Nanocannabinoides como terapia frente a glioma / Nannocannabinoids for brain tumor drug delivery

Las patologías cerebrales representan un desafío terapéutico por la restricción al paso de fármacos a través de la barrera hematoencefálica. Por ello, actualmente se persigue diseñar transportadores de fármacos capaces de atravesar de manera eficiente el endotelio cerebral tras su administración intravenosa. Sin embargo, el impacto traslacional de la nanomedicina es aún discreto. Sin duda, la transición de un desarrollo empírico hacia un diseño racional adecuado a las necesidades terapéuticas concretas en cada caso aumentará las posibilidades de éxito.Bajo esta premisa y aprovechando tanto el tropismo cerebral como la actividad antiproliferativa del cannabidiol, y a fin de contribuir al diseño racional de nanocápsulas dirigidas para el tratamiento de gliomas, hemos evaluado la influencia de distintos parámetros en su comportamiento in vitro e in vivo. Efectivamente, hemos demostrado que tanto el paso a través de barrera hematoencefálica como la captación por células de glioma, así como la velocidad de liberación de fármacos pueden modularse variando su tamaño de partícula. El método térmico de inversión de fases posibilita la obtención de nanocápsulas bajo demanda en términos de tamaño gracias al modelo matemático lineal en una variable aquí descrito.Además, hemos desarrollado una novedosa estrategia de vectorización con cannabidiol (que incluso supera a otras que ya se encuentran en ensayos clínicos). Asimismo, las nanocápsulas sirven como transportadores de liberación prolongada del cannabidiol, superando así sus problemas de formulación que venían limitando su potencial terapéutico.En conjunto, las nanocápsulas lipídicas, cargadas y funcionalizadas con cannabidiol, constituyen prometedores candidatos para el tratamiento de gliomas. (AU)

Brain diseases are a major health challenge as brain drug delivery is truly hindered by the blood-brain barrier. Therefore, targeted drug nanocarriers arise as an alternative to achieve efficient transport across the brain endothelium following minimally-invasive intravenous injection. However, the global translational impact of nanomedicine remains modest. Certainly, the transition from empirical development towards a rational design tailored to the specific disease needs is likely to improve the chances of success.Under this assumption and taking advantage of both the natural brain tropism and the antiproliferative activity of cannabidiol, to contribute to the rational design of targeted nanocapsules for glioma therapy, we have thoroughly screened the influence of distinct parameters on their in vitro and in vivo behaviour. Effectively, we have demonstrated that both the brain and glioma targeting ability and the drug release rate can be tailored by varying the particle size of the nanocapsules. This fine size-tailoring can be achieved by the phase inversion temperature method thanks to the hereindescribed linear univariate mathematical model as a function of the oily phase/surfactant mass ratio.Moreover, we have introduced, on the one hand, a pioneering brain tumor targeting strategy with cannabidiol (with better targeting properties than other strategies that have already reached the clinical trials stage) and, on the other hand, nanocapsules as extendedrelease carriers of cannabidiol to overcome the formulation problems that have traditionally constrained its therapeutic potential.Altogether, small lipid nanocapsules loaded and functionalized with cannabidiol arise as promising dually-targeted candidates for intravenous treatment of glioma. (AU)

Nanocannabinoides como terapia frente a glioma / Nannocannabinoids for brain tumor drug delivery

Brain diseases are a major health challenge as brain drug delivery is truly hindered by the blood-brain barrier. Therefore, targeted drug nanocarriers arise as an alternative to achieve efficient transport across the brain endothelium following minimally-invasive intravenous injection. However, the global translational impact of nanomedicine remains modest. Certainly, the transition from empirical development towards a rational design tailored to the specific disease needs is likely to improve the chances of success. Under this assumption and taking advantage of both the natural brain tropism and the antiproliferative activity of cannabidiol, to contribute to the rational design of targeted nanocapsules for glioma therapy, we have thoroughly screened the influence of distinct parameters on their in vitro and in vivo behaviour. Effectively, we have demonstrated that both the brain and glioma targeting ability and the drug release rate can be tailored by varying the particle size of the nanocapsules. This fine size-tailoring can be achieved by the phase inversion temperature method thanks to the hereindescribed linear univariate mathematical model as a function of the oily phase/surfactant mass ratio. Moreover, we have introduced, on the one hand, a pioneering brain tumor targeting strategy with cannabidiol (with better targeting properties than other strategies that have already reached the clinical trials stage) and, on the other hand, nanocapsules as extendedrelease carriers of cannabidiol to overcome the formulation problems that have traditionally constrained its therapeutic potential. Altogether, small lipid nanocapsules loaded and functionalized with cannabidiol arise as promising dually-targeted candidates for intravenous treatment of glioma

