AIM To evaluate the safety and efficacy of the bioartificial liver support system in canines with acute liver failure (ALF). METHODS Nine canines with acute liver failure by acetaminophen induced received TECA Ⅰ...AIM To evaluate the safety and efficacy of the bioartificial liver support system in canines with acute liver failure (ALF). METHODS Nine canines with acute liver failure by acetaminophen induced received TECA Ⅰ bioartificial liver support system (BALSS) from Hong Kong TECA LTD Co. Blood was perfused through a hollow fiber tube containing (1 2)×10 10 the porcine hepatocytes. In contrast, another 10 canines with acute liver failure by Acetaminophen received drugs. Each treatment lasted 6 hours. RESULTS BALSS treatment resulted in beneficial effects for acetaminophen induced ALF canines with survival and with the recovery of the liver functions and tissues, and plasma ammonia decreased from 135 9μmol/L ± 17 5μmol/L to 65 7μmol/L ± 22 0μmol/L , 32 5μmol/L ± 8 8μmol/L , GPT from 97 8U/L ± 8 7U/L to 64 8U/L ± 11 9U/L , 19 0U/L ± 6 3U/L , GOT from 103 0U/L ± 16 7U/L to 75 7U/L ± 19 6U/L , 26 5U/L ± 5 0U/L , and AKP from 158 3U/L ± 12 1U/L to 114 5U/L ± 19 8U/L , 43 8U/L ± 5 6U/L during and after the treatment. In contrast, 10 ALF canines in both the drug and control groups died 1 or 2 days after treatment. CONCLUSION TECA 1 artificial liver support system is safe and efficacious for canines with acute liver failure.展开更多
BACKGROUND Acute liver failure(ALF) has a high mortality varying from 80% to 85% with rapid progress in multi-organ system failure. Bioartificial liver(BAL) support systems have the potential to provide temporary supp...BACKGROUND Acute liver failure(ALF) has a high mortality varying from 80% to 85% with rapid progress in multi-organ system failure. Bioartificial liver(BAL) support systems have the potential to provide temporary support to bridge patients with ALF to liver transplantation or spontaneous recovery. In the past decades, several BAL support systems have been conducted in clinical trials. More recently,concerns have been raised on the renovation of high-quality cell sources and configuration of BAL support systems to provide more benefits to ALF models in preclinical experiments.AIM To investigate the characteristics of studies about BAL support systems for ALF,and to evaluate their effects on mortality.METHODS Eligible clinical trials and preclinical experiments on large animals were identified on Cochrane Library, PubMed, and EMbase up to March 6, 2019. Two reviewers independently extracted the necessary information, including key BAL indicators, survival and indicating outcomes, and adverse events during treatment. Descriptive analysis was used to identify the characteristics of the included studies, and a meta-analysis including only randomized controlled trial (RCT) studies was done to calculate the overall effect of BAL on mortality among humans and large animals, respectively.RESULTS Of the 30 selected studies, 18 were clinical trials and 12 were preclinical experiments. The meta-analysis result suggested that BAL might reduce mortality in ALF in large animals, probably due to the recent improvement of BAL, including the type, cell source, cell mass, and bioreactor, but seemed ineffective for humans (BAL vs control: relative risk(95% confidence interval),0.27(0.12-0.62) for animals and 0.72(0.48-1.08) for humans)Liver and renal functions, hematologic and coagulative parameters, encephalopathy index, and neurological indicators seemed to improve after BAL, with neither meaningful adverse events nor porcine endogenous retrovirus infection.CONCLUSION BAL may reduce the mortality of ALF by bridging the gap between展开更多
Many different artificial liver support systems(biological and non-biological) have been developed,tested pre-clinically and some have been applied in clinical trials.Based on theoretical considerations a biological a...Many different artificial liver support systems(biological and non-biological) have been developed,tested pre-clinically and some have been applied in clinical trials.Based on theoretical considerations a biological artificial liver(BAL) should be preferred above the non-biological ones.However,clinical application of the BAL is still experimental.Here we try to analyze which hurdles have to be taken before the BAL will become standard equipment in the intensive care unit for patients with acute liver failure or acute deterioration of chronic liver disease.展开更多
