The aim of this work was to develop, optimize and characterize a silymarin-laden polyvinylpyrrolidone (PVP)-polyethylene glycol (PEG) polymeric composite to resolve low aqueous solubility and dissolution rate problem of the drug. A number of silymarin-laden polymeric formulations were fabricated with different quantities of PVP K-30 and PEG 6000 by the solvent-evaporation method. The effect of PVP K-30 and PEG 6000 on the aqueous solubility and dissolution rate was investigated. The optimized formulation and its constituents were characterized using powder X-ray diffraction (PXRD), differential scanning calorimetry (DSC), scanning electron microscopy (SEM) and Fourier transform infrared spectroscopy (FTIR) techniques. Both the PEG 6000 and PVP K-30 positively affected the aqueous solubility and dissolution rate of the drug. In particular, a formulation consisting of silymarin, PVP K-30 and PEG 6000 (0.25/1.5/1.5, w/w/w) furnished the highest solubility (24.39±2.95 mg/mL) and an excellent dissolution profile (~100% in 40 min). The solubility enhancement with this formulation was ~1150-fold as compared to plain silymarin powder. Moreover, all the constituents existed in the amorphous state in this silymarin-laden PVP-PEG polymeric composite. Accordingly, this formulation might be a promising tool to administer silymarin with an enhanced effect via the oral route.
In this study, we fabricated pH-sensitive polyvinylpyrrolidone/acrylic acid (PVP/AA) hydrogels by a free-radical polymerisation method with variation in the content of monomer, polymer and cross-linking agent. Swelling was performed in USP phosphate buffer solutions of pH 1.2, 5.5, 6.5 and 7.5 with constant ionic strength. Network structure was evaluated by different parameters and FTIR confirmed the formation of cross-linked hydrogels. X-ray crystallography showed molecular dispersion of tramadol HCl. A drug release study was carried out in phosphate buffer solutions of pH 1.2, 5.5 and 7.5 for selected samples. It was observed that swelling and drug release from hydrogels can be modified by changing composition and degree of cross-linking of the hydrogels under investigation. Swelling coefficient was high at higher pH values except for the one containing high PVP content. Drug release increased by increasing the pH of the medium and AA contents in hydrogels while increasing the concentration of cross-linking agent had the opposite effect. Analysis of the drug release mechanism revealed non-Fickian transport of tramadol from the hydrogels.Uniterms: Drugs/release. Hydrogels/pH sensitive. Polyvinylpyrrolidone-acrilic acid/hidrogels. Tramadol hydrochloride. Methylene bisacrylamide.Nesse estudo, preparamos hidrogéis de polivinilpirrolidona/ácido acrílico(PVP/AA), sensíveis ao pH, por meio de método de polimerização de radical livre, com variações no conteúdo de monômero, de polímero e de agente de ligação cruzada. O inchamento foi realizado em soluções tampão fosfato USP pH 1,2, 5,5, 6,5 e 7,5, com força iônica constante. A estrutura reticular foi avaliada por diferentes parâmetros e o FTIR confirmou a formação de hidrogéis de ligação cruzada. A cristalografia de raios X mostrou dispersão molecular do cloridrato de tramadol. Realizou-se estudo de liberação do fármaco em soluções tampão fosfato pH 1,2, 5,5 e 7,5 para amostras selecionadas. Observou-se que o inchamento e a liberação do fármaco dos hidrogéis podem ser modificados mudando-se a composição e o grau de ligação cruzada dos hidrogéis em estudo. O coeficiente de inchamento foi alto em pH mais altos, exceto para um deles com alto conteúdo de PVP. A liberação do fármaco aumentou com o aumento do pH do meio e do conteúdo em AA nos hidrogéis, enquanto que o aumento na concentração do agente de ligação cruzada apresentou efeito oposto. A análise do mecanismo de liberação do fármaco revelou transporte não Fickiano do tramadol dos hidrogéis.
Background:
Gallic acid (GA-3,4,5-trihydroxybenzoic acid), a phenolic phytochemical, is a
ubiquitous secondary metabolite found in most plants, with appreciable concentrations in grapes seed, rose flowers,
sumac, oak and witch hazel. GA often results from the hydrolysis of terpenes and the polyphenol tannic acid.
Applications:
It exhibits powerful antioxidant, anti-inflammatory, antimicrobial, and anti-cancer activities. Most
intriguing benefit has been reported to be on the skin. Due to these beneficial properties, GA and its derivatives
(e.g. lipid-soluble phenols such as synthetic gallic esters aka gallates) have been extensively used as an adjuvant
in a number of therapeutic formulations, as a substitute of hydrocortisone in children with atopic dermatitis (AD)
and other skin conditions (hyperpigmentation, wound healing), and as a cosmetic ingredient. GA has a USFDA
GRAS status (generally recognized as safe), exhibiting fairly low systemic toxicity and associated mortality at
acute doses in many experimental models. Despite anti-skin aging benefits obtained with relatively safe GA formulations,
few cases of gallate-induced skin allergic have been reported in humans. Therefore, approaches to
improve the bioavailability and biodegradability of this poor-water soluble and non-biodegradable phenolic compound
are warranted.
Purpose:
This review has focused on the recently reported biological activities pertaining to the skin as well as
the pharmacological properties of GA and its derivatives with special emphasis on its use in (nano-) cosmetic
formulations. Since this is an evolving area of research, an adequate emphasis has been placed upon advantages
and disadvantages of various nanoformulations.
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