A Comprehensive Review of Essential Oil–Nanotechnology Synergy for Advanced Dermocosmetic Delivery

This review investigates the convergence of nanotechnology and essential oils in advanced dermocosmetic delivery. It outlines the pivotal role of inorganic and polymeric nanoparticles, such as titanium dioxide, zinc oxide, and gold nanocarriers, in cosmeceutical applications, facilitating slow release, deeper skin penetration, and increased retention of active compounds. Essential oils, renowned for therapeutic benefits, face translation challenges due to volatility and low water solubility. This review explores the potential use of plant nanovesicles as carriers, emphasizing safety, stability, and scalability, offering a sustainable and cost-effective industrial application. Nanomaterial integration in consumer products, particularly cosmetics, is prevalent, with nanocarriers enhancing the permeation of bioactive compounds into deeper skin layers. The review emphasizes recent nanotechnological advancements, covering nanoparticle penetration, experimental models, and therapeutic applications in dermatology, ranging from non-invasive vaccination to transdermal drug delivery. Additionally, the review delves into nanomaterials’ role in addressing skin aging, focusing on tissue regeneration. Nanomaterials loaded with cosmeceuticals, such as phytochemicals and vitamins, are explored as promising solutions to mitigate signs of aging, including wrinkles and dry skin, providing innovative approaches to skin rejuvenation. Overall, the review offers a comprehensive synthesis of essential oil–nanoparticle synergy, shedding light on the current landscape and future potential of advanced dermocosmetic delivery systems

Purification, chemical characterization and evaluation of the antioxidant potential of carvacrol from <i>Thymus vulgaris</i>

This work focuses on the purification, chemical characterization and evaluation of the antioxidant activity of carvacrol in order to determine its contribution in the high antioxidant potential of Thymus vulgaris essential oil (TEO). Firstly, 68% of carvacrol was purified from TEO using chromatography on silica gel column and then chemically characterized using spectroscopic techniques (IR, MS and 1H and 13C NMR). In vitro, the antioxidant activity has been determined using DPPH, ABTS•+ and iron chelating assays. All assays proved the strong radical scavenging and reducing power of carvacrol. In vivo, antioxidant capacity towards stressed Saccharomyces cerevisiae cells was investigated by evaluating cell viability, antioxidant enzymes’ activity, the level of lipid peroxidation (LPO) as well as the activity of succinate dehydrogenase (SDH). Using carvacrol in a dose dependent manner (6.25-25 μg/mL), cell viability was outstandingly improved by 34.5-55% compared to stressed cells. Antioxidant enzymes (CAT, SOD, GR) activities were also brought back to values comparable to control cells along with lower LPO (0.81±0.07 nmol/mg) and SDH (1.15± 0.07 μmol/min/mg of protein) at 25 μg/mL. These findings suggest that the powerful antioxidant properties of TEO found in our previous study were mainly associated to its main component (carvacrol) that showed higher antioxidant activity compared to the other components. Therefore, carvacrol can be of a great use as a pharmacological agent against damages related to oxidative stress.</p