BACKGROUND: Bioartificial liver support systems are becoming an effective therapy for hepatic failure. Bioreactors, as key devices in these systems, can provide a favorable growth and metabolic environment, mass excha...BACKGROUND: Bioartificial liver support systems are becoming an effective therapy for hepatic failure. Bioreactors, as key devices in these systems, can provide a favorable growth and metabolic environment, mass exchange, and immunological isolation as a platform. Currently, stagnancy in bioreactor research is the main factor restricting the development of bioartificial liver support systems. DATA SOURCES: A PubMed database search of English-language literature was performed to identify relevant articles using the keywords 'bioreactor', 'bioartificial liver', 'hepatocyte', and 'liver failure'. More than 40 articles related to the bioreactors of bioartificial livers were reviewed. RESULTS: Some progress has been made in the improvement of structures, functions, and modified macromolecular materials related to bioreactors in recent years. The current data on the improvement of bioreactor configurations for bioartificial livers or on the potential of the use of certain scaffold materials in bioreactors, combined with the clinical efficacy and safety evaluation of cultured hepatocytes in vitro, indicate that the AMC (Academic Medical Center) BAL bioreactor and MELS (modular extracorporeal liver support) BAL bioreactor system can partly replace the synthetic and metabolic functions of the liver in phase I clinical studies. In addition, it has been indicated that the microfluidic PDMS (polydimethylsiloxane) bioreactor, or SlideBioreactor, and the microfabricated grooved bioreactor are appropriate for hepatocyte culture, which is also promising for bioartificial livers. Similarly, modified scaffolds can promote the adhesion, growth, and function of hepatocytes, and provide reliable materials for bioreactors. CONCLUSIONS: Bioreactors, as key devices in bioartificial livers, play an important role in the therapy for liver failure both now and in the future. Bioreactor configurations are indispensable for the development of bioartificial livers used for liver failure, just as the modified scaffold materials available for b展开更多
BACKGROUND: Orthotopic liver transplantation (OLT) is the most effective therapy for liver failure. However, OLT is severely limited by the shortage of liver donors. Bioartificial liver (BAL) shows great potential as ...BACKGROUND: Orthotopic liver transplantation (OLT) is the most effective therapy for liver failure. However, OLT is severely limited by the shortage of liver donors. Bioartificial liver (BAL) shows great potential as an alternative therapy for liver failure In recent years, progress has been made in BAL regarding genetically engineered cell lines, immortalized human hepatocytes, methods for preserving the phenotype of primary human hepatocytes, and other functional hepatocytes derived from stem cells. DATA SOURCES: A systematic search of PubMed and ISI Web of Science was performed to identify relevant studies in English language literature using the Key words such as liver failure bioartificial liver, hepatocyte, stem cells, differentiation, and immortalization. More than 200 articles related to the cell sources of hepatocyte in BAL were systematically reviewed. RESULTS: Methods for preserving the phenotype of primary human hepatocytes have been successfully developed. Many genetically engineered cell lines and immortalized human hepatocytes have also been established. Among these cell lines the incorporation of BAL with GS-HepG2 cells or alginate encapsulated HepG2 cells could prolong the survival time and improve pathophysiological parameters in an animal model of liver failure. The cBAL111 cells were evaluated using the AMC-BAL bioreactor, which could eliminate ammonia and lidocaine, and produce albumin. Importantly, BAL loading with HepLi-4 cells could significantly improve the blood biochemical parameters, and prolong the survival time in pigs with liver failure. Other functional hepatocytes differentiated from stem cells, such as human liver progenitor cells, have been successfully achieved. CONCLUSIONS: Aside from genetically modified liver cell lines and immortalized human hepatocytes, other functionalhepatocytes derived from stem cells show great potential as cell sources for BAL. BAL with safe and effective liver cells may be achieved for clinical liver failure in the near future.展开更多
