Proteins,cells and bacteria adhering to the surface of medical devices can lead to thrombosis and infection,resulting in significant clinical mortality.Here,we report a zwitterionic polymers-armored amyloid-like prote...Proteins,cells and bacteria adhering to the surface of medical devices can lead to thrombosis and infection,resulting in significant clinical mortality.Here,we report a zwitterionic polymers-armored amyloid-like protein surface engineering strategy we called as“armored-tank”strategy for dual functionalization of medical devices.The“armored-tank”strategy is realized by decoration of partially conformational transformed LZM(PCTL)assembly through oxidant-mediated process,followed by armoring with super-hydrophilic poly-2-methacryloyloxyethyl phosphorylcholine(pMPC).The outer armor of the“armored-tank”shows potent and durable zone defense against fibrinogen,platelet and bacteria adhesion,leading to long-term antithrombogenic properties over 14 days in vivo without anticoagulation.Additionally,the“fired”PCTL from“armored-tank”actively and effectively kills both Gram-positive and Gram-negative bacterial over 30 days as a supplement to the lacking bactericidal functions of passive outer armor.Overall,this“armored-tank”surface engineering strategy serves as a promising solution for preventing biofouling and thrombotic occlusion of medical devices.展开更多
Thrombus formation and tissue embedding significantly impair the clinical efficacy and retrievability of temporary interventional medical devices.Herein,we report an insect sclerotization-inspired antifouling armor fo...Thrombus formation and tissue embedding significantly impair the clinical efficacy and retrievability of temporary interventional medical devices.Herein,we report an insect sclerotization-inspired antifouling armor for tailoring temporary interventional devices with durable resistance to protein adsorption and the following protein-mediated complications.By mimicking the phenol-polyamine chemistry assisted by phenol oxidases during sclerotization,we develop a facile one-step method to crosslink bovine serum albumin(BSA)with oxidized hydrocaffeic acid(HCA),resulting in a stable and universal BSA@HCA armor.Furthermore,the surface of the BSA@HCA armor,enriched with carboxyl groups,supports the secondary grafting of polyethylene glycol(PEG),further enhancing both its antifouling performance and durability.The synergy of robustly immobilized BSA and covalently grafted PEG provide potent resistance to the adhesion of proteins,platelets,and vascular cells in vitro.In ex vivo blood circulation experiment,the armored surface reduces thrombus formation by 95%.Moreover,the antifouling armor retained over 60%of its fouling resistance after 28 days of immersion in PBS.Overall,our armor engineering strategy presents a promising solution for enhancing the antifouling properties and clinical performance of temporary interventional medical devices.展开更多
Thrombosis and infections are the two major complications associated with extracorporeal circuits and indwelling medical devices,leading to significant mortality in clinic.To address this issue,here,we report a biomim...Thrombosis and infections are the two major complications associated with extracorporeal circuits and indwelling medical devices,leading to significant mortality in clinic.To address this issue,here,we report a biomimetic surface engineering strategy by the integration of mussel-inspired adhesive peptide,with bio-orthogonal click chemistry,to tailor the surface functionalities of tubing and catheters.Inspired by mussel adhesive foot protein,a bioclickable peptide mimic(DOPA)4-azidebased structure is designed and grafted on an aminated tubing robustly based on catechol-amine chemistry.Then,the dibenzylcyclooctyne(DBCO)modified nitric oxide generating species of 1,4,7,10-tetraazacyclododecane-1,4,7,10-tetraacetic acid(DOTA)chelated copper ions and the DBCO-modified antimicrobial peptide(DBCO-AMP)are clicked onto the grafted surfaces via bio-orthogonal reaction.The combination of the robustly grafted AMP and Cu-DOTA endows the modified tubing with durable antimicrobial properties and ability in long-term catalytically generating NO from endogenous snitrosothiols to resist adhesion/activation of platelets,thus preventing the formation of thrombosis.Overall,this biomimetic surface engineering technology provides a promising solution for multicomponent surface functionalization and the surface bioengineering of biomedical devices with enhanced clinical performance.展开更多
Universal coatings with versatile surface adhesion,good mechanochemical robustness,and the capacity for secondary modification are of great scientific interest.However,incorporating these advantages into a system is s...Universal coatings with versatile surface adhesion,good mechanochemical robustness,and the capacity for secondary modification are of great scientific interest.However,incorporating these advantages into a system is still a great challenge.Here,we report a series of catechol-decorated polyallylamines(CPAs),denoted as pseudo-Mytilus edulis foot protein 5(pseudoMefp-5),that mimic not only the catechol and amine groups but also the backbone of Mefp-5.CPAs can fabricate highly adhesive,robust,multifunctional polyCPA(PCPA)coatings based on synergetic catechol-polyamine chemistry as universal building blocks.Due to the interpenetrating entangled network architectures,these coatings exhibit high chemical robustness against harsh conditions(HCl,pH 1;NaOH,pH 14;H2O2,30%),good mechanical robustness,and wear resistance.In addition,PCPA coatings provide abundant grafting sites,enabling the fabrication of various functional surfaces through secondary modification.Furthermore,the versatility,multifaceted robustness,and scalability of PCPA coatings indicate their great potential for surface engineering,especially for withstanding harsh conditions in multipurpose biomedical applications.展开更多
基金supported by by the National Natural Science Foundation of China(Project 82202325,82072072,32171326,32261160372)the Guang Dong Basic and Applied Basic Research Foundation(2022B1515130010,2021A1515111035)China Postdoctoral Science Foundation(2022M721524).
