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Synergistic Treatment of Mixed 1,4-Dioxane and Chlorinated Solvent Contaminations by Coupling Electrochemical Oxidation with Aerobic Biodegradation Jeramy R. Jasmann, Phillip B. Gedalanga, Thomas Borch, Shaily Mahendra, and Jens Blotevogel Environ. Sci. Technol., Just Accepted Manuscript • DOI: 10.1021/acs.est.7b03134 • Publication Date (Web): 12 Oct 2017 Downloaded from http://pubs.acs.org on October 13, 2017
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Synergistic Treatment of Mixed 1,4-Dioxane and Chlorinated Solvent Contaminations by Coupling Electrochemical Oxidation with Aerobic Biodegradation Jeramy R. JasmannA,†, Phillip B. GedalangaB, Thomas BorchA,C,D, Shaily MahendraB, Jens BlotevogelC,*
A
Department of Chemistry, Colorado State University, Fort Collins, Colorado, CO 80523, USA
B
Department of Civil and Environmental Engineering, University of California, Los Angeles, CA 90095, USA
C
Department of Civil and Environmental Engineering, Colorado State University, Fort Collins, CO 80523, USA
D
Department of Soil and Crop Sciences, Colorado State University, Fort Collins, CO 80523, USA
†
Current address: U.S. Geological Survey, National Research Program, Boulder, CO 80303, USA
TOC Art
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ABSTRACT
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Biodegradation of the persistent groundwater contaminant 1,4-dioxane is often hindered
3
by the absence of dissolved oxygen and the co-occurrence of inhibiting chlorinated solvents.
4
Using flow-through electrolytic reactors equipped with Ti/IrO2-Ta2O5 mesh electrodes, we show
5
that combining electrochemical oxidation with aerobic biodegradation produces an over-additive
6
treatment effect for degrading 1,4-dioxane. In reactors bioaugmented by Pseudonocardia
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dioxanivorans CB1190 with 3.0 V applied, 1,4-dioxane was oxidized 2.5 times faster than in
8
bioaugmented control reactors without an applied potential, and 12 times faster than by abiotic
9
electrolysis only. Quantitative polymerase chain reaction analyses of CB1190 abundance,
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oxidation-reduction potential, and dissolved oxygen measurements indicated that microbial
11
growth was promoted by anodic oxygen-generating reactions. At a higher potential of 8.0 V,
12
however, the cell abundance near the anode was diminished, likely due to unfavorable pH and/or
13
redox conditions. When coupled to electrolysis, biodegradation of 1,4-dioxane was sustained
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even in the presence of the common co-contaminant trichloroethene in the influent. Our findings
15
demonstrate that combining electrolytic treatment with aerobic biodegradation may be a
16
promising synergistic approach for the treatment of mixed contaminants.
17 18 19
INTRODUCTION
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1,4-Dioxane, a widely used solvent stabilizer, is a persistent organic pollutant frequently
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observed in groundwater impacted by chlorinated volatile organic compounds.1-3 Recent reports
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of contaminated site data from across the United States highlight the high probability of co-
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occurrence of 1,4-dioxane with vapor degreasers such as trichloroethene (TCE) and 1,1,1-
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trichloroethane (1,1,1-TCA).3-5 1,4-Dioxane’s miscibility in water and low sorption affinity to
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soil make it highly mobile in groundwater, frequently leading to large plume development.
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While often at sub-mg/L concentrations in dilute groundwater plumes, 1,4-dioxane
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concentrations can occur at tens or hundreds of mg/L in source zones and industrial
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wastewater.3,6-8 1,4-dioxane is highly recalcitrant, and commonly applied remediation
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technologies for chlorinated solvent co-contaminants, like sorption and air stripping, have been
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ineffective for its removal. Advanced oxidation processes (AOPs) involving UV light can
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produce highly reactive hydroxyl radicals (•OH) to mineralize 1,4-dioxane, 9-12 but the high cost 2 ACS Paragon Plus Environment
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typically limits their use to treatment of relatively small water volumes and ex situ treatment.
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Thus, the development of more cost-effective treatment options is critically needed.
