Development and In Vitro Evaluation of Vitamin E-Enriched Nanoemulsion Vehicles Loaded with Genistein for Chemoprevention Against UVB-Induced Skin Damage.

There is a great need for effective protection against cutaneous pathologies arising from chronic exposure to harmful solar UVB radiations. A promising pharmaceutical strategy to improve the efficacy of chemotherapeutic/preventative natural compounds (e.g., soy isoflavone Genistein, Gen) is to enhance their dermal delivery using nanoemulsion (NE) formulations. This report investigates the development of nanoemulsified tocotrienol(T3)-rich fraction of red palm oil (Tocomin®), to yield an optimal NE delivery system for dermal photoprotection (z-average size <150 nm, ζ-potential ≈ -30 mV, polydispersity index < 0.25). Physicochemical characterization and photostability studies indicate NE formulations utilizing surfactant mixture (Smix) of Solutol® HS-15 (SHS15) blended with vitamin E TPGS (TPGS) as cosurfactant was significantly superior to formulations that utilized Lutrol® F68 (LF68) as the cosurfactant. A ratio of 60:40 of SHS15-TPGS-NE was further identified as lead Tocomin® NE topical platform using in vitro pharmaceutical skin reactivity studies that assess cutaneous irritancy and cytotoxicity. Prototype Tocomin® NE loaded with the antiphotocarcinogenic molecule Gen (Gen-Tocomin® NE) showed slow-release profile in both liquid and cream forms. Gen-Tocomin® NE also showed excellent biocompatibility, and provided substantial UVB protection to cultured subcutaneous L929 fibroblasts, indicating the great potential of our Tocomin® NE warranting further prototype development as topical pharmaceutical platform for skin photoprotection applications.

Layered nanoemulsions as mucoadhesive buccal systems for controlled delivery of oral cancer therapeutics.

Oral cavity and oropharyngeal cancers are considered the eighth most common cancer worldwide, with relatively poor prognosis (62% of patients surviving 5 years, after diagnosis). The aim of this study was to develop a proof-of-concept mucoadhesive lozenge/buccal tablet, as a potential platform for direct sustained delivery of therapeutic antimitotic nanomedicines. Our system would serve as an adjuvant therapy for oral cancer patients undergoing full-scale diagnostic and operative treatment plans. We utilized lipid-based nanocarriers, namely nanoemulsions (NEs), containing mixed-polyethoxylated emulsifiers and a tocopheryl moiety-enriched oil phase. Prototype NEs, loaded with the proapoptotic lipophilic drug genistein (Gen), were further processed into buccal tablet formulations. The chitosan polyelectrolyte solution overcoat rendered NE droplets cationic, by acting as a mucoadhesive interfacial NE layer. With approximate size of 110 nm, the positively charged chitosan-layered NE (+25 mV) vs negatively charged chitosan-free/primary aqueous NE (-28 mV) exhibited a controlled-release profile and effective mucoadhesion for liquid oral spray prototypes. When punch-pressed, porous NE-based buccal tablets were physically evaluated for hardness, friability, and swelling in addition to ex vivo tissue mucoadhesion force and retention time measurements. Chitosan-containing NE tablets were found equivalent to primary NE and placebo tablets in compression tests, yet significantly superior in all ex vivo adhesion and in vitro release assays (P≤0.05). Following biocompatibility screening of prototype chitosan-layered NEs, substantial anticancer activity of selected cationic Gen-loaded NE formulations, against two oropahryngeal carcinomas, was observed. The data strongly indicate the potential of such nanomucoadhesive systems as maintenance therapy for oral cancer patients awaiting surgical removal, or postresection of identified cancerous lesions.

Enhanced cytotoxicity of optimized liposomal genistein via specific induction of apoptosis in breast, ovarian and prostate carcinomas.

