutaneous wound healing and skin regeneration.展开更多
Skin damage resulting from burns,injuries,or diseases can lead to significant functional and esthetic deficits.However,traditional treatments,such as skin grafting,have limitations including limited donor skin availab...Skin damage resulting from burns,injuries,or diseases can lead to significant functional and esthetic deficits.However,traditional treatments,such as skin grafting,have limitations including limited donor skin availability,poor aesthetics,and functional impairment.Skin tissue engineering provides a promising alternative,with engineered artificial skins offering a highly viable avenue.Engineered artificial skin is designed to mimic or replace the functions of natural human skin and find applications in various medical treatments,particularly for severe burns,chronic wounds,and other skin injuries or defects.These artificial skins aim to promote wound healing,provide temporary coverage,permanent skin replacement,and restore the skin’s barrier function.Artificial skins have diverse applications in medicine and wound care,addressing burns,chronic wounds,and traumatic injuries.They also serve as valuable tools for research in tissue engineering,offering experimental models for studying wound healing mechanisms,testing new biomaterials,and exploring innovative approaches to skin regeneration.This review provides an overview of current construction strategies for engineered artificial skin,including cell sources,biomaterials,and construction techniques.It further explores the primary application areas and future prospects of artificial skin,highlighting their potential to revolutionize skin reconstruction and advance the field of regenerative medicine.展开更多
Bioprinting has exhibited remarkable promises for the fabrication of functional skin substitutes.However,there are some significant challenges for the treatment of full-thickness skin defects in clinical practice.It i...Bioprinting has exhibited remarkable promises for the fabrication of functional skin substitutes.However,there are some significant challenges for the treatment of full-thickness skin defects in clinical practice.It is necessary to determine bioinks with suitable mechanical properties and desirable biocompatibilities.Additionally,the key for printing skin is to design the skin structure optimally,enabling the function of the skin.In this study,the full-thickness skin scaffolds were prepared with a gradient pore structure constructing the dense layer,epidermis,and dermis by different ratios of bioinks.We hypothesized that the dense layer protects the wound surface and maintains a moist environment on the wound surface.By developing a suitable hydrogel bioink formulation(sodium alginate/gelatin/collagen),to simulate the physiological structure of the skin via 3D printing,the proportion of hydrogels was optimized corresponding to each layer.These results reveal that the scaffold has interconnected macroscopic channels,and sodium alginate/gelatin/collagen scaffolds accelerated wound healing,reduced skin wound contraction,and re-epithelialization in vivo.It is expected to provide a rapid and economical production method of skin scaffolds for future clinical applications.展开更多
Skin tissue engineering with considerable skin regeneration capability is an urgent need for the wound site.The current challenge for researchers is to develop a bionic scaffold that imitates the extracellular matrix ...Skin tissue engineering with considerable skin regeneration capability is an urgent need for the wound site.The current challenge for researchers is to develop a bionic scaffold that imitates the extracellular matrix for the regeneration of the damaged regions.In our study,poly(L-lactide-co-caprolactone)(PLCL)was blended with polyurethane(PU)to obtain nanofibrous scaffolds via electrospinning.The electrospun fibers with 50%PLCL content had a certain number of intersections and jointing points,and exhibited significantly enhanced mechani-cal properties combined with suitable porosity.Moreover,cell activities demonstrated that PU/PLCL membranes had significantly biological advantages in enhanced growth of human skin fibroblasts with spreading morphology compared with PU membranes,indicating good cytocompatibility of composite scaffolds.These findings proved that PU/PLCL electrospun membranes have great potential in applications of skin tissue engineering.展开更多
One of the leading causes of wound healing delays is bacterial infection,which limits the process of restoring the histological and functional integrity of the skin.Electrospun nanofibrous materials(ENMs)are biocompat...One of the leading causes of wound healing delays is bacterial infection,which limits the process of restoring the histological and functional integrity of the skin.Electrospun nanofibrous materials(ENMs)are biocompatible and biodegradable,and they can provide specific physical,chemical,and biological cues to accelerate wound healing.Based on this fact,a series of multifunctional ENMs for complex clinical applications,particularly infected skin injuries,have been developed.Anti-biotics,antimicrobial peptides(AMPs),metals and metal oxides(MMOs),and antibacterial polymers have previously been incorporated into ENMs through advanced material processing techniques,endowing ENMs with enhanced and excellent antibacterial activity.This review summarizes wound healing issues and provides recent advances in antibacterial ENMs created by cutting-edge technology.The future of clinical and translational research on ENMs is also discussed.展开更多
