Ketoroloac tromethamine loaded nanodispersion incorporated into thermosensitive in situ gel for prolonged ocular delivery.

The present study was designed to improve the ocular availability of ketorolac tromethamine and to prolong its precorneal residence time for the treatment of postoperative ocular inflammation. Ketorolac tromethamine nanodispersions were successfully prepared by nanoprecipitation method using Eudragit(®) RL100. These nanodispersions were characterized in terms of particle size, zeta potential, entrapment efficiency and in vitro release. Consequently, the optimum nanodispersion was incorporated into thermosensitive in situ gel. The optimum gelling capacity was obtained by 20% Pluronic(®) F-127 and 14% Pluronic(®) F-127/1.5% HPMC K4m. The gelling temperature and gelation time of the in situ gels increased by decreasing the concentration of Pluronic(®) F-127. The mucoadhesive strength was significantly improved by the addition of HPMC. Incorporation of ketorolac tromethamine loaded nanodispersions into in situ gel bases sustained the release of ketorolac tromethamine, improved its ocular availability and prolonged its residence time without causing irritation to eye.

Formulation and corneal permeation of ketorolac tromethamine-loaded chitosan nanoparticles.

The aim of this work was to formulate chitosan (CS)-based nanoparticles (NPs) loaded with ketorolac tromethamine (KT) intended for topical ocular delivery. NPs were prepared using ionic gelation method incorporating tri-polyphosphate (TPP) as cross-linker. Following the preparation, the composition of the system was optimized in terms of their particle size, zeta potential, entrapment efficiency (EE) and morphology, as well as performing structural characterization studies using Fourier transform infrared spectroscopy (FT-IR) and differential scanning calorimetry (DSC). The data suggested that the size of the NPs was affected by CS/TPP ratio where the diameter of the NPs ranged from 108.0 ± 2.4 nm to 257.2 ± 18.6 nm. A correlation between drug EE and the corresponding drug concentration added to the formulation was observed, where the EE of the NPs increased with increasing drug concentration, for up to 10 mg/mL. FT-IR and DSC revealed that KT was dispersed within the NPs where the phosphate groups of TPP were associated with the ammonium groups of CS. The in vitro release profile of KT from CS NPs showed significant differences (p < 0.05) compared to KT solution. Furthermore, mucoadhesion studies revealed adhesive properties of the formulated NPs. The KT-loaded NPs were found to be stable when stored at different storage conditions for a period of 3 months. The ex vivo corneal permeation studies performed on excised porcine eye balls confirmed the ability of NPs in retaining the drug on the eye surface for a relatively longer time. These results demonstrate the potential of CS-based NPs for the ocular delivery of KT.

Differential effects of non-steroidal anti-inflammatory drugs on mitochondrial dysfunction during oxidative stress.

We investigated the effects of several non-steroidal anti-inflammatory drugs on swelling related properties of mitochondria, with an emphasis on compounds that are marketed and utilized topically in the eye (nepafenac, ketorolac, diclofenac, bromfenac), and compared these to the effects of amfenac (a metabolite of nepafenac) and to celecoxib (active principle of Celebrex). With the exception of the last compound, none of the drugs promote swelling of normal mitochondria that are well energized by succinate oxidation. However, swelling is seen when the mitochondria are under an oxidative stress due to the presence of t-butylhydroperoxide. When used at 200 microM the order of potency is celecoxib > bromfenac > diclofenac > ketorolac > amfenac > nepafenac approximately equal to 0. Again with the exception of celecoxib, this swelling is not seen when mitochondria are depleted of endogenous Ca(2+) and is accelerated when exogenous Ca(2+) is provided. Sr(2+) does not substitute for exogenous Ca(2+) and prevents swelling in the presence of endogenous Ca(2+) only. The same is true for ruthenium red (inhibitor of the Ca(2+) uniporter), for cyclosporin A (inhibitor of the mitochondrial permeability transition), and for a 3.4 kDa polyethylene glycol (polymer that cancels the force which drives swelling following the permeability transition). It is concluded that several non-steroidal anti-inflammatory drugs promote the mitochondrial permeability transition under conditions of oxidative stress and in a Ca(2+) dependent fashion, whereas celecoxib functions by another mechanism. Potency of those compounds that promote the transition varies widely with bromfenac being the most potent and nepafenac having almost no effect. The mitochondrial dysfunction which is caused by the transition may underlie side effects that are produced by some of these compounds.

Influence of ultrasound on the percutaneous absorption of ketorolac tromethamine in vitro across rat skin.

The influence of ultrasound on percutaneous absorption of ketorolac tromethamine was studied in vitro across rat skin. Sonication was carried out with a continuous mode, at an intensity of 1-3 W/cm2 and a frequency of 1 MHz for 30 min. A significant increase in permeation of ketorolac through rat skin was observed with the applied sonication at 3 W/cm2 when compared with permeation at 1 and 2 W/cm2. Enhanced ketorolac penetration at 3 W/cm2 can be explained by the mechanical and/or thermal action of ultrasound waves. The distance of the ultrasound probe from the skin surface did not influence the flux of the drug. Pretreatment of skin by 5% d-limonene in ethanol for 2 hr followed by sonication at 3 W/cm2 (30 min) significantly enhanced the permeation of ketorolac when compared with passive flux with or without enhancer pretreatment.