So far, various approaches have been proposed to improve dermal drug delivery. The use of chemical penetration enhancers has a long history of application, while methods based on the electrical current (such as iontophoresis) stand out as promising \"active\" techniques. Aiming to evaluate the contribution of different approaches to dermal delivery, in this work curcumin-loaded nanoemulsions with and without monoterpenes (eucalyptol or pinene) as chemical penetration enhancers, and a custom-made adhesive dermal delivery system based on iontophoresis were designed and assessed. In an in vivo study applying skin bioengineering techniques, their safety profile was proven. Three examined iontophoresis protocols, with total skin exposure time of 15 min (continuous flow for 15 min (15-0); 3 min of continuous flow and 2 min pause (3-2; 5 cycles) and 5 min of continuous flow and 1 min pause (5-1; 3 cycles) were equally efficient in terms of the total amount of curcumin that penetrated through the superficial skin layers (in vivo tape stripping) (Q3-2 = 7.04 ± 3.21 μg/cm2; Q5-1 = 6.66 ± 2.11 μg/cm2; Q15-0 = 6.96 ± 3.21 μg/cm2), significantly more efficient compared to the referent nanoemulsion and monoterpene-containing nanoemulsions. Further improvement of an efficient mobile adhesive system for iontophoresis would be a practical contribution in the field of dermal drug application.

OBJECTIVE: Despite extensive preclinical investigations, in-vivo properties and formulation characteristics that improve CNS drug delivery following systemic dosing of nanoemulsions remain incompletely understood.
METHODS: The CNS targeting potential of systemically administered nanoemulsions was evaluated by formulating rapamycin containing fish oil nanoemulsions, and testing the combined effect of formulation characteristics such as the circulation half-life and particle size distribution, on CNS delivery of rapamycin containing fish oil nanoemulsions in mice.
RESULTS: Results generated with rapamycin nanoemulsions suggested that circulation half-life and particle size distribution did not impact the brain targeting efficiency of rapamycin containing fish oil nanoemulsions. Further, in the absence of any improvement in the systemic exposures of rapamycin, nanoemulsions did not outperform their aqueous counterpart with respect to the extent of CNS drug delivery.
CONCLUSIONS: Our findings confirm that BBB penetration, which primarily depends on intrinsic drug-related properties, may not be significantly improved following encapsulation of drugs in nanoemulsions. Graphical Abstract The CNS targeting potential of systemically administered nanoemulsions was investigated by formulating various rapamycin containing fish oil nanoemulsions associated with different formulation characteristics such as the circulation half-life and particle size distribution. The targeting efficiency (TE) defined as the ratio of the brain exposures to the accompanying systemic exposures of rapamycin was estimated for each formulation following IV dosing in mice.

Cancer is the second cause of death worldwide, exceeded only by cardiovascular diseases. The prevalent treatment currently used against metastatic cancer is chemotherapy. Among the most studied drugs that inhibit neoplastic cells from acquiring unlimited replicative ability (a hallmark of cancer) are the taxanes. They operate via a unique molecular mechanism affecting mitosis. In this review, we show this mechanism for one of them, paclitaxel, and for other (non-taxanes) anti-mitotic drugs. However, the use of paclitaxel is seriously limited (its bioavailability is <10%) due to several long-standing challenges: its poor water solubility (0.3 μg/mL), its being a substrate for the efflux multidrug transporter P-gp, and, in the case of oral delivery, its first-pass metabolism by certain enzymes. Adequate delivery methods are therefore required to enhance the anti-tumor activity of paclitaxel. Thus, we have also reviewed drug delivery strategies in light of the various physical, chemical, and enzymatic obstacles facing the (especially oral) delivery of drugs in general and paclitaxel in particular. Among the powerful and versatile platforms that have been developed and achieved unprecedented opportunities as drug carriers, microemulsions might have great potential for this aim. This is due to properties such as thermodynamic stability (leading to long shelf-life), increased drug solubilization, and ease of preparation and administration. In this review, we define microemulsions and nanoemulsions, analyze their pertinent properties, and review the results of several drug delivery carriers based on these systems.