Hydrogel wound dressings can play critical roles in wound healing protecting the wound from trauma or contamination and providing an ideal environment to support the growth of endogenous cells and promote wound closur...Hydrogel wound dressings can play critical roles in wound healing protecting the wound from trauma or contamination and providing an ideal environment to support the growth of endogenous cells and promote wound closure.This work presents a self-assembling hydrogel dressing that can assist the wound repair process mimicking the hierarchical structure of skin extracellular matrix.To this aim,the co-assembly behaviour of a carboxylated variant of xyloglucan(CXG)with a peptide amphiphile(PA-H3)has been investigated to generate hierarchical constructs with tuneable molecular composition,structure,and properties.Transmission electron microscopy and circular dichroism at a low concentration shows that CXG and PA-H3 co-assemble into nanofibres by hydrophobic and electrostatic interactions and further aggregate into nanofibre bundles and networks.At a higher concentration,CXG and PA-H3 yield hydrogels that have been characterized for their morphology by scanning electron microscopy and for the mechanical properties by smallamplitude oscillatory shear rheological measurements and compression tests at different CXG/PAH3 ratios.A preliminary biological evaluation has been carried out both in vitro with HaCat cells and in vivo in a mouse model.展开更多
基金This work was supported by the National Basic Research Program of China (973 Program, 2014CB542202), the National HiTech Research and Development Program of China (863 Program, 2012AA020502), the National Natural Science Foundation of China (81130080 and 31300879), and the Key University Science Research Project of Jiangsu Province (16KJA310005). It was also a project funded by the Priority Academic Program Development of Jiangsu Higher Education Institutions (PAPD).
文摘Tissue engineering is a relatively new but rapidly developing field in the medical sciences. Noncoding RNAs(ncRNAs) are functional RNA molecules without a protein-coding function; they can regulate cellular behavior and change the biological milieu of the tissue. The application of ncRNAs in tissue engineering is starting to attract increasing attention as a means of resolving a large number of unmet healthcare needs, although ncRNA-based approaches have not yet entered clinical practice. In-depth research on the regulation and delivery of ncRNAs may improve their application in tissue engineering.The aim of this review is: to outline essential ncRNAs that are related to tissue engineering for the repair and regeneration of nerve, skin, liver, vascular system, and muscle tissue; to discuss their regulation and delivery; and to anticipate their potential therapeutic applications.
基金supported by National Institutes of Health Award R01DE028614,R56HL157190,R21AR082668,and R01AR078743,and 2236 CoCirculation2 of TUBITAK award 121C359.
文摘Craniomaxillofacial(CMF)reconstruction is a challenging clinical dilemma.It often necessitates skin replacement in the form of autologous graft or flap surgery,which differ from one another based on hypodermal/dermal content.Unfortunately,both approaches are plagued by scarring,poor cosmesis,inadequate restoration of native anatomy and hair,alopecia,donor site morbidity,and potential for failure.Therefore,new reconstructive approaches are warranted,and tissue engineered skin represents an exciting alternative.In this study,we demonstrated the reconstruction of CMF full-thickness skin defects using intraoperative bioprinting(IOB),which enabled the repair of defects via direct bioprinting of multiple layers of skin on immunodeficient rats in a surgical setting.Using a newly formulated patient-sourced allogenic bioink consisting of both human adipose-derived extracellular matrix(adECM)and stem cells(ADSCs),skin loss was reconstructed by precise deposition of the hypodermal and dermal components under three different sets of animal studies.adECM,even at a very low concentration such as 2%or less,has shown to be bioprintable via droplet-based bioprinting and exhibited de novo adipogenic capabilities both in vitro and in vivo.Our findings demonstrate that the combinatorial delivery of adECM and ADSCs facilitated the reconstruction of three full-thickness skin defects,accomplishing near-complete wound closure within two weeks.More importantly,both hypodermal adipogenesis and downgrowth of hair follicle-like structures were achieved in this two-week time frame.Our approach illustrates the translational potential of using human-derived materials and IOB technologies for full-thickness skin loss.
