Nanoemulsions Containing a Coumarin-Rich Extract from Pterocaulon balansae (Asteraceae) for the Treatment of Ocular Acanthamoeba Keratitis.

This study describes the incorporation of a coumarin-rich extract from Pterocaulon balansae into nanoemulsions intended for the local treatment of ocular keratitis caused by Acanthamoeba. The n-hexane dewaxed extract of P. balansae was characterized by HPLC/PDA and UPLC/MS. The presence of four major coumarins was detected, where 5-methoxy-6,7-methylenedioxycoumarin was selected as a chemical marker. This extract was then incorporated into nanoemulsions composed of medium chain triglycerides and egg-lecithin, through spontaneous emulsification. Such a procedure yielded the formation of monodisperse nanoemulsions in a sub-300-nm range, regardless of the amount of extract incorporated (1.0-5.0 mg/mL). The amoebicidal activity against Acanthamoeba castellanii was both dose-dependent and incubation time-dependent. A reduction of 95% of trophozoite viability was detected after 24 h of incubation with a nanoemulsion at 1.25 mg/mL of coumarins, being a similar effect detected for chlorhexidine. These results suggest a potential of the formulations developed in this study as a new strategy for the treatment of ocular keratitis caused by Acanthamoeba.

Antioxidant Effect of Nanoemulsions Containing Extract of Achyrocline satureioides (Lam) D.C.-Asteraceae.

Ethanolic extracts of Achyrocline satureioides have pronounced antioxidant activity mainly due to the presence of the flavonoid quercetin. However, direct topical application of the extract is not possible due to the presence of high amounts of ethanol. In this sense, nanoemulsions arise as an alternative for topical formulation associating molecules with limited aqueous solubility. This article describes the development of topical nanoemulsions containing either A. satureioides extract or one of its most abundant flavonoid, quercetin. Nanoemulsions composed of octyldodecanol, egg lecithin, water and extract (NEE), or quercetin (NEQ) were prepared by spontaneous emulsification. This process led to monodisperse nanoemulsions presenting a mean droplet size of approximately 200-300 nm, negative zeta potential, and high association efficiency. A study of quercetin skin retention using porcine skin which was performed using a Franz diffusion cell revealed a higher accumulation of quercetin in skin for NEE when compared to NEQ. Finally, the antioxidant activity of formulations was measured by thiobarbituric acid-reactive species and the APPH model. A lower lipoperoxidation for the extract in respect to quercetin solution was observed. However, no difference between NEQ and NEE lipoperoxidation could be seen. The protection against lipoperoxidation by the formulations was also measured in the skin, where lower formation of reactive species was observed after treatment with NEE. In conclusion, this study shows the formulation effect on the physicochemical properties of nanoemulsions as well as on the skin retention and antioxidant activity of quercetin.

Cationic nanoemulsions as nucleic acids delivery systems.

Since the first clinical studies, knowledge in the field of gene therapy has advanced significantly, and these advances led to the development and subsequent approval of the first gene medicines. Although viral vectors-based products offer efficient gene expression, problems related to their safety and immune response have limited their clinical use. Thus, design and optimization of nonviral vectors is presented as a promising strategy in this scenario. Nonviral systems are nanotechnology-based products composed of polymers or lipids, which are usually biodegradable and biocompatible. Cationic liposomes are the most studied nonviral carriers and knowledge about these systems has greatly evolved, especially in understanding the role of phospholipids and cationic lipids. However, the search for efficient delivery systems aiming at gene therapy remains a challenge. In this context, cationic nanoemulsions have proved to be an interesting approach, as their ability to protect and efficiently deliver nucleic acids for diverse therapeutic applications has been demonstrated. This review focused on cationic nanoemulsions designed for gene therapy, providing an overview on their composition, physicochemical properties, and their efficacy on biological response in vitro and in vivo.

Hybrid nanoparticle design based on cationized gelatin and the polyanions dextran sulfate and chondroitin sulfate for ocular gene therapy.

We describe the development of hybrid nanoparticles composed of cationized gelatin and the polyanions CS and DS for gene therapy in the ocular surface. The physicochemical properties of the nanoparticles that impact their bioperformance, such as average size and zeta potential, can be conveniently modulated by changing the ratio of polymers and the crosslinker. These systems associate plasmid DNA and are able to protect it from DNase I degradation. We corroborate that the introduction of CS or DS in the formulation decreases the in vitro toxicity of the nanoparticles to human corneal cells without compromising the transfection efficiency. These nanoparticles are potential candidates for the development of safer and more effective nanomedicines for ocular therapy.

Chemically modified gelatin as biomaterial in the design of new nanomedicines.

The synthesis of new polymers has led to dramatic enhancements in the medical field. In particular, new chemical entities provided new prospects in tissue engineering, cellular therapy and drug delivery. However, significant efforts still need to be taken in consideration in order to achieve diverse clinical applications in these fields, which is challenging because of the lack of suitable materials with desired microstructure, permeability, degradation rates, products, and suitable mechanical properties. For these reasons some chemical strategies are focused in back to the nature approaches or, in other words, in improving the properties of natural polymers by chemical modifications. We report that by using a simple chemical modification technique we can obtain new biomaterials, specifically suitable for biomedical applications. Concretely, we describe the chemical modification of gelatin and the suitable characteristics of the modified protein to develop new nanomedicines. This protein was selected because of its enormous potential in biomedicine, which is currently limited due to the difficulty of its use without toxic chemical crosslinkers. The modification of the protein was based on the transformation of the carboxylic group into amido groups after their reaction with polyamines, leading to a positively charged biopolymer. To cationize the gelatin two polyamines where used: ethylenediamine and spermine, the latter being one of the endogenous polyamines which has a very positive influence over cells. This modification was monitored by physico-chemical techniques such as NMR, spectrophotometry and potentiometry. With the most promising modified gelatins we were able to develop nanoparticles using the ionotropic gelation technique. In order to determine the ability of these new nanosystems to associate bioactive molecules we selected a model plasmid DNA. The developed nanosystems were characterized corroborating their ability to associate the genetic material. In conclusion, we were able to obtain a semi-synthetic biomaterial with tunable physico-chemical properties, which can be used to develop new nanosystems with the ability to associate genetic material. We therefore propose that the gelatin, with its chemical modification, provide a unique biomaterial for the development of new nanomedicines.

On the use of nanotechnology-based strategies for association of complex matrices from plant extracts

AbstractDepending on the method of extraction, plant extracts can contain an enormous variety of active molecules, such as phenolic compounds, essential oils, alkaloids, among others. In many cases, from a pharmacological point of view, it is interesting to work with crude extract or fractions instead of a single isolated compound. This could be due to multi-targeting effect of the extract, lack of knowledge of the active compounds, synergistic effect of the extract compounds, among others. In any case, in order to achieve a final product some issues must be overcome, including poor stability, solvent toxicity, and low solubility of the bioactive compound. Recently many nanotechnology-based strategies have been proposed as an alternative to solve these problems, especially liposomes, nanoemulsions and nanoparticles. In this sense, the present work aims to review the main nanotechnological approaches used for association of different plant extracts and the main achievements from using these technologies.