Moxifloxacin Hydrochloride-Loaded Eudragit® RL 100 and Kollidon® SR Based Nanoparticles: Formulation, In vitro Characterization and Cytotoxicity.

BACKGROUND: Considering the low ocular bioavailability of conventional formulations used for ocular bacterial infection treatment, there is a need to design efficient novel drug delivery systems that may enhance precorneal retention time and corneal permeability. AIM AND OBJECTIVE: The current research focuses on developing nanosized and non-toxic Eudragit® RL 100 and Kollidon® SR nanoparticles loaded with moxifloxacin hydrochloride (MOX) for its prolonged release to be promising for effective ocular delivery. METHODS: In this study, MOX incorporation was carried out by spray drying method aiming ocular delivery. In vitro characteristics were evaluated in detail with different methods. RESULTS: MOX was successfully incorporated into Eudragit® RL 100 and Kollidon® SR polymeric nanoparticles by a spray-drying process. Particle size, zeta potential, entrapment efficiency, particle morphology, thermal, FTIR, NMR analyses and MOX quantification using HPLC method were carried out to evaluate the nanoparticles prepared. MOX loaded nanoparticles demonstrated nanosized and spherical shape while in vitro release studies demonstrated modified-release pattern, which followed the Korsmeyer-Peppas kinetic model. Following the successful incorporation of MOX into the nanoparticles, the formulation (MOX: Eudragit® RL 100, 1:5) (ERL-MOX 2) was selected for further studies because of its better characteristics like cationic zeta potential, smaller particle size, narrow size distribution and more uniform prolonged release pattern. Moreover, ERLMOX 2 formulation remained stable for 3 months and demonstrated higher cell viability values for MOX. CONCLUSION: In vitro characterization analyses showed that non-toxic, nano-sized and cationic ERL-MOX 2 formulation has the potential of enhancing ocular bioavailability.

Gamma-aminobutyric acid loaded halloysite nanotubes and in vitro-in vivo evaluation for brain delivery.

Gamma-aminobutyric acid (GABA) is a key neurotransmitter where it usually inhibits impulse transmission. GABA release blockage or postsynaptic reaction were determined to provoke epileptic convulsions. The aim of the present study was the development of brain-targeted, nanosized, nontoxic, biocompatible, highly specific formulations. Incorporation of GABA into halloysite nanotubes (HNT) was performed using different methods. Particle size, zeta potential and pH measurements, morphological, thermal, XRD, FTIR analyses and GABA quantification by validated HPLC method were used for the characterization of the systems prepared. Release pattern of GABA from the nanotubes was determined using a dialysis membrane. Following successful incorporation of GABA into HNTs for brain delivery, nanotube formulation coded HNT-GABA H1 was selected for in vivo studies. Smaller particle size with narrow size distribution, possible HNT-GABA interaction indicated by thermal, XRD and FTIR analyses and prolonged release were the parameters considered in this selection. Moreover, HNT-GABA H1 remained stable for 3-month storage period and showed higher cell viability values than GABA. Rats were used in in vivo studies and potential of anticonvulsant effect of GABA was determined in the pentylenetetrazole model of seizure. HNT-GABA H1 was found to increase latency of seizure, decrease ending time of the convulsion, duration of severe convulsion and mortality rate significantly compared to pure GABA. After administration of HNT-GABA H1, GABA concentration in Stratum corsatum measured by enzyme immune assay showed that it was not significantly higher than GABA administered alone. These findings suggest that GABA loaded HNTs reduces the duration of all phases of convulsion indicating efficient delivery of GABA to all brain areas to interfere with epileptic mechanism.