molecular formula C25H38O5 B1681759 Simvastatin CAS No. 79902-63-9

Simvastatin

カタログ番号: B1681759
CAS番号: 79902-63-9
分子量: 418.6 g/mol
InChIキー: RYMZZMVNJRMUDD-HGQWONQESA-N
注意: 研究専用です。人間または獣医用ではありません。
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説明

シムバスタチンは、スタチン系に属する脂質低下薬です。主に脂質レベルの上昇を抑制し、心臓発作や脳卒中などの心血管イベントのリスクを軽減するために使用されます。 シムバスタチンは、コレステロール生合成において重要な役割を果たす酵素ヒドロキシメチルグルタリルCoAレダクターゼ(HMG-CoAレダクターゼ)を阻害することで作用します .

2. 製法

シムバスタチンは、アスペルギルス・テレウスという真菌の醗酵産物を原料として合成されます。合成経路には、いくつかの重要なステップが含まれます。

工業生産方法では、これらのステップを最適化して、高収率で高純度の製品を実現することに重点が置かれています。このプロセスには、目的の製品を得るために、温度、pH、溶媒の使用などの反応条件を厳密に制御することが含まれます。

3. 化学反応解析

シムバスタチンは、いくつかのタイプの化学反応を起こします。

これらの反応で使用される一般的な試薬には、加水分解用の水や酸化用のシトクロムP450酵素などがあります。生成される主な生成物には、活性型のβ-ヒドロキシ酸型や様々な酸化代謝産物があります。

4. 科学研究における用途

シムバスタチンは、様々な科学研究に応用されています。

生化学分析

Biochemical Properties

Simvastatin interacts with the enzyme HMG-CoA reductase, which is the key rate-limiting enzyme in the cholesterol biosynthetic pathway . By competitively inhibiting this enzyme, this compound not only reduces the cellular production of cholesterol but also affects the biosynthesis of several intermediates of the mevalonate pathway, such as farnesylpyrophosphate and geranylgeranylpyrophosphate .

Cellular Effects

This compound has been shown to have profound effects on various types of cells and cellular processes. For instance, it has been found to inhibit glucose metabolism and legumain activity in human myotubes . It also exerts inhibitory effects on the NLRP3 inflammasome and toll-like receptors, which are implicated in inflammation and atherosclerosis .

Molecular Mechanism

This compound exerts its effects at the molecular level by inhibiting the conversion of HMG-CoA to mevalonic acid, a key step in the cholesterol synthesis pathway . This inhibition is achieved by the competitive inhibition of the enzyme HMG-CoA reductase . Furthermore, this compound can suppress TLR4/MyD88/NF-ĸB signaling and cause an immune response shift to an anti-inflammatory response .

Temporal Effects in Laboratory Settings

In laboratory settings, this compound has been shown to cause a dose-dependent decrease in both glucose uptake and oxidation in mature myotubes . Moreover, long-term studies indicate that little or no attenuation of these changes in serum lipid and lipoprotein levels occurred with administration of this compound for 3 to 5.4 years .

Dosage Effects in Animal Models

In animal models, this compound has been shown to cause bioaccumulation over time, which was augmented upon addition of bile acids . High doses of this compound have been associated with increased osteoporosis risk , and extensive muscle-specific damage, particularly in the organization of sarcomeres and in mitochondria .

Metabolic Pathways

This compound is involved in the cholesterol biosynthesis pathway, where it inhibits the conversion of HMG-CoA to mevalonic acid . This action not only inhibits the cellular production of cholesterol but also affects the biosynthesis of several intermediates of the mevalonate pathway .

Transport and Distribution

This compound is transported into bacteria cells leading to a drug bioaccumulation over time, which is augmented upon addition of bile acids . A decrease of total drug level during the incubation indicates that the drug is partly biotransformed by bacterial enzymes .