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Recent laboratory studies have documented successful aerobic biodegradation of 1,4-
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dioxane either co-metabolically13-16 or metabolically,16-18 and one study demonstrated microbially
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driven Fenton-based degradation19 of 1,4-dioxane in a system alternating between aerobic and
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anaerobic conditions. These studies indicate that bioremediation of 1,4-dioxane is generally
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possible under suitable conditions. However, three factors may limit the site-specific
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biodegradation potential for 1,4-dioxane: (1) lack of dissolved oxygen for aerobic microbial
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respiration, (2) low activity of indigenous bacterial populations, and (3) inhibition of microbial
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metabolism by chlorinated solvents.20-22 Currently, all pure culture isolates capable of 1,4-
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dioxane biodegradation require O2 as the terminal electron acceptor.13-18 This constraint has been
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prohibitive to natural attenuation approaches since 1,4-dioxane contamination often occurs in
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anoxic water conditions. Recent investigations by Mahendra and coworkers20,22 revealed that
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TCE, 1,1,1-TCA, and the abiotic transformation products 1,1-dichloroethene (1,1-DCE) and cis-
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1,2-dichloroethene (cis-DCE) caused metabolic inhibition of the 1,4-dioxane-metabolizing
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bacteria Pseudonocardia dioxanivorans CB1190. The observed decrease in biodegradation rates
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were attributed to delayed ATP production and down-regulation of the 1,4-dioxane
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monooxygenase (dxmB) and aldehyde dehydrogenase (aldH) genes essential to the production of
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enzymes known to be significant in the 1,4-dioxane degradation pathway.23 However, these
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studies also indicated that the inhibition was non-competitive and reversible, opening up the
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opportunity for full metabolic recovery once the chlorinated compounds were removed. Hand
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and coworkers provided similar evidence for TCE-caused inhibition of 1,4-dioxane
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biodegradation in two co-metabolizing bacteria, Mycobacterium vaccae JOB5 and Rhodococcus
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jostii RHA1.21 Despite this inhibitory effect, groundwater concentration data and detection of in
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situ biomarkers for 1,4-dioxane-metabolizing bacteria from 2000 to 2016 provide encouraging
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evidence for natural 1,4-dioxane attenuation in some plumes co-contaminated with TCE.4,24,25
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Still, observable biodegradation was limited to aerobic regions of the aquifers and negatively
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correlated with concentrations of chlorinated volatile organics. Thus, in order for biodegradation
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of 1,4-dioxane to become a widely used remediation strategy, some form of biostimulation or
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augmentation is required, along with an economical treatment process to address inhibiting co-
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contaminants such as TCE.13,26 3 ACS Paragon Plus Environment
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Electrochemical degradation has previously been shown to effectively mineralize
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chlorinated solvents both by reductive dechlorination and •OH mediated oxidation.27-29 1,4-
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dioxane is also degraded by electrochemical treatment via strongly oxidizing •OH radicals
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generated by the oxidation of H2O at the anode.30-32 Our previous work using abiotic flow-
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through, electrochemical reactors with Ti/IrO2-Ta2O5 electrodes confirmed that 1,4-dioxane
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(influent concentrations 0.3 to 41.4 mg/L) was degraded into CO2 and small organic acid and
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aldehyde intermediates32 known to be readily biodegradable.27,33-35 It has also been shown that
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chloride, often present in natural waters, can potentially be transformed to highly oxidized
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chlorine species by electrolysis, assisting in the mineralization of 1,4-dioxane and other
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contaminants,36 although these species could also be destructive to microbial cells.37-40 By taking
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advantage of the concurrent electrolysis of bulk water to evolve molecular oxygen from the
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anode half reaction, 2 H2O(l) → O2(g) + 4 H+(aq) + 4e-,41-43 a dramatic shift in redox potential from
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hypoxic to highly oxic conditions can be achieved. We thus hypothesized that electrochemical
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treatment would degrade 1,4-dioxane and microbially inhibiting co-contaminants such as TCE
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while simultaneously generating O2 essential to aerobic respiration, thus leading to enhanced
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aerobic biodegradation rates of 1,4-dioxane.33,34
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To test our hypothesis, we built flow-through electrolytic column reactors with
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dimensionally stable, Ti/IrO2-Ta2O5 mesh electrodes, which are commercially available and have
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several beneficial properties. Metal oxide electrodes, like Ti/IrO2-Ta2O5, have a higher oxidation
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state available (i.e. Ir4+ → Ir5+) close to the thermodynamic potential for aqueous oxygen
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evolution, making them excellent candidates for the electrocatalytic generation of O2 at low
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power requirements.41,44,45 Published comparisons have shown the relatively low oxygen
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evolution potential of Ti/IrO2-Ta2O5 (1.5 - 1.8 V vs. SHE, standard hydrogen electrode) also
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coincides with less disinfection by-product (DBP) formation compared to other electrode
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materials used for organic contaminant degradation such as PbO2, RuO2-IrO2, Pt-IrO2, and SnO2-
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Sb.45,46 Detailed reaction schemes describing O2 production and organic pollutant oxidation can
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be found in the Supporting Information (SI, Reactions 1 - 6). Furthermore, previous studies have
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demonstrated this mixed metal oxide coating to have favorable surface chemistry interactions and
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degradation efficiencies with chlorinated contaminants, like TCE.29,47,48 Finally, at a cost of ~400
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$/m2, it is substantially cheaper than many other electrodes such as boron-doped diamond anodes
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(~15,000 $/m2),37 and previous field demonstrations, including use as an in situ permeable 4 ACS Paragon Plus Environment
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electrolytic barrier for chlorinated solvent removal, have revealed a long service life (i.e., no loss
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in electrolytic performance during greater than 2 years of continuous treatment).28,49
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We used Pseudonocardia dioxanivorans CB1190 (hereafter “CB1190”) as the model
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bacterium for 1,4-dioxane biodegradation due to its versatile capabilities to metabolize a wide
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range of organic molecules (although not TCE), while also being able to rapidly metabolize 1,4-
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dioxane at rates ranging from 1.1 to 19.8 mg·min-1 per mg of protein in the biomass.17,18,50 From
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among the chlorinated solvents that have been characterized with respect to inhibiting 1,4-
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dioxane degradation by CB1190,22 TCE was chosen because the dichloroethene isomers are
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substantially more volatile and may easily be stripped by electrolytically produced gasses, and
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1,1,1-TCA has shown very little inhibition to CB1190 metabolism.
