ABSTRACT
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 formula-tion 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 dis-solution 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 (24.3972.95 mg/mL) and an excellent dissolution profile (~100% in 40 min). The solubility enhancement with this formulation was ~1150-fold as com-pared 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.
ABSTRACT
Abstract The aim of the present research was to develop a silymarin-laden PVP-nanocontainer providing ameliorated aqueous solubility and dissolution of the drug. Several silymarin-laden formulations were formed with varying quantities of PVP and SDS via the solvent evaporation method using the electrospraying technique. The influence of the hydrophilic carriers on solubility and dissolution was explored. The solid-state characterization was carried out by particle-size analysis, PXRD, DSC, FTIR and SEM. All of the formulations demonstrated better solubility and dissolution than did silymarin plain powder. Both the SDS and PVP had positive effects on solubility and dissolution of silymarin in the aqueous media. An increased solubility was attained as the drug/PVP ratio was 1/4; however, further increase in PVP did not provide significant improvement. In particular, a nanocontainer formulation prepared with silymarin, PVP and SDS (1/4/0.5, w/w/w) exhibited the best solubility (26432.76 ± 1749.00 μg/mL) and an excellent dissolution (~92 % in 20 min) than did silymarin plain powder. Also, it demonstrated similar dissolution profiles compared to a commercial product; therefore, might be bioequivalent to the commercial product (f 1 = 3 and f 2 = 69). Moreover, cumulative undersize distribution values as represented by X10, X50 and X90 were 201 ± 21.01 nm, 488 ± 36.05 nm and 392 ± 48.10 nm, respectively. The drug existed in the amorphous state in the PVP-nanocontainers with no strong chemical bonding with other excipients. Thus, this formulation might be used for more effective administration of silymarin via the oral route.
Subject(s)
Silymarin/administration & dosage , Spectrometry, Mass, Electrospray Ionization , Dissolution , NanoparticlesABSTRACT
Complexos de rutênio, em razão da menor toxicidade e por poderem exibir atividade citotóxica ou antimetastática, tem sido considerados como alternativas potencialmente promissoras aos complexos de platina para tratamento de câncer. Nosso grupo de pesquisa tem investigado a interação de íons metálicos com fármacos anti-inflamatórios não esteroides (FAINEs) e já obteve sucesso na preparação de metalofármacos de dirutênio(II,III)-FAINEs, os quais se mostraram promissores com relação à atividade frente a modelos de glioma. Com a finalidade de contribuir para o entendimento das propriedades físico-químicas desses complexos, o presente trabalho teve como principal objetivo analisar propriedades consideradas particularmente essenciais a um potencial candidato a fármaco, tais como, estabilidade no estado sólido, lipofilicidade, solubilidade aquosa e dissolução intrínseca. Um complexo inédito de fórmula [Ru2Cl(feno)4], em que feno = fenoprofenato, foi sintetizado e caracterizado por meio de análise elementar, espectroscopia eletrônica, espectroscopia vibracional, difratometria de raios X, análise térmica e espectrometria de massas. Os complexos já testados anteriormente para atividade biológica, [Ru2Cl(ibp)4], ibp = ibuprofenato, e [Ru2(cet)4Cl], cet = cetoprofenato, foram analisados quanto à estabilidade no estado sólido por meio da determinação isotérmica de variação de massa. As lipofilicidades desses dois complexos, juntamente com a dos fármacos de origem e a do precursor sintético [Ru2(O2CH3)4Cl], foram avaliadas pelo método shake flask, e suas solubilidade aquosas foram investigadas em presença de co-solventes alcoólicos. Investigou-se ainda a velocidade de dissolução intrínseca do [Ru2Cl(ibp)4] que se encontra em estágio avançado de estudos biológicos. Os resultados obtidos trazem novas informações sobre o comportamento térmico dos complexos e sobre suas características biofarmacêutica
Ruthenium complexes, mainly due to the lower toxicity and the cytotoxic and anti-metastatic activities, have been considered as potentially promising alternatives to platinum drugs for cancer treatment. Our research group has investigated the interactions of diruthenium metal cores with anti-inflammatory non-steroidal drugs (NSAIDs) and succeeded in preparing diruthenium(II,III)-NSAIDs metallodrugs which show promising activity against glioma models. With the aim of elucidating the physico-chemical properties of these complexes, the major objective of the present work was to investigate properties which are considered as essential for a potential candidate to drug, e.g., stability in the solid state, lipophilicity, aqueous solubility and intrinsic dissolution. A new complex of formula [Ru2Cl(feno)4], where feno = fenoprofen, was synthesized and characterized by elemental analysis, electronic spectroscopy, vibrational spectroscopy, X-rays difractommetry, thermal analysis and mass spectrometry. The complexes previously tested for biological properties, [Ru2Cl(ibp)4], ibp = ibuprofenate, and [Ru2(cet)4Cl], cet = cetoprofenate, were inv estigated for the stability in the solid state by isothermal thermogravimetry. The lipophilicity of the se complexes, as well as those of the parent drugs and of the precursor [Ru2(O2CH3)4Cl], was evaluated by the shake flask method, and their aqueous solubility in the presence of alcohol co-solvents was investigated. In addition, the intrinsic dissolution rate was determined for [Ru2Cl(ibp)4], which is undergoing advanced biological studies. The results provide important new information on the thermal behavior of the complexes and also on their biopharmaceutical propertie