• Journal of Life Science
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• v.28 no.4
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• pp.472-477
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• 2018

Pravastatin sodium is a 3-hydroxy-3-methylglutaryl-coenzyme A (HMG-CoA) reductase inhibitor used in the treatment of hypercholesterolemia by reducing cholesterol biosynthesis. Pharmaceutical excipients of commonly used including water, diluents, stabilizers, disintegrants, lubricants and colorants, and were identified for compatibility. All tests were performed by means of physical mixture of pravastatin and the excipients, which were placed in a press-through-pack (PTP) and incubated under accelerated conditions ($40^{\circ}C$ and 75% relative humidity) for 3 months. The blends of pravastatin with all excipients developed white, off white, and light brown powders, which showed no changes upon visual analysis. Accelerated conditions changed the degradation profile of pravastatin calcium in the HPLC system when mixed with different excipients. Although most excipients can have minor effects on pravastatin stability, the major degradation product from pravastatin was lactone. Low-level interaction (assay and impurity) was induced by all excipients except for microcrystalline cellulose and croscarmellose sodium. These excipients increased lactone impurity in 3 months by as much as 0.22% and 0.18% respectively. The total mixture slightly increased the lactone impurity (by 0.43% in 3 months) of pravastatin. There was no change in the assays of all excipients. These results will be helpful in studying tablet size reductions for convenience of use.

• Food Engineering Progress
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• v.13 no.4
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• pp.243-250
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• 2009

Pravastatin sodium, competitive inhibitors of HMG-CoA(3-hydroxy-3-methylglutaryl coenzyme A) reductase, is produced from the culture broth of Streptomyces carbophilus KCCM 10370, The production of Pravastatin sodium was increased about 45 fold compared to wild type by UV mutation. Production of Pravastatin was also improved by continuous feeding of Compactin sodium to 24% and bioconversion ratio was also increased to 4.3% by intermittent addition. In main culture, concentration of Compactin sodium was kept less than 0.1%(w/v) under continuous feeding of Compactin sodium then product was 0.49% and bioconversion was 70%. After finishing the fermentation, Pravastatin was purified by various chromatographies such as Diaion HP20 resin column, Partition, and ODS(Octa-Decylsilyl Silicagel) resin column with a final yield of 70~72% and over 99.7% purity. The IR, UV, and NMR study of the purified Pravastatin sodium showed the same pattern as that of EP(European Pharmacopoeia).

• Korean Journal of Clinical Pharmacy
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• v.24 no.4
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• pp.231-239
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• 2014

Background and objective: Pravastatin has been shown to have favorable risk-benefit profile when it is administered to hypercholesterolemic subjects to prevent cardiovascular events. However, subjects with impaired OATP1B1 activity may be more susceptible to pravastatin-induced muscle toxicity than subjects with normal OATP1B1 activity. A systematic review was conducted to evaluate the effect of SLCO1B1 genetic polymorphism on pharmacokinetics of pravastatin. Method: Medline$^{(R)}$ and Embase$^{(R)}$ were searched for relevant studies until July 2013. The search terms used were pravastatin AND (SLCO1B1 OR OATP1B1 OR LST1 OR SLC21A6) AND (gene OR $genetic^*$ OR $genomic^*$ OR $pharmacogenet^*$ OR $pharmacogenom^*$ OR $polymorph^*$). Results: A meta-analysis of the area under the concentration-time curve (AUC) of pravastatin in $SLCO1B1^*15$ and $SLCO1B1^*1a/^*1a$ was conducted. Five studies met all the inclusion criteria and methodological requirements. There was no statistically significant difference in the AUC value between $SLCO1B1^*15$ and $SLCO1B1^*1a/^*1a$ (p=0.728). However, $SLCO1B1^*15$ participants exhibited significantly higher AUC values than $SLCO1B1^*1b/^*1b$ carriers (p<0.001). In case of $SLCO1B1^*15^*15$ carriers, they had significantly higher AUC value than $SLCO1B1^*1a/^*1a$ subjects (p=0.002). Lastly, compared with to the subjects of $SLCO1B1^*1a/^*1a$, the carriers of heterozygous $SLCO1B1^*15$ increased the AUC value of pravastatin statistically significantly in Asian population (p=0.014). Conclusion: The present meta-analysis suggests that subjects with $SLCO1B1^*15$ are associated with increased AUC of pravastatin.

