Development of a standardized adsorbable organofluorine screening method for wastewaters with detection by combustion ion chromatography.

Per- and polyfluoroalkyl substances (PFAS) are man-made organofluorine chemicals that can contaminate environmental waters and have gained worldwide attention over the past two decades. PFAS are most frequently detected by mass spectrometric targeted analysis methods which may not detect all the PFAS in samples. This report describes the investigation of adsorbable organofluorine (AOF) with detection by combustion ion chromatography (CIC) for detection of PFAS in surface waters and wastewaters that adsorb to granular activated carbon (GAC) with the recognition that this technique measures more than just PFAS. Overall mean recoveries of 77-120% were obtained in 17 of the 18 tested surface water and wastewater matrices spiked with perfluoropentane sulfonate (PFPeS) and 55-119% mean recoveries were obtained in 11 of the 12 surface water and wastewater matrices spiked with a PFAS mixture. Poor method performance (34-39% mean recoveries) was observed in landfill leachate wastewater. Method detection limits of 1.4-2.2 µg L-1 were achieved using 100 mL sample volumes adsorbed onto commercially available GAC. This report demonstrates that this AOF technique can be a useful screening tool for estimating organofluorine concentrations when PFAS contamination is suspected.

The evaluation of hollow-fiber ultrafiltration and celite concentration of enteroviruses, adenoviruses and bacteriophage from different water matrices.

The collection of waterborne pathogen occurrence data often requires the concentration of microbes from large volumes of water due to the low number of microorganisms that are typically present in environmental and drinking waters. Hollow-fiber ultrafiltration (HFUF) has shown promise in the recovery of various microorganisms. This study has demonstrated that the HFUF primary concentration method is effective at recovering bacteriophage φX174, poliovirus, enterovirus 70, echovirus 7, coxsackievirus B4 and adenovirus 41 from large volumes of tap and river water with an average recovery of all viruses of 73.4% and 81.0%, respectively. This study also evaluated an effective secondary concentration method using celite for the recovery of bacteriophage and enteric viruses tested from HFUF concentrates of both matrices. Overall, the complete concentration method (HFUF primary concentration plus celite secondary concentration) resulted in a concentration factor of 3333 and average recoveries for all viruses from tap and river waters of 60.6% and 60.0%, respectively.