Subcellular Localization

This compound has been shown to cause alterations in the intracellular distribution of lysosomal cysteine proteases . In addition, protein isoprenylation permits the covalent attachment, subcellular localization, and intracellular trafficking of membrane-associated proteins .

準備方法

Simvastatin is synthesized from a fermentation product of the fungus Aspergillus terreus. The synthetic route involves several key steps:

Industrial production methods focus on optimizing these steps to ensure high yield and purity. The process involves stringent control of reaction conditions such as temperature, pH, and solvent use to achieve the desired product.

化学反応の分析

Simvastatin undergoes several types of chemical reactions:

Common reagents used in these reactions include water for hydrolysis and cytochrome P450 enzymes for oxidation. The major products formed include the active β-hydroxyacid form and various oxidized metabolites.

類似化合物との比較

シムバスタチンは、アトルバスタチン、ロサルバスタチン、プラバスタチン、フルバスタチン、ロバスタチンなどの他のスタチンと比較されることが多いです。 これらの化合物はすべて、同様の作用機序を共有していますが、薬物動態学的特性、効力、副作用プロファイルが異なります . たとえば、

    アトルバスタチン: シムバスタチンと比較して、高効力で半減期が長いことが知られています。

    ロサルバスタチン: LDLコレステロールを低下させる効果が高くなりますが、筋肉関連の副作用を起こす可能性があります。

    プラバスタチン: シムバスタチンと比較して、脂溶性が低く、薬物相互作用が少ないです。

シムバスタチンは、血液脳関門を通過する独特の能力と、心血管疾患の管理における広範な使用が、その独自の利点を強調しています .

特性

IUPAC Name

[(1S,3R,7S,8S,8aR)-8-[2-[(2R,4R)-4-hydroxy-6-oxooxan-2-yl]ethyl]-3,7-dimethyl-1,2,3,7,8,8a-hexahydronaphthalen-1-yl] 2,2-dimethylbutanoate
Source PubChem
URL https://pubchem.ncbi.nlm.nih.gov
Description Data deposited in or computed by PubChem

InChI

InChI=1S/C25H38O5/c1-6-25(4,5)24(28)30-21-12-15(2)11-17-8-7-16(3)20(23(17)21)10-9-19-13-18(26)14-22(27)29-19/h7-8,11,15-16,18-21,23,26H,6,9-10,12-14H2,1-5H3/t15-,16-,18+,19+,20-,21-,23-/m0/s1
Source PubChem
URL https://pubchem.ncbi.nlm.nih.gov
Description Data deposited in or computed by PubChem

InChI Key

RYMZZMVNJRMUDD-HGQWONQESA-N
Source PubChem
URL https://pubchem.ncbi.nlm.nih.gov
Description Data deposited in or computed by PubChem

Canonical SMILES

CCC(C)(C)C(=O)OC1CC(C=C2C1C(C(C=C2)C)CCC3CC(CC(=O)O3)O)C
Source PubChem
URL https://pubchem.ncbi.nlm.nih.gov
Description Data deposited in or computed by PubChem

Isomeric SMILES

CCC(C)(C)C(=O)O[C@H]1C[C@H](C=C2[C@H]1[C@H]([C@H](C=C2)C)CC[C@@H]3C[C@H](CC(=O)O3)O)C
Source PubChem
URL https://pubchem.ncbi.nlm.nih.gov
Description Data deposited in or computed by PubChem

Molecular Formula

C25H38O5
Source PubChem
URL https://pubchem.ncbi.nlm.nih.gov
Description Data deposited in or computed by PubChem

DSSTOX Substance ID

DTXSID0023581
Record name Simvastatin
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Molecular Weight

418.6 g/mol
Source PubChem
URL https://pubchem.ncbi.nlm.nih.gov
Description Data deposited in or computed by PubChem

Physical Description

Solid
Record name Simvastatin
Source Human Metabolome Database (HMDB)
URL http://www.hmdb.ca/metabolites/HMDB0005007
Description The Human Metabolome Database (HMDB) is a freely available electronic database containing detailed information about small molecule metabolites found in the human body.
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Solubility

