Travoprost Liquid Nanocrystals: An Innovative Armamentarium for Effective Glaucoma Therapy.

To date, the ophthalmic application of liquid crystalline nanostructures (LCNs) has not been thoroughly reconnoitered, yet they have been extensively used. LCNs are primarily made up of glyceryl monooleate (GMO) or phytantriol as a lipid, a stabilizing agent, and a penetration enhancer (PE). For optimization, the D-optimal design was exploited. A characterization using TEM and XRPD was conducted. Optimized LCNs were loaded with the anti-glaucoma drug Travoprost (TRAVO). Ex vivo permeation across the cornea, in vivo pharmacokinetics, and pharmacodynamic studies were performed along with ocular tolerability examinations. Optimized LCNs are constituted of GMO, Tween® 80 as a stabilizer, and either oleic acid or Captex® 8000 as PE at 25 mg each. TRAVO-LNCs, F-1-L and F-3-L, showed particle sizes of 216.20 ± 6.12 and 129.40 ± 11.73 nm, with EE% of 85.30 ± 4.29 and 82.54 ± 7.65%, respectively, revealing the highest drug permeation parameters. The bioavailability of both attained 106.1% and 322.82%, respectively, relative to the market product TRAVATAN®. They exhibited respective intraocular pressure reductions lasting for 48 and 72 h, compared to 36 h for TRAVATAN®. All LCNs exhibited no evidence of ocular injury in comparison to the control eye. The findings revealed the competence of TRAVO-tailored LCNs in glaucoma treatment and suggested the potential application of a novel platform in ocular delivery.

Engineered triamcinolone acetonide loaded glycerosomes as a novel ear delivery system for the treatment of otitis media.

Ear-oriented therapeutics vehiculation strategies are requisites for effective treatment of various otic ailments including otitis media (OM). Conquering minimal permeability of the intrinsic barrier of middle ear; intact tympanic membrane (TM) is still a defiance. In this study, the fabrication of glycerosomes was explored to boost triamcinolone acetonide (TA) delivery to the middle ear via the otic application to improve treatment of OM. Opting a d-optimal design, TA glycerosomes were formulated and optimized using ethanol injection method. The optimized formula was assessed for morphology, viscosity, ex vivo TM permeation and deposition and physical stability. Moreover, OM induction in rats using lipopolysaccharides was conducted, histological and biochemical investigations were performed to assess the therapeutic potential of TA glycerosomes and their tolerability as well. The optimized formula displayed a nanosized value (106.1 ± 2.82), low polydispersity index (0.079 ± 0.04), satisfactory drug entrapment efficiency (80.62 ± 4.41 %), shear thinning behavior and excellent physical stability. Ex-vivo TM permeation and deposition monitoring for 24 h demonstrated greater flux and deposition compared to free drug. More importantly, the in vivo studies demonstrated the supremacy of glycerosomes with respect to tolerability and efficacy in alleviating OM following ototopical application compared to marketed drug. Such therapeutic modality represents a promising option to boost the efficacy of otic drugs, awaiting clinical translation.

Delineating penetration enhancer-enriched liquid crystalline nanostructures as novel platforms for improved ophthalmic delivery.

Liquid crystalline nanostructures (LCNs), for instance cubosomes, have been widely used as a promising carrier for drug delivery through the last few years. To date, the ophthalmic application of these platforms was not well explored, and the effect of integrating penetration enhancers (PEs) into LCNs has not been investigated yet. Hence, the present work aimed coupling novel PEs into glyceryl monooleate-based cubosomes for ocular administration. Various enhancers viz, free fatty acids (oleic and linoleic acids), natural terpenes (D-limonene and cineole), medium-chain triglycerides (Captex® 1000 and Captex® 8000), mono-/di-glycerides (Capmul® MCM, Capmul® PG-8, and Capmul® PG-12) were tested at different amounts. The morphology of the formed LCNs was investigated using transmission electron microscopy (TEM). The crystallinity and thermal behavior studies were also conducted. The ocular safety of optimized formulae was tested via hen's egg test-chorioallantoic membrane (HET-CAM), rabbit eye Draize test, and histopathological examinations of ocular tissues. Confocal laser scanning microscopy (CLSM) was utilized to assess the enhanced permeation of fluorescently-labeled LCNs across corneal layers. The acceptable formulations exhibited relatively homogenous particle nano-sizes ranging from 139.26 ± 3.68 to 590.56 ± 24.86 nm carrying negative surface charges. TEM images, X-ray patterns and DSC thermograms demonstrated the influential effect of PEs in developing altered crystalline structures. The ocular compatibility of optimized LCNs was confirmed. The corneal distribution using CLSM proved the disseminated fluorescence intensity of LCNs enriched with oleic acid, Captex® 8000 and Capmul® MCM. Selected LCNs showed good physical stability upon storage and lyophilization. The results demonstrated the efficiency of tailored PE-modified LCNs in enhancing the ocular transport with no evidence of any irritation potential, and hence suggested their prospective applicability in ophthalmic drug delivery.