HSPiP and QbD oriented optimized green nanoemulsion to treat chloramphenicol contaminated water

Abstract

Nanoemulsion is an isotropic and kinetically stable system used for multiple purposes. Exhaustive flow of chloramphenicol (CAMP) in the water systems raised global thereat to aquatic and human lives. Innate cohesive energy of the material is the basis of predictive HSPiP program. We aimed to prepare biocompatible nanoemulsion employing eugenol oil, lecithin, tween 80, and propylene glycol) for the contaminated water treatment. Furthermore, experimental design oriented robust nanoemulsion (OCEN1) investigated the impact of composition, CTime (exposure time), and nanoemulsion characteristics on percent removal efficiency (%RE). Thermodynamic stability study was conducted at different temperatures. Finally, the presence of CAMP in the treated water was negated by ICP-OES (inductively coupled plasma-optical emission spectroscopy). HSP (Hansen solubility parameters) and experimental solubility data were the basis of excipient selection. A blend of tween-80 and lecithin served as surfactant mixture (Smix) to stabilize nanoemulsion. OCEN1 was associated with high desirability (D = 0.93), low size (43 nm), low PDI (0.19), high %RE (90.72 % over period of 17 min of exposure time), optimal viscosity (1.12 cP), and high zeta potential (−25 mV). Experimental design identified significant impact of composition, exposure time (CTime), and nanoemulsion characteristics on %RE as prime factors to consider before wastewater treatment plant installation. Thus, the approach is simple, rapid, ecofriendly, and scalable to treat CAMP contaminated water with high selectivity and efficiency.