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Our specific objectives were to (a) determine whether anodic generation of O2 improves
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biodegradation rates of 1,4-dioxane and (b) investigate the impacts of voltage potentials and
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presence of TCE as co-contaminant on degradation kinetics of 1,4-dioxane and spatial CB1190
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abundance relative to the electrodes. Consequently, this is the first study to provide a
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fundamental basis for combined electrochemical and biological treatment for 1,4-dioxane-
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contaminated waters, both when occurring on its own and in the presence of potentially
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inhibiting co-contaminants.
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MATERIALS AND METHODS
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Chemicals. All chemicals were used as received. 1,4-Dioxane (99.5%, Burdick &
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Jackson), TCE (99.5%, Alfa Aesar), 1,1-DCE (99%, Alfa Aesar), and vinyl chloride (99%, Alfa
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Aesar) were used to prepare calibration standards and/or influent contaminant mixtures while
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dichloromethane (99.96%, OmniSolv Millipore EMD) was used as an extraction solvent prior to
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quantitation of chemical analytes. Additionally, deuterated 1,4-dioxane-d8 (99% and 99 atom
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%D, Sigma Aldrich) was used for isotopic dilution quantitation.
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Sterilization and Disinfection Protocol. All glassware, metal laboratory equipment, and
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sand used for abiotic control experiments were dry heat-sterilized in a furnace at 232°C for 12-18
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hours or autoclaved at 121°C and 23 psig for 20 minutes (Tuttnauer 2870 EP Autoclave). Non-
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autoclavable materials, i.e. work bench surface and the PVC sand column reactors, were
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disinfected either with 70% ethanol or 10% bleach solutions. 5 ACS Paragon Plus Environment
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Bacterial Strain and Culture Conditions. The model 1,4-dioxane metabolizing
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bacterium, Pseudonocardia dioxanivorans strain CB1190, was harvested by a 1% (v/v) transfer
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from an actively growing pure culture into ammonium mineral salts (AMS) nutrient medium
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similar to previously reported procedures (Appendix A in Supporting Information).17,22 The AMS
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medium’s main constituents, 660 mg/L (NH4)2SO4 and 1000 mg/L MgSO4·7H2O, serve as
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important nitrogen and sulfur sources for CB1190. In addition, the AMS medium serves as a
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proxy for groundwater since it consists of a complex mixture of other inorganic ions commonly
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found in groundwater environments such as Ca2+, Fe2+, Zn2+, Mn2+, SO42- and Cl-. Aqueous
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CB1190 cultures were grown aerobically in AMS medium and sequentially harvested by 1 - 10
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% (v/v) transfers into larger and larger volumes of fresh AMS solution, ending in 4.0-L
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polycarbonate Nalgene containers, which were then used to inoculate silica sand (Figure S3).
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Spikes of 1,4-dioxane were added every 2 to 5 days, maintaining levels at 80 - 100 mg/L, to
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provide ongoing renewal of the sole carbon and energy source. Throughout the process, aqueous
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and sand cultures were incubated at 30°C with continuous agitation at 100 rpm to
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homogeneously mix the 1,4-dioxane carbon source and micronutrients, and infuse oxygen. Only
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“active” CB1190 cultures were used to inoculate sand, and only “active” batches of this
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homogeneously mixed inoculated sand were used to pack into bioaugmented column reactors.
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Initial CB1190 population densities (planktonic and sessile) were measured by qPCR analysis
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immediately following transfer into column reactors. Targeting “active” cultures was meant to
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provide sand containing CB1190 communities at peak population density and metabolic activity
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prior to initiating each flow-through column experiment. We characterized “active” CB1190
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cultures as those with (a) consistent, rapid 1,4-dioxane biodegradation (biodegradation rates > 10
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mg/L/day), (b) high CB1190 bacteria populations detected on aerobic count plates (1:1000
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dilution having > 5 colonies/cm2 of petrifilm plate), and (c) evidence of the culture experiencing
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mid- to late-exponential growth phase indicated by increased bacterial ATP production (Figure
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S3). To track ATP concentrations over time, luminescence analysis (BioTek Synergy HT) was
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completed within two hours of sampling using the Promega BacTiter-GloTM Microbial Cell
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Viability Assay following Promega Technical Bulletin #TB337 and Protocol for Measuring ATP
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from Bacteria Bulletin. Bacterial abundance was monitored by counting bacterial colonies on 3M
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Petrifilm Aerobic Count Plates following manufacturer’s protocol.
