Effect of inorganic salts on the clouding behavior of hydroxypropyl methyl cellulose in presence of amphiphilic drugs.

In this paper we report the effect of two cationic (imipramine hydrochloride (IMP) and promazine hydrochloride (PMZ)) and one anionic (sodium salt of ibuprofen (IBF)) drugs on the clouding behavior of a nonionic polymer hydroxypropyl methyl cellulose (HPMC). Though all the three drugs increase the cloud point (CP) of HPMC, the effect was found to be minimum in the case of IBF. Further, the effect of adding salts (NaF, NaCl, NaBr, NaNO(3), Na(2)SO(4), Na(3)PO(4), KCl, KBr, KNO(3)) in the presence of amphiphilic drugs (IMP and PMZ) on the CP of HPMC was seen. Almost linear decrease in the CP was observed with the [salt] at fixed concentrations of these drugs whereas in the absence of drugs the decrement in the CP was slight. The energetic parameters (ΔG(c)(0), ΔH(c)(0) and TΔS(c)(0)) were evaluated and it implies that the disruption of water structure becomes significantly prominent at lower concentrations of the drugs at fixed salt concentrations.

A comparative study of interaction of ibuprofen with biocompatible polymers.

In this paper we are reporting the interaction of a non-steroidal anti-inflammatory drug ibuprofen (IBF) with various biocompatible polymers. Being amphiphilic, the drug interacts with the polymers similar to the interaction of surfactants and polymers. Therefore, we have considered the polymer-amphiphile interaction approach using conductimetry. The polymers of different charges (cationic, anionic, and nonionic) have been taken for the study. It was found that the critical aggregation concentration (cac) decreases on increasing the polymer concentrations of cationic as well as nonionic polymers whereas it increases for anionic polymers. The results imply that anionic IBF interacts with cationic and nonionic polymers more strongly as compared to the anionic polymers. A possible anionic-anionic repulsion is responsible for the weak interaction of IBF with anionic polymers. On the other side, the critical micelle concentration (cmc) increases for all polymers which is a usual indication of the interaction between amphiphiles and polymers. Free energies of aggregation (ΔG(agg)) and micellization (ΔG(mic)) were also computed with the help of degrees of micelle ionization obtained from the specific conductivity - [IBF] isotherms.

Complexation behavior of gelatin with amphiphilic drug imipramine hydrochloride as studied by conductimetry, surface tensiometry and circular dichroism studies.

Herein we report our studies carried out on the interaction between IMP and gelatin in aqueous medium at 25°C using conductimetry, surface tensiometry and circular dichroism (CD) techniques. Both surface tensiometry and conductimetry results indicate that the drug interacts with the gelatin in a surfactant-like manner, i.e., both critical aggregation (cac) and polymer saturation points (psp) were observed. The interaction starts with the formation of a highly surface-active complex as revealed by the lowering of surface tension on the addition of drug to the macromolecule. The decrease in cac on increasing gelatin concentration is an indication of the strong interaction between gelatin and IMP. However, at low concentration of gelatin the interaction was not much strong as exposed by surface tension study, i.e., the cac was not very clear (as with higher gelatin concentrations). As usual, the psp increased on increasing the gelatin concentration and was always higher than the critical micelle concentration of the drug in pure aqueous medium. Using CD measurements the influence of IMP on the secondary structure of gelatin in aqueous solutions was also investigated. CD studies (performed at very low drug concentrations) illustrated that the random coil content of gelatin increases with increasing drug concentration. Free energies of aggregation (ΔG(agg)) and micellization (ΔG(mic)) were computed with the help of degrees of micelle ionization obtained from the specific conductivity - [IMP] plots.