AI Article Synopsis
- Detecting trace amounts of poorly soluble pharmaceuticals, like ibuprofen, in environmental and clinical settings is challenging due to factors like low concentrations and complex sample types.
- This study introduces an innovative approach using on-line flow extraction combined with SERS measurements in a microfluidic setup, specifically targeting ibuprofen in wastewater.
- The method shows significant benefits, including simplicity, high reliability, and very low detection limits, making it effective for monitoring pharmaceuticals without extensive sample preparation.
Article Abstract
Detection of trace amounts of poorly water-soluble pharmaceuticals or related (bio)solutions represents a key challenge in environment protection and clinical diagnostics. However, this task is complicated by low concentrations of pharmaceuticals, complex sample matrices, and sophisticated sample preparative routes. In this work, we present an alternative approach on the basis of an on-line flow extraction procedure and SERS measurements performed in a microfluidic regime. The advantages of our approach were demonstrated using ibuprofen (Ibu), which is considered as a common pharmaceutical contaminant in wastewater and should be monitored in various bioliquids. The extraction of Ibu from water to the dichloromethane phase was performed with an optimized microfluidic mixer architecture. As SERS tags, lipophilic functionalized gold multibranched nanoparticles (AuMs) were added to the organic phase. After microfluidic extraction, Ibu was captured by the functionalized AuM surface and recognized by on-line SERS measurements with up to 10-8 M detection limit. The main advantages of the proposed approach can be regarded as its simplicity, lack of need for preliminary sample preparation, high reliability, the absence of sample pretreatment, and low detection limits.
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| http://dx.doi.org/10.1039/d0an02360d | DOI Listing |
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