Proton pump inhibitors activation

Proton Pump Inhibitors and Acid Pump Antagonists retinoid X receptor (RXR) and is also activated by various lipophilic compounds produced by the body such as bile acids and steroids. PXR heterodimerized with RXR stimulates the transcription of cytochrome P450 3A monooxygenases (CYP3A) and other genes involved in the detoxification and elimination of the... 

Proton Pump Inhibitors and Acid Pump Antagonists. Figure 2 Chemical mechanism of irreversible PPIs. PPIs are accumulated in acidic lumen and converted to active sulfenic acid and/or sulfenamide by acid catalysis. These active forms bind to extracytoplasmic cysteines of the gastric H.K-ATPase [3]. 

The proton pump inhibitors are particularly important in the treatment of Helicobacter pylori in patients with active duodenal ulcers. Helicobacter pylori (H. pylori) has been implicated as a causative organism in a type of chronic gastritis and in a large number of cases of peptic and duodenal ulcers. 

Eradication therapy with a proton pump inhibitor-based three-drug regimen should be considered for all patients who test positive for HP and have an active ulcer or a documented history of either an ulcer or ulcer-related complication. Different antibiotics should be used if a second course of HP eradication therapy is required. 

Benzimidazole is an important heterocyclic nucleus in the field of medicinal chemistry. The most prominent benzimidazole compound in nature is N-ribosyldimethylbenzimidazole, which serves as an axial ligand for cobalt in vitamin B12. The versatile nature of benzimidazole makes it a highly explored molecule in medicinal chemistry. A number of pharmacological activities are associated with benzimidazole derivatives such as anthelmintic, antiulcer, antipsychotic, proton pump inhibitor, antianxiety, anti-emetic and sedative, vasodilator, anticancer, analgesic, antihistaminic, antifungal, antiviral and antimicrobial. 

AstraZeneca launched omeprazole in 1988. It is a safe and effective drug for acid reflux, functioning as a proton pump inhibitor. However, the patent has expired and AstraZeneca has to compete against generics. The company developed the active isomer and called it esomeprazole. It was approved by the Mutual Recognition process in Europe in July 2000, and by the US Food and Drug Administration in February 2001. The chemical formulas for omeprazole and esomeprazole are shown below. 

Omeprazole (p. 167) can cause maximal inhibition of HCl secretion. Given orally in gastric juice-resistant capsules, it reaches parietal cells via the blood. In the acidic milieu of the mucosa, an active metabolite is formed and binds covalently to the ATP-driven proton pump (H+/K+ ATPase) that transports H+ in exchange for IC into the gastric juice. Lansoprazole and pantoprazole produce analogous effects. The proton pump inhibitors are first-line drugs for the treatment of gastroesophageal reflux disease. 

At neutral pH proton pump inhibitors are chemically stable, lipid-soluble, weak bases that have no inhibitory activity. In an acid environment they become protonated and a sulfenamide is formed. This sulfenamide binds covalently to the K+H+-ATPase proton pump in the gastric parietal cells, inhibiting this enzyme irreversibly and thus the entry of H+ ions into lumen. Omeprazole metabolizes at a pH of about 3.9. 1, whereas rabeprazole metabolizes at a pH of about 4.9. Secretion of acid only becomes possible again after new molecules of K+H+-ATPase are formed. 

Rabeprazole belongs to substituted benzimidazole proton-pump inhibitors. In gastric parietal cells, rabeprazole is proto-nated, accumulates and is transformed to an active sulfenamide. 

The proton pump inhibitors are lipophilic weak bases (pKa 4-5) and after intestinal absorption diffuse readily across lipid membranes into acidified compartments (eg, the parietal cell canaliculus). The prodrug rapidly becomes protonated within the canaliculus and is concentrated more than 1000-fold by Henderson-Hasselbalch trapping (see Chapter 1). There, it rapidly undergoes a molecular conversion to the active form, a reactive thiophilic sulfenamide cation, which forms a covalent disulfide bond with the H +, K+ ATPase, irreversibly inactivating the enzyme. 

From a pharmacokinetic perspective, proton pump inhibitors are ideal drugs they have a short serum half-life, they are concentrated and activated near their site of action, and they have a long duration of action. 

Proton pump inhibitors (PPIs), eg, omeprazole, lansoprazole Irreversible blockade of H +, K+-ATPase pump in active parietal cells of stomach Long-lasting reduction of stimulated and nocturnal acid secretion Peptic ulcer, gastroesophageal reflux disease, erosive gastritis Half-lives much shorter than duration of action low toxicity reduction of stomach acid may reduce absorption of some drugs and increase that of others... 

Finally, it is universally accepted at present that Helicobacter pylori infection has a definitive ethiological role in peptic ulcer disease, and that erradication therapy is warranted in these clinical scenarios. The majority of therapeutic trials have included the application of triple therapy with proton pump inhibitors or ranitidine bismuth citrate, clarithromycin and either amoxycillin or metronidazol and is to date the treatment of choice. However, recent studies have reported antibiotic resistance which can be one reason for failure of treatment of Helicobacter pylori infection [101-103], and new treatment strategies are therefore Wellcome. Flavonoids, in addition to their gastroprotective activity previously commented, have been also shown to inhibit Helicobacter pylori growth in vitro. In this way, Beil et al. [50]... 

The pharmacokinetics of available proton pump inhibitors are shown in Table 63-2. Their bioavailability is decreased approximately 50% by food hence, the drugs should be administered on an empty stomach. In a fasting state, only 10% of proton pumps are actively secreting acid and susceptible to inhibition. Proton pump inhibitors should be administered approximately 1 hour before a meal (usually breakfast or dinner), so that the peak serum concentration coincides with the maximal activity of proton pump secretion. The drugs have a short serum half-life of about 1.5 hours however, the duration of acid inhibition lasts up to 24 hours due to the irreversible inactivation of the proton pump. At least 18 hours are required for synthesis of new H+/K+ ATPase pump molecules. Because not all proton pumps are inactivated with the first dose of medication, up to 3-4 days of daily medication are required before the full acid-inhibiting potential is reached. Similarly, after stopping the drug, it takes 3-4 days for full acid secretion to return. 

From a pharmacokinetic perspective, proton pump inhibitors are ideal drugs they have a short serum half-life, they are concentrated and activated near their site of action, and they have a long duration of action. In contrast to H2 antagonists, proton pump inhibitors inhibit both fasting and meal-stimulated secretion because they block the final common pathway of acid secretion, the proton pump. In standard doses, proton pump inhibitors inhibit 90-98% of 24-hour acid secretion. 

There are currently four racemic PPIs available on the market omeprazole, lansoprazole, pantoprazole, and rabeprazole. (More recently, enantiomerically pure versions have also been studied and developed, e.g., S-omeprazole, marketed by AstraZeneca as esomeprazole see Chapter II-2.) Proton pump inhibitors share the same core structure, the substituted pyridylmethyl-sulfmyl-benzimidazole, but differ in terms of substituents on this core structure. The absolute requirements of the core structure for the activity of PPIs was not understood until it became clear that the active PPIs are derived from inactive prodrugs the prodrugs are transformed, in the acid-secreting parietal cells, by a unique cascade of chemical structural transformations leading to the active principle, a cyclic sulfenamide species. Inhibition of acid secretion in turn is then achieved by formation of covalent disulfide bonds with key cysteines of the (H+/K+)-ATPase. 

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