Liposomes, lipid nanocapsules and smartCrystals®: A comparative study for an effective quercetin delivery to the skin.

Quercetin is a flavonoid with strong antioxidant and antiinflammatory activities considered as a potential drug candidate for skin exogenous supplementation. Nevertheless, crude quercetin suffers from poor water solubility and consequently topical inactivity. Therefore, quercetin formulation within a suitable system that overcomes its solubility limitation is a matter of investigation. Three approaches were tested to improve quercetin delivery to skin: liposomes, lipid nanocapsules (LNC) and smartCrystals®. These nanoformulations were compared in terms of average particle size, homogeneity (PDI), quercetin loading and cellular interactions with HaCaT (keratinocytes) and TPH-1 (monocytes) cell lines. Finally, two formulations were selected for testing quercetin delivery to human skin in vivo using stripping test. Different size distribution was obtained with each strategy starting from 26 nm with quercetin LNC, 179 nm with liposomes to 295 nm with quercetin smartCrystals®. The drug loading varied with each formulation from 0.56 mg/ml with liposomes, 10.8 mg/ml with LNC to 14.4 mg/ml with smartCrystals®. No toxicity was observed in HaCaT cells with quercetin and free radical scavenging ability was established at 5 µg/ml. The safety of quercetin at 5 µg/ml was further confirmed on THP-1 cells with efficient free radical scavenging ability. Finally, skin penetration evidenced different behavior between the two selected forms (LNC and SmartCrystals®), which could lead to different promising strategies for skin protection. On one side, quercetin smartCrystals® seems to enable the superficial deposition of quercetin on top of the skin, which presents a good strategy for a quercetin-based sunscreen product. On the other side, LNC seems to allow quercetin delivery to viable epidermis that holds the promise for skin inflammatory disorders such as psoriasis.

Molybdenum cluster loaded PLGA nanoparticles: An innovative theranostic approach for the treatment of ovarian cancer.

We evaluate poly (d,l-lactide-co-glycolide) (PLGA) nanoparticles embedding inorganic molybdenum octahedral cluster for photodynamic therapy of cancer (PDT). Tetrabutyl ammonium salt of Mo6Br14 cluster unit, (TBA)2Mo6Br14, presents promising photosensitization activity in the destruction of targeted cancer cells. Stable cluster loaded nanoparticles (CNPs) were prepared by solvent displacement method showing spherical shapes, zeta potential values around -30 mV, polydispersity index lower than 0.2 and sizes around 100 nm. FT-IR and DSC analysis revealed the lack of strong chemical interaction between the cluster and the polymer within the nanoparticles. In vitro release study showed that (TBA)2Mo6Br14 was totally dissolved in 20 min, while CNPs were able to control the release of encapsulated cluster. In vitro cellular viability studies conducted on A2780 ovarian cancer cell line treated up to 72 h with cluster or CNPs did not show any sign of toxicity in concentrations up to 20 µg/ml. This concentration was selected for photo-activation test on A2780 cells and CNPs were able to generate oxygen singlet resulting in a decrease of the cellular viability up to 50%, respectively compared to non-activated conditions. This work presents (TBA)2Mo6Br14 as a novel photosensitizer for PDT and suggests PLGA nanoparticles as an efficient delivery system intended for tumor targeting.

Dermal quercetin lipid nanocapsules: Influence of the formulation on antioxidant activity and cellular protection against hydrogen peroxide.

Quercetin is a plant flavonoid with strong antioxidant and antiinflammatory properties interesting for skin protection. However, its poor water solubility limits its penetration and so its efficiency on skin. For this purpose, quercetin lipid nanocapsules were formulated implementing phase inversion technique wherein several modifications were introduced to enhance quercetin loading. Quercetin lipid nanocapsules were formulated with two particle size range, (50nm and 20nm) allowing a drug loading of 18.6 and 32mM respectively. The successful encapsulation of quercetin within lipid nanocapsules increased its apparent water solubility by more than 5000 fold (from 0.5µg/ml to about 5mg/ml). The physicochemical properties of these formulations such as surface charge, stability and morphology were characterized. Lipid nanocapsules had spherical shape and were stable for 28days at 25°C. Quercetin release from lipid nanocapsules was studied and revealed a prolonged release kinetics during 24h. Using DPPH assay, we demonstrated that the formulation process of lipid nanocapsules did not modify the antioxidant activity of quercetin in vitro (92.3%). With the goal of a future dermal application, quercetin lipid nanocapsules were applied to THP-1 monocytes and proved the cellular safety of the formulation up to 2µg/ml of quercetin. Finally, formulated quercetin was as efficient as the crude form in the protection of THP-1 cells from oxidative stress by exogenous hydrogen peroxide. With its lipophilic nature and occlusive effect on skin, lipid nanocapsules present a promising strategy to deliver quercetin to skin tissue and can be of value for other poorly water soluble drug candidates.

Quercetin topical application, from conventional dosage forms to nanodosage forms.

Skin is a multifunctional organ with activities in protection, metabolism and regulation. Skin is in a continuous exposure to oxidizing agents and inflammogens from the sun and from the contact with the environment. These agents may overload the skin auto-defense capacity. To strengthen skin defense mechanisms against oxidation and inflammation, supplementation of exogenous antioxidants is a promising strategy. Quercetin is a flavonoid with very pronounced effective antioxidant and antiinflammatory activities, and thus a candidate of first choice for such skin supplementation. Quercetin showed interesting actions in cellular and animal based models, ranging from protecting cells from UV irradiation to support skin regeneration in wound healing. However, due to its poor solubility, quercetin has limited skin penetration ability, and various formulation approaches were taken to increase its dermal penetration. In this article, the quercetin antioxidant and antiinflammatory activities in wound healing and supporting skin against aging are discussed in detail. In addition, quercetin topical formulations from conventional emulsions to novel nanoformulations in terms of skin penetration enhancement are also presented. This article gives a comprehensive review of quercetin for topical application from biological effects to pharmaceutical formulation design for the last 25 years of research.

Dermal quercetin smartCrystals®: Formulation development, antioxidant activity and cellular safety.

Flavonoids are natural plant pigments, which possess high antioxidative and antiradical activities. However, their poor water solubility led to a limited bioavailability. To overcome this major hurdle, quercetin nanocrystals were produced implementing smartCrystals® technology. This process combines bead milling and subsequent high-pressure homogenization at relatively low pressure (300bar). To test the possibility to develop a dermal formulation from quercetin smartCrystals®, quercetin nanosuspensions were admixed to Lutrol® F127 and hydroxythylcellulose nonionic gels. The physicochemical properties (morphology, size and charge), saturation solubility, dissolution velocity and the antioxidant properties (DPPH assay) as well as the cellular interaction of the produced quercetin smartCrystals® were studied and compared to crude quercetin powder. Quercetin smartCrystals® showed a strong increase in the saturation solubility and the dissolution velocity (7.6 fold). SmartCrystals® loaded or not into gels proved to be physically stable over a period of three months at 25°C. Interestingly, in vitro DPPH assay confirmed the preservation of quercetin antioxidative properties after nanonization. In parallel, the nanocrystalline form did not display cellular toxicity, even at high concentration (50µg/ml), as assayed on an epithelial cell line (VERO cells). In addition, the nanocrystalline form confirmed a protective activity for VERO cells against hydrogen peroxide induced toxicity in vitro. This new formulation presents a promising approach to deliver quercetin efficiently to skin in well-tolerated formulations.