YAKHAK HOEJI (약학회지)

The Pharmaceutical Society of Korea (대한약학회)
권호 표지

Quantitative Analysis of Lovastatin in Human Plasma and urine by Reversed-Phase High-Performance Liquid Chromatography

역상 고속액체크로마토그라프법을 이용한 혈장 및 뇨 중 로바스타틴의 정량

  • Choi, Hye-Jin (Division of Pharmaceutical Services, Samsung Medical Center) ;
  • Kim, Myoung-Min (Clinical Pharmacology Laboratory, Samsung Biomedical Research Institute) ;
  • Choi, Kyung-Eob (Division of Pharmaceutical Services, Samsung Medical Center, Clinical Pharmacology Laboratory, Samsung Biomedical Research Institute)
  • 최혜진 (삼성서울병원 약제부) ;
  • 김명민 (삼성생명과학연구소 임상약리학연구실) ;
  • 최경업 (삼성서울병원 약제부, 삼성생명과학연구소 임상약리학연구실)
  • Published : 1998.10.01
Download PDF
⟨ Previous Next ⟩

Abstract

Lovastatin (LOVA), a fungal metabolite isolated from cultures of Aspergillus terreus, is a competitive HMG-CoA reductase inhibitor used for the treatment of primary hyper cholesterolemia, and has also been shown to suppress growth in a variety of non-glioma tumor cell lines. A sensitive reversed-phase high-perfonnance liquid chromatographic method with ultraviolet (UV) absorbance detection has been developed to quantitate LOVA in human plasma and urine samples using liquid-liquid extraction procedure. Baseline separation of LOVA and internal standard, simvastatin was achieved on a Novapak $C_{18}$ analytical column with a mobile phase containing 0.025M $NaH_2PO_4$: CAN (35:65, v/v%), adjusted pH to 4.5. The flow rate was set at 1.5ml/min, and the column effluent was monitored by a UV detection at 238nm. The limit of quantification was determined to be 0.5${\mu}$g/ml while extraction efficiency of LOVA ranged from 73.4-82.9% at LOVA concentrations of 0.5 to 10${\mu}$g/ml. Good linearity with correlation coefficients greater than 0.999 was obtained in the range of LOVA concentrations from 0.5 to 10${\mu}$g/ml. The accuracy and the precision were proven excellent with relative standard deviation (RSD, %) and relative error (RE, %) of less than 4.2 and 4.0, respectively. Intraday precision, evaluated at five LOVA concentrations (0.5, 1, 2, 5, 10${\mu}$g/ml) and expressed as RSD ranged from 0-1.82% while the interday precision at the same concentrations ranged from 0.7-10.5%. The analytical method described was then successfully employed for the determination of LOVA concentrations in plasma samples obtained during a phase II clinical trial using high doses of LOVA (30-40mg/kg/day). This method could be further utilized for the ongoing pharmacolkinetic studies and therapeutic drug monitoring of the high-dose LOVA therapy in adenocarcinoma patients.

Keywords

References

  1. Drugs v.36 Lovastatin. A preliminary review of its pharmacodynamic properties and therapeutic use in hyperlipidaemia. Henwood, J. M.;Heel, R. C.
  2. Proc. Natl. Acad. Sci. USA. v.88 Cell cycle-specific effects of lovastatin. Jakobisiak, M.;Bruno, S.;Skierski, J. S.;Darzynkiewicz, Z.
  3. Cancer Res. v.51 Synchronization of tumor and normal cells from G1 to multiple cell cycles by lovastatin. Keyomarsi, K.;Sandoval, L.;Band, V.;Pardee, A. B.
  4. J. Clin. Invest. v.76 Supression of murine neuroblastoma growth in vivo by mevinolin, a competitive inhibitor of hydroxy-3-methylglutaryl-coenzyme A reductase. Maltese, W. A.;Defendini, R.;Green, R. A.;Sheridan, K. M.;Donley, D. K.
  5. J. Clim. Pharmacol. v.30 Comparative pharmacokinetics of pravastatin and lovastatin. Pan, H. Y.;Devault, A. R.;Wang-Iverson, D.;Ivashkiv E.;Swanson, B. N.;Sugerman, A. A.
  6. Clin Pharm. v.7 Lovastatin: A new cholesterol-lowering agent. McKenney, J. M.
  7. Pharmacotherapy v.7 Lovastatin: A new cholesterol-lowering agent. Krukemyer, J. J.;Talbert, R. L.
  8. Physician's Desk reference $Mevacor^ⓡ$ package insert Merck sharp, Dohme;Oradell. N. J.(ed.)
  9. J. Chromatogr. v.383 Determination of mevinolin and mevinolinic acid in plasma and bile by reversed-phase high-performance liquid chromatography. Stubbs, R. J.;Schwartz, m.;Bayne, W. F.
  10. Cancer Commun. v.3 Lovastatin, a cholesterol biosynthesis inhibitor, inhibits the growth of human H-ras oncogene transformed cells in nude mice. Sebti, S. M.;Tkalcevic, G. T.;Jani, J. P.
  11. Biochem. Biophys. Res. Commun. v.180 Inhibition of growth factor signaling pathways by lovastatin. Vincent, T. S.;Wulfert, E.;Merler, E.
  12. J. Clin. Pharmacol. v.32 Comparative Pharmacokinetics of lovastatin, simvastatin and pravastatin in Humans. Pentikainen, P. J.;Saraheimo, M.;Schwartz, J. I.;Amin, R. D.;Schwartz, M. S.;Brunner-Ferber, F.;Rogers, J. D.
  13. J. Pharm. Biomed. Anal. v.10 Simultaneous determination of simvastatin and its hydroxy acid form in human plasma by high-performance liquid chromatography with UV detection. Carlucci, G.;Mazzeo, P.;Bior, L.;Bologna, M.
  14. Drug Metab. Dispos. v.18 Biotranformation of lovastain: I. Structure elucidation of in vivo metabolites in the rat and mouse. Vyas, K. P.;Kari, P. H.;Pitzenberger, S. M.;Halpin, R. A.;Ramjit, H. G.;Arision, B.;Murphy, J. S.;Hoffman, W. F.;Schwartz, M. S.;Ulm, E. H.;Duggan, D. E.
  15. Drug Metab. and Dispos. v.18 Biotransformation of lovastatin: Ⅱ. In vitro metabolism by rat and mouse liver microsomes and involvement of cytochrome P-450 in dehydrogenation of lovastatin. Vyas, K. P.;Kari, P. H.;Prakash, S. R.;Duggan, D. E.
  16. J. Cell. Physiol. v.155 Isoprenoid regulation of cell growth: Identification of mevalonate-labelled compounds inducing DNA synthesis in human breast cancer cells depleted of serum and mevalonate. Wejde, j.;Carlberg, M.;Hjertman, M.;Larssonm, O.
  17. Practical HPLC Method Development(2nd ed.) Snyder, L. R.;Kirkland, J. J.;Glajch, L. G.