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Flow-Through Column Reactors. Bench-scale flow-through experiments were
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performed using 10-cm I.D. x 45-cm long clear PVC column reactors (Figure 1 and Figure S1),
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packed with 8-12 mesh quartz silica sand and two permeable, disc-shaped Ti/IrO2-Ta2O5 mesh
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electrodes installed perpendicular to flow (78.5 cm2 cross-sectional area, 1mm thick with 1.0 x
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2.8 mm diamond-shaped openings, Corrpro Companies). All column reactors were operated in
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the dark, under opaque plastic, to prevent potential photolysis of 1,4-dioxane. PVC column
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reactors were chemically disinfected (70% ethanol) between experiments and repacked with
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CB1190-inoculated silica sand for all bioaugmented experiments, and repacked with heat-
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sterilized silica sand (232°C for 18 hours) for all non-bioaugmented control experiments. One
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column reactor was used for all 3V experiments, a second column reactor for all 8V experiments,
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and a third was used for all 0V experiments.
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In addition to the influent (12.5 cm before anode) and effluent (32.5 cm downstream of
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anode) liquid sample ports, three additional liquid ports (L1, L2, and L3) and solid ports (S1, S2,
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and S3) were installed along the column flow path at distances of 2.5, 12.5, and 22.5 cm
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downstream of the leading anode (Figure 1). Thus, L1 (S1) is located midway between the
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leading anode (positive polarity) and trailing cathode (negative polarity) which have 5.0 cm of
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separation between them.
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0
2.5
12.5
22.5
RE2
RE1
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32.5cm
PVC PVC tube endcap
gas vents
Direction of Flow S1
S2
S3
Leffluent
Linfluent
+
L1
-
L2
L3
Contaminant Feedstock 1,4-Dioxane in AMS medium (TCE as co-contaminant)
Effluent Reservoir
+ - anode & cathode working electrodes S L RE
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solid sample ports liquid sample ports Ag/AgCl reference electrode (redox) silica sand (8/12 mesh)
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Figure 1. Schematic of flow-through electrolytic reactors used for non-bioaugmented electrolytic degradation, bioaugmented biodegradation and combined electro-biodegradation experiments. Solid sample ports have removable threaded PVC plugs (1” diameter) to allow access to sand within the reactor. Liquid sample ports have 3-way valves. Gas vents are exhausted into large tedlar bags.
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Influent feedstock (in 20-L glass carboys) was composed of degassed, hypoxic AMS
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medium spiked with 100 mg/L 1,4-dioxane (and additional 5 mg/L TCE for co-contaminant
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experiments). A high 1,4-dioxane concentration was chosen so that CB1190 biodegradation
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rates would not be limited by electron donor availability and to assess degradation performance
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under challenging conditions, such as in source zones and industrial wastewaters.3,5 The specific
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conductivity of the medium was 3.4 - 3.6 mS/cm and initial dissolved oxygen concentration
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(DO) after degassing was 2.9 - 3.1 mg/L. The pH was adjusted to 6.9 ± 0.1 using NaOH before
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adding phosphate buffer (KH2PO4 / K2HPO4). Completely anoxic feedstock conditions could not
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be maintained without the addition of unwanted oxygen scavenger compounds that may have
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interfered with electrochemical reactions or biological functions. All flow-through sand column
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experiments were operated at 22 ± 2°C (ambient temperature) and a flow rate of 1.07 mL/min. 8 ACS Paragon Plus Environment
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Constant feedstock flow rates (Q) of 1.07 mL·min-1 were confirmed each day by volumetric
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analysis. To account for the sand column reactor porosity (ϕ, average of 0.43) and the flux
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through the reactor’s cross-sectional area (A, 78.5 cm2), flow rate is expressed as its seepage
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velocity (vs) of 46 cm/d, since vs = Q / (A · ϕ) = (1.07cm3·min-1 x 1440min·day-1) / (78.5cm2 x
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0.43). Ten different experimental regimes were tested for the treatment of 100 mg/L 1,4-dioxane
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feedstock under the following conditions: 3V ± CB1190 ± TCE, 8V ± CB1190 ± TCE, and 0V +
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CB1190 ± TCE (Figure S1). To minimize sorption effects, feedstock solution was flowed
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through each column reactor prior to each new treatment regime until influent and effluent
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contaminant concentrations were stable (± 3% coefficient of variation). The target voltage was
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then initiated (0, 3.0 or 8.0 V), and effluent concentrations were monitored until achieving
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steady-state conditions (i.e. stable effluent concentrations over time). Steady-state conditions
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were achieved within 3 - 5 pore volumes (3 - 5 days), and replicate aqueous samples (n ≥ 3) of
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the influent and effluent were taken at 1 - 2 day intervals. Aqueous samples were filtered with
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Acrodisc 0.45-µm nylon membrane syringe filters (Pall Corporation) and extracted into
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dichloromethane solvent prior to analysis for 1,4-dioxane and chlorinated ethenes using an
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Agilent 6890N gas chromatograph (GC) coupled to an Agilent 5973N mass spectrometer (MS)
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in full scan mode (m/z 40-250 Da) and selected ion monitoring (SIM) mode. 1-µL injections
207
were made using a 4:1 split flow ratio and an inlet temperature of 250°C. The GC was equipped
208
with a Restek Rxi-624Sil MS mid-polarity column (30 m x 0.25 mm ID x 1.4 µm df). The
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Helium carrier gas was to set to constant flow at 2.0 mL/min. The initial oven temperature was
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held at 40°C for 2 minutes, then ramped at 8°C/min to 100°C, followed by an additional ramp of
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40°C/min to 160°C and held for 1 minute.
