Estudio sobre las interacciones de interfase entre vesículas biológicas y superficies inorgánicas de biomateriales por medio de microscopía de fuerza atómica

F. Solera; J. Vega; S. Madrigal; A. Loria

doi:10.54495/Rev.Cientifica.v22i1.125

Autores/as

F. Solera Laboratorio Nacional de Nanotecnología. Centro Nacional de Alta Tecnología. Consejo Nacional de Rectores
J. Vega Laboratorio Nacional de Nanotecnología. Centro Nacional de Alta Tecnología. Consejo Nacional de Rectores
S. Madrigal Laboratorio de Polímeros. Escuela de Química. Universidad Nacional
A. Loria Instituto de Investigaciones Farmacéuticas. Faculta de Farmacia. Universidad de Costa Rica

DOI:

https://doi.org/10.54495/Rev.Cientifica.v22i1.125

Palabras clave:

Interfase, vesículas biológicas, biomateriales, microscopía de fuerza atómica, liposomas

Resumen

Incompatibilidades de interfase en la interacción entre las micropartículas biológicas que normalmente circulan en la sangre y la superficie de los implantes de biomateriales están normalmente asociadas con posteriores reacciones de rechazo por parte del sistema inmune. Ello requiere un modelo explicativo de la conducta observada en la interface de los liposomas y las plaquetas en contacto con biomateriales y superficies inorgánicas. Por lo tanto, el análisis de la relación entre el equilibrio iónico de las fuerzas de superficie de atracción entre liposoma -superficie /grado de deformación y el cambio en las propiedades de la superficie de las nanopartículas liposomales absorbidas por la modificación de superficie de los liposomas con biopolímeros como el quitosano. Se ha hecho progreso en la comprensión de la dinámica de las interfaces para la consistencia de diferentes
vesículas de lípidos como modelo, y se ha encontrado que el recubrimiento de biopolímero de vesículas de lípidos con quitosano proporciona mejor estabilidad física y un aumento en la interfaz entre los biomateriales y nanopartículas inorgánicas biomiméticas.

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