New solid phase microextraction fibers with green clay coating via radio frequency magnetron sputtering for detecting low-polar compounds in water samples

Developing highly sensitive and selective measurement techniques to detect trace compounds in diverse matrices is a significant challenge in analytical chemistry. These techniques must adhere to green chemistry principles by minimizing organic solvent use, simplifying sample preparation, and streaml...

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Published in:Analytica chimica acta 2024-12, Vol.1332, p.343375, Article 343375
Main Authors: Fiscal-Ladino, Jhon, Lozada-Castro, Juan Jose, Rios-Acevedo, Jhon Jairo, Montaño-Montoya, Diego, Carasek, Eduardo, Richter, Pablo, Pulzara-Mora, Alvaro, Martínez, Liliana Moncayo, Rosero-Moreano, Milton
Format: Article
Language:English
Subjects:
adsorbents
adsorption
alloys
analytical chemistry
chlorinated hydrocarbons
clay
environmental impact
films (materials)
Green chemistry
hydrophobicity
lindane
montmorillonite
Montmorillonite clay
Nickel–titanium alloy
Organochlorine pesticides
public health
radio waves
silylation
Solid phase microextraction
solvents
spectroscopy
Water analysis
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Summary:Developing highly sensitive and selective measurement techniques to detect trace compounds in diverse matrices is a significant challenge in analytical chemistry. These techniques must adhere to green chemistry principles by minimizing organic solvent use, simplifying sample preparation, and streamlining process steps. Additionally, there is a growing need for sustainable analytical methods due to increased environmental awareness. The problem addressed in this work is the need for an eco-friendly and efficient method for the extraction and detection of trace organochlorine pesticides in water samples. We employed SPME using a novel clay thin film sorbent, deposited on a nickel-titanium alloy wire via magnetron sputtering. Montmorillonite clay was chosen for its excellent adsorption properties and eco-friendly nature, aligning with green chemistry principles. The approach involved coating the SPME fiber with hydrophobic modified montmorillonite clay, followed by silylation. The method was tested for extracting 12 model organochlorine pesticides, including BHC, lindane, and DDT, demonstrating high isolation efficiency. The coated thin film and its silylation modification were characterized using standard spectroscopic techniques, confirming the successful creation of a new adsorbent phase. The direct immersion SPME approach achieved relative recoveries ranging from 65 % to 99 %, with reproducibility (RSD) below 6 %. This method provided low detection limits (10–15 ng L−1) and quantitation limits (32–50 ng L−1). Our approach offers an eco-friendly, highly efficient solution for the extraction and detection of trace organochlorine pesticides. The significant improvement in recovery rates and reproducibility, combined with low detection and quantitation limits, underscores the potential of this method to enhance analytical practices in environmental monitoring and public health. Furthermore, the use of sustainable materials and processes aligns with global efforts to reduce environmental impact in analytical chemistry. [Display omitted] •Novel SPME fibers coated with a clay thin film are eco-friendly and highly efficient.•The clay sputter target used as the coating is sustainable material in line with green chemistry principles.•The lab-made SPME fibers developed here represent a green sample preparation technology.
ISSN:0003-2670
1873-4324
1873-4324
DOI:10.1016/j.aca.2024.343375