ABSTRACT
Valsartan, a water-insoluble drug, is mainly used in the treatment of hypertension albeit with reduced oral bioavailability. The aim of work was to develop a valsartan:beta-cyclodextrin (VAL:beta-CD) pharmaceutical composition in order to improve its water solubility and bioavailability. The VAL:beta-CD complexes were prepared by the kneading, solid dispersion and freeze-drying methods, of which the freeze-drying method (FDY) was found to be the best to prepare an inclusion complex. A physical mixture PM was also prepared. Complexes were characterized by thermal analysis, Fourier transformed-infrared (FTIR) spectroscopy, Powder X-ray diffractometry, intrinsic dissolution and NMR (2D-ROESY). Phase-solubility analysis showed A(L)-type diagrams with beta-cyclodextrin (beta-CD). Microcalorimetric titrations suggested the formation of 1:1 inclusion complex between VAL and beta-CD. The apparent stability constants K(1:1) calculated from phase-solubility plots were 165.4 M(-1) (298 K), 145.0 M(-1) (303 K) and 111.3 M(-1) (310 K). In vivo experiments in rats showed that reduction in arterial pressure for the FDY complex is better than with valsartan used alone. The better activity of FDY can be attributed to the higher solubility of valsartan after inclusion in the cyclodextrin cavity, as suggest by the intrinsic dissolution studies.
Subject(s)
Antihypertensive Agents/chemistry , Antihypertensive Agents/therapeutic use , Cyclodextrins/chemistry , Hypertension/drug therapy , Tetrazoles/chemistry , Valine/analogs & derivatives , Animals , Hypertension/chemically induced , Magnetic Resonance Spectroscopy , Male , Molecular Structure , Rats , Rats, Wistar , Spectroscopy, Fourier Transform Infrared , Valine/chemistry , ValsartanABSTRACT
In this study we evaluated by telemetry the effects of ANG II and ANG-(1-7) infusion on the circadian rhythms of blood pressure (BP) and heart rate (HR) and on the cardiovascular adjustment resulting from restraint stress in rats. ANG II or ANG-(1-7) or vehicle were infused subcutaneously for 7 days. Restraint stress was carried out before, during, and after infusion at 7-day intervals. Parallel with an increase in MAP, ANG II infusion produced an inversion of MAP circadian rhythm with a significant MAP acrophase inversion. It also produced bradycardia during the first 3 days of infusion. Thereafter, HR progressively increased, reaching values similar to or above those of the control period at the end of the infusion period. HR circadian variation was not changed by ANG II infusion. Strikingly, ANG II significantly attenuated the increase in MAP induced by restraint stress without altering the HR response. ANG-(1-7) infusion produced a slight but significant decrease in MAP restricted to the daytime period. No significant changes in the MAP acrophase were observed. In addition, ANG-(1-7) infusion produced a small but significant sustained bradycardia. ANG-(1-7) did not change cardiovascular responses to restraint stress. These data indicate that ANG II can influence the activity of brain areas involved in the determination of stress-induced or circadian-dependent variations of blood pressure without changing HR fluctuations. A significant modulatory influence of ANG-(1-7) on basal MAP and HR is also suggested.