Preparation of stabilized submicron fenofibrate crystals on niacin as a hydrophilic hydrotropic carrier.

Fenofibrate is antihyperlipidemic which has low and variable oral bioavailability due to erratic dissolution characteristics. Niacin showed a potential atheroprotective effects suggesting possible co-administration with fenofibrate with a potential for development of fixed dose combination. The chemical structure of both drugs highlights the opportunity for interaction upon co-processing due to the existence of complementary hydrogen bonding sites. Accordingly, fenofibrate and niacin were co-processed by wet co-grinding and the resulting product was assessed using scanning electron microscopy, FTIR, thermal analysis and X-ray diffraction in addition to dissolution studies. The instrumental analysis indicated the development of submicron fenofibrate crystals stabilized over the surface of niacin crystals. The developed submicron crystals showed fast dissolution of fenofibrate depending on the relative proportions of fenofibrate to niacin. Co-processing of both drugs at dose ratio which contained higher proportion of niacin resulted in further enhancement in the dissolution rate. This further enhancement was attributed to the hydrotropic effect of niacin which was proved by solubility study in addition to size reduction. This supposition was confirmed from the inferior dissolution of fenofibrate from the physical mixture. The study introduces fenofibrate/niacin as potential fixed dose combination for augmented dissolution rate and pharmacological effects.

Eutexia for enhanced dissolution rate and anti-inflammatory activity of nonsteroidal anti-inflammatory agents: Caffeine as a melting point modulator.

Fast dissolution of nonsteroidal anti-inflammatory drugs (NSAIDs) is a prerequisite from patient perspective. However, most NSAIDs are slowly dissolving acidic compounds. Caffeine, a commonly used analgesic adjuvant with NSAIDs showed high potential as eutectic co-former for acidic compounds. The study investigated eutectic forming potential of caffeine with meloxicam, aceclofenac and flurbiprofen. Each drug was co-ground with caffeine in various ratios and the products were characterized by thermal analysis to determine the optimum eutectic composition from phase diagram and Tamman's triangle. The optimum systems were subjected to X-ray powder diffraction (XRPD), Fourier-transform infrared (FTIR) and dissolution studies. Co-ground systems at dose ratio were also assessed for drug dissolution and anti-inflammatory effect using carrageenan induced rat paw edema method. Eutexia was confirmed by thermal analysis with the optimum composition being 1:1, 1:1 and 1:2 (NSAID: caffeine) for aceclofenac, flurbiprofen and meloxicam, respectively. Eutexia did not alter FTIR spectra with minor changes being recorded in XRPD patterns. The eutectic systems underwent fast liberation of drugs with fast dissolution being retained even at dose ratios. Dissolution enhancement was associated with enhanced anti-inflammatory response. The study introduced caffeine as eutectic forming analgesic for fixed dose combination with NSAIDs to enhance drug dissolution and anti-inflammatory effect.