Clinical use of genistein against cancer is limited by its extremely low aqueous solubility, poor bioavailability and pharmacokinetics. Based on structural analogy with steroidal compounds, liposomal vehicle compositions were designed and optimized for maximum incorporation of genistein's flavonoid structure. Model conventional and stealth liposomes of genistein (GenLip)--incorporating unsaturated phospholipids and cholesterol--have demonstrated enhanced drug solubilization (over 350-folds > aqueous drug solution), shelf-life stability, and extended release profile. Owing to effective cellular delivery, preservation of genistein's antioxidant activity was confirmed through marked neutralization of peroxides via GenLip, in both quantitative and microscopic fluorescent-probe oxidation assays. Furthermore, significant broad-spectrum anticancer efficacy of GenLip, in murine and human cancer cell lines (p < 0.05-0.001), was achieved in a concentration and time-dependent manner--approx. 5-7 lower IC50 values versus all non-incorporated drug controls. Indicative of key pro-apoptotic activity, GenLip produced DNA laddering, with 1/3 of free drug solution content, and resulted in the highest induction level of P53-independent apoptotic pathway markers, compared to all treatments, in our assays (namely, mitochondrial polarization, and caspase-3/7 enzymes). Our proof-of-principle pharmaceutical design of genistein-loaded liposomes shows optimal loading capacity and physico-chemical properties, which improved cellular delivery and specific pro-apototic effectiveness of incorporated drug, against various cancers.

Mitochondria-specific pro-apoptotic activity of genistein lipidic nanocarriers.

Genistein (Gen) soy isoflavone produces extensive pro-apoptotic anticancer effects, mediated predominantly via induction of mitochondrial damages. Rationalization of the native mitochondrial selectivity of Gen, utilizing biophysical model assumptions, led to our design of cationic lipid-based nanocarriers (NC) of Gen. Prototype nanoformulations, lipidic micelles (Mic) and nanoemulsions (NEs) incorporated Gen to serve as both therapeutic and targeting moieties, specific for mitochondria. Both Gen-NCs, showing superior physicochemical properties, produced significant cytotoxicity (5-10-fold lower EC50), compared to all drug controls, in hepatic and colon carcinomas. Owing to the mitochondria-specific accumulation of Gen-NCs, their mitochondrial depolarization effect was most evident, leading to marked activation of intrinsic apoptotic pathway markers--cytosolic cytochrme c and specific caspase-9--thus, confirming the direct mitochondrial action of Gen-NCs. This mechanistic evidence of the mitochondria specificity of our Gen-NE and Gen-Mic strongly indicates their potential as targeted delivery nanosystems to augment anticancer efficacy of many lipophilic chemotherapeutics.

Development and evaluation of tocopherol-rich argan oil-based nanoemulsions as vehicles possessing anticancer activity.

In recent years, diverse nanoemulsion vehicles (NEs) have been developed with vast potential for improving therapeutic index of clinically approved and experimental drugs. Using oils rich in omega-3 and omega-6 polyunsaturated fatty acids (PUFA), several promising nanoemulsion formulations have been developed recently for oral and systemic administration. The aim of our present work is to successfully develop and characterize optimized nanoemulsion platform, using the PUFA-rich argan oil that contain several important anti-inflammatory and antimitotic natural components. Using various emulsifying mixtures of polyethoxylated solutol HS-15 and polyethyleneglucol Vitamin E succinyl ester (TPGS), to form different NEs showing extended shelf-life stability. The physicochemical properties of prototype argan NEs were analyzed and utilizing a 32 full factorial design, followed by biocompatibility screen, using normal vascular myocytes and areolar fibroblasts. While 90-180 day stability of NEs correlated with TPGS:solutol surfactant blend ratios, adverse effects on integrity of test cultures were only noted at high TPGS content in the emulsifier system, exceeding 80%. Finally, the anti-proliferative efficacy of selected stable and acceptably biocompatible nanoscale TPGS-emulsified argan oil formulations was investigated using murine breast and colon carcinoma cells. The IC50 values of the combination of argan oil and TPGS (40-80% wt of emulsifiers) were 5-9 folds lower compared to TPGS-free and argan-oil free control NEs. Argan oil NE, stabilized with Vitamin E TPGS and solutol HS mixtures, demonstrated significant pro-apoptotic effect on both test cancer cell lines, indicating built-in anticancer properties for such NE platform, potentially enhancing overall antineoplastic effects of incorporated candidate chemotherapeutic agents.