Biphasic dissolution combined with modified cylinder method-A new promising method for dissolution test in drug-loaded nanoemulsions.

Dissolution testing is important in assessing the in vitro drug release performance for oral administration dosage forms. However, currently, a simple and efficient in vitro test to investigate critical factors that may impact the drug release and bioavailability at the development stage of a drug-loaded nanoemulsion (NE) is lacking. Thus, in this study, we developed a new combined biphasic and modified cylinder (BP + MC) method to evaluate the dissolution profile of NEs. Flubendazole (FLZ), a Biopharmaceutical Classification System (BCS) Class II drug, offers a new prospective for drug repositioning for treating lung cancer and cryptococcal meningitis. We compared the drug release profiles of three different FLZ formulations (micronized as a suspension, loaded in NE, and solubilized in oil) by using three different methods (dialysis bag, modified cylinder method, and a new BP + MC method). The results showed potential higher drug release of FLZ from the suspension compared to FLZ-loaded NE at pH 1.2, and higher drug release from FLZ-loaded NE compared to other forms in octanol phase. These results correlate well with the in vivo test performed in mice carried out in our previous works. Furthermore, the partition mechanism of the drug released from the NE is discussed in-depth in this article, as well as the advantage of drug-loaded NEs over other preparations in creating supersaturable conditions. Based on the results, we provide new insights into how dissolution methods for a poorly water-solubility drug can be designed. Therefore, we present this new combined BP + MC method as a potential new discriminative dissolution test for future studies when developing drug-loaded NE and comparing with other dosage forms.

Cutting-edge advances in therapy for the posterior segment of the eye: Solid lipid nanoparticles and nanostructured lipid carriers.

Posterior segment eye diseases affect more than 300 million patients worldwide resulting in severe visual impairment. The treatments available are invasive, costly, present irregular effectiveness, and cause serious adverse effects. These drawbacks significantly reduce patient compliance. In the last decade, solid lipid nanoparticle (SLN) and nanostructured lipid carrier (NLC) have shown potential as innovative carriers for lipophilic drug substances to overcome hurdles in treating the eye posterior segment. This review shows the advantages of these formulations, focusing on their compatibility with ocular tissues, which increases the internalization of the drug substances. Additionally, SLN and NLC can reduce the clearance by the eye's protective mechanisms due to adhesive properties related to nanometric size. Therefore, these preparations may allow the treating of several ophthalmic diseases by topical administration, increasing the interval between doses. This feature can decrease adverse effects and enhance efficacy, ultimately improving patient compliance. Thus, this critical review presents the performance of the in vitro, ex vivo, and in vivo assays that support the potential of SLN and NLC to treat diseases of the posterior segment of the eye. These nanoparticles have shown to be promising alternative towards a major shift in developing ophthalmic products.

Cancer treatment in the lymphatic system: A prospective targeting employing nanostructured systems.

Cancer related to lymphangiogenesis has gained a great deal of attention in recent decades ever since specific markers of this intriguing system were discovered. Unlike the blood system, the lymphatic system has unique features that can advance cancer in future metastasis, or, conversely, can provide an opportunity to prevent or treat this disease that affects people worldwide. The aim of this review is to show the recent research of cancer treatment associated with the lymphatic system, considered one of the main gateways for disseminating metastatic cells to distant organs. Nanostructured systems based on theranostics and immunotherapies can offer several options for this complex disease. Precision targeting and accumulation of nanomaterials into the tumor sites and their elimination, or targeting the specific immune defense cells to promote optimal regression of cancer cells are highlighted in this paper. Moreover, therapies based on nanostructured systems through lymphatic systems may reduce the side effects and toxicity, avoid first pass hepatic metabolism, and improve patient recovery. We emphasize the general understanding of the association between the immune and lymphatic systems, their interaction with tumor cells, the mechanisms involved and the recent developments in several nanotechnology treatments related to this disease.

Rifampicin nanocrystals: Towards an innovative approach to treat tuberculosis.

Tuberculosis (TB) is one of the top ten causes of death worldwide and a leading cause of death in HIV patients. Rifampicin (Rif), a low water-soluble drug, is a critical first-line treatment and the most effective drug substance for therapy of drug-susceptible TB. However, Rif has high interindividual pharmacokinetic variability, mainly due to its highly variable absorption caused by its poor solubility. Drug nanocrystals are a promising technology to overcome this variability by increasing the surface area. This strategy allows for increasing the dissolution rate and improving the bioavailability of this BCS class II drug. In this study, Rif nanocrystals were prepared by a wet-bead milling method. A 3-factor, 3-level Box-Behnken design was used to investigate the independent variables: the concentration of rifampicin, the concentration of the stabilizing agent (Povacoat® type F), and the mass of zirconia beads. Two optimized formulations, F1-Rif and F2-Rif, were characterized by determining their particle size and size distribution, morphology, crystal properties, and antimicrobial activity. Differential scanning calorimetry (DSC) and powder X-ray diffraction (PXRD) revealed that rifampicin's polymorph II crystal structure was unchanged. The reduced particle size of <500 nm (100-fold decrease) increased the saturation solubility and dissolution rate up to 1.74-fold. The novel polymer, Povacoat®, demonstrated to be a suitable stabilizer to maintain the physical stability of nanosuspensions over two years. The Rif nanocrystals showed antimicrobial activity (0.25 µg/mL) not significantly different from standard rifampicin powder. However, the low cytotoxicity of the nanosuspensions in HepG2 cells was determined. When compared to the commercial product, the nanosuspension increased the rifampicin concentration 2-fold. In conclusion, the Rif nanosuspension allows half the needed volume of administration, which might increase compliance among children and elderly patients throughout the long-term treatment of TB.