Determination of Chlorophenols in Water According to U.S. EPA Method 528
Applications | 2016 | Thermo Fisher ScientificInstrumentation
Phenolic and chlorophenolic compounds are widely used in industrial processes and can contaminate water resources, posing risks to ecosystems and human health.
Monitoring these pollutants at trace levels is essential for environmental protection and regulatory compliance.
The aim of this study was to develop a comprehensive analytical workflow based on U.S. EPA Method 528 for the determination of chlorophenols in water.
It integrates automated solid-phase extraction and gas chromatography–mass spectrometry to achieve high throughput and reliability.
Water samples were collected in 1 L bottles without headspace, dechlorinated with sodium sulfite, and acidified to pH 2 for preservation and SPE efficiency.
Automated SPE was performed on a Dionex AutoTrace 280 using HyperSep Retain PEP cartridges with conditioning, loading, washing, drying, and elution steps in dichloromethane.
Eluates were concentrated under nitrogen, spiked with internal standards, and analyzed by a Thermo Scientific TRACE 1310 GC equipped with a TraceGOLD TG-5MS column and an ISQ LT mass spectrometer in full-scan mode.
System control and data handling were managed by Chromeleon 7.2 CDS and a TriPlus RSH autosampler.
Calibration curves for 14 analytes showed excellent linearity (r2 > 0.99 for most compounds).
System repeatability exhibited low RSD values (1.2–3.0 %) across five injections.
Recovery studies at 10 ppb spike levels yielded rates between 72 % and 101 %, in compliance with EPA 528 acceptance ranges.
Chromatographic separation demonstrated baseline resolution of all target chlorophenols.
Automated SPE reduces manual labor, solvent consumption, and exposure to hazardous chemicals while enhancing reproducibility.
The fully integrated GC-MS workflow streamlines analysis from sample preparation to reporting, making it ideal for routine environmental monitoring, QA/QC laboratories, and regulatory testing.
Further improvements may include coupling online SPE to GC-MS for real-time monitoring, employing tandem mass spectrometry for enhanced selectivity, and developing miniaturized or field-deployable platforms.
Advanced data analytics and machine learning could optimize method performance and enable rapid decision making in water quality management.
The automated workflow based on EPA Method 528 provides a robust, reproducible, and high-throughput solution for chlorophenol analysis in water with minimal operator intervention.
Its integration of automated SPE, autosampling, and chromatography data systems ensures reliable results and operational efficiency.
GC/MSD, Sample Preparation, GC/SQ
IndustriesEnvironmental
ManufacturerThermo Fisher Scientific
Summary
Importance of the Topic
Phenolic and chlorophenolic compounds are widely used in industrial processes and can contaminate water resources, posing risks to ecosystems and human health.
Monitoring these pollutants at trace levels is essential for environmental protection and regulatory compliance.
Objectives and Study Overview
The aim of this study was to develop a comprehensive analytical workflow based on U.S. EPA Method 528 for the determination of chlorophenols in water.
It integrates automated solid-phase extraction and gas chromatography–mass spectrometry to achieve high throughput and reliability.
Methodology and Instrumentation
Water samples were collected in 1 L bottles without headspace, dechlorinated with sodium sulfite, and acidified to pH 2 for preservation and SPE efficiency.
Automated SPE was performed on a Dionex AutoTrace 280 using HyperSep Retain PEP cartridges with conditioning, loading, washing, drying, and elution steps in dichloromethane.
Eluates were concentrated under nitrogen, spiked with internal standards, and analyzed by a Thermo Scientific TRACE 1310 GC equipped with a TraceGOLD TG-5MS column and an ISQ LT mass spectrometer in full-scan mode.
System control and data handling were managed by Chromeleon 7.2 CDS and a TriPlus RSH autosampler.
Main Results and Discussion
Calibration curves for 14 analytes showed excellent linearity (r2 > 0.99 for most compounds).
System repeatability exhibited low RSD values (1.2–3.0 %) across five injections.
Recovery studies at 10 ppb spike levels yielded rates between 72 % and 101 %, in compliance with EPA 528 acceptance ranges.
Chromatographic separation demonstrated baseline resolution of all target chlorophenols.
Benefits and Practical Applications
Automated SPE reduces manual labor, solvent consumption, and exposure to hazardous chemicals while enhancing reproducibility.
The fully integrated GC-MS workflow streamlines analysis from sample preparation to reporting, making it ideal for routine environmental monitoring, QA/QC laboratories, and regulatory testing.
Future Trends and Opportunities
Further improvements may include coupling online SPE to GC-MS for real-time monitoring, employing tandem mass spectrometry for enhanced selectivity, and developing miniaturized or field-deployable platforms.
Advanced data analytics and machine learning could optimize method performance and enable rapid decision making in water quality management.
Conclusion
The automated workflow based on EPA Method 528 provides a robust, reproducible, and high-throughput solution for chlorophenol analysis in water with minimal operator intervention.
Its integration of automated SPE, autosampling, and chromatography data systems ensures reliable results and operational efficiency.
References
- US EPA Method 528 Determination of Phenols in Drinking Water by GC-MS
- Thermo Fisher Scientific Application Note 10451
- Restek Phenols Calibration Mix EPA 528 p/n 31694
- Thermo Scientific TraceGOLD TG-5MS Column P/N 26098-1420
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