Insoluble, In water, 3.0X10-2 mg/L, temp not specified, Solubility (mg/mL): chloroform 610; DMSO 540; methanol 200; ethanol 160; n-hexane 0.15; 0.1 M HCl 0.06; polyethylene glycol-400 70; propylene glycol 30; 0.1 M NaOH 70, 1.22e-02 g/L
Record name Simvastatin
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Record name Simvastatin
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Record name Simvastatin
Source Human Metabolome Database (HMDB)
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Mechanism of Action

Simvastatin is a prodrug in which the 6-membered lactone ring of simvastatin is hydrolyzed in vivo to generate the beta,delta-dihydroxy acid, an active metabolite structurally similar to HMG-CoA (hydroxymethylglutaryl CoA). Once hydrolyzed, simvastatin competes with HMG-CoA for HMG-CoA reductase, a hepatic microsomal enzyme, which catalyzes the conversion of HMG-CoA to mevalonate, an early rate-limiting step in cholesterol biosynthesis. Simvastatin acts primarily in the liver, where decreased hepatic cholesterol concentrations stimulate the upregulation of hepatic low density lipoprotein (LDL) receptors which increases hepatic uptake of LDL. Simvastatin also inhibits hepatic synthesis of very low density lipoprotein (VLDL). The overall effect is a decrease in plasma LDL and VLDL. At therapeutic doses, the HMG-CoA enzyme is not completely blocked by simvastatin activity, thereby allowing biologically necessary amounts of mevalonate to remain available. As mevalonate is an early step in the biosynthetic pathway for cholesterol, therapy with simvastatin would also not be expected to cause any accumulation of potentially toxic sterols. In addition, HMG-CoA is metabolized readily back to acetyl-CoA, which participates in many biosynthetic processes in the body. In vitro and in vivo animal studies also demonstrate that simvastatin exerts vasculoprotective effects independent of its lipid-lowering properties, also known as the pleiotropic effects of statins. This includes improvement in endothelial function, enhanced stability of atherosclerotic plaques, reduced oxidative stress and inflammation, and inhibition of the thrombogenic response. Statins have also been found to bind allosterically to β2 integrin function-associated antigen-1 (LFA-1), which plays an important role in leukocyte trafficking and in T cell activation., Simvastatin is a prodrug and is hydrolyzed to its active beta-hydroxyacid form, simvastatin acid, after administration. Simvastatin is a specific inhibitor of 3-hydroxy-3-methylglutaryl-coenzyme A (HMG-CoA) reductase, the enzyme that catalyzes the conversion of HMG-CoA to mevalonate, an early and rate limiting step in the biosynthetic pathway for cholesterol. In addition, simvastatin reduces VLDL and TG and increases HDL-C., The HDL-associated enzyme paraoxonase protects LDLs from oxidative stress. 3-Hydroxy-3-methylglutaryl coenzyme A reductase inhibitors (statins) appear to favorably influence the atherosclerotic process by different mechanisms. The present study examined the influence of simvastatin on paraoxonase expression and serum paraoxonase levels. Simvastatin upregulated in a dose-dependent manner the activity of the promoter of the paraoxonase gene in expression cassettes transfected into HepG2 cells. Upregulation could be blocked by mevalonate and other intermediates of the cholesterol biosynthetic pathway. Simvastatin increased nuclear factors, notably sterol regulatory element-binding protein-2, capable of binding to the paraoxonase promoter; this was also blocked by mevalonate. Sterol regulatory element-binding protein-2 upregulated promoter activity in vitro. Patients treated with statin