Bioavailability of aspirin in rats comparing the drug's uptake into gastrointestinal tissue and vascular and lymphatic systems: implications on aspirin's chemopreventive action.

Aspirin is an effective analgesic and antiplatelet drug that in addition to its ability to reduce pain, inflammation and fever, appears to have efficacy in the prevention/treatment of a range of diseases including heart disease, numerous cancers and Alzheimer's. It is important to understand the bioavailability of aspirin and its major metabolite, salicylic acid, since dosage and route of administration can vary for treating differing diseases, and the major side-effects of aspirin, upper gastrointestinal ulceration and bleeding, are dose-dependent. We examined the time course for gastroduodenal uptake of aspirin and the appearance of its major metabolite salicylic acid in blood and lymph after intragastric (to simulate oral) and intraduodenal (to simulate enteric-coating) dosing in rats. Results show that after intragastric dosing, intact aspirin is absorbed primarily by the gastric mucosa and to a lesser extent by the duodenal mucosa. When aspirin is dosed intragastrically or intraduodenally, a much greater concentration of aspirin enters the lymph than the blood. In contrast, the concentration of salicylic acid was higher in blood than in lymph. Lymph levels of both aspirin and salicylic acid were sufficiently high so as to perform a pharmacologic function there, possibly as a chemopreventive agent against colon cancer and potentially the metastatic spread of non-gastrointestinal cancers.

Formula Feeding Predisposes Gut to NSAID-Induced Small Intestinal Injury.

OBJECTIVES: Breast feeding protects infants from many diseases, including necrotizing enterocolitis, peptic ulceration and infectious diarrhea. Conversely, maternal separation stress and Non-Steroidal Anti-Inflammatory Drugs (NSAID's) can induce intestinal injury and bleeding. This study aimed to evaluate in suckling rats if maternal separation/formula feeding leads to increased intestinal sensitivity to indomethacin (indo)-induced intestinal injury and to look at potential mechanisms involved. METHODS: Nine-day-old rats were dam-fed or separated/trained to formula-feed for 6 days prior to indo administration (5 mg/kg/day) or saline (control) for 3 days. Intestinal bleeding and injury were assessed by measuring luminal and Fecal Hemoglobin (Hob) and jejunal histology. Maturation of the intestine was assessed by measuring luminal bile acids, jejunal sucrase, serum corticosterone, and mRNA expression of ileal Apical Sodium-Dependent Bile Acid Transporter (ASBT). RESULTS: At 17 days, formula-fed indo-treated pups had a 2-fold increase in luminal Hb compared to formula-fed control pups and had evidence of morphological injury to the small intestinal mucosa as observed at the light microscopic level, whereas indo had no effect on dam-fed littermates. In addition, formula-fed rats had significant increases in luminal bile acid, sucrase specific activity, serum corticosterone, and expression of ASBT mRNA compared to dam-fed rats. CONCLUSION: Maternal separation stress may cause early intestinal maturational changes induced by corticosteroid release, including increased epithelial exposure to bile acids. These maturational changes may have a sensitizing rather than protective effect against indo-induced injury in the new-born.

Gastrointestinal safety and therapeutic efficacy of parenterally administered phosphatidylcholine-associated indomethacin in rodent model systems.

BACKGROUND AND PURPOSE: Indomethacin is a non-steroidal anti-inflammatory drug (NSAID) that is limited in its enteral or parenteral use by side effects of gastroduodenal bleeding and ulceration. We have investigated the ability of phosphatidylcholine associated with indomethacin to form a therapeutically effective drug (INDO-PC) with reduced gastrointestinal (GI) toxicity for parenteral use. EXPERIMENTAL APPROACH: Rats were treated acutely by intravenous or chronically with subcutaneous injection of vehicle, indomethacin or INDO-PC using three related protocols. We then evaluated the following properties of these parenterally administered test drugs: (i) GI toxicity (luminal and faecal haemoglobin; intestinal perforations and adhesions; and haematocrit); (ii) bioavailability (plasma indomethacin); and (iii) therapeutic efficacy (analgesia from sensitivity to pressure; anti-inflammatory from ankle thickness; cyclo-oxygenase (COX) inhibition from synovial fluid prostaglandin E(2) concentration) in rats with adjuvant-induced joint inflammation. KEY RESULTS: Acute and chronic dosing with INDO-PC produced less GI bleeding and intestinal injury than indomethacin alone, whereas the bioavailability, analgesic, anti-inflammatory and COX inhibitory activity of INDO-PC were comparable to indomethacin. CONCLUSIONS AND IMPLICATIONS: The chemical association of phosphatidylcholine with indomethacin appears to markedly reduce the GI toxicity of the NSAID while providing equivalent therapeutic efficacy in a parenteral INDO-PC formulation.

