Rosuvastatin is not extensively metabolized, as demonstrated by the small amount of radiolabeled dose that is recovered as a metabolite (~10%). Cytochrome P450 (CYP) 2C9 is primarily responsible for the formation of rosuvastatin's major metabolite, N-desmethylrosuvastatin, which has approximately 20-50% of the pharmacological activity of its parent compound in vitro. However, this metabolic pathway isn't deemed to be clinically significant as there were no observable effects found on rosuvastatin pharmacokinetics when rosuvastatin was coadministered with fluconazole, a potent CYP2C9 inhibitor. In vitro and in vivo data indicate that rosuvastatin has no clinically significant cytochrome P450 interactions (as substrate, inhibitor or inducer). Consequently, there is little potential for drug-drug interactions upon coadministration with agents that are metabolized by cytochrome P450.
Rosuvastatin is not extensively metabolized; approximately 10% of a radiolabeled dose is recovered as metabolite. The major metabolite is N-desmethyl rosuvastatin, which is formed principally by cytochrome P450 \ 2C9, and in vitro studies have demonstrated that N-desmethyl rosuvastatin has approximately one-sixth to one-half the HMG-CoA reductase inhibitory activity of the parent compound. Overall, greater than 90% of active plasma HMG-CoA reductase inhibitory activity is accounted for by the parent compound.
Not extensively metabolized. Only ~10% is excreted as metabolite. Cytochrome P450 (CYP) 2C9 is primarily responsible for the formation of rosuvastatin's major metabolite, N-desmethylrosuvastatin. N-desmethylrosuvastatin has approximately 50% of the pharmacological activity of its parent compound in vitro. Rosuvastatin clearance is not dependent on metabolism by cytochrome P450 3A4 to a clinically significant extent. Rosuvastatin accounts for greater than 90% of the pharmacologic action. Inhibitors of CYP2C9 increase the AUC by less than 2-fold. This interaction does not appear to be clinically significant.
Route of Elimination: Rosuvastatin is not extensively metabolized; approximately 10% of a radiolabeled dose is recovered as metabolite. Following oral administration, rosuvastatin and its metabolites are primarily excreted in the feces (90%). After an intravenous dose, approximately 28% of total body clearance was via the renal route, and 72% by the hepatic route.
Half Life: 19 hours
IDENTIFICATION AND USE: Rosuvastatin is hydroxymethylglutaryl-CoA reductase inhibitor. It is is indicated to reduce the risk of stroke, myocardial infarction, and arterial revascularization procedures. HUMAN EXPOSURE AND TOXICITY: Rosuvastatin is the most potent 3-hydroxy-3-methyl-glutaryl-coenzyme A reductase inhibitor commercially available to lower low-density lipoprotein cholesterol. Rosuvastatin has been associated with several adverse effects, including rhabdomyolysis and arthralgias. Myopathy and rhabdomyolysis with acute renal failure secondary to myoglobinuria have been reported in patients receiving statins, including rosuvastatin. These adverse effects can occur at any dosage, but the risk is increased with the highest dosage of rosuvastatin (40 mg daily). There is a report of Takotsubo cardiomyopathy, triggered by delayed-onset rhabdomyolysis following the administration of long-term rosuvastatin treatment, without any preceding stressors or changes in the patient's medical condition, in association with complaints of non-specific muscle-related symptoms. Literature reported the case of a marathon runner who presented with acute rhabdomyolysis during competition while being under rosuvastatin treatment. A 77-year-old patient developed acute pancreatitis after treatment with rosuvastatin, which resolved on withdrawal of the medication. There have been rare postmarketing reports of fatal and non-fatal hepatic failure in patients taking statins, including rosuvastatin. The genotoxic potential of rosuvastatin was assessed by chromosomal aberrations (CAs), micronucleus (MN) and DNA damage by comet assay in human peripheral blood lymphocytes. According to these results, rosuvastatin is cytotoxic and clastogenic/aneugenic in human peripheral lymphocytes. ANIMAL STUDIES: Rosuvastatin was shown to be of low acute toxicity following administration of single doses to rats and dogs by oral and intravenous routes. There were no mortalities in rats given an oral dose of 1000 mg/kg or 2000 mg/kg, and other than depression of bodyweight at 2000 mg/kg, there were no treatment-related effects at either dose level. Dogs received oral doses of 1000 mg/kg or 2000 mg/kg with vomiting on the day of dosing observed as the major clinical finding in both sexes. In a 104-week carcinogenicity study in rats at dose levels of 2, 20, 60 or 80 mg/kg/day, the incidence of uterine polyps was statistically significantly increased only in females at the dose of 80 mg/kg/day. In a 107-week carcinogenicity study in mice given 10, 60, 200 or 400 mg/kg/day, the 400 mg/kg/day dose was poorly tolerated, resulting in early termination of this dose group. An increased incidence of hepatocellular carcinomas was observed at 200 mg/kg/day and an increase in hepatocellular adenomas was seen at 60 and 200 mg/kg/day. Rosuvastatin administration did not indicate a teratogenic effect in rats at </= 25 mg/kg/day or in rabbits </= 3 mg/kg/day. In vitro, rosuvastatin was not mutagenic or clastogenic with or without metabolic activation in the Ames test with Salmonella typhimurium and Escherichia coli, L-5178 y +/- mouse lymphomas, and the chromosomal aberration assay in Chinese hamster lung cells. Rosuvastatin was negative in the in vivo mouse micronucleus test.