Bioartificial liver assist devices (BALs) offer anopportunity for critical care physicians and transplantsurgeons to stabilize patients prior to orthotopic livertransplantation. Such devices may also act as a bridgeto...Bioartificial liver assist devices (BALs) offer anopportunity for critical care physicians and transplantsurgeons to stabilize patients prior to orthotopic livertransplantation. Such devices may also act as a bridgeto transplant, providing liver support to patientsawaiting transplant, or as support for patients post liv-ing-related donor transplant. Four BAL devices thatrely on hepatocytes cultured in hollow fiber membranecartridges (Circe Biomedical HepatAssist (r), VitagenELADTM, Gerlach BELS, and Excorp Medical BLSS)are currently in various stages of clinical evalua-tion. Comparison of the four devices shows that severalunique approaches based upon the same overall systemarchitecture are possible. Preliminary results of theExcorp Medical BLSS Phase I safety evaluation at theUniversity of Pittsburgh, after treating four patients(F, 41, acetominophen-induced, two support periods;M, 50, Wilson's disease, one support period; F, 53, a-cute alcoholic hepatitis, two support periods; F, 24,chemotherapy-induced, one support period) are pre-sented. All patients presented with hypoglycemia andtransient hypotension at the start of extracorporealperfusion. Hypoglycemia was treated by IV dextroseand the transient hypotension responded positively toIV fluid bolus. Heparin anticoagulation was used onlyin the second patient. No serious or adverse eventswere noted in the four patients. Moderate biochemicalresponse to support was noted in all patients. Morecomplete characterization of the safety of the BLSSrequires completion of the Phase I safety evaluation.展开更多
BACKGROUND: For nearly three decades, extracorporeal bioartificial liver (BAL) support systems have been anticipated as promising tools for the treatment of liver failure. However, these systems are still far from cli...BACKGROUND: For nearly three decades, extracorporeal bioartificial liver (BAL) support systems have been anticipated as promising tools for the treatment of liver failure. However, these systems are still far from clinical application. This review aimed to analyze the key challenges to the development of BALs. DATA SOURCE: We carried out a PubMed search of Englishlanguage articles relevant to extracorporeal BAL support systems and liver failure. RESULTS: Extracorporeal BALs face a series of challenges. First, an appropriate cell source for BAL is not readily available. Second, existing bioreactors do not provide in vivolike oxygenation and bile secretion. Third, emergency needs cannot be met by current BALs. Finally, the effectiveness of BALs, either in animals or in patients, has been difficult to document. CONCLUSIONS: Extracorporeal BAL support systems are mainly challenged by incompetent cell sources and flawed bioreactors. To advance this technology, future research is needed to provide more insights into interpreting the conditions for hepatocyte differentiation and liver microstructure formation.展开更多
文摘AIM To evaluate the safety and efficacy of the bioartificial liver support system in canines with acute liver failure (ALF). METHODS Nine canines with acute liver failure by acetaminophen induced received TECA Ⅰ bioartificial liver support system (BALSS) from Hong Kong TECA LTD Co. Blood was perfused through a hollow fiber tube containing (1 2)×10 10 the porcine hepatocytes. In contrast, another 10 canines with acute liver failure by Acetaminophen received drugs. Each treatment lasted 6 hours. RESULTS BALSS treatment resulted in beneficial effects for acetaminophen induced ALF canines with survival and with the recovery of the liver functions and tissues, and plasma ammonia decreased from 135 9μmol/L ± 17 5μmol/L to 65 7μmol/L ± 22 0μmol/L , 32 5μmol/L ± 8 8μmol/L , GPT from 97 8U/L ± 8 7U/L to 64 8U/L ± 11 9U/L , 19 0U/L ± 6 3U/L , GOT from 103 0U/L ± 16 7U/L to 75 7U/L ± 19 6U/L , 26 5U/L ± 5 0U/L , and AKP from 158 3U/L ± 12 1U/L to 114 5U/L ± 19 8U/L , 43 8U/L ± 5 6U/L during and after the treatment. In contrast, 10 ALF canines in both the drug and control groups died 1 or 2 days after treatment. CONCLUSION TECA 1 artificial liver support system is safe and efficacious for canines with acute liver failure.