showed a significant increase in serum concentrations and activities of paraoxonase. The data indicate that simvastatin can modulate expression in vitro of the antioxidant enzyme paraoxonase and is associated with increased serum paraoxonase concentration and activity. It is consistent with effects of simvastatin treatment, which have the potential to influence beneficially antiatherogenic mechanisms at the HDL level. The study provides evidence for 1 molecular mechanism by which paraoxonase gene expression could be regulated., ... We report in this work that, unexpectedly, simvastatin enhances LPS-induced IL-12p40 production by murine macrophages, and that it does so by activating the IL-12p40 promoter. Mutational analysis and dominant-negative expression studies indicate that both C/EBP and AP-1 transcription factors have a crucial role in promoter activation. This occurs via a c-Fos- and c-Jun-based mechanism; we demonstrate that ectopic expression of c-Jun activates the IL-12p40 promoter, whereas expression of c-Fos inhibits IL-12p40 promoter activity. Simvastatin prevents LPS-induced c-Fos expression, thereby relieving the inhibitory effect of c-Fos on the IL-12p40 promoter. Concomitantly, simvastatin induces the phosphorylation of c-Jun by the c-Jun N-terminal kinase, resulting in c-Jun-dependent activation of the IL-12p40 promoter. This appears to be a general mechanism because simvastatin also augments LPS-dependent activation of the TNF-alpha promoter, perhaps because the TNF-alpha promoter has C/EBP and AP-1 binding sites in a similar configuration to the IL-12p40 promoter. The fact that simvastatin potently augments LPS-induced IL-12p40 and TNF-alpha production has implications for the treatment of bacterial infections in statin-treated patients., Statins are increasingly recognized as mediators of direct cellular effects independent of their lipid lowering capacity. Therefore, the time and concentration dependence of various statin-mediated cellular alterations was compared in renal mesangial cells. The effects of statins on cell proliferation, gene expression, cytoskeletal alterations, apoptosis, and cytotoxicity were analyzed in cultured mesangial cells using standard techniques. Results. Simvastatin and lovastatin decreased proliferation and cell number of rat mesangial cells concentration-dependently. Concurrently, the expression of the fibrogenic protein connective tissue growth factor (CTGF) was impaired and actin stress fibers, which are typical of mesangial cells in culture, became disassembled by simvastatin. A decrease of the posttranslational modification of RhoA by geranylgeranyl moieties was detected, supporting a role for RhoA as mediator of statin effects. Induction of apoptosis, determined by activation of caspase-3 and DNA fragmentation, and necrosis only occurred at later time points, when the morphology of the cells was strongly altered and the cells detached from the surface due to changes in the actin cytoskeleton. Basically, the same results were obtained with a human mesangial cell line. Furthermore, statin effects were mimicked by inhibition of the geranylgeranyltransferase. Most of the cellular effects of the lipophilic statins occurred within the same time and concentration range, suggesting a common molecular mechanism. Only apoptosis and necrosis were observed at later time points or with higher concentrations of simvastatin and thus seem to be secondary to the changes in gene expression and alterations of the actin cytoskeleton., For more Mechanism of Action (Complete) data for Simvastatin (6 total), please visit the HSDB record page.
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Color/Form

