Development of ophthalmic nanoemulsions of ß-caryophyllene for the treatment of Acanthamoeba keratitis.

Although rare, amoebic keratitis (AK) is a disease caused by Acanthamoeba spp. that can lead to blindness. The drugs currently available for its treatment are very toxic, which has motivated the investigation for more effective and safe therapeutic options. In this study, the in vitro activity of ß-caryophyllene (BCP) was exploited taking into account its action against other protozoans as well as its well-known healing and anti-inflammatory properties (aspects relevant for the AK pathogenesis). On the other hand, high volatilization and oxidation phenomena are found for this compound, which led to its incorporation into nanoemulsions (NEs). Two emulsifying agents were tested, resulting in monodisperse systems with reduced droplet size (<265 nm) and high surface charge (positive and negative for NEs prepared with cetrimonium bromide -CTAB and Phosal® 50+, respectively). NEs prepared with CTAB were shown to be more stable after long-term storage at 4 and 25 °C than those prepared with Phosal®. Pure BCP, at the highest concentration (500 µM), resulted in a level of inhibition of Acanthamoeba trophozoites equivalent to that of reference drug (chlorhexidine). This activity was even greater after oil nanoencapsulation. The reduced droplet size could improve the interaction of the oil with the microorganism, justifying this finding. Changes in surface charge did not impact the activity. Positively charged NEs improved the interaction and retention of BCP in the cornea and thus should be prioritized for further studies.

Effect of Vehicle Composition on the Preparation of Different Types of Dapsone Crystals for Topical Drug Delivery.

Topical formulations composed of API-pure crystals have been increasingly studied, especially in regards to the impact of particle size in penetration efficiency. Less attention, however, has been devoted to the solid-state properties of drugs delivered to the skin. In this study, we address the effect of formulation composition on the crystal form existing in topical products. Dapsone (DAP) gel formulations were prepared by mixing an organic solution containing DAP with an aqueous solution containing polymers and preservatives. The organic solvent was chosen as ethoxydiglycol (DEGEE), polyethylene glycol (PEG), or 1-methyl-2-pirrolidone (MPR) to assess the impact of composition on DAP crystal form. Such solvent variations resulted in different particulate matter. In terms of crystalline nature, the presence of DEGEE in formulations induced the crystallization of DAP hydrate, while PEG cocrystal and a mixture of hydrate and MPR solvate crystallized from the same amounts of PEG and MPR, respectively. Microscopic analysis of the gels showed heterogeneous particles with different characteristics. The behavior of gels after application to the skin was also tested. Interestingly, the different formulations seemed to accumulate in different regions of the skin. This could be the result of the effect of vehicle composition/excipients on the characteristics of the skin, such as hydration. The site-specific accumulation, however, was more pronounced in crystal-loaded gels as opposed to blank formulations. These results indicate that future studies should consider the effect of formulation composition on the API crystal form landscape as part of the strategies used to successfully target drug delivery to the skin.

How to define the experimental conditions of skin permeation assays for drugs presenting biopharmaceutical limitations? The experience with testosterone.

Cutaneous permeation assays are crucial to attest the performance or bioequivalence of topical or transdermal products. Although the official guidelines (e.g., FDA/EMA) play a key role in harmonizing the experimental design, alternative methods are often proposed by the scientific community, which makes it difficult to compare results from different studies. In this review, permeation assays with testosterone (TST) were selected to show this high variability in drug transport rate. The main sources of variation discussed were tissue thickness, animal model, donor and receptor fluid constitution, type of solubilizing agent used in aqueous fluids, drug concentration, degree of supersaturation, skin lipid content, number of experimental times and the physical-chemical stability of the molecule in test fluids. This variation becomes even more critical for molecules that present biopharmaceutical limitations such as TST. In addition, the skin presents specific receptors for this hormone due to its physiological action in this region of the body, which makes the evaluation of the TST transport rate in this tissue even more challenging. The impact of each experimental parameter mentioned above on the flux or permeation coefficient of TST is discussed in detail in the review. Assays used to evaluate tissue integrity are also presented.

Transbuccal delivery of metal complexes of isoniazid as an alternative to overcome antimicrobial resistance problems.

In isolated isoniazid (INH)-resistant strains, deletion or mutations in thekatGgene have been identified, which result in loss of catalase-peroxidase activity. This enzyme plays a key role in the activation of this prodrug. As an alternative, the coordination of the INH to metal complexes has been purposed to activate it regardless of enzyme functionality. Although pentacyanido(isoniazid)ferrate(II) complexes have shown to be effective against resistant strains of Mycobacterium tuberculosis, low oral bioavailability was found. In this context, buccal mucosa was selected as an alternative route to the metal complex delivery. Moreover, oral manifestations of tuberculosis(TB) have been observed in some patients, particularly when resistant strains are present, and no therapeutic options are currently available on the market. Pentacyanidoferrate (PCF-INH) and Prussian-blue (PB-INH) complexes were initially prepared and characterized, followed by buccal permeability studies in Franz-type diffusion cells. The electrochemical potential of the complexes demonstrated their ability to self-activate. Job's method suggested the presence of structural defects in PB-INH complexes, which was correlated with permeability results. In fact, PB-INH showed a higher dissociation rate in salt-rich aqueous medium and thus a high transport rate of INH through the buccal mucosa. Its passage through the tissue would not be possible due to the high molecular size. PCF-INH, in turn, presented a lower dissociation rate in the salt-rich aqueous medium, justifying its slower transport rate through the tissue. Taken together, these results suggest that INH-based metal complexes may be efficiently administered through the buccal route, impacting on both oral bioavailability and microbial resistance.