If only at a small scale,islet transplantation has successfully addressed what ought to be the primary endpoint of any cell therapy:the functional replenishment of damaged tissue in patients.After years of less-thanop...If only at a small scale,islet transplantation has successfully addressed what ought to be the primary endpoint of any cell therapy:the functional replenishment of damaged tissue in patients.After years of less-thanoptimal approaches to immunosuppression,recent advances consistently yield long-term graft survival rates comparable to those of whole pancreas transplantation.Limited organ availability is the main hurdle that stands in the way of the widespread clinical utilization of this pioneering intervention.Progress in stem cell research over the past decade,coupled with our decades-long experience with islet transplantation,is shaping the future of cell therapies for the treatment of diabetes.Here we review the most promising avenues of research aimed at generating an inexhaustible supply of insulin-producing cells for islet regeneration,including the differentiation of pluripotent and multipotent stem cells of embryonic and adult origin along the beta cell lineage and the direct reprogramming of non-endocrine tissues into insulin-producing cells.展开更多
Strategies to fill the huge gap in supply versus demand of human organs include bioartificial organs, growing humanized organs in animals, cell therapy, and implantable bioengineered constructs. Reproducing the comple...Strategies to fill the huge gap in supply versus demand of human organs include bioartificial organs, growing humanized organs in animals, cell therapy, and implantable bioengineered constructs. Reproducing the complex relations between different cell types, generation of adequate vasculature, and immunological complications are road blocks in generation of bioengineered organs, while immunological complications limit the use of humanized organs produced in animals. Recent developments in induced pluripotent stem cell (iPSC) biology offer a possibility of generating human, patient-specific organs in non-human primates (NHP) using patient-derived iPSC and NHP-derived iPSC lacking the critical developmental genes for the organ of interest complementing a NHP tetraploid embryo. The organ derived in this way will have the same human leukocyte antigen (HLA) profile as the patient. This approach can be curative in genetic disorders as this offers the possibility of gene manipulation and correction of the patient's genome at the iPSC stage before tetraploid complementation. The process of generation of patient-specific organs such as the liver in this way has the great advantage of making use of the natural signaling cascades in the natural milieu probably resulting in organs of great quality for transplantation. However, the inexorable scientific developments in this direction involve several social issues and hence we need to educate and prepare society in advance to accept the revolutionary consequences, good, bad and ugly.展开更多
Around 400 million people worldwide suffer from diabetes mellitus.The major pathological event for Type 1 diabetes and advanced Type 2 diabetes is loss or impairment of insulin-secreting β cells of the pancreas.For t...Around 400 million people worldwide suffer from diabetes mellitus.The major pathological event for Type 1 diabetes and advanced Type 2 diabetes is loss or impairment of insulin-secreting β cells of the pancreas.For the past 100 years,daily insulin injection has served as a life-saving treatment for these patients.However,insulin injection often cannot achieve full glucose control,and over time poor glucose control leads to severe complications and mortality.As an alternative treatment,islet transplantation has been demonstrated to effectively maintain glucose homeostasis in diabetic patients,but its wide application is limited by the scarcity of donated islets.Therefore,it is important to define new strategies to obtain functional human β cells for transplantation therapies.Here,we summarize recent progress towards the production of β cells in vitro from pluripotent stem cells or somatic cell types including a cells,pancreatic exocrine cells,gastrointestinal stem cells,fibroblasts and hepatocytes.We also discuss novel methods for optimizing β cell transplantation and maintenance in vivo.From our perspective,the future of βcell replacement therapy is very promising although it is still challenging to control differentiation of β cells in vitro and to protect these cells from autoimmune attack in Type 1 diabetic patients.Overall,tremendous progress has been made in understanding βcell differentiation and producing functional β cells with different methods.In the coming years,we believe more clinical trials will be launched to move these technologies towards treatments to benefit diabetic patients.展开更多
基金Supported by Funding of the National Institutes of Healththe Juvenile Diabetes Research Foundation+2 种基金the American Diabetes Associationthe Foundation for Diabetes Researchthe Diabetes Research Institute Foundation
文摘If only at a small scale,islet transplantation has successfully addressed what ought to be the primary endpoint of any cell therapy:the functional replenishment of damaged tissue in patients.After years of less-thanoptimal approaches to immunosuppression,recent advances consistently yield long-term graft survival rates comparable to those of whole pancreas transplantation.Limited organ availability is the main hurdle that stands in the way of the widespread clinical utilization of this pioneering intervention.Progress in stem cell research over the past decade,coupled with our decades-long experience with islet transplantation,is shaping the future of cell therapies for the treatment of diabetes.Here we review the most promising avenues of research aimed at generating an inexhaustible supply of insulin-producing cells for islet regeneration,including the differentiation of pluripotent and multipotent stem cells of embryonic and adult origin along the beta cell lineage and the direct reprogramming of non-endocrine tissues into insulin-producing cells.
文摘Strategies to fill the huge gap in supply versus demand of human organs include bioartificial organs, growing humanized organs in animals, cell therapy, and implantable bioengineered constructs. Reproducing the complex relations between different cell types, generation of adequate vasculature, and immunological complications are road blocks in generation of bioengineered organs, while immunological complications limit the use of humanized organs produced in animals. Recent developments in induced pluripotent stem cell (iPSC) biology offer a possibility of generating human, patient-specific organs in non-human primates (NHP) using patient-derived iPSC and NHP-derived iPSC lacking the critical developmental genes for the organ of interest complementing a NHP tetraploid embryo. The organ derived in this way will have the same human leukocyte antigen (HLA) profile as the patient. This approach can be curative in genetic disorders as this offers the possibility of gene manipulation and correction of the patient's genome at the iPSC stage before tetraploid complementation. The process of generation of patient-specific organs such as the liver in this way has the great advantage of making use of the natural signaling cascades in the natural milieu probably resulting in organs of great quality for transplantation. However, the inexorable scientific developments in this direction involve several social issues and hence we need to educate and prepare society in advance to accept the revolutionary consequences, good, bad and ugly.
文摘Around 400 million people worldwide suffer from diabetes mellitus.The major pathological event for Type 1 diabetes and advanced Type 2 diabetes is loss or impairment of insulin-secreting β cells of the pancreas.For the past 100 years,daily insulin injection has served as a life-saving treatment for these patients.However,insulin injection often cannot achieve full glucose control,and over time poor glucose control leads to severe complications and mortality.As an alternative treatment,islet transplantation has been demonstrated to effectively maintain glucose homeostasis in diabetic patients,but its wide application is limited by the scarcity of donated islets.Therefore,it is important to define new strategies to obtain functional human β cells for transplantation therapies.Here,we summarize recent progress towards the production of β cells in vitro from pluripotent stem cells or somatic cell types including a cells,pancreatic exocrine cells,gastrointestinal stem cells,fibroblasts and hepatocytes.We also discuss novel methods for optimizing β cell transplantation and maintenance in vivo.From our perspective,the future of βcell replacement therapy is very promising although it is still challenging to control differentiation of β cells in vitro and to protect these cells from autoimmune attack in Type 1 diabetic patients.Overall,tremendous progress has been made in understanding βcell differentiation and producing functional β cells with different methods.In the coming years,we believe more clinical trials will be launched to move these technologies towards treatments to benefit diabetic patients.
