Development of high surface area organosilicate nanoparticulate thin films for use in sensing hydrophobic compounds in sediment and water

Biosensors
By: , and 

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Abstract

The scope of this study was to apply advances in materials science, specifically the use of organosilicate nanoparticles as a high surface area platform for passive sampling of chemicals or pre-concentration for active sensing in multiple-phase complex environmental media. We have developed a novel nanoporous organosilicate (NPO) film as an extraction phase and proof of concept for application in adsorbing hydrophobic compounds in water and sediment. We characterized the NPO film properties and provided optimization for synthesis and coatings in order to apply the technology in environmental media. NPO films in this study had a very high surface area, up to 1325 m2/g due to the high level of mesoporosity in the film. The potential application of the NPO film as a sorbent phase for sensors or passive samplers was evaluated using a model hydrophobic chemical, polychlorinated biphenyls (PCB), in water and sediment. Sorption of PCB to this porous high surface area nanoparticle platform was highly correlated with the bioavailable fraction of PCB measured using whole sediment chemistry, porewater chemistry determined by solid-phase microextraction fiber methods, and the Lumbriculus variegatus bioaccumulation bioassay. The surface-modified NPO films in this study were found to highly sorb chemicals with a log octanol-water partition coefficient (Kow) greater than four; however, surface modification of these particles would be required for application to other chemicals.

Publication type Article
Publication Subtype Journal Article
Title Development of high surface area organosilicate nanoparticulate thin films for use in sensing hydrophobic compounds in sediment and water
Series title Biosensors
DOI 10.3390/bios14060288
Volume 14
Issue 6
Year Published 2024
Language English
Publisher MDPI
Contributing office(s) Columbia Environmental Research Center
Description 288, 12 p.
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