文摘BACKGROUND Acute liver failure(ALF) has a high mortality varying from 80% to 85% with rapid progress in multi-organ system failure. Bioartificial liver(BAL) support systems have the potential to provide temporary support to bridge patients with ALF to liver transplantation or spontaneous recovery. In the past decades, several BAL support systems have been conducted in clinical trials. More recently,concerns have been raised on the renovation of high-quality cell sources and configuration of BAL support systems to provide more benefits to ALF models in preclinical experiments.AIM To investigate the characteristics of studies about BAL support systems for ALF,and to evaluate their effects on mortality.METHODS Eligible clinical trials and preclinical experiments on large animals were identified on Cochrane Library, PubMed, and EMbase up to March 6, 2019. Two reviewers independently extracted the necessary information, including key BAL indicators, survival and indicating outcomes, and adverse events during treatment. Descriptive analysis was used to identify the characteristics of the included studies, and a meta-analysis including only randomized controlled trial (RCT) studies was done to calculate the overall effect of BAL on mortality among humans and large animals, respectively.RESULTS Of the 30 selected studies, 18 were clinical trials and 12 were preclinical experiments. The meta-analysis result suggested that BAL might reduce mortality in ALF in large animals, probably due to the recent improvement of BAL, including the type, cell source, cell mass, and bioreactor, but seemed ineffective for humans (BAL vs control: relative risk(95% confidence interval),0.27(0.12-0.62) for animals and 0.72(0.48-1.08) for humans)Liver and renal functions, hematologic and coagulative parameters, encephalopathy index, and neurological indicators seemed to improve after BAL, with neither meaningful adverse events nor porcine endogenous retrovirus infection.CONCLUSION BAL may reduce the mortality of ALF by bridging the gap between
文摘Many different artificial liver support systems(biological and non-biological) have been developed,tested pre-clinically and some have been applied in clinical trials.Based on theoretical considerations a biological artificial liver(BAL) should be preferred above the non-biological ones.However,clinical application of the BAL is still experimental.Here we try to analyze which hurdles have to be taken before the BAL will become standard equipment in the intensive care unit for patients with acute liver failure or acute deterioration of chronic liver disease.
基金supported by grants from the National High Technolgoy Research and Development(863)Program of China(2006AA02A140)the National Natural Science Foundation of China(30630023)Zhejiang Health Science Foundation(2007A081)
文摘BACKGROUND: Bioartificial liver support systems are becoming an effective therapy for hepatic failure. Bioreactors, as key devices in these systems, can provide a favorable growth and metabolic environment, mass exchange, and immunological isolation as a platform. Currently, stagnancy in bioreactor research is the main factor restricting the development of bioartificial liver support systems. DATA SOURCES: A PubMed database search of English-language literature was performed to identify relevant articles using the keywords 'bioreactor', 'bioartificial liver', 'hepatocyte', and 'liver failure'. More than 40 articles related to the bioreactors of bioartificial livers were reviewed. RESULTS: Some progress has been made in the improvement of structures, functions, and modified macromolecular materials related to bioreactors in recent years. The current data on the improvement of bioreactor configurations for bioartificial livers or on the potential of the use of certain scaffold materials in bioreactors, combined with the clinical efficacy and safety evaluation of cultured hepatocytes in vitro, indicate that the AMC (Academic Medical Center) BAL bioreactor and MELS (modular extracorporeal liver support) BAL bioreactor system can partly replace the synthetic and metabolic functions of the liver in phase I clinical studies. In addition, it has been indicated that the microfluidic PDMS (polydimethylsiloxane) bioreactor, or SlideBioreactor, and the microfabricated grooved bioreactor are appropriate for hepatocyte culture, which is also promising for bioartificial livers. Similarly, modified scaffolds can promote the adhesion, growth, and function of hepatocytes, and provide reliable materials for bioreactors. CONCLUSIONS: Bioreactors, as key devices in bioartificial livers, play an important role in the therapy for liver failure both now and in the future. Bioreactor configurations are indispensable for the development of bioartificial livers used for liver failure, just as the modified scaffold materials available for b
基金supported by grants from the Chinese High-Tech Research & Development (863) Program (2011AA020104)Science Fund for Creative Research Groups of the National Natural Science Foundation of China (81121002)+1 种基金the Fundamental Research Funds for the Central Universitiesthe Technology Group Project for Infectious Disease Control of Zhejiang Province (2009R50041)
