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Urea Synthesis (urea + synthesis)

Distribution by Scientific Domains
Medical Sciences87%

Selected Abstracts

Intrahepatic amino acid and glucose metabolism in a D -galactosamine,induced rat liver failure model

HEPATOLOGY, Issue 2 2001
Kosuke Arai
A better understanding of the hepatic metabolic pathways affected by fulminant hepatic failure (FHF) would help develop nutritional support and other nonsurgical medical therapies for FHF. We used an isolated perfused liver system in combination with a mass-balance model of hepatic intermediary metabolism to generate a comprehensive map of metabolic alterations in the liver in FHF. To induce FHF, rats were fasted for 36 hours, during which they received 2 D -galactosamine injections. The livers were then perfused for 60 minutes via the portal vein with amino acid,supplemented Eagle minimal essential medium containing 3% wt/vol bovine serum albumin and oxygenated with 95% O2/5% CO2. Control rats were fasted for 36 hours with no other treatment before perfusion. FHF rat livers exhibited reduced amino acid uptake, a switch from gluconeogenesis to glycolysis, and a decrease in urea synthesis, but no change in ammonia consumption compared with normal fasted rat livers. Mass-balance analysis showed that hepatic glucose synthesis was inhibited as a result of a reduction in amino acid entry into the tricarboxylic acid cycle by anaplerosis. Furthermore, FHF inhibited intrahepatic aspartate synthesis, which resulted in a 50% reduction in urea cycle flux. Urea synthesis by conversion of exogenous arginine to ornithine was unchanged. Ammonia removal was quantitatively maintained by glutamine synthesis from glutamate and a decrease in the conversion of glutamate to ,-ketoglutarate. Mass-balance analysis of hepatic metabolism will be useful in characterizing changes during FHF, and in elucidating the effects of nutritional supplements and other treatments on hepatic function. [source]

The mitochondrial proteome: A dynamic functional program in tissues and disease states,

ENVIRONMENTAL AND MOLECULAR MUTAGENESIS, Issue 5 2010
Robert S. Balaban
Abstract The nuclear DNA transcriptional programming of the mitochondria proteome varies dramatically between tissues depending on its functional requirements. This programming generally regulates all of the proteins associated with a metabolic or biosynthetic pathway associated with a given function, essentially regulating the maximum rate of the pathway while keeping the enzymes at the same molar ratio. This may permit the same regulatory mechanisms to function at low- and high-flux capacity situations. This alteration in total protein content results in rather dramatic changes in the mitochondria proteome between tissues. A tissues mitochondria proteome also changes with disease state, in Type 1 diabetes the liver mitochondrial proteome shifts to support ATP production, urea synthesis, and fatty acid oxidation. Acute flux regulation is modulated by numerous posttranslational events that also are highly variable between tissues. The most studied posttranslational modification is protein phosphorylation, which is found all of the complexes of oxidative phosphorylation and most of the major metabolic pathways. The functional significance of these modifications is currently a major area of research along with the kinase and phosphatase regulatory network. This near ubiquitous presence of protein phosphorylations, and other posttranslational events, in the matrix suggest that not all posttranslational events have functional significance. Screening methods are being introduced to detect the active or dynamic posttranslational sites to focus attention on sites that might provide insight into regulatory mechanisms. Environ. Mol. Mutagen., 2010. Published 2010 Wiley-Liss, Inc. [source]

Interorgan ammonia and amino acid metabolism in metabolically stable patients with cirrhosis and a TIPSS

