4 resultados para Ornithine phenylacetate
em Aston University Research Archive
Resumo:
The objective of the work described was to identify and synthesize a range of biodegradable hypercoiling or hydrophobically associating polymers to mimic natural apoproteins, such as those found in lung surfactant or plasma apolipoproteins. Stirred interfacial polymerization was used to synthesize potentially biodegradable aromatic polyamides (Mw of 12,000-26,000) based on L-Iysine, L-Iysine ethyl ester, L-ornithine and DL-diaminopropionic acid, by reaction with isophthaloyl chloride. A similar technique was used to synthesize aliphatic polyamides based on L-Iysine ethyl ester and either adipoyl chloride or glutaryl chloride resulting in the synthesis of poly(lysine ethyl ester adipamide) [PLETESA] or poly(lysine ethyl ester glutaramide) (Mw of 126,000 and 26,000, respectively). PLETESA was found to be soluble in both polar and non-polar solvents and the hydrophobic/hydrophilic balance could be modified by partial saponification (66-75%) of the ethyl ester side chains. Surface or interfacial tension/pH profiles were used to assess the conformation of both the poly(isophthalamides) and partially saponified PLETESA in aqueous solution. The results demonstrated that a loss of charge from the polymer was accompanied by an initial fall in surface activity, followed by a rise in activity, and ultimately, by polymer precipitation. These observations were explained by a collapse of the polymer chains into non-surface active intramolecular coils, followed by a transition to an amphipathic conformation, and finally to a collapsed hydrophobe. 2-Dimensional NMR analysis of polymer conformation in polar and non-polar solvents revealed intramolecular associations between the hydrophobic groups within partially saponified PLETESA. Unsaponified PLETESA appeared to form a coiled structure in polar solvents where the ethyl ester side chains were contained within the polymer coil. The implications of the secondary structure of PLETESA and potential biomedical applications are discussed.
Resumo:
Nitric oxide is a free-radical gas which can exert both protective and damaging effects. The objectives of the thesis were: (i) to investigate arginine metabolism in isolated rat gastric mucosal cells, (ii) to investigate the role of NO in the induction of ornithine decarboxylase in the rat gastric mucosa damaged by hypertonic saline in vivo, (iii) to expose primary cultures of guinea-pig gastric mucosal cells to oxidative challenge and an NO donor, and to investigate the response in terms of heat shock protein 72 (HSP 72) induction, and (iv) to investigate the induction of iNOS and the role of potential modulators of activity in gastric cell lines. Isolated rat gastric mucosal cells converted exogenous arginine to ornithine and citrulline. This metabolism of arginine was not affected by a range of NO synthase inhibitors, but was reduced by the arginase inhibitors NG-hydroxy-L-arginine and L-ornithine. Thus, the predominant pathway of arginine metabolism involves arginase and ornithine transcarbamoylase, not NO synthase. Pretreatment of rats with NG-nitro-L-arginine promoted activation of ornithine decarboxylase after intragastric hypertonic saline, but did not increase acid phosphatase release (damage). NO may therefore restrict activation of ornithine decarboxylase in response to damage. Exposure of primary cultures of guinea-pig gastric mucosal cells to S-nitroso-N-acetyl-penicillamine (SNAP) caused a concentration dependent induction of HSP 72, which was inhibited by an NO scavenger and blockade of transcription. The effect of SNAP was enhanced by decreasing the intracellular reduced thiol content with diethyl maleate, which itself also induced HSP 72 formation. Substantial amounts of NO may induce defensive responses in cells. Induction of iNOS was not detected in HGT-1 or AGS cells exposed to cytokines. Conclusions An arginase pathway may restrict availability of arginine for NO synthase in gastric mucosa or may be present to supply ornithine for polyamine synthesis. NO may modulate the response to damage of the stomach epithelium in vivo. Exogenous NO may induce a defensive response in gastric mucosal cells.
