Clotrimazole nanoemulsion for malaria chemotherapy. Part II: stability assessment, in vivo pharmacodynamic evaluations and toxicological studies.

The aim of present investigation was to evaluate the potential of clotrimazole as antimalarial drug. Due to poor aqueous solubility and high lipophilicity, it was previously formulated in a nanoemulsion based system. The intrinsic effects of nanoemulsion on improvement of antimalarial activity of clotrimazole were assessed in mice infected with Plasmodium berghei and compared to its suspension formulation. In four-day suppressive test, mice treated with 10mg/kg clotrimazole nanoemulsion showed the highest suppression of parasitemia and; parasitemia was significantly lower than that of 10mg/kg clotrimazole suspension. In onset of activity and recrudescence test, percent reduction of parasitemia was significantly higher in 10 and 15 mg/kg clotrimazole nanoemulsion groups compared to 15 mg/kg suspension group. In both murine models, survival of mice treated with nanoemulsion was significantly prolonged compared to suspension at equivalent doses. The inhibition of parasite growth by clotrimazole in the nanoemulsion was dose dependent as determined by test for linear trend. In repeated dose oral toxicity, levels of serum liver enzymes and biomarkers of hepatotoxicity did not vary significantly from control. Six-month stability testing of the clotrimazole nanoemulsion exhibited no changes in various physiochemical attributes of drug product compared to initial analysis.

Curcumin-loaded hydrogel nanoparticles: application in anti-malarial therapy and toxicological evaluation.

The present investigation involved preparation of hydrogel nanoparticles using a combination of hydroxyl propyl methyl cellulose and polyvinyl pyrrolidone. The objective was to exploit the size and hydrophilic nature of the formulated nanocarriers to enhance absorption and prolong the rapid clearance of curcumin due to possible evasion of the reticulo-endothelial system. Reproducible nanoparticles of size around 100 nm, a fairly narrow distribution and encapsulation efficiency of 72%, were produced by the solvent emulsion-evaporation technique. This optimized system was further subjected to freeze-drying. The freeze-dried product was readily reconstituted with distilled water. The reconstituted product exhibited a size and distribution similar to that before freeze-drying, drug content of greater than 99% and presence of amorphous drug when analyzed by differential scanning calorimetry (DSC) which may result in possible improved absorption of curcumin. In vivo anti-malarial studies revealed significant superior action of nanoparticles over curcumin control suggesting the possibility of the formulation being employed as an adjunct anti-malarial therapy along with the standard therapy. Acute and subacute toxicity studies confirmed the oral safety of the formulation. A battery of genotoxicity studies was conducted to evaluate the nongenotoxic potential of the developed formulation thus indicating the possibility of the formulation being employed for prolonged duration.