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The MS was programmed to scan for m/z 62 and 64 (vinyl chloride) in segment 1 from
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1.0 to 3.52 minutes after injection. Segment 2 was set to scan for m/z 61 and 96 (DCE isomers)
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until 5.0 minutes when segment 3 began scanning for m/z 95 and 130 (TCE). Segment 4 started
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at 6.25 minutes scanning for m/z 64 and 96 (1,4-dioxane-d8) as well as m/z 58 and 88 (1,4-
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dioxane). Each ion was assigned a dwell time of 100 µs. Quantitation with GC/MS(SIM) for all
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chlorinated compounds was performed using external calibration standards. External standard
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calibration was also used for 1,4-dioxane in experiments with 1,4-dioxane as the only
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contaminant in the feedstock. Isotopic dilution calibration was use to quantify 1,4-dioxane in all
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co-contaminant experiments, using 1,4-dioxane-d8 as the internal standard to correct for analyte 9 ACS Paragon Plus Environment
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losses due to sample preparation or variations in instrument response. Calibration was obtained
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by plotting the ratio of the analyte signal to the 1,4-dioxane-d8 signal as a function of the analyte
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standard concentration. Further analytical method descriptions are provided in the Supporting
224
Information.
225
Physicochemical Measurements. Daily measurements were made of voltage and current
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between the anode and cathode (Fluke Multimeter). Solution oxidation-reduction potential (ORP)
227
was measured against Ag/AgCl reference micro-electrodes (RE-5, World Precision Instruments)
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at two locations within the column, RE1 and RE2 in Figure 1. Solution pH was measured for all
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experimental regimes in the influent, the effluent, and from aqueous ports L1, L2, and L3 along
230
the column flow path (Figure 1). The pH was measured using a pH electrode (±0.1 pH unit
231
precision) and confirmed by pH indicator strips at beginning and end of experiments. Specific
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conductivity and dissolved oxygen levels were measured comprehensively only for the
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bioaugmented/mixed contaminant experiments using Hach HQ40d meter with graphite
234
conductivity and luminescent DO probes. Calibration of the DO probe with auto salinity
235
corrections was performed according to the water-saturated air (100%) procedure in
236
manufacturer’s operation manual.
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Quantitative Polymerase Chain Reaction (qPCR). Nucleic acid primers for the dxmB
238
gene, which codes for the dioxane monooxygenase β subunit, were used to quantify this target by
239
qPCR analysis as described in Gedalanga, et al.23 Additionally, the dxmB gene target was used as
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a proxy for CB1190 population abundance due to its known requirement for 1,4-dioxane
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biodegradation.23 At the start and completion of each ~2-week flow-through experiment, 0.5-mL
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liquid samples and 0.5-g solid sand samples were collected into 2.0-mL microcentrifuge tubes,
243
sealed, and frozen at -20°C. Liquid aliquots were sampled via passive flow from valves at the
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influent, inter-column locations L1, L2, L3, and effluent (duplicates collected from each
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location). Removable, threaded PVC plugs at ports S1, S2, and S3 provided access to collect
246
duplicate sand samples from center and outer portions of each reactor with heat-sterilized, 1.0-cm
247
diameter metal tubes (detailed description in SI). Replicate qPCR analyses were performed for
248
each duplicate sample collected, and the average of the four values obtained was used to estimate
249
CB1190 abundance at each location along the column flow path.
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In preparation for qPCR analysis, DNA was extracted from sand and liquid phase samples
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using a bead beating method followed by phenol/chloroform purification.23 Briefly, liquid 10 ACS Paragon Plus Environment
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samples were centrifuged to pellet the biomass for 3 minutes at 13,200 x g. The supernatant was
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discarded and DNA was extracted from the pelleted biomass by addition of 0.25 mL extraction
254
buffer, 0.1 mL 10% sodium dodecyl sulfate, and 1 mL saturated phenol to all tubes. Samples
255
were heated at 65˚C for 2 minutes followed by bead beating for 2 minutes using a minibead
256
beater-16 (Biospec Products, Bartlesville, OK). Lysed samples were incubated at 65˚C for 8 min
257
followed by another round of bead beating for 2 min. Samples were centrifuged and the lysate
258
was transferred to a sterile 1.7-mL microcentrifuge tube for phenol/chloroform purification.