• The Journal of Internal Korean Medicine
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• v.38 no.3
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• pp.327-335
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• 2017

Objective: The goal of this preclinical study was to compare the dyslipidemic effect of pravastatin with that of herbal medicine in rats. Methods: In total, 40 rats were divided into 4 groups: Normal (10 rats), Control (10 rats), Statin alone (10 rats), and the MO-PM-S group (10 rats), which was given the powder of the cortex of Magnolia officinalis Rehd. et Wils., the root of Polygonum multiflorum Thunb, and pravastatin. The Control group, the Statin alone group, and the MO-PM-S group were all given a high-fat (45%) diet that made them obese. After 2 weeks of drug administration, the dyslipidemic effect of pravastatin was compared with that of herbal medicine in rats by analyzing the lipid profiles, measuring the body weights, and taking biopsies (liver, aorta). Results: The herbal medicine and the statin complex group got a much lower TG level and a slightly higher HDL-cholesterol level than the other groups. However, it got a higher total cholesterol and LDL-cholesterol level than the other groups. In biopsies, 30% of the Statin alone group and 10% of the MO-PM-S group showed mild histopathologic findings in the liver. Conclusion: The cortex of the Magnolia officinalis Rehd. et Wils. and the root of Polygonum multiflorum Thunb have dyslipidemic effects from the perspective of a TG level and HDL-cholesterol. However, the herbal mixture has a raising effect on both the LDL-cholesterol and the total cholesterol levels. Therefore, we cannot conclude that the herbal mixture helps to prevent dyslipidemia. In liver biopsies, the group administered with both the herbal mixture and the statin showed less histopathologic findings than the group administered with statin alone. This means that the herbal mixture helps to prevent fatty degeneration of the liver.

• Proceedings of the Korean Society of Applied Pharmacology
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• 1994.04a
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• pp.332-332
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• 1994

식이습관을 바꾸지 않는 상태에서 4주간의 placebo 투여후 혈청 Total-C치가 240mg/dl 이상인 원발성 고콜레스테 혈증환자 25예씩 두군으로 하여 제1군은 lovastatin 20mg에서 80mg을 1일 1회 저녁에 12주간 투여하였고, 제2군은 pravastatin 5mg을 12주간 아침 저녁으로 2회 경구 투여하였다. Lovastatin과 pravastatin 12주 투여후 혈청 Total-C치는 309$\pm$46mg/d1에서 201$\pm$37mg/d1로, 281$\pm$41mg/d1에서 218$\pm$31mg/d1로, 혈청LDL-C치는 230$\pm$46mg/d1에서 125$\pm$40mg/d1로, 199$\pm$46mg/d1에서 137$\pm$37mg/d1로 각각 유의하게 감소 하였다. (p < 0.005)혈청 Apo B치는 183$\pm$32mg/d1에서 114$\pm$26mg/d1로, 164$\pm$38mg/d1에서 123$\pm$20mg/d1로, 혈청 Apo B / Apo A-1 ratio는 1.6$\pm$0.4에서 1.0$\pm$0.3으로, 1.4$\pm$0.5에서 1.0$\pm$0.3으로 각각 유의하게 감소하였다. (p < 0.005) Lovastatin 및 pravastatin 투여후 임상적으로 의미있는 중상이나 검사상 이상 소견은 관찰되지 않았다.