Resumo:
Previous studies in man have shown that following dosing with L--3,4-dihydroxyphenylalanine (L-DOPA) and cotrimoxazole, plasma biopterins were raised. By analogy with dihydropteridine reductase deficient children in whom plasma biopterins are greatly elevated and the observations that these preparations were dihydropteridine reductase inhibitors, it was assumed that these raised plasma levels were due to increased efflux from tissues which resulted in tissue depletion of biopterins. In some human disease states such as senile dementia of the Alzheimer type lowered plasma biopterins were observed; by analogy with tetrahydrobiopterin synthesis deficient children these reduced plasma biopterins were attributed to lowered tetrahydrobiopterin synthesis and concomitant low tissue biopterin levels. Because of ethical considerations it was not possible to measure directly the tissue biopterins changes in either case. The Wistar rat was used as a model for human tetrahydrobiopterin metabolism, since tissues not normally accessible for study in humans, such as the brain and liver, could be examined for their effects on tetrahydrobiopterin metabolism after administration of the various agents. Plasma total biopterins in normal conditions were found to be much higher than in healthy humans. The elevation of plasma total biopterins concentration following the administration of dihydropteridine reductase inhibitors to humans, such as L-DOPA and cotrimoxazole was not observed in the rat. However, the administration of inhibitors of de novo tetrahydrobiopterin biosynthesis, such as diaminohydroxypyrimidine (DAHP) and bromocriptine was shown to decrease plasma biopterins concentration. In general, hepatic biopterins were decreased after administration of both dihydropteridine reductase inhibitors and de novo biosynthesis inhibitors. Drugs which are direct (bromocriptine) or indirect (L-DOPA and Sinemet Plus) agonists at dopamine receptors were investigated and were shown to decrease hepatic total biopterins concentration, but had no effect on brain biopterins. Bromocriptine was demonstrated as a potent inhibitor of de novo tetrahydrobiopterin biosynthesis in vivo and in vitro. Cotrimoxazole decreased brain tetrahydrobiopterin concentration. DAHP was effective in causing hyperphenylalaninaemia due to tetrahydrobiopterin deficiency in the rat. p-hydroxyphenylacetate was shown to be an effective inhibitor of dihydropteridine reductase in vivo. Phenylacetate administration had no observable effect on tetrahydrobiopterin metabolism, but did cause tyrosinaemia. It is proposed that scopolamine reduces tetrahydrobiopterin turnover. Lead and aluminium exposure caused deranged tetrahydrobiopterin metabolism. Aluminium, but not lead decreased brain choline acetyltransferase activity. Phenylalanine loading in normal human subjects was followed by an elevation in plasma biopterins which was not observed after tyrosine loading. Plasma N : B ratios correlated well with VEP latencies after tyrosine loading, but not after phenylalanine loading in healthy subjects. The use of derived pterin measurements as an indicator of tetrahydrobiopterin turnover or tetrahydrofolate status is discussed in the text.
Resumo:
A variety of islet microencapsulation techniques have been investigated to establish which method provides the least occlusive barrier to net insulin release in vitro, and optimum biocompatibility for islet implantation in vivo. NMRI mouse islets have been microencapsulated with Na+ -alginate-poly-L-lysine (PLL)/poly-L-ornithine (PLO)-alginate, Ba2+ -alginate and agarose gels. Both free and microencapsulated islets responded to glucose challenge in static incubation and perifusion by significantly increasing their rate of insulin release and theophylline significantly potentiated the insulin response to glucose. While little insulin was released from microencapsulated islets after short term (2 hours) static incubation, significantly greater amounts were released in response to glucose challenge after extended (8-24 hours) incubation. However, insulin release from all types of microencapsulated islets was significantly reduced compared with free islets. Na+ -alginate-PLO-alginate microencapsulated islets were significantly more responsive to elevated glucose than Na+ -alginate-PLL-alginate microencapsulated islets, due to the enhanced porosity of PLO membranes. The outer alginate layer created a significant barrier to glucose/insulin exchange and reduced the insulin responsiveness of microencapsulated islets to glucose. Ba2+ -alginate membrane coated islets, generated by the density gradient method, were the most responsive to glucose challenge. Low concentrations of NG-monomethyl L-arginine (L-NMMA) had no significant effect on glucose stimulated insulin release from either free or microencapsulated islets. However, 1.0 mmol/1 L-NMMA significantly inhibited the insulin response of both free and microencapsulated islets to glucose challenge. In vivo work designed to evaluate the extent of pericapsular fibrosis after 28 days ip. and sc. implantation of microencapsulated islets into STZ-diabetic recipients, revealed that the inclusion of islets within microcapsules increased their immunogenicity and markedly increased the extent of pericapsular fibrosis. When the outer alginate layer was omitted from microcapsules, little or no pericapsular mononuclear cell deposition was observed. The subcutaneous site was not suitable for microencapsulated islet transplantation in NMRI recipient mice. Systemic immunosuppression using cyclosporin A was effective in preventing pericapsular mononuclear cell deposition, while L-NMMA loading into microcapsules had no significant effect on pericapsular fibrosis, although it did maintain the integrity of microencapsulated islets.