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Nucleic acid extracts were resuspended in 100 µL of nuclease-free H2O and stored at -80˚C until
260
further analyses.
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All qPCR reactions were performed in a total volume of 20 µL containing 1X Kapa Sybr
262
Fast qPCR Master Mix (Kapa Biosystems, Wilmington, MA), 0.25 µM of each primer
263
(IDTDNA, San Diego, CA), and 2 µL of template DNA. All reactions were performed on an
264
Applied Biosystems StepOnePlus real-time PCR system (Life Technologies, Carlsbad, CA) as
265
previously described23 and were accompanied with a melt curve analysis to confirm the
266
specificity of qPCR products.
267
(Minimum Information for Publication of Quantitative Real-Time PCR Experiments) can be
268
found in Table S3.
Additional details following MIQE reporting requirements
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RESULTS AND DISCUSSION
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1,4-Dioxane Degradation in the Absence of Co-contaminant. Investigations on
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coupled electrochemical and biological treatment of 1,4-dioxane were performed at flow rates of
274
1.07 mL/min, or seepage velocity of 46 cm/d, in sand-packed flow-through column reactors
275
equipped with permeable Ti/IrO2-Ta2O5 mesh electrodes (Figure 1). In non-bioaugmented
276
(“abiotic”) reactors at 3.0 V and 8.0 V in the absence of TCE, only 14.6 and 11.7 mg 1,4-dioxane
277
were oxidized per hour per m2 of electrode surface area, respectively (uncertainty of ± 13.9 mg·h-
278
1
279
with electrochemical oxidation, additional electrode pairs would need to be added sequentially
280
down the flow path to increase hydraulic retention time and improve overall degradation
281
capacity. Although higher concentrations of reactive •OH radicals would be generated at 8.0 V
282
(2.34 mA/cm2) than at 3.0 V (0.20 mA/cm2), these two voltage applications for non-
·m-2, Figure 2). Thus, in a full-scale application treating high contaminant concentrations only
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283
bioaugmented columns exhibited an insignificant difference in degradation rate (p = 1.0). The
284
reason for 8.0 V producing equal (or slightly lower than 3.0 V) removal rates can be justified by
285
the overall reaction rate being controlled by mass transfer setting the upper constraint on
286
degradation rate. The limitation on oxidation of 1,4-dioxane by •OH radicals on, or very near, the
287
electrode surface is compounded in the 8.0 V reactor by more pronounced visible coverage of the
288
mesh electrodes with gas bubbles, thereby reducing hydraulic conductivity and creating
289
preferential flow paths.32,51,52
290
291 292 293 294 295 296 297 298
Figure 2. 1,4-Dioxane degradation rates for non-bioaugmented and P. dioxanivorans CB1190 bioaugmented reactors in the absence (striped) and presence (solid) of TCE co-contaminant (n ≥ 3). The percentage of TCE removed during the mixed co-contaminant experiments is represented by the shaded region of the pie charts above the corresponding bar plot. Error bars of ±13.9 mg·h1 ·m-2 were generated by transforming a precision calculation of the mean absolute deviation for instrumental measurements of influent 1,4-dioxane concentrations (calculations shown in Table S1). 12 ACS Paragon Plus Environment
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299
For bioaugmented experiments, the sand was inoculated with “active” CB1190
300
transferred at, or near, peak population density and activity, as described in the Materials and
301
Methods section. In the CB1190 bioaugmented control column (no voltage) with degassed
302
feedstock (initial DO of 3.0 ± 0.1 mg/L, ORP of 0.98 V vs. SHE), a 1,4-dioxane degradation rate
303
of 68.7 mg·h-1·m-2 was observed, about 5 times faster than in either non-bioaugmented
304
electrolytic column, and demonstrating that the microaerophilic CB1190 has the capacity to
305
metabolize 1,4-dioxane even at hypoxic DO levels (~2-3 mg/L). However, previous
306
investigations have shown that the 1,4-dioxane biodegradation capacity of CB1190 would cease
307
in a purely anoxic environment. When electrolysis and biodegradation processes were combined,
308
degradation rates substantially increased in an over-additive manner to 169 mg·h-1·m-2 at 3.0 V
309
and 101 mg·h-1·m-2 at 8.0 V. This degradation rate of 169 mg·h-1·m-2 in the bioaugmented reactor,
310
the highest achieved in this study, was 12 times higher than non-bioaugmented 3.0 V electrolysis,
311
15 times higher than non-bioaugmented 8.0 V electrolysis, and 2.5 times higher than the
312
bioaugmented control reactors without applied potential. The improvement of electro-
313
biodegradation rates over biotic treatment alone would be expected to be even greater had we
314
been able to achieve maintain completely anoxic conditions in preparing the feedstock solutions.
