Litcius/Paper detail

Towards the Standardization of Intestinal In Vitro Advanced Barrier Model for Nanoparticles Uptake and Crossing: The SiO2 Case Study

Olimpia Vincentini, Valentina Prota, Serena Cecchetti, Lucia Bertuccini, Antonella Tinari, Francesca Iosi, Isabella De Angelis

2022Cells24 citationsDOIOpen Access PDF

Abstract

Increasing interest is being addressed to the development of a reliable, reproducible and relevant in vitro model of intestinal barrier, mainly for engineered nanomaterials hazard and risk assessment, in order to meet regulatory and scientific demands. Starting from the consolidated Caco-2 cell model, widely used for determining translocation of drugs and chemicals, the establishment of an advanced intestinal barrier model with different level of complexity is important for overcoming Caco-2 monoculture limitations. For this purpose, a tri-culture model, consisting of two human intestinal epithelial cells (Caco-2 and HT29-MTX) and a human lymphocyte B cell (Raji B), was developed by several research groups to mimic the in vivo intestinal epithelium, furnishing appropriate tools for nanotoxicological studies. However, tri-culture model shows high levels of variability in ENM uptake/translocation studies. With the aim of implementing the standardization and optimization of this tri-culture for ENM translocation studies, the present paper intends to identify and discuss such relevant parameters involved in model establishment as: tri-culture condition set-up, barrier integrity evaluation, mucus characterization, M-cell induction. SiO2 fluorescent nanoparticles were used to compare the different models. Although a low level of SiO2 translocation is reported for all the different culture conditions. a relevant role of mucus and M-cells in NPs uptake/translocation has been highlighted.

Topics & Concepts

Chromosomal translocationIntestinal epitheliumIn vitroMucusIn vivoCell biologyChemistryComputational biologyBiologyEpitheliumBiochemistryBiotechnologyGeneticsGeneEcologyAdvanced Drug Delivery SystemsNanoparticles: synthesis and applicationsDrug Transport and Resistance Mechanisms