1. Progress and future of in vitro models to study translocation of nanoparticles
- Author
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Ruud J. B. Peters, Samantha K. Kloet, Hedwig M. Braakhuis, Margriet V. D. Z. Park, Ivonne M.C.M. Rietjens, Hans Bouwmeester, Meike van der Zande, Sanja Kezic, Séverine Le Gac, Susann Bellmann, Petra Krystek, Frieke Kuper, Faculty of Science and Technology, and Developmental BioEngineering
- Subjects
Pathology ,Novel Foods & Agrochains ,Health, Toxicology and Mutagenesis ,short-term inhalation ,Placenta ,Review Article ,Toxicology ,Novel Foods & Agroketens ,Placental barrier ,BU Contaminants & Toxins ,Tissue Distribution ,BU Toxicology, Novel Foods & Agrochains ,organs-on-chips ,zinc-oxide nanoparticles ,Lung ,Air liquid interface ,EWI-26767 ,BU Toxicology ,General Medicine ,m-cell model ,In vitro models ,Microfluidic Analytical Techniques ,Human situation ,Toxicokinetics ,BU Toxicologie, Novel Foods & Agroketens ,pulmonary drug-delivery ,Animal Testing Alternative ,Dermal ,Coculture Technique ,Oral ,medicine.medical_specialty ,BU Toxicologie ,BU Contaminanten & Toxines ,air-liquid interface ,Rodentia ,Computational biology ,plasma-mass spectrometry ,Biology ,Animal Testing Alternatives ,Models, Biological ,In vivo ,medicine ,Animals ,Humans ,IR-99341 ,titanium-dioxide nanoparticles ,Toxicologie ,VLAG ,METIS-315577 ,In vitro ,Coculture Techniques ,gold nanoparticles ,Titanium dioxide nanoparticles ,Nanoparticles ,field-flow fractionation - Abstract
The increasing use of nanoparticles in products likely results in increased exposure of both workers and consumers. Because of their small size, there are concerns that nanoparticles unintentionally cross the barriers of the human body. Several in vivo rodent studies show that, dependent on the exposure route, time, and concentration, and their characteristics, nanoparticles can cross the lung, gut, skin, and placental barrier. This review aims to evaluate the performance of in vitro models that mimic the barriers of the human body, with a focus on the lung, gut, skin, and placental barrier. For these barriers, in vitro models of varying complexity are available, ranging from single-cell-type monolayer to multi-cell (3D) models. Only a few studies are available that allow comparison of the in vitro translocation to in vivo data. This situation could change since the availability of analytical detection techniques is no longer a limiting factor for this comparison. We conclude that to further develop in vitro models to be used in risk assessment, the current strategy to improve the models to more closely mimic the human situation by using co-cultures of different cell types and microfluidic approaches to better control the tissue microenvironments are essential. At the current state of the art, the in vitro models do not yet allow prediction of absolute transfer rates but they do support the definition of relative transfer rates and can thus help to reduce animal testing by setting priorities for subsequent in vivo testing.
- Published
- 2015