Las patologías cerebrales representan un desafío terapéutico por la restricción al paso de fármacos a través de la barrera hematoencefálica. Por ello, actualmente se persigue diseñar transportadores de fármacos capaces de atravesar de manera eficiente el endotelio cerebral tras su administración intravenosa. Sin embargo, el impacto traslacional de la nanomedicina es aún discreto. Sin duda, la transición de un desarrollo empírico hacia un diseño racional adecuado a las necesidades terapéuticas concretas en cada caso aumentará las posibilidades de éxito. Bajo esta premisa y aprovechando tanto el tropismo cerebral como la actividad antiproliferativa del cannabidiol, y a fin de contribuir al diseño racional de nanocápsulas dirigidas para el tratamiento de gliomas, hemos evaluado la influencia de distintos parámetros en su comportamiento in vitro e in vivo. Efectivamente, hemos demostrado que tanto el paso a través de barrera hematoencefálica como la captación por células de glioma, así como la velocidad de liberación de fármacos pueden modularse variando su tamaño de partícula. El método térmico de inversión de fases posibilita la obtención de nanocápsulas bajo demanda en términos de tamaño gracias al modelo matemático lineal en una variable aquí descrito. Además, hemos desarrollado una novedosa estrategia de vectorización con cannabidiol (que incluso supera a otras que ya se encuentran en ensayos clínicos). Asimismo, las nanocápsulas sirven como transportadores de liberación prolongada del cannabidiol, superando así sus problemas de formulación que venían limitando su potencial terapéutico. En conjunto, las nanocápsulas lipídicas, cargadas y funcionalizadas con cannabidiol, constituyen prometedores candidatos para el tratamiento de gliomas

Lipid nanocapsules decorated and loaded with cannabidiol as targeted prolonged release carriers for glioma therapy: In vitro screening of critical parameters.

The therapeutic potential of cannabinoids has been truly constrained heretofore due to their strong psychoactive effects and their high lipophilicity. In this context, precisely due to the lack of psychoactive properties, cannabidiol (CBD), the second major component of Cannabis sativa, arises as the phytocannabinoid with the most auspicious therapeutic potential. Hence, the incorporation of CBD in lipid nanocapsules (LNCs) will contribute to overcome the dosing problems associated with cannabinoids. Herein, we have prepared LNCs decorated and loaded with CBD for glioma therapy and screened in vitro their critical parameters. On the one hand, we have encapsulated CBD into the oily core of LNCs to test their in vitro efficacy as extended-release carriers against the human glioblastoma cell line U373MG. The in vitro antitumor effect was highly dependent on the size of LNCs due to its pivotal role in the extent of CBD release. Effectively, a comparison between two differently-sized LNCs (namely, 20-nm and 50-nm sized carriers) showed that the smaller LNCs reduced by 3.0-fold the IC50 value of their 50-nm sized counterparts. On the other hand, to explore the potential of this phytocannabinoid to target any of the cannabinoid receptors overexpressed in glioma cells, we decorated the LNCs with CBD. This functionalization strategy enhanced the in vitro glioma targeting by 3.4-fold in comparison with their equally-sized undecorated counterparts. Lastly, the combination of CBD-loading with CBD-functionalization further reduced the IC50 values. Hence, the potential of these two strategies of CBD incorporation into LNCs deserves subsequent in vivo evaluation.