HEPATOLOGY, Issue 5 2002
Steven W. M. Olde Damink
Ammonia is central to the pathogenesis of hepatic encephalopathy. This study was designed to determine the quantitative dynamics of ammonia metabolism in patients with cirrhosis and previous treatment with a transjugular intrahepatic portosystemic stent shunt (TIPSS). We studied 24 patients with cirrhosis who underwent TIPSS portography. Blood was sampled and blood flows were measured across portal drained viscera, leg, kidney, and liver, and arteriovenous differences across the spleen and the inferior and superior mesenteric veins. The highest amount of ammonia was produced by the portal drained viscera. The kidneys also produced ammonia in amounts that equaled total hepatosplanchnic area production. Skeletal muscle removed more ammonia than the cirrhotic liver. The amount of nitrogen that was taken up by muscle in the form of ammonia was less than the glutamine that was released. The portal drained viscera consumed glutamine and produced ammonia, alanine, and citrulline. Urea was released in the splenic and superior mesenteric vein, contributing to whole-body ureagenesis in these cirrhotic patients. In conclusion, hyperammonemia in metabolically stable, overnight-fasted patients with cirrhosis of the liver and a TIPSS results from portosystemic shunting and renal ammonia production. Skeletal muscle removes more ammonia from the circulation than the cirrhotic liver. Muscle releases excessive amounts of the nontoxic nitrogen carrier glutamine, which can lead to ammonia production in the portal drained viscera (PDV) and kidneys. Urinary ammonia excretion and urea synthesis appear to be the only way to remove ammonia from the body. [source]

Intrahepatic amino acid and glucose metabolism in a D -galactosamine,induced rat liver failure model

HEPATOLOGY, Issue 2 2001
Kosuke Arai
A better understanding of the hepatic metabolic pathways affected by fulminant hepatic failure (FHF) would help develop nutritional support and other nonsurgical medical therapies for FHF. We used an isolated perfused liver system in combination with a mass-balance model of hepatic intermediary metabolism to generate a comprehensive map of metabolic alterations in the liver in FHF. To induce FHF, rats were fasted for 36 hours, during which they received 2 D -galactosamine injections. The livers were then perfused for 60 minutes via the portal vein with amino acid,supplemented Eagle minimal essential medium containing 3% wt/vol bovine serum albumin and oxygenated with 95% O2/5% CO2. Control rats were fasted for 36 hours with no other treatment before perfusion. FHF rat livers exhibited reduced amino acid uptake, a switch from gluconeogenesis to glycolysis, and a decrease in urea synthesis, but no change in ammonia consumption compared with normal fasted rat livers. Mass-balance analysis showed that hepatic glucose synthesis was inhibited as a result of a reduction in amino acid entry into the tricarboxylic acid cycle by anaplerosis. Furthermore, FHF inhibited intrahepatic aspartate synthesis, which resulted in a 50% reduction in urea cycle flux. Urea synthesis by conversion of exogenous arginine to ornithine was unchanged. Ammonia removal was quantitatively maintained by glutamine synthesis from glutamate and a decrease in the conversion of glutamate to ,-ketoglutarate. Mass-balance analysis of hepatic metabolism will be useful in characterizing changes during FHF, and in elucidating the effects of nutritional supplements and other treatments on hepatic function. [source]

In vitro analysis of cryopreserved alginate,poly- l -lysine,alginate-microencapsulated human hepatocytes

LIVER INTERNATIONAL, Issue 4 2010
Hualian Hang
Abstract Background: The availability of well-characterized human hepatocytes that can be frozen and thawed will be critical for cell therapy. We addressed whether human hepatocytes can recover after microencapsulated cryopreservation and investigated whether these cryopreserved microencapsulated hepatocytes can be used for clinical applications. Methods: Adult hepatocytes of 18 separate donors were isolated with a two-step extracorporeal collagenase perfusion technique. After pre-incubation at 4 °C for 12,24 h in HepatoZYME-SFM, hepatocytes were microencapsulated using alginate,poly- l -lysine,alginate microcapsules. The microencapsulated hepatocytes were transferred to a complete medium containing 10% dimethyl sulphoxide. They were immediately placed into an isopropanol progressive freezing container at ,80 °C overnight and immersed in liquid nitrogen the next day. During the post-thawing culture period, albumin secretion, urea synthesis, cell cycle, mRNA and protein levels, as well as the morphology and pathology structure of pre-incubation before microencapsulated cryopreservation (PMC) groups were analysed. Results: Compared with the immediate cryopreservation (IC) groups, we found significant improvement in the mRNA and protein levels in the attached cells, and higher secretion of albumin and urea levels after thawing. In the attached cultured human cryopreserved/thawed hepatocytes from the PMC group, albumin production was not significantly different from those of the direct culture groups on days 2, 3 and 4. The preserved morphology in the PMC group compared with the IC group was obvious. Conclusions: The results of the present study suggested recovery of the functional and morphological integrity of human hepatocytes after pre-incubation at 4 °C for 12,24 h before microencapsulated cryopreservation. These studies offer the possibility for clinical applications in pharmacotoxicology, bioartificial liver and cell therapy in humans. [source]