Naproxen-PC: a GI safe and highly effective anti-inflammatory.

UNLABELLED: We have been developing a family of phosphatidylcholine (PC)-associated NSAIDs, which appear to have improved GI safety and therapeutic efficacy in both rodent model systems and pilot clinical trials. As naproxen has been demonstrated to be associated with the lowest cardiovascular adverse events in comparison with both COX-2 selective inhibitors and conventional NSAIDs, we have been developing a Naproxen-PC formulation for evaluation in animal models and clinical trials. We have determined that an oil-based formulation of naproxen and triple strength soy lecithin provides excellent GI protection in both: 1) an acute NSAID-induced intestinal bleeding model in rats pretreated with L-NAME that are intragastrically administered a single dose of naproxen (at a dose of 50 mg/kg) vs the equivalent dose of Naproxen-PC; and 2) a more chronic model (at a naproxen dose of 25 mg/kg BID) in rats that have pre-existing hindpaw inflammation (induced with a intradermal injection of Complete Freund's Adjuvant/CFA). Both models demonstrate the superior GI safety of Naproxen-PC vs naproxen while this novel formulation had significant anti-inflammatory efficacy to reduce hindpaw edema and the generation of PGE(2) in the collected joint synovial fluid. CONCLUSION: Naproxen-PC appears to induce significantly less GI injury and bleeding in two rodent model systems while maintaining anti-inflammatory and COX-inhibitory activity.

Surface phospholipids in gastric injury and protection when a selective cyclooxygenase-2 inhibitor (Coxib) is used in combination with aspirin.

BACKGROUND AND PURPOSE: Clinical studies demonstrate that aspirin consumption reverses the gastrointestinal (GI) benefits of coxibs, by an undefined mechanism. EXPERIMENTAL APPROACH: Rodent models were employed to investigate the effects of combinations of celecoxib and aspirin on gastric ulcerogenesis, bleeding, surface hydrophobicity (by contact angle analysis) and ulcer healing. We also evaluated the effects of phosphatidylcholine (PC)-associated aspirin in these rodent models and confirmed its cyclooxygenase (COX)-inhibitory activity by measuring mucosal prostaglandin E(2) (PGE(2)) concentration. We present evidence that aspirin's ability to induce gastric injury and bleeding in rats, was exacerbated in the presence of a coxib and was dependent on its ability to reduce gastric surface hydrophobicity. In contrast, co-administration of phosphatidylcholine (PC)-associated aspirin and celecoxib induced little or no gastric injury/bleeding and maintained the stomach's hydrophobic properties. Interestingly, aspirin and aspirin/PC equally inhibited gastric mucosal PGE(2) concentration. Aspirin in combination with a coxib retarded the healing of experimentally induced gastric ulcers, whereas healing rates of rats treated with celecoxib in combination with aspirin/PC were comparable to controls. CONCLUSIONS AND IMPLICATIONS: Aspirin's gastric toxicity in combination with a coxib can be dissociated from its ability to inhibit COX-1 and appears to be dependent, in part, on its ability to attenuate the stomach's surface hydrophobic barrier. This adverse drug interaction between aspirin and coxibs, which impacts the treatment of osteoarthritic and cardiac patients requiring cardiovascular prophylaxis, can be circumvented by the administration of phosphatidylcholine (PC)-associated aspirin, to maintain the stomach's hydrophobic properties.

Altered gastrin regulation in mice infected with Helicobacter felis.

Altered gastrin expression associated with Helicobacter pylori infection may contribute to the pathogenesis of peptic ulcer disease or gastric cancer in man, but gastrin has not been investigated in a murine model of Helicobacter infection. C57BL/6 mice were inoculated with Helicobacter felis and examined after 4-21 weeks for G and D cell numbers, antral gastrin and somatostatin mRNA, and luminal pH. In H. felis-infected mice, gastrin mRNA declined at four and six weeks after infection to 57% and 23%, respectively, of uninfected control values. Concurrently, somatostatin mRNA showed no change at four weeks and a modest 25% decrease at six weeks after infection. Similar reductions were noted in G and D cell numbers, resulting in a decrease in the G/D cell ratio after mice were infected with H. felis. Infected animals also showed a loss of parietal and chief cells, and an increased gastric pH. H. felis infection in C57BL/6 mice leads to an early suppression of G cell number and gastrin mRNA. These changes precede an alteration in somatostatin cell number and mRNA and, coupled with reductions in parietal and chief cells, may contribute both to severe impairment of gastric acid output and the potential for carcinogenic processes.