315
The dramatic increase in 1,4-dioxane removal rate has to be attributed to anodic O2 generation
316
resulting in an advantageous environment for aerobic biodegradation processes42 since the
317
coupled treatment regime at 3.0 V performed significantly better than either treatment on its own.
318
The manifestation of a highly oxidative environment was evidenced by the considerable
319
generation of O2 gas bubbles at the anode and by elevated solution ORP measurements at the
320
anode of 1.8 V and 4.4 V vs. SHE for the electro-bioreactors at 3.0 and 8.0 V, respectively (Table
321
1). We were unable to perform DO measurements in these reactors; however, DO concentrations
322
measured in analogous bioaugmented reactors with TCE present exhibited extraordinarily high
323
concentrations of 11.0 and 15.7 mg/L at 3.0 and 8.0 V, respectively (Table S2). Since ORP
324
measurements in Table 1 show comparable mean values near 1.7 ± 0.3 V for all experiments with
325
3.0 V applied, it is reasonable to use ORP as a proxy for revealing dissolved oxygen shifts and
326
assume that all 3.0 V reactors generated DO concentrations in the range of 5 to 11 mg/L. Hence,
327
by providing O2 as a terminal electron acceptor for aerobic metabolism, concurrent electrolysis
328
and biodegradation processes outperformed the degradation efficiencies of all other regimes
329
tested. 13 ACS Paragon Plus Environment
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Table 1. Physicochemical parameters measured along the column flow path. Data is divided into 1,4-dioxane degradation experiments conducted without TCE (a) and with 5 mg/L of TCE cocontaminant (b).
333 (a)
Non-bioaugmented, 1,4-dioxane (-) TCE Sample port
2
3V and 0.2 mA/cm *
Bioaugmented with CB1190, 1,4-dioxane (-) TCE
2
2
8V and 2.3 mA/cm
0V and 0 mA/cm
2
3V and 0.3 mA/cm
2
8V and 1.6 mA/cm
distance downgradient
pH
ORP (V)
pH
ORP (V)
pH
ORP (V)
pH
ORP (V)
pH
ORP (V)
influent
7.0
0.6
7.0
0.6
6.8
0.7
6.8
0.98 ± 0.5
6.8
0.98 ± 0.5 4.4
S1 = 2.5 cm
8.4 ± 3.1
1.6
9.1 ± 2.9
4.2
6.8
0.3
4.7
1.8
3.1 ± 0.8
S2 = 12.5 cm
6.9
-1.0
6.8
-1.1
6.8
0.1
6.5
0.1
5.8
0.0
S3 = 22.5 cm
7.0
0.1
6.9
-0.1
6.8
-0.2
6.7
0.1
6.3
-0.2
effluent =32.5 cm
6.9
0.3
6.8
0.1
-0.2
6.8
0.2
6.3
0.2
standard deviation**
± 0.3
± 0.05
± 0.3
± 0.05
6.8 ± 0.3
± 0.2
± 0.3
± 0.2
± 0.3
± 0.3
(b)
Non-bioaugmented, 1,4-dioxane (+) TCE Sample port
distance downgradient
2
3V and 0.2 mA/cm * pH
ORP (V)
Bioaugmented with CB1190, 1,4-dioxane (+) TCE 2
0V and 0 mA/cm2
8V and 1.2 mA/cm pH
ORP (V)
pH
ORP (V)
3V and 0.2 mA/cm2 pH
ORP (V)
8V and 1.1 mA/cm2 pH
ORP (V)
influent
7.0
0.6
7.0
0.6
7.0
0.5
7.0
0.5
7.0
0.5
S1 = 2.5 cm
6.5 ± 1.7
1.7
2.3 ± 0.5
3.7
7.0
0.2
7.3 ± 0.6
1.6
5.3
S2 = 12.5 cm
7.5 ± 1.7
0.0
9.0
-0.2
7.0
-0.1
7.0
0.1
12.0 11.3 ± 1.2
S3 = 22.5 cm
7.0
0.2
6.8 ± 0.5
0.3
7.0
-0.1
7.0
0.3
9.5 ± 0.9
0.4
effluent =32.5 cm standard deviation**
6.6
0.3
±0.3
± 0.03
5.5 ± 0.3
0.0
0.4
7.0
-0.1
7.0
0.7
4.2
0.8
± 0.2
±0.3
± 0.1
± 0.3
± 0.2
± 0.3
± 0.4
ORP, oxidation reduction potential vs. SHE (standard hydrogen electrode) *all current densities are averages of n =3, with uncertainties less than ± 0.01 mA/cm2 **the standard deviation (n=3) is explicitly written for measurements when exceeding the common one shown below each column
334
335
Although electrolysis provides O2 necessary for aerobic biodegradation, electrochemical
336
processes may also cause cellular death associated with the production of biologically destructive
337
hydroxyl radicals (SI, Reactions 1 to 6)53 or highly oxidized chlorine species (e.g., hypochlorous
338
acid) and other DBPs.37,54 In addition, considerable pH fluctuations near the electrodes may be
339
harmful to microbial populations as well. Electrolysis commonly produces an acidic boundary
340
layer at the anode surface due to the oxidation of water molecules to form H+ ions, and more
341
alkaline conditions surround the cathode due to H+ reduction to H2 gas and production of OH-
342
ions in solution.55 Hence, it was important that we investigated the impacts of these potentially
343
adverse conditions on the viability of CB1190 by analyzing both liquid (planktonic) and
344
solid/sand (biofilm) aliquots at various positions along the column reactor to locate zones of
345
microbial inhibition or proliferation adjacent to, or downstream of, the anode. Quantitative PCR 14 ACS Paragon Plus Environment
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346
data on the dxmB gene biomarker was used as a proxy for CB1190 cell abundance to elucidate
347
preferential location(s) of microbial proliferation, either in biofilm or planktonic forms, leading
348
to a better understanding of optimum spacing between multiple electrode pairs or reactor
349
dimensions.