文摘BACKGROUND: Orthotopic liver transplantation (OLT) is the most effective therapy for liver failure. However, OLT is severely limited by the shortage of liver donors. Bioartificial liver (BAL) shows great potential as an alternative therapy for liver failure In recent years, progress has been made in BAL regarding genetically engineered cell lines, immortalized human hepatocytes, methods for preserving the phenotype of primary human hepatocytes, and other functional hepatocytes derived from stem cells. DATA SOURCES: A systematic search of PubMed and ISI Web of Science was performed to identify relevant studies in English language literature using the Key words such as liver failure bioartificial liver, hepatocyte, stem cells, differentiation, and immortalization. More than 200 articles related to the cell sources of hepatocyte in BAL were systematically reviewed. RESULTS: Methods for preserving the phenotype of primary human hepatocytes have been successfully developed. Many genetically engineered cell lines and immortalized human hepatocytes have also been established. Among these cell lines the incorporation of BAL with GS-HepG2 cells or alginate encapsulated HepG2 cells could prolong the survival time and improve pathophysiological parameters in an animal model of liver failure. The cBAL111 cells were evaluated using the AMC-BAL bioreactor, which could eliminate ammonia and lidocaine, and produce albumin. Importantly, BAL loading with HepLi-4 cells could significantly improve the blood biochemical parameters, and prolong the survival time in pigs with liver failure. Other functional hepatocytes differentiated from stem cells, such as human liver progenitor cells, have been successfully achieved. CONCLUSIONS: Aside from genetically modified liver cell lines and immortalized human hepatocytes, other functionalhepatocytes derived from stem cells show great potential as cell sources for BAL. BAL with safe and effective liver cells may be achieved for clinical liver failure in the near future.
文摘Bioartificial liver assist devices (BALs) offer anopportunity for critical care physicians and transplantsurgeons to stabilize patients prior to orthotopic livertransplantation. Such devices may also act as a bridgeto transplant, providing liver support to patientsawaiting transplant, or as support for patients post liv-ing-related donor transplant. Four BAL devices thatrely on hepatocytes cultured in hollow fiber membranecartridges (Circe Biomedical HepatAssist (r), VitagenELADTM, Gerlach BELS, and Excorp Medical BLSS)are currently in various stages of clinical evalua-tion. Comparison of the four devices shows that severalunique approaches based upon the same overall systemarchitecture are possible. Preliminary results of theExcorp Medical BLSS Phase I safety evaluation at theUniversity of Pittsburgh, after treating four patients(F, 41, acetominophen-induced, two support periods;M, 50, Wilson's disease, one support period; F, 53, a-cute alcoholic hepatitis, two support periods; F, 24,chemotherapy-induced, one support period) are pre-sented. All patients presented with hypoglycemia andtransient hypotension at the start of extracorporealperfusion. Hypoglycemia was treated by IV dextroseand the transient hypotension responded positively toIV fluid bolus. Heparin anticoagulation was used onlyin the second patient. No serious or adverse eventswere noted in the four patients. Moderate biochemicalresponse to support was noted in all patients. Morecomplete characterization of the safety of the BLSSrequires completion of the Phase I safety evaluation.
基金supported by grants from the National Natural Science Foundation of China (30630023)the Science Fund for Creative Research Groups of the National Natural Science Foundation of China (81121002)
文摘BACKGROUND: For nearly three decades, extracorporeal bioartificial liver (BAL) support systems have been anticipated as promising tools for the treatment of liver failure. However, these systems are still far from clinical application. This review aimed to analyze the key challenges to the development of BALs. DATA SOURCE: We carried out a PubMed search of Englishlanguage articles relevant to extracorporeal BAL support systems and liver failure. RESULTS: Extracorporeal BALs face a series of challenges. First, an appropriate cell source for BAL is not readily available. Second, existing bioreactors do not provide in vivolike oxygenation and bile secretion. Third, emergency needs cannot be met by current BALs. Finally, the effectiveness of BALs, either in animals or in patients, has been difficult to document. CONCLUSIONS: Extracorporeal BAL support systems are mainly challenged by incompetent cell sources and flawed bioreactors. To advance this technology, future research is needed to provide more insights into interpreting the conditions for hepatocyte differentiation and liver microstructure formation.
