FORMULATION, EVALUATION AND IN VITRO DISSOLUTION PERFORMANCE OF ENALAPRIL MALEATE SUSTAINED RELEASE MATRICES: EFFECT OF POLYMER COMPOSITION AND VISCOSITY GRADE.

The present study aimed at developing the sustained release matrix tablets of enalapril maleate and evaluating the effect of polymer concentration and viscosity grade on drug release. The sustained release enalapril maleate tablets were successfully formulated by direct compression method using nonionic cellulose ethers HPMC K15, HPMC K100 and HPC polymers either alone or in combination. In-vitio drug release study was carried out in phosphate buffer (pH 6.8) for a period of 24 h following USP dissolution apparatus II i.e., paddle apparatus. Model dependent approaches like zero-order, first order, Higuchi's model and Korsmeyer-Peppas model were used to assess drug release from various formulations. All the three polymers alone or in combination sustained the drug release. The drug release characteristics from HPMC and HPC polymer followed zero order release kinetics except for 45% concentration of all polymers alone or in combination where by the drug release followed Higuchi's model. In all cases, the drug release mechanism was both diffusion as well as erosion.

Towards a correlation between drug properties and in vitro transdermal flux variability.

Over recent years, there has been growing evidence that the permeability coefficient variability describing any specific transdermal drug delivery system is not always normally distributed. However, since different researchers have used different test compounds, methodologies and skin types, it has been difficult to identify any general correlation between drug properties and flux variability. The aim of the present study was to investigate whether there was a relationship between these two variables. To this end, six different compounds (sucrose, adenosine, aldosterone, corticosterone, oestradiol and testosterone) exhibiting a range of partition coefficients but relatively similar molecular weights were screened by taking multiple replicate measurements of their permeation profiles as they penetrated across porcine skin in vitro. It was found that for relatively hydrophilic solutes (log P(o/w)< or = approximately 2.5), physicochemical properties that facilitated slow transdermal flux were associated with more positively skewed permeability coefficient distributions while rapid flux was associated with more symmetric distributions. However, no correlation could be found between molecular properties and the extent of statistical fit to either the normal or log-normal distribution.

Assessment of drug permeability distributions in two different model skins.

Past in vitro studies with human skin have indicated that drug permeability coefficient (Kp) distributions do not always follow a Gaussian-normal pattern. This has major statistical implications, exemplified by the fact that use of t-tests to evaluate significance is limited to normally distributed populations. Percutaneous absorption research often involves using animal or synthetic skins to simulate less readily available human skin. However, negligible work has been performed on assessing the permeability variabilities of these model membranes. This paper aims to fill this gap. To this end, four studies were undertaken representing two different drugs (caffeine and testosterone) with each drug penetrating through two different model skins (silicone membrane and pig skin). It was determined that in the silicone membrane studies, both compounds' Kp distributions could be fitted to a normal pattern. In contrast, in the pig skin studies, there were notable differences between each drug. While the testosterone Kp values could be fitted to a normal distribution, this was not possible with the caffeine Kp data, which could be fitted to a log-normal distribution. There is some evidence from the literature as well as physicochemical considerations that these outcomes may reflect general trends that are dependent upon both membrane and penetrant properties.