• The Korean journal of internal medicine
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• v.33 no.6
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• pp.1210-1223
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• 2018

Background/Aims: The co-occurrence of obesity aggravates asthma symptoms. Diet-induced obesity increases helper T cell (TH) 17 cell differentiation in adipose tissue and the spleen. The 3-hydroxy-3-methylglutaryl-coenzyme A reductase inhibitor pravastatin can potentially be used to treat asthma in obese patients by inhibiting interleukin 17 (IL-17) expression. This study investigated the combined effects of pravastatin and anti-IL-17 antibody treatment on allergic inflammation in a mouse model of obesity-related asthma. Methods: High-fat diet (HFD)-induced obesity was induced in C57BL/6 mice with or without ovalbumin (OVA) sensitization and challenge. Mice were administered the anti-IL-17 antibody, pravastatin, or both, and pathophysiological and immunological responses were analyzed. Results: HFD exacerbated allergic airway inflammation in the bronchoalveolar lavage fluid of HFD-OVA mice as compared to OVA mice. Blockading of the IL-17 in the HFD-OVA mice decreased airway hyper-responsiveness (AHR) and airway inflammation compared to the HFD-OVA mice. Moreover, the administration of the anti-IL-17 antibody decreased the leptin/adiponectin ratio in the HFD-OVA but not the OVA mice. Co-administration of pravastatin and anti-IL-17 inhibited airway inflammation and AHR, decreased goblet cell numbers, and increased adipokine levels in obese asthmatic mice. Conclusions: These results suggest that the IL-17-leptin/adiponectin axis plays a key role in airway inflammation in obesity-related asthma. Our findings suggest a potential new treatment for IL-17 as a target that may benefit obesity-related asthma patients who respond poorly to typical asthma medications.

• Analytical Science and Technology
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• v.22 no.5
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• pp.407-414
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• 2009

A simultaneous determination method for cholesterol, lanosterol and desmosterol was developed using gas chromatography/mass spectrometry. Urine was enzymatically hydrolyzed with ${\beta}$-glucuronidase/arylsulfatase. Samples were prepared using extractions with a mixture of ethyl acetate-hexane (2:3, v/v), followed by derivatization with a mixture of MSTFA/TMSI/TMCS (100:2:5 v/v/v). All analyses were performed using GC/MS in selective ion monitoring mode. Good linearities ($r^2=0.998{\sim}0.999$) in calibration curve and a satisfactory recovery (80.0%~113%) were achieved. Accuracy and precision values within ${\pm}15%$ in the concentration range of 5 to 200 ng/mL were also observed for all compounds. The developed method was applied to pravastatin-treated (70 and 250 mg/kg/day for 7 days, oral) hyperlipidemia rats. Those sterols were significantly lower in drug-treated rats compared to the controls, which justifies the drug efficacy. Therefore, these results indicate that the developed method was successfully applied to examine statin drug efficacy with urine sample.

• Proceedings of the Korean Society of Applied Pharmacology
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• 2003.11a
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• pp.44-58
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• 2003

• 대한임상약리학회:학술대회논문집
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• 2006.11a
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• pp.41-42
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• 2006

• Journal of Microbiology and Biotechnology
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• v.27 no.5
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• pp.956-964
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• 2017

Compactin and pravastatin are competitive cholesterol biosynthesis inhibitors of 3-hydroxy-3-methylglutaryl-CoA reductase and belong to the statin drugs; however, the latter shows superior pharmacokinetic characteristics. Previously, we reported that the bacterial P450, CYP105D7, from Streptomyces avermitilis can catalyze the hydroxylation of 1-deoxypentalenic acid, diclofenac, and naringenin. Here, we demonstrate that CYP105D7 could also catalyze compactin hydroxylation in vitro. In the presence of both bacterial and cyanobacterial redox partner systems with an NADPH regeneration system, the reaction produced two hydroxylated products, including pravastatin (hydroxylated at the C6 position). The steady-state kinetic parameters were measured using the redox partners of putidaredoxin and its reductase. The $k_m$ and $k_{cat}$ values for compactin were $39.1{\pm}8.8{\mu}M$ and $1.12{\pm}0.09min^{-1}$, respectively. The $k_{cat}/K_m$ value for compactin ($0.029min^{-1}{\cdot}{\mu}M^{-1}$) was lower than that for diclofenac ($0.114min^{-1}{\cdot}{\mu}M^{-1}$). Spectroscopic analysis showed that CYP105D7 binds to compactin with a $K_d$ value of $17.5{\pm}3.6{\mu}M$. Molecular docking analysis was performed to build a possible binding model of compactin. Comparisons of different substrates with CYP105D7 were conclusively illustrated for the first time.