基金supported by the National Natural Science Foundation of China (grant numbers: 51973172)Natural Science Foundation of Shaanxi Province (No. 2020JC03 and 2019TD-020)+2 种基金State Key Laboratory for Mechanical Behavior of Materials, and Opening Project of Key Laboratory of Shaanxi Province for Craniofacial Precision Medicine Research, College of Stomatology, Xi’an Jiaotong University (No. 2019LHM-KFKT008)the World-Class Universities (Disciplines)the Characteristic Development Guidance Funds for the Central Universities
文摘Bacterial infection and the ever-increasing bacterial resistance have imposed severe threat to human health.And bacterial contamination could significantly menace the wound healing process.Considering the sophisticated wound healing process,novel strategies for skin tissue engineering are focused on the integration of bioactive ingredients,antibacterial agents included,into biomaterials with different morphologies to improve cell behaviors and promote wound healing.However,a comprehensive review on antibacterial wound dressing to enhance wound healing has not been reported.In this review,various antibacterial biomaterials as wound dressings will be discussed.Different kinds of antibacterial agents,including antibiotics,nanoparticles(metal and metallic oxides,lightinduced antibacterial agents),cationic organic agents,and others,and their recent advances are summarized.Biomaterial selection and fabrication of biomaterials with different structures and forms,including films,hydrogel,electrospun nanofibers,sponge,foam and three-dimension(3D)printed scaffold for skin regeneration,are elaborated discussed.Current challenges and the future perspectives are presented in thismultidisciplinary field.We envision that this review will provide a general insight to the elegant design and further refinement of wound dressing.
基金The authors are deeply saddened by the recent passing(2nd November 2015)of Professor Howard Greenthe pioneer of cultured skin cell therapy.The authors are always grateful to him for his help and the gift of 3T3-J2 which made possible the use of cultured epithelial autografts to treat severe burn injuries in Singapore
文摘Current advances in basic stem cell research and tissue engineering augur well for the development of improved cultured skin tissue substitutes:a class of products that is still fraught with limitations for clinical use.Although the ability to grow autologous keratinocytes in-vitro from a small skin biopsy into sheets of stratified epithelium(within 3 to 4 weeks)helped alleviate the problem of insufficient donor site for extensive burn,many burn units still have to grapple with insufficient skin allografts which are used as intermediate wound coverage after burn excision.Alternatives offered by tissue-engineered skin dermal replacements to meet emergency demand have been used fairly successfully.Despite the availability of these commercial products,they all suffer from the same problems of extremely high cost,sub-normal skin microstructure and inconsistent engraftment,especially in full thickness burns.Clinical practice for severe burn treatment has since evolved to incorporate these tissue-engineered skin substitutes,usually as an adjunct to speed up epithelization for wound closure and/or to improve quality of life by improving the functional and cosmetic results long-term.This review seeks to bring the reader through the beginnings of skin tissue engineering,the utilization of some of the key products developed for the treatment of severe burns and the hope of harnessing stem cells to improve on current practice.
文摘The use of polymer based composites in the treatment of skin tissue damages,has got huge attention in clinical demand,which enforced the scientists to improve the methods of biopolymer designing in order to obtain highly efficient system for complete restoration of damaged tissue.In last few decades,chitosan-based biomaterials have major applications in skin tissue engineering due to its biocompatible,hemostatic,antimicrobial and biodegradable capabilities.This article overviewed the promising biological properties of chitosan and further discussed the various preparation methods involved in chitosan-based biomaterials.In addition,this review also gave a comprehensive discussion of different forms of chitosan-based biomaterials including membrane,sponge,nanofiber and hydrogel that were extensively employed in skin tissue engineering.This review will help to form a base for the advanced applications of chitosan-based biomaterials in treatment of skin tissue damages.