Rosuvastatin is a competitive inhibitor of HMG-CoA reductase. HMG-CoA reductase catalyzes the conversion of HMG-CoA to mevalonate, an early rate-limiting step in cholesterol biosynthesis. Rosuvastatin acts primarily in the liver. Decreased hepatic cholesterol concentrations stimulate the upregulation of hepatic low density lipoprotein (LDL) receptors which increases hepatic uptake of LDL. Rosuvastatin also inhibits hepatic synthesis of very low density lipoprotein (VLDL). The overall effect is a decrease in plasma LDL and VLDL.
In vitro and in vivo animal studies also demonstrate that rosuvastatin exerts vasculoprotective effects independent of its lipid-lowering properties. Rosuvastatin exerts an anti-inflammatory effect on rat mesenteric microvascular endothelium by attenuating leukocyte rolling, adherence and transmigration (A2814). The drug also modulates nitric oxide synthase (NOS) expression and reduces ischemic-reperfusion injuries in rat hearts (A2818). Rosuvastatin increases the bioavailability of nitric oxide (A2814, 12031849, 15914111) by upregulating NOS (A2816) and by increasing the stability of NOS through post-transcriptional polyadenylation (A7824). It is unclear as to how rosuvastatin brings about these effects though they may be due to decreased concentrations of mevalonic acid.
Rosuvastatin therapy is associated with mild, asymptomatic and usually transient serum aminotransferase elevations in 1% to 3% of patients. ALT levels above 3 times the upper limit of normal (ULN) occur slightly more frequently among rosuvastatin treated [1.1%] than placebo [0.5%] recipients. Serum enzyme elevations are more common with higher doses of rosuvastatin, being 2.2% with 40 mg daily. Most of these elevations are self-limited and do not require dose modification. Rosuvastatin is also associated with frank, clinically apparent hepatic injury but this is rare, occurring in less than 1:10,000 patients. The onset is typically after 2 to 4 months ,and the pattern of serum enzyme elevations is usually hepatocellular, although cholestatic cases have also been reported. Rash, fever and eosinophilia are uncommon. Several statins including rosuvastatin have been linked to hepatitis with autoimmune features marked by ANA positivity, elevations in serum immunoglobulin levels, and a clinical response to corticosteroids. Such features are not, however, invariable (Case 1). The injury is usually self-limited and resolves rapidly once rosuvastatin is stopped, but it can be severe and fatal instances have been reported.
In a study of healthy white male volunteers, the absolute oral bioavailability of rosuvastatin was found to be approximately 20% while absorption was estimated to be 50%, which is consistent with a substantial first-pass effect after oral dosing. Another study in healthy volunteers found that the peak plasma concentration (Cmax) of rosuvastatin was 6.06ng/mL and was reached at a median of 5 hours following oral dosing. Both Cmax and AUC increased in approximate proportion to dose. Neither food nor evening versus morning administration was shown to have an effect on the AUC of rosuvastatin. Many statins are known to interact with hepatic uptake transporters and thus reach high concentrations at their site of action in the liver. Breast Cancer Resistance Protein (BCRP) is a membrane-bound protein that plays an important role in the absorption of rosuvastatin, particularly as CYP3A4 has minimal involvement in its metabolism. Evidence from pharmacogenetic studies of c.421C>A single nucleotide polymorphisms (SNPs) in the gene for BCRP has demonstrated that individuals with the 421AA genotype have reduced functional activity and 2.4-fold higher AUC and Cmax values for rosuvastatin compared to study individuals with the control 421CC genotype. This has important implications for the variation in response to the drug in terms of efficacy and toxicity, particularly as the BCRP c.421C>A polymorphism occurs more frequently in Asian populations than in Caucasians. Other statin drugs impacted by this polymorphism include [fluvastatin] and [atorvastatin]. Genetic differences in the OATP1B1 (organic-anion-transporting polypeptide 1B1) hepatic transporter have also been shown to impact rosuvastatin pharmacokinetics. Evidence from pharmacogenetic studies of the c.521T>C SNP showed that rosuvastatin AUC was increased 1.62-fold for individuals homozygous for 521CC compared to homozygous 521TT individuals. Other statin drugs impacted by this polymorphism include [simvastatin], [pitavastatin], [atorvastatin], and [pravastatin]. For patients known to have the above-mentioned c.421AA BCRP or c.521CC OATP1B1 genotypes, a maximum daily dose of 20mg of rosuvastatin is recommended to avoid adverse effects from the increased exposure to the drug, such as muscle pain and risk of rhabdomyolysis.
