Abstract
Detection of micropollutants such as steroid hormones occurring in the aquatic environment at concentrations between ng/L and µg/L remains a major challenge, in particular when treatment efficiency is to be evaluated. Steroid hormones are typically analysed using mass-spectrometry methods, requiring pre-concentration and/or derivatisation procedures to achieve required detection limits. Free of sample preparation steps, the use of radiolabelled contaminants with liquid scintillation counting is limited to single-compound systems and require a separation of hormone mixtures before detection. In this work, a method was developed coupling ultra-high-pressure liquid chromatography (UHPLC) with flow scintillation analysis (FSA) for separation and detection of radiolabelled estrone, 17ß-estradiol, testosterone and progesterone. Adjustment of the flow rate of scintillation liquid and UHPLC mobile phase, gradient time, column temperature, and injection volume allowed the separation of steroid hormones and degradation products. The limit-of-detection (LOD = 1.5–2.4 ng/L) and limit-of-quantification (LOQ = 3.4–4.3 ng/L) for steroid hormones were comparable with the current state-of-the-art technique (LC-MS/MS) for non-derivatised compounds. Although the method cannot be applied to real water samples (unless spiked with radiotracers), it serves as a useful tool for the development of water treatment technologies at laboratory scale as demonstrated via: i) adsorption on polymer-based spherical activated carbon, ii) retention in nanofiltration, iii) photodegradation using a photocatalytic membrane.
Highlights
Detection of micropollutants such as steroid hormones occurring in the aquatic environment at concentrations between ng/L and μg/L remains a major challenge, in particular when treatment efficiency is to be evaluated
The samples were kept inside the autosampler (Flexar FX ultra-high performance liquid chromatography (UHPLC), Perkin Elmer) at a temperature of 4 °C and injected onto the column thermostated in an liquid chromatography (LC) Column Oven (Flexar LC, Perkin Elmer)
The methanol-water gradient elution was realised by the UHPLC pump (Flexar FX-20, Perkin Elmer)
Summary
Detection of micropollutants such as steroid hormones occurring in the aquatic environment at concentrations between ng/L and μg/L remains a major challenge, in particular when treatment efficiency is to be evaluated. Steroid hormones are typically analysed using mass-spectrometry methods, requiring pre-concentration and/or derivatisation procedures to achieve required detection limits. Free of sample preparation steps, the use of radiolabelled contaminants with liquid scintillation counting is limited to single-compound systems and require a separation of hormone mixtures before detection. The detection and quantitation of micropollutants with conventional mass-spectroscopy methods involves additional sample preparation steps, such as derivatisation and pre-concentration, to achieve better sensitivity. As increasing the injected analyte mass on column is desired, pre-concentration (enrichment process) may be performed using extraction techniques, such as solid-phase extraction (SPE). These require often the large sample volumes that may not be available in laboratory experiments. The above procedures extend the analysis time and reduce the sample throughput[25], but may become an additional source of error due to variation of recovery[26] or incomplete derivatisation[27]
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