Maintenance of integrity and function of isolated hepatocytes during extended suspension culture at 25°C

LIVER INTERNATIONAL, Issue 3 2003
Alan J. Wigg
Abstract: Isolated hepatocytes in suspension provide a number of advantages for use in bioartificial liver device, however, poor stability of this cell preparation at physiological temperatures is an apparent barrier preventing their use. We therefore investigated the integrity and differentiated function of isolated rat hepatocytes under conditions of mild hypothermia. Isolated hepatocytes were suspended in a bicarbonate buffered saline medium, supplemented with glucose and bovine serum albumin (BSA), and maintained for 48 h at 25 °C on a rotary shaker under an atmosphere of 95% O2 and 5% CO2. Under these conditions there was no significant decline in cell viability and good preservation of cellular morphology on transmission electron microscopy for at least 24 h. Isolated hepatocytes in suspension at 25 °C were also able to maintain normal Na + and K + ion gradients. The cellular energy status ([ATP], ATP/ADP ratio, cytoplasmic and mitochondrial redox potentials), metabolic function (urea synthesis and ammonia removal), albumin synthesis and phase I and phase II drug detoxification activity of these cells were also maintained for at least 24 h post isolation. These observations demonstrate the robust nature of mildly hypothermic isolated hepatocytes in suspension and encourage further studies re-examining the feasibility of using this cell preparation in bioartificial livers. [source]

Alginate-encapsulated HepG2 Cells in a Fluidized Bed Bioreactor Maintain Function in Human Liver Failure Plasma

ARTIFICIAL ORGANS, Issue 12 2009
Sam M. Coward
Abstract Alginate-encapsulated HepG2 cells cultured in microgravity have the potential to serve as the cellular component of a bioartificial liver. This study investigates their performance in normal and liver failure (LF) human plasma over 6,8 h in a fluidized bed bioreactor. After 8 days of microgravity culture, beads containing 1.5 × 109 cells were perfused for up to 8 h at 48 mL/min with 300 mL of plasma. After exposure to 90% LF plasma, vital dye staining showed maintained cell viability, while a 7% increase in lactate dehydrogenase activity indicated minimal cell damage. Glucose consumption, lactate production, and a 4.3-fold linear increase in alpha-fetoprotein levels were observed. Detoxificatory function was demonstrated by quantification of bilirubin conjugation, urea synthesis, and Cyp450 1A activity. These data show that in LF plasma, alginate-encapsulated HepG2 cells can maintain viability, and metabolic, synthetic, and detoxificatory activities, indicating that the system can be scaled-up to form the biological component of a bioartificial liver. [source]

SiO2 Entrapment of Animal Cells: Liver-Specific Metabolic Activities in Silica-Overlaid Hepatocytes

ARTIFICIAL ORGANS, Issue 8 2002
Maurizio Muraca
Abstract: Rat hepatocytes in a collagen-gel sandwich configuration were exposed to silicon alkoxides in a gas phase, yielding a 0.05 to 0.15 ,m porous silica layer on the gel surface. Cell viability was unaffected by the procedure. After 24 h, bilirubin conjugation, ammonia removal, urea synthesis, and diazepam metabolism were unaffected by the procedure. However, both the ammonia removal rate and diazepam metabolism were increased after 48 hr, whereas urea synthesis was unaffected. These data indicate that silica overlay allows efficient metabolic activity of collagen-gel entrapped hepatocytes. The fact that the KM of bilirubin conjugation was unaffected by the presence of the silica membrane suggests that the transport of albumin-bound substrates is not decreased. The enhancement in some metabolic activities found 48 h after the entrapment procedure may be the result of favorable changes in the hepatocyte microenvironment. These characteristics might be useful for the development of organotypical bioartificial liver devices. [source]