Magnesium(Mg)is the fourth most abundant element in the human body and is important in terms of specific osteogenesis functions.Here,we provide a comprehensive review of the use of magnesium-based biomaterials(MBs)in ...Magnesium(Mg)is the fourth most abundant element in the human body and is important in terms of specific osteogenesis functions.Here,we provide a comprehensive review of the use of magnesium-based biomaterials(MBs)in bone reconstruction.We review the history of MBs and their excellent biocompatibility,biodegradability and osteopromotive properties,highlighting them as candidates for a new generation of biodegradable orthopedic implants.In particular,the results reported in the field-specific literature(280 articles)in recent decades are dissected with respect to the extensive variety of MBs for orthopedic applications,including Mg/Mg alloys,bioglasses,bioceramics,and polymer materials.We also summarize the osteogenic mechanism of MBs,including a detailed section on the physiological process,namely,the enhanced osteogenesis,promotion of osteoblast adhesion and motility,immunomodulation,and enhanced angiogenesis.Moreover,the merits and limitations of current bone grafts and substitutes are compared.The objective of this review is to reveal the strong potential of MBs for their use as agents in bone repair and regeneration and to highlight issues that impede their clinical translation.Finally,the development and challenges of MBs for transplanted orthopedic materials are discussed.展开更多
Cancer immunotherapy harnesses the immune system to attack tumors and has received extensive attention in recent years.Cancer vaccines as an important branch of immunotherapy are designed for delivering tumor antigens...Cancer immunotherapy harnesses the immune system to attack tumors and has received extensive attention in recent years.Cancer vaccines as an important branch of immunotherapy are designed for delivering tumor antigens to antigen-presenting cells(APCs)to stimulate a strong immune response to against tumors,representing a potentially therapeutic and prophylactic effect with the long-term anticancer benefits.Nevertheless,the disappointing outcomes of their clinical use might be attributed to dilemma in antigen selection,immunogenicity,lymph nodes(LNs)targeting ability,lysosomal escape ability,immune evasion,etc.Nanotechnology,aiming to overcome these barriers,has been utilized in cancer vaccine development for decades.Numerous preclinical and clinical studies demonstrate positive results in nanomaterials-based cancer vaccines with considerable improvement in the vaccine efficacy.In this review,we systematically introduced the characteristics of nanovaccines and highlighted the different types of nanomaterials used for cancer vaccine design.In addition,the opportunities and challenges of the emerging nanotechnology-based cancer vaccines were discussed.展开更多
基金financial support from the National Natural Science Foundation of China(No.81672230)the Natural Science Foundation of Chongqing(No.cstc2020jcyjmsxm2234)+1 种基金the Top-notch Young Talent Project of Chongqing Traditional Chinese Medicine Hospital(No.CQSZYY2020008)the Chongqing Graduate Research Innovation Project(No.CYS20199)。
文摘Magnesium(Mg)is the fourth most abundant element in the human body and is important in terms of specific osteogenesis functions.Here,we provide a comprehensive review of the use of magnesium-based biomaterials(MBs)in bone reconstruction.We review the history of MBs and their excellent biocompatibility,biodegradability and osteopromotive properties,highlighting them as candidates for a new generation of biodegradable orthopedic implants.In particular,the results reported in the field-specific literature(280 articles)in recent decades are dissected with respect to the extensive variety of MBs for orthopedic applications,including Mg/Mg alloys,bioglasses,bioceramics,and polymer materials.We also summarize the osteogenic mechanism of MBs,including a detailed section on the physiological process,namely,the enhanced osteogenesis,promotion of osteoblast adhesion and motility,immunomodulation,and enhanced angiogenesis.Moreover,the merits and limitations of current bone grafts and substitutes are compared.The objective of this review is to reveal the strong potential of MBs for their use as agents in bone repair and regeneration and to highlight issues that impede their clinical translation.Finally,the development and challenges of MBs for transplanted orthopedic materials are discussed.
基金supported by the National Science Foundation for Excellent Young Scholars(No.32122052)National Natural Science Foundation Regional Innovation and Development(No.U19A2003).
文摘Cancer immunotherapy harnesses the immune system to attack tumors and has received extensive attention in recent years.Cancer vaccines as an important branch of immunotherapy are designed for delivering tumor antigens to antigen-presenting cells(APCs)to stimulate a strong immune response to against tumors,representing a potentially therapeutic and prophylactic effect with the long-term anticancer benefits.Nevertheless,the disappointing outcomes of their clinical use might be attributed to dilemma in antigen selection,immunogenicity,lymph nodes(LNs)targeting ability,lysosomal escape ability,immune evasion,etc.Nanotechnology,aiming to overcome these barriers,has been utilized in cancer vaccine development for decades.Numerous preclinical and clinical studies demonstrate positive results in nanomaterials-based cancer vaccines with considerable improvement in the vaccine efficacy.In this review,we systematically introduced the characteristics of nanovaccines and highlighted the different types of nanomaterials used for cancer vaccine design.In addition,the opportunities and challenges of the emerging nanotechnology-based cancer vaccines were discussed.