Rosuvastatin is not extensively metabolized; approximately 10% of a radiolabeled dose is recovered as metabolite. Following oral administration, rosuvastatin and its metabolites are primarily excreted in the feces (90%). After an intravenous dose, approximately 28% of total body clearance was via the renal route, and 72% by the hepatic route. A study in healthy adult male volunteers found that approximately 90% of the rosuvastatin dose was recovered in feces within 72 hours after dose, while the remaining 10% was recovered in urine. The drug was completely excreted from the body after 10 days of dosing. They also found that approximately 76.8% of the excreted dose was unchanged from the parent compound, with the remaining dose recovered as the metabolites n-desmethyl rosuvastatin and rosuvastatin-5S-lactone. Renal tubular secretion is responsible for >90% of total renal clearance, and is believed to be mediated primarily by the uptake transporter OAT3 (Organic anion transporter 1), while OAT1 had minimal involvement.
Rosuvastatin undergoes first-pass extraction in the liver, which is the primary site of cholesterol synthesis and LDL-C clearance. The mean volume of distribution at steady-state of rosuvastatin is approximately 134 litres.
In clinical pharmacology studies in man, peak plasma concentrations of rosuvastatin were reached 3 to 5 hours following oral dosing. Both Cmax and AUC increased in approximate proportion to Crestor dose. The absolute bioavailability of rosuvastatin is approximately 20%. Administration of Crestor with food did not affect the AUC of rosuvastatin. The AUC of rosuvastatin does not differ following evening or morning drug administration.
Mean volume of distribution at steady-state of rosuvastatin is approximately 134 liters. Rosuvastatin is 88% bound to plasma proteins, mostly albumin. This binding is reversible and independent of plasma concentrations.
DISUBSTITUTED TRIFLUOROMETHYL PYRIMIDINONES AND THEIR USE
申请人:BAYER PHARMA AKTIENGESELLSCHAFT
公开号:US20160221965A1
公开(公告)日:2016-08-04
The present application relates to novel 2,5-disubstituted 6-(trifluoromethyl)pyrimidin-4(3H)-one derivatives, to processes for their preparation, to their use alone or in combinations for the treatment and/or prevention of diseases, and to their use for preparing medicaments for the treatment and/or prevention of diseases, in particular for treatment and/or prevention of cardiovascular, renal, inflammatory and fibrotic diseases.
[EN] CATHEPSIN CYSTEINE PROTEASE INHIBITORS<br/>[FR] INHIBITEURS DE PROTÉASES À CYSTÉINE DE TYPE CATHEPSINES
申请人:MERCK SHARP & DOHME
公开号:WO2015054038A1
公开(公告)日:2015-04-16
This invention relates to a novel class of compounds which are cysteine protease inhibitors, including but not limited to, inhibitors of cathepsins K, L, S and B. These compounds are useful for treating diseases in which inhibition of bone resorption is indicated, such as osteoporosis.
[EN] SULFONYL COMPOUNDS THAT INTERACT WITH GLUCOKINASE REGULATORY PROTEIN<br/>[FR] COMPOSÉS DE SULFONYLE QUI INTERAGISSENT AVEC LA PROTÉINE RÉGULATRICE DE LA GLUCOKINASE
申请人:AMGEN INC
公开号:WO2013123444A1
公开(公告)日:2013-08-22
The present invention relates to sulfonyl compounds that interact with glucokinase regulatory protein. In addition, the present invention relates to methods of treating type 2 diabetes, and other diseases and/or conditions where glucokinase regulatory protein is involved using the compounds, or pharmaceutically acceptable salts thereof, and pharmaceutical compositions that contain the compounds, or pharmaceutically acceptable salts thereof.