White to off-white crystalline powder from n-butyl chloride + hexane

CAS No.

79902-63-9
Record name Simvastatin
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Record name Butanoic acid, 2,2-dimethyl-, (1S,3R,7S,8S,8aR)-1,2,3,7,8,8a-hexahydro-3,7-dimethyl-8-[2-[(2R,4R)-tetrahydro-4-hydroxy-6-oxo-2H-pyran-2-yl]ethyl]-1-naphthalenyl ester
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Record name (1S,3R,7S,8S,8aR)-8-[2-[(2R,4R)-4-Hydroxy-6-oxotetrahydro-2H-pyran-2-yl]ethyl]-3,7-dimethyl-1,2,3,7,8,8a-hexahydronaphthalen-1-yl 2,2-dimethylbutanoate.
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Melting Point

135-138 °C, 135 - 138 °C
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Retrosynthesis Analysis

AI-Powered Synthesis Planning: Our tool employs the Template_relevance Pistachio, Template_relevance Bkms_metabolic, Template_relevance Pistachio_ringbreaker, Template_relevance Reaxys, Template_relevance Reaxys_biocatalysis model, leveraging a vast database of chemical reactions to predict feasible synthetic routes.

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Strategy Settings

Precursor scoring Relevance Heuristic
Min. plausibility 0.01
Model Template_relevance
Template Set Pistachio/Bkms_metabolic/Pistachio_ringbreaker/Reaxys/Reaxys_biocatalysis
Top-N result to add to graph 6

Feasible Synthetic Routes

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Customer
Q & A

Q1: What is the primary mechanism of action of simvastatin?

A: this compound is a 3-hydroxy-3-methylglutaryl coenzyme A (HMG-CoA) reductase inhibitor. It competitively inhibits HMG-CoA reductase, the rate-limiting enzyme in cholesterol biosynthesis. This inhibition leads to a decrease in intracellular cholesterol levels. [, , ]

Q2: Does this compound have cholesterol-independent effects?

A: Yes, beyond its cholesterol-lowering effects, this compound exhibits pleiotropic effects, influencing various cellular processes. Research suggests this compound can regulate Rho/Rho-kinases (ROCK) and endothelial nitric oxide synthase (eNOS), proteins crucial in inflammatory responses. []

Q3: How does this compound impact fibrinolytic activity?

A: this compound has been shown to stimulate fibrinolytic activity in human peritoneal mesothelial cells. It accomplishes this by increasing the production of tissue-type plasminogen activator (t-PA) and decreasing the production of plasminogen activator inhibitor-1 (PAI-1). This effect appears to be independent of its cholesterol-lowering action. []

Q4: What role does this compound play in the mevalonate pathway?

A: By inhibiting HMG-CoA reductase, this compound restricts the availability of mevalonate, a precursor not only for cholesterol but also for farnesyl pyrophosphate (FPP) and geranylgeranyl pyrophosphate (GGPP). These isoprenoids are crucial for various cellular processes, including protein prenylation. [, ]

Q5: How does this compound's impact on the mevalonate pathway relate to its anti-inflammatory effects?

A: The inhibition of FPP and GGPP synthesis, due to this compound's effect on the mevalonate pathway, leads to decreased protein prenylation. This decrease is thought to contribute to this compound's anti-inflammatory actions, as protein prenylation is essential for the proper functioning of certain inflammatory signaling pathways. [, ]

Q6: Can geranylgeranyl pyrophosphate (GGPP) counteract the effects of this compound?

A: Yes, research indicates that GGPP supplementation can prevent this compound-induced inhibition of tendon cell proliferation and cell cycle progression. This suggests that GGPP plays a role in the adverse effects of this compound on tendon cells. []

Q7: What is the molecular formula and weight of this compound?

A: The molecular formula of this compound is C25H38O6, and its molecular weight is 418.57 g/mol. [, ]

Q8: How is this compound typically administered?

A: this compound is administered orally as a prodrug in its inactive lactone form. []

Q9: What happens to this compound in the body?

A: Once ingested, the inactive lactone form of this compound is metabolized in the liver into its active β-hydroxy acid form. []

Q10: Has this compound shown any catalytic properties?

A10: The provided research does not focus on this compound's catalytic properties. The focus is primarily on its pharmacological activity as an HMG-CoA reductase inhibitor and its subsequent effects on various biological processes.

Q11: Have computational methods been used in this compound research?

A11: While the provided research articles primarily focus on experimental investigations, computational chemistry and modeling can be valuable tools for understanding this compound's interactions with its target (HMG-CoA reductase) and for exploring structure-activity relationships.

Q12: What is the impact of this compound formulation on its dissolution?

A: Research shows that the addition of Cremophor-EL, a surfactant, to this compound tablets using a wet granulation method improved the dissolution rate compared to generic this compound tablets. []

Q13: What are the SHE considerations for this compound?