基金The reported study was supported in part by research grants from the 2019 Chongqing Support Program for Entrepreneurship and Innovation(No.cx2019113)(JF)the 2019 Science and Technology Research Plan Project of Chongqing Education Commission(KJQN201900410)(JF)+9 种基金the 2019 Youth Innovative Talent Training Program of Chongqing Education Commission(No.CY200409)(JF)the 2019 Funding for Postdoctoral Research(Chongqing Human Resources and Social Security Bureau No.298)(JF)and the National Key Research and Development Program of China(2016YFC1000803)RRR,TCH and GAA were partially funded by the National Institutes of Health(DE030480)WW was supported by the Medical Scientist Training Program of the National Institutes of Health(T32 GM007281)This project was also supported in part by The University of Chicago Cancer Center Support Grant(P30CA014599)the National Center for Advancing Translational Sciences of the National Institutes of Health through Grant Number UL1 TR000430TCH was also supported by the Mabel Green Myers Research Endowment Fund,The University of Chicago Orthopaedics Alumni Fund,and The University of Chicago SHOCK Fund.Funding sources were not involved in the study designin the collection,analysis and/or interpretation of datain the writing of the reportor in the decision to submit the paper for publication.
文摘Skin injury is repaired through a multi-phase wound healing process of tissue granulation and re-epithelialization.Any failure in the healing process may lead to chronic non-healing wounds or abnormal scar formation.Although significant progress has been made in developing novel scaffolds and/or cell-based therapeutic strategies to promote wound healing,effective management of large chronic skin wounds remains a clinical challenge.Keratinocytes are critical to re-epithelialization and wound healing.Here,we investigated whether exogenous keratinocytes,in combination with a citrate-based scaffold,enhanced skin wound healing.We first established reversibly immortalized mouse keratinocytes(iKera),and confirmed that the iKera cells expressed keratinocyte markers,and were responsive to UVB treatment,and were non-tumorigenic.In a proof-of-principle experiment,we demonstrated that iKera cells embedded in citrate-based scaffold PPCN provided more effective re-epithelialization and cutaneous wound healing than that of either PPCN or iKera cells alone,in a mouse skin wound model.Thus,these results demonstrate that iKera cells may serve as a valuable skin epithelial source when,combining with appropriate biocompatible scaffolds,to investigate cutaneous wound healing and skin regeneration.
基金supported by grants from National Natural Science Foundation of China(NO.81974288)National Natural Science Foundation of China(NO.82302812)Natural Science Foundation of Zhejiang Province of China(LQ22E030004),。
文摘Skin damage resulting from burns,injuries,or diseases can lead to significant functional and esthetic deficits.However,traditional treatments,such as skin grafting,have limitations including limited donor skin availability,poor aesthetics,and functional impairment.Skin tissue engineering provides a promising alternative,with engineered artificial skins offering a highly viable avenue.Engineered artificial skin is designed to mimic or replace the functions of natural human skin and find applications in various medical treatments,particularly for severe burns,chronic wounds,and other skin injuries or defects.These artificial skins aim to promote wound healing,provide temporary coverage,permanent skin replacement,and restore the skin’s barrier function.Artificial skins have diverse applications in medicine and wound care,addressing burns,chronic wounds,and traumatic injuries.They also serve as valuable tools for research in tissue engineering,offering experimental models for studying wound healing mechanisms,testing new biomaterials,and exploring innovative approaches to skin regeneration.This review provides an overview of current construction strategies for engineered artificial skin,including cell sources,biomaterials,and construction techniques.It further explores the primary application areas and future prospects of artificial skin,highlighting their potential to revolutionize skin reconstruction and advance the field of regenerative medicine.
基金This work was supported by the National Key R&D Program of China(2018YFA0703100)Jiangsu Key Technology Research Development Program(BE2017664)+3 种基金Shanghai Jiao Tong University Biomedical Engineering Cross Research Foundation(YG2017QN15)the National Natural Science Foundation of China(No.82072217 and 81772135)Shanghai health committee(20184Y0053)Shanghai“Rising stars of medical talent”Youth development program,Shanghai Jiao Tong University K.C.Wong Medical Fellowship Fund.