Recombinant human lactoferrin is effective in the treatment of Helicobacter felis-infected mice.

Recombinant human lactoferrin possesses in-vitro antibiotic and anti-inflammatory activity similar to the native form. It was tested for in-vivo activity in mice infected with the gastritis-inducing bacterium Helicobacter felis. A two-week course of treatment with lactoferrin was sufficient to partially reverse both infection-induced gastritis and the infection rate, and fully reverse gastric surface hydrophobicity changes. A comparison of lactoferrin with amoxicillin and standard triple therapy revealed no differences in infection rate. These results show that recombinant human lactoferrin is effective in a mouse model of Helicobacter infection, and support further testing of this promising agent for this application.

Attenuation of hydrophobic phospholipid barrier is an early event in Helicobacter felis-induced gastritis in mice.

Helicobacter pylori infection has been linked to the development of gastritis which can then progress to a number of disease entities including peptic ulcer disease and gastric cancer. Since the pathogenic mechanism by which the bacteria causes gastritis is unresolved, we employed a model system, the H. felis-infected mouse to investigate the temporal relationship between bacterially-induced alterations in the hydrophobic phospholipid barrier of the stomach and the development of gastritis. In the present study, C57BL/6 mice were inoculated with 10(9) CFU of H. felis and the changes in gastric wet weight, histology, surface hydrophobicity, phospholipid/phosphatidylcholine concentration, phospholipase A2 activity, and the pH of collected gastric juice were measured 0.5-2 months postinoculation. In related experiments, we investigated the effects of treating H. felis infected mice with antibiotic/ bismuth therapy on the above gastric properties. It was determined that both gastric surface hydrophobicity and phospholipid composition were significantly attenuated as early as 2-4 weeks postinfection, preceding signs of mucosal inflammation and glandular atrophy as indicated by increases in gastric wet weight, pH and a disappearance in parietal cells. These early H. felis-induced changes in gastric surface hydrophobicity and phospholipid concentration were reversed by antibiotic/bismuth therapy. Based on these results we conclude that H. felis infection induces an early transformation of the stomach from a hydrophobic to an acid-sensitive hydrophilic state that may trigger the subsequent development of gastritis.

Antibiotic properties of bovine lactoferrin on Helicobacter pylori.

To investigate a potential new treatment for gastric Helicobacter pylori infection, we have examined the use of the natural antibiotic lactoferrin, found in bovine milk, for activity against Helicobacter species both in vitro and in vivo. Lactoferrin was bacteriostatic to H. pylori when cultured at concentrations > or =0.5 mg/ml. Growth of H. pylori was not inhibited by another milk constituent, lysozyme, or by a metabolite of lactoferrin, lactoferricin B, but growth was inhibited by the iron chelator deferoxamine mesylate. Lactoferrin inhibition of growth could be reversed by addition of excess iron to the medium. Lactoferrin in retail dairy milk was found to be more stable intragastrically than unbuffered, purified lactoferrin. Treatment of H. felis-infected mice with lactoferrin partially reversed mucosal disease manifestations. It is concluded that bovine lactoferrin has significant antimicrobial activity against Helicobacter species in vitro and in vivo. Bovine lactoferrin should be further investigated for possible use in H. pylori infections in man.

Effect of omeprazole on the bioavailability of unmodified and phospholipid-complexed aspirin in rats.

BACKGROUND: Treatment and prevention of non-steroidal anti-inflammatory drug-induced gastropathy involve the concurrent use of antisecretory drugs. Recently, we have shown that the ability of these drugs to increase the intragastric pH to values > > pKa of NSAIDs compromises their therapeutic activity. In the present study, we evaluated the potential of omeprazole to interfere with the bioavailability of aspirin administered to rats either alone or complexed with the zwitterionic phospholipid, dipalmitoylphosphatidylcholine (DPPC). METHODS: Aspirin or aspirin/DPPC was administered intragastrically to rats pre-dosed with either saline or omeprazole. Concentrations of aspirin and salicylic acid in the blood and the gastric mucosa were assessed by HPLC and the 6-keto-PGF1 alpha gastric mucosal concentration by radioimmunoassay. RESULTS: Gastric absorption of aspirin and its relative bioavailability were reduced by an antisecretory dose of omeprazole; its inhibitory effect on gastric prostaglandin synthesis was consequently attenuated. However, these effects could be partly overcome if aspirin was administered as a complex with DPPC. CONCLUSIONS: These observations suggest that: (i) DPPC increases the lipid solubility and gastric permeability of NSAIDs; and (ii) neutralization of the gastric pH results in a shift of aspirin absorption toward the intestine where it could be degraded to salicylic acid.