文摘Proteins,cells and bacteria adhering to the surface of medical devices can lead to thrombosis and infection,resulting in significant clinical mortality.Here,we report a zwitterionic polymers-armored amyloid-like protein surface engineering strategy we called as“armored-tank”strategy for dual functionalization of medical devices.The“armored-tank”strategy is realized by decoration of partially conformational transformed LZM(PCTL)assembly through oxidant-mediated process,followed by armoring with super-hydrophilic poly-2-methacryloyloxyethyl phosphorylcholine(pMPC).The outer armor of the“armored-tank”shows potent and durable zone defense against fibrinogen,platelet and bacteria adhesion,leading to long-term antithrombogenic properties over 14 days in vivo without anticoagulation.Additionally,the“fired”PCTL from“armored-tank”actively and effectively kills both Gram-positive and Gram-negative bacterial over 30 days as a supplement to the lacking bactericidal functions of passive outer armor.Overall,this“armored-tank”surface engineering strategy serves as a promising solution for preventing biofouling and thrombotic occlusion of medical devices.
基金supported by the National Natural Science Foundation of China,China(Project 82202325,82072072,32171326,32261160372)the Guangdong Basic and Applied Basic Research Foundation,China(2022B1515130010,2021A1515111035)+2 种基金Dongguan Science and Technology of Social Development Program,China(20231800906311,20231800900332)China Postdoctoral Science Foundation,China(2022M721524)Leading Talent Project of Guangzhou Development District,China(2020-L013)。
文摘Thrombus formation and tissue embedding significantly impair the clinical efficacy and retrievability of temporary interventional medical devices.Herein,we report an insect sclerotization-inspired antifouling armor for tailoring temporary interventional devices with durable resistance to protein adsorption and the following protein-mediated complications.By mimicking the phenol-polyamine chemistry assisted by phenol oxidases during sclerotization,we develop a facile one-step method to crosslink bovine serum albumin(BSA)with oxidized hydrocaffeic acid(HCA),resulting in a stable and universal BSA@HCA armor.Furthermore,the surface of the BSA@HCA armor,enriched with carboxyl groups,supports the secondary grafting of polyethylene glycol(PEG),further enhancing both its antifouling performance and durability.The synergy of robustly immobilized BSA and covalently grafted PEG provide potent resistance to the adhesion of proteins,platelets,and vascular cells in vitro.In ex vivo blood circulation experiment,the armored surface reduces thrombus formation by 95%.Moreover,the antifouling armor retained over 60%of its fouling resistance after 28 days of immersion in PBS.Overall,our armor engineering strategy presents a promising solution for enhancing the antifouling properties and clinical performance of temporary interventional medical devices.
基金the National Natural Science Foundation of China(Project 82072072)(Z.Y)International Cooperation Project by Science and Technology Department of Sichuan Province(2021YFH0056 and 2019YFH0103)(Z.Y)the Fundamental Research Funds for the Central Universities(2682020ZT82 and 2682020ZT76)(Z.Y).
文摘Thrombosis and infections are the two major complications associated with extracorporeal circuits and indwelling medical devices,leading to significant mortality in clinic.To address this issue,here,we report a biomimetic surface engineering strategy by the integration of mussel-inspired adhesive peptide,with bio-orthogonal click chemistry,to tailor the surface functionalities of tubing and catheters.Inspired by mussel adhesive foot protein,a bioclickable peptide mimic(DOPA)4-azidebased structure is designed and grafted on an aminated tubing robustly based on catechol-amine chemistry.Then,the dibenzylcyclooctyne(DBCO)modified nitric oxide generating species of 1,4,7,10-tetraazacyclododecane-1,4,7,10-tetraacetic acid(DOTA)chelated copper ions and the DBCO-modified antimicrobial peptide(DBCO-AMP)are clicked onto the grafted surfaces via bio-orthogonal reaction.The combination of the robustly grafted AMP and Cu-DOTA endows the modified tubing with durable antimicrobial properties and ability in long-term catalytically generating NO from endogenous snitrosothiols to resist adhesion/activation of platelets,thus preventing the formation of thrombosis.Overall,this biomimetic surface engineering technology provides a promising solution for multicomponent surface functionalization and the surface bioengineering of biomedical devices with enhanced clinical performance.
基金supported by the National Natural Science Foundation of China(projects 82072072,32171326,82272157,32261160372,and 82350710800)the Guangdong Basic and Applied Basic Research Foundation(2022B1515130010 and 2021A1515111035)+1 种基金the National Natural Science Foundation of China/Research Grants Council(NSFC/RGC)Joint Research Scheme(N_PolyU526/22)the Leading Talent Project of Guangzhou Development District(2020-L013)。
文摘Universal coatings with versatile surface adhesion,good mechanochemical robustness,and the capacity for secondary modification are of great scientific interest.However,incorporating these advantages into a system is still a great challenge.Here,we report a series of catechol-decorated polyallylamines(CPAs),denoted as pseudo-Mytilus edulis foot protein 5(pseudoMefp-5),that mimic not only the catechol and amine groups but also the backbone of Mefp-5.CPAs can fabricate highly adhesive,robust,multifunctional polyCPA(PCPA)coatings based on synergetic catechol-polyamine chemistry as universal building blocks.Due to the interpenetrating entangled network architectures,these coatings exhibit high chemical robustness against harsh conditions(HCl,pH 1;NaOH,pH 14;H2O2,30%),good mechanical robustness,and wear resistance.In addition,PCPA coatings provide abundant grafting sites,enabling the fabrication of various functional surfaces through secondary modification.Furthermore,the versatility,multifaceted robustness,and scalability of PCPA coatings indicate their great potential for surface engineering,especially for withstanding harsh conditions in multipurpose biomedical applications.