文摘Bioprinting has exhibited remarkable promises for the fabrication of functional skin substitutes.However,there are some significant challenges for the treatment of full-thickness skin defects in clinical practice.It is necessary to determine bioinks with suitable mechanical properties and desirable biocompatibilities.Additionally,the key for printing skin is to design the skin structure optimally,enabling the function of the skin.In this study,the full-thickness skin scaffolds were prepared with a gradient pore structure constructing the dense layer,epidermis,and dermis by different ratios of bioinks.We hypothesized that the dense layer protects the wound surface and maintains a moist environment on the wound surface.By developing a suitable hydrogel bioink formulation(sodium alginate/gelatin/collagen),to simulate the physiological structure of the skin via 3D printing,the proportion of hydrogels was optimized corresponding to each layer.These results reveal that the scaffold has interconnected macroscopic channels,and sodium alginate/gelatin/collagen scaffolds accelerated wound healing,reduced skin wound contraction,and re-epithelialization in vivo.It is expected to provide a rapid and economical production method of skin scaffolds for future clinical applications.
基金funded by National Natural Science Foundation of China(No.31870934).
文摘Skin tissue engineering with considerable skin regeneration capability is an urgent need for the wound site.The current challenge for researchers is to develop a bionic scaffold that imitates the extracellular matrix for the regeneration of the damaged regions.In our study,poly(L-lactide-co-caprolactone)(PLCL)was blended with polyurethane(PU)to obtain nanofibrous scaffolds via electrospinning.The electrospun fibers with 50%PLCL content had a certain number of intersections and jointing points,and exhibited significantly enhanced mechani-cal properties combined with suitable porosity.Moreover,cell activities demonstrated that PU/PLCL membranes had significantly biological advantages in enhanced growth of human skin fibroblasts with spreading morphology compared with PU membranes,indicating good cytocompatibility of composite scaffolds.These findings proved that PU/PLCL electrospun membranes have great potential in applications of skin tissue engineering.
基金supported by Fellowship of China National Postdoctoral Program for Innovative Talents(BX20220240)Improvement Project for Theranostic Ability on Difficulty Miscellaneous Disease(Tumor)from National Health Commission of China(ZLYNXM202006)+1 种基金Chinese Central Special Fund for Local Science and Technology Development of Hubei Province(2018ZYYD023)Science and Technology Department of Hubei Province Key Project(2018ACA159).
文摘One of the leading causes of wound healing delays is bacterial infection,which limits the process of restoring the histological and functional integrity of the skin.Electrospun nanofibrous materials(ENMs)are biocompatible and biodegradable,and they can provide specific physical,chemical,and biological cues to accelerate wound healing.Based on this fact,a series of multifunctional ENMs for complex clinical applications,particularly infected skin injuries,have been developed.Anti-biotics,antimicrobial peptides(AMPs),metals and metal oxides(MMOs),and antibacterial polymers have previously been incorporated into ENMs through advanced material processing techniques,endowing ENMs with enhanced and excellent antibacterial activity.This review summarizes wound healing issues and provides recent advances in antibacterial ENMs created by cutting-edge technology.The future of clinical and translational research on ENMs is also discussed.
基金support of the ERC Starting Grant(STROFUNSCAFF)the UK Regenerative Medicine Platform(UKRMP2)Acellular/Smart Materials.C.D.acknowledges the support of University of Palermo FFR 2018/2021.
文摘Hydrogel wound dressings can play critical roles in wound healing protecting the wound from trauma or contamination and providing an ideal environment to support the growth of endogenous cells and promote wound closure.This work presents a self-assembling hydrogel dressing that can assist the wound repair process mimicking the hierarchical structure of skin extracellular matrix.To this aim,the co-assembly behaviour of a carboxylated variant of xyloglucan(CXG)with a peptide amphiphile(PA-H3)has been investigated to generate hierarchical constructs with tuneable molecular composition,structure,and properties.Transmission electron microscopy and circular dichroism at a low concentration shows that CXG and PA-H3 co-assemble into nanofibres by hydrophobic and electrostatic interactions and further aggregate into nanofibre bundles and networks.At a higher concentration,CXG and PA-H3 yield hydrogels that have been characterized for their morphology by scanning electron microscopy and for the mechanical properties by smallamplitude oscillatory shear rheological measurements and compression tests at different CXG/PAH3 ratios.A preliminary biological evaluation has been carried out both in vitro with HaCat cells and in vivo in a mouse model.