A13: As a pharmaceutical compound, this compound manufacturing and disposal require adherence to strict SHE regulations to ensure worker safety, prevent environmental contamination, and ensure responsible handling of pharmaceutical waste.

Q14: How is this compound absorbed and distributed in the body?

A: this compound is administered orally and is absorbed from the gastrointestinal tract. Its bioavailability is relatively low due to extensive first-pass metabolism in the liver. []

Q15: What are the primary routes of this compound metabolism and excretion?

A: this compound is extensively metabolized in the liver, primarily by cytochrome P450 (CYP) enzymes, particularly CYP3A4. [, ] Metabolites are excreted in bile and urine. []

Q16: Can other medications influence this compound pharmacokinetics?

A: Yes, drug interactions can occur with this compound. Co-administration with clarithromycin, an inhibitor of CYP3A4, significantly increased this compound's maximum plasma concentration (Cmax) and area under the curve (AUC), indicating a potential for increased risk of adverse events. [] RRR-a-tocopherol, also known to interact with CYP3A, has been shown to significantly induce the clearance rate of this compound, potentially decreasing its lipid-lowering effect. []

Q17: What is the relationship between this compound dosage and its effects on heart rate in the presence of metoprolol?

A: A study in rats found that two weeks of this compound administration at different doses did not significantly modify the heart rate-depressing effects of metoprolol. []

Q18: Has this compound demonstrated efficacy in preclinical models of disease?

A18: Yes, this compound has shown promising results in various preclinical models:

  • Colitis: In a mouse model of colitis, this compound at a dose of 50 mg/kg/day showed a significant increase in colon length, a significant decrease in nitric oxide and malondialdehyde levels, and a significant increase in reduced glutathione levels, suggesting protective effects against colitis. []
  • Pulmonary Hypertension: this compound has been shown to prevent the development of pulmonary hypertension in rat models. [, ]
  • Spinal Cord Injury: In a rat model of spinal cord injury, this compound promoted the mobilization of bone marrow-derived stem cells to the injury site, leading to improved functional recovery. [, ]

Q19: Has this compound shown efficacy in clinical studies?

A: Yes, clinical trials have demonstrated the efficacy of this compound in managing hypercholesterolemia and reducing cardiovascular events. [, ]

Q20: What are the known toxicological considerations for this compound?

A: While generally considered safe, this compound can cause side effects. The most serious, although rare, is rhabdomyolysis (muscle breakdown). []

Q21: Have there been efforts to develop targeted delivery systems for this compound?

A: Yes, one study investigated the use of hydroxyapatite fiber (HAF) as a carrier for this compound to promote bone formation. The study found that a combination of HAF and this compound stimulated new bone formation in a rabbit model. [] Another study explored the effects of topical this compound solution compared to oral administration for reducing post-laparotomy adhesions in rats, finding that both methods were effective. []

Q22: What biomarkers are relevant for monitoring this compound's effects?

A22: Several biomarkers are used to assess the efficacy and safety of this compound treatment:

  • Lipid Profile: Total cholesterol, low-density lipoprotein (LDL) cholesterol, high-density lipoprotein (HDL) cholesterol, and triglycerides are routinely monitored. [, ]
  • Inflammatory Markers: C-reactive protein (CRP), interleukin-6 (IL-6), and fibrinogen levels can be measured to assess the anti-inflammatory effects of this compound. [, , ]
  • Liver Enzymes: Liver function tests are essential for monitoring potential liver toxicity, a rare but serious side effect of statins. []

Q23: What analytical techniques are commonly used to quantify this compound?

A: High-performance liquid chromatography (HPLC) coupled with various detectors, such as UV, fluorescence, and mass spectrometry (MS), are widely used to determine this compound concentration in biological samples. []

Q24: What factors affect this compound's dissolution and solubility?

A: this compound's dissolution rate and solubility are influenced by factors like particle size, crystal form, and the presence of excipients in its pharmaceutical formulations. []

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