Aquasomal drug delivery system: A special emphasis on the formulation techniques and applications

Prakash Rajak; Rofiqul  Islam; Arka Karmakar; Biman Bhuyan

doi:10.30827/ars.v64i4.28264

Autores/as

Prakash Rajak Department of Pharmaceutical Sciences, Faculty of Science and Engineering, Dibrugarh University, Dibrugarh 786004, Assam, India https://orcid.org/0000-0001-7072-7705
Rofiqul Islam University of Science and Technology, Department of Pharmaceutical Sciences, Meghalaya, India
Arka Karmakar Dibrugarh University, Faculty of Science and Engineering, Department of Pharmaceutical Sciences, Dibrugarh, Assam, India.
Biman Bhuyan Dibrugarh University, Faculty of Science and Engineering, Department of Pharmaceutical Sciences, Dibrugarh, Assam, India

DOI:

https://doi.org/10.30827/ars.v64i4.28264

Palabras clave:

Aquasomas; nanotecnología; autoensamblaje; nanopartículas cerámicas; Fosfato calcico

Resumen

Introducción: Aquasome es un sistema portador de nanopartículas autoensamblado con tres capas. El sistema se compone de un núcleo sólido nanocristalino interno recubierto de oligómero polihidroxilado. Adsorbidas en la capa recubierta se encuentran moléculas de fármacos o compuestos bioquímicamente activos. El autoensamblaje en este sentido se refiere a la formación independiente de moléculas en patrones organizados, de larga duración y con enlaces no covalentes. nueva tecnología de administración de fármacos. El artículo aborda principalmente los procesos de formulación utilizados para crear nanoestructuras autoensambladas y sus diversas aplicaciones posibles.

Método: En la búsqueda bibliográfica se utilizaron varias bases de datos en línea, incluidas Science Direct, Medline, Web of Science, Google Scholar y Scopus. Se realizaron búsquedas en los conjuntos de datos en busca de entradas de estudios hasta julio de 2023. El documento de revisión aborda especialmente muchos elementos de la formación de aquasomas por parte de varios investigadores que emplean métodos/técnicas modificadas como la coprecipitación, la autoprecipitación, la pulverización catódica, etc. También ilustra una variedad de campos de terapia en los que se ha reconocido que el aquasoma tiene una gran influencia, como el oxígeno y el transporte de extractos.

Resultados: El núcleo sólido es responsable de brindar estabilidad estructural, mientras que el recubrimiento oligomérico es crucial para proteger contra la deshidratación y estabilizar las moléculas bioactivas. Este vehículo de administración de fármacos biodegradable a escala nanométrica muestra una tendencia a acumularse en el hígado y los músculos. La no modificación de la adsorción del fármaco en la superficie del aquasoma facilita una respuesta farmacológica rápida al permitir el reconocimiento sin obstrucciones del receptor en el sitio de acción.

Conclusiones: Aquasome, una molécula autoensamblada de tres capas, es un sistema de administración de fármacos simple pero nuevo con un prometedor potencial de transporte para aumentar la solubilidad y la biodisponibilidad de fármacos poco solubles. A pesar de una serie de desafíos, como el consumo de tiempo, los procesos sofisticados, la seguridad y los altos costos de investigación, el aquasome puede surgir como un vehículo vesicular alternativo en el futuro.

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