Investigation of liquid sodium alginates as mucoadhesive bandages coating the oesophageal mucosa and protecting it from gastric reflux

Gastro-oesophageal Reflux Disease (GORD), is generally caused by excess gastric reflux back to the oesophagus where damage to the mucosa results in injury. GORD is a very common disease in western countries, more than a quarter of western people are suffering from this disease and there is a trend that the percentage population in eastern countries who are diagnosed as GORD is increasing. GORD and its complications damage the quality of life and can lead to serious oesophageal diseases including Barrett’s disease and oesophageal carcinoma. Sodium alginate dissolved in water forms a viscous liquid and can coat on oesophageal mucosa for a period of time. In this study the ability of the liquid alginate to adhere to the oesophageal mucosa was investigated and the factors that affect this retention were examined. The potential of this liquid alginate as a drug delivery vehicle to extend the duration of contact with the oesophageal mucosa was confirmed by this study. The capacity of an alginate coating to retard acid and pepsin diffusion, the two main aggressive factors in gastric reflux, was investigated. A significant reduction in acid and pepsin diffusion by alginate gel layer was demonstrated in this project, indicating that alginate has great potential to protect against damage caused by acidic reflux. A novel method was introduced using an independent score system to assess the protection of oesophageal tissue by a coating of liquid alginate using microscopy as a technique. This technique demonstrated that alginate can protect the oesophageal epithelial tissue from the damage caused by gastric acid and pepsin. Many techniques were used in this study. The experimental results suggested that liquid sodium alginate is a very promising candidate in treating local oesophageal diseases through forming a coating on the oesophageal mucosal surface, retarding the diffusion of components of gastric refluxate and thus reducing the contact of these noxious factors with the epithelium and minimising injury.

Regulation of mucus secretion by cells isolated from the rat gastric mucosa

     This study was undertaken to further understanding of the mechanisms which regulate mucus secretion by rat stomach cells. Particular objectives were: (i) to develop and use a radiochemical assay to estimate the secretion of mucin by a suspension of gastric mucosal cells in vitro, (ii) to develop and use a solid-phase enzyme immunoassay (EIA) to study the regulation of the release of bulk gastric mucin from the isolated cells and (iii) to compare the results obtained with the two procedures.      Cells were isolated by exposure of gastric mucosa to pronase and EDTA. Cell suspensions were preincubated with D-[6-3H]glucosamine. [3H]-labelled material of high molecular mass released into the incubation medium, was purified by Fast Protein Liquid Chromatography, and appeared to be gastric mucin. Some unidentified [3H]-labelled material of lower molecular mass was also found in the medium. Release of [3H]-labelled high molecular mass material was essentially linearly related to time. Secretin, isoprenaline and carbachol stimulated release of [3H]-labelled high molecular mass material. The half-maximally effective concentrations of secretin and isoprenaline were 2.3nM and 34nM respectively. Histamine, gastrin and epidermal growth factor were without effect.      A rabbit polyclonal antibody was raised by using purified 'native' rat gastric mucin as immunogen. The antibody preparation appeared specific for rat gastric mucin and was used to establish a quantitative solid-phase EIA. Release of bulk mucin was essentially linearly related to time. Phorbol-12-myristate-13-acetate (PMA), forskolin and A23187 dose-dependently stimulated bulk mucin release. Synergistic interactions were observed between PMA and forskolin, and PMA and A23187. Secretin and isoprenaline were confirmed as mucin secretogogues.      In conclusion gastric mucin release was investigated for the first time by using a suspension of gastric mucosal cells. Two different assay procedures were developed. Some pathways and agents responsible for controlling mucin secretion were identified.

Production and action of local mediators in the rat gastric mucosa

This study concerns the production and action of the local mediators nitric oxide (NO) and prostaglandin E2 (PGE2) in the rat gastric mucosa. The major objectives were: (i) to determine which mucosal cell type(s) contained NO synthase activity, (ii) to establish the functional role(s) of NO in the gastric mucosa and (iii) to investigate regulation of gastric PGE2 production. Gastric mucosal cells were isolated by pronase digestion coupled with intermittent calcium chelation and were separated by either density-gradient centrifugation or by counterflow elutriation. The distribution of Ca2+ -dependent NO synthase activity, measured via the conversion of [14C]-L-arginine to [14C]-L- citrulline, paralleled the distribution of mucous cells in elutriated fractions. Pre-treatment of rats with lipopolysaccharide caused the induction of Ca2+ -independent NO synthase in the elutriator fractions enriched with mucous cells. Incubation of isolated cells with the NO donor isosorbide dinitrate (ISDN) produced a concentration-dependent increase in the guanosine 3',-5'-cyclic monophosphate (cGMP) content which was accompanied by a concentration-dependent increase in release of immunoreactive mucin. Intragastric administration of ISDN of dibutyryl cGMP in vivo increased the thickness of the mucus layer overlying the gastric mucosa. The NO donor S-nitroso-N-acetylpenicillamine (SNAP) produced a concentration-dependent inhibition (IC50 247 μM) of histamine-stimulated aminopyrine accumulation, a measure of secretory activity, in cell suspensions containing > 80% parietal cells. SNAP increased the cGMP content of the suspension but did not decrease cellular viability, glucose oxidation or adenosine 3',5'-cyclic monophosphate content. The inhibitory effect of SNAP was observed in permeabilised cells stimulated with ATP and was stereospecifically blocked by preincubation with Rp-8-bromoguanosine 3'-5'-monophosphorothioate, which inhibits activation of cGMP-dependent protein kinase. Stimulation of PGE2 release by bradykinin in a low density cell fraction, enriched with parietal cells and devoid of vascular endothelial cells and macrophages, involved a bradykinin B1 receptor. In summary, NO synthase activity is probably present in gastric mucous epithelial cells. NO may promote mucus secretion by elevation of cGMP. NO donors inhibit acid secretion at a specific site and their action may involve cGMP. The bradykinin B1 receptor is involved with PGE2 production in the gastric mucosa.