350
Upon CB1190 inoculation of the sand used in columns for the 0 V, 3.0 V and 8.0 V
351
treatments of 1,4-dioxane in the absence of TCE, initial measurements of mean abundance values
352
after packing the reactors were 4.1×108 cells/mL for planktonic form and 1.3×107 cells/g for
353
CB1190 present as biofilm on sand particles (Figure 3 a,b). These levels are thought to represent
354
maximum population density achievable on this sand media since the cultures were growing
355
under ideal conditions up until this point. Considering the total volume of water and total mass of
356
sand in the reactors, we note that similar to previous reports,56 the planktonic biomass was equal
357
to or slightly greater than biofilm-associated biomass.
358
After two weeks of flow-through operation in the biological control (0 V) reactor, the pH
359
remained stable at 6.8, the planktonic CB1190 abundances dropped from 3.7×108 cells/mL at
360
port L1 to 1.0×107 at the effluent site down gradient. The biofilm levels also dropped by two
361
orders of magnitude down to 1.5×105and 2.1×105 cells/g at solid sample ports S3 and S5,
362
respectively. Thus, CB1190 growth rates were at least sufficient enough to overcome the steady-
363
state biomass losses of 1.0×107 cells/mL measured in the effluent caused by hydraulic shear
364
forces.57 Although these losses in microbial populations were observed, the remaining CB1190
365
was in quantities high enough to produce the 1,4-dioxane biodegradation rate observed here of
366
68.7 mg·h-1·m-2.18,22 Table 1 shows that ORP values along the column were steadily decreasing
367
from 0.7 to -0.2 V vs. SHE, likely due to biochemical oxygen demand for CB1190’s cellular
368
respiration. This decrease in CB1190 communities correlated to more negative ORP levels would
369
add credence to the need for adding charged electrodes to generate beneficial oxygen
370
downgradient.
371
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372 373 374 375 376 377 378 379 380
Figure 3. P. dioxanivorans CB1190 bioaugmented plots showing planktonic abundance (a,c) and biofilm abundance (b,d) of CB1190 cells along the horizontal flow path in the absence (a,b) and presence (c,d) of TCE co-contaminant, plotted as a function of distance from the anode. Sampling ports 1, 2, 3 and effluent correspond to 2.5, 12.5, 22.5 and 32.5 cm downstream from the anode. Any samples that were below the qPCR method limits of detection (LOD), 10 cells/mL for liquid samples and 40 cells/g for solid samples, were plotted just below LOD line. The error bars represent the average range of qPCR duplicates (2 analytical replicate analyses of each duplicate sample).
381 382
At the low stimulation voltage of 3.0 V, ORP levels reached 1.8 V vs SHE and pH levels
383
dropped to 4.7 between the electrodes, which is near the growth range previously reported for
384
CB1190 from pH 5.0 - 8.0.17 After the cathode, the pH rapidly returned to the starting influent
385
pH of 6.8 (Table 1).
386
experimental and modeling studies have demonstrated that their high reactivity limits their
387
existence to a narrow zone of less than 1 µm from the anode surface.55,58-60 Consequently, any
Although free radicals like •OH can be damaging to cellular life,53
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388
adverse conditions caused by the presence of •OH are only expected in the immediate vicinity of
389
the anode. Despite these risks, high mean planktonic abundances near 1.5×108 cells/mL along the
390
reactor flow path revealed that the overall conditions remained conducive to cellular growth
391
(Figure 3 a,b) and reported greater overall 1,4-dioxane degradation rates than biological control
392
rates. Our measurements revealed that CB1190 populations were not homogenous at different
393
distances from the anode. At sample port 1, between the electrodes, biofilm counts were below
394
the qPCR detection limit (BDL, < 40 cells/g); and planktonic cell counts dropped slightly from
395
4.1×108 initially to 6.8×107 cells/mL after equilibrating to the 3.0 V system for two weeks. The
396
subsequent CB1190 population rebound to 3.0×108 planktonic cells/mL and 1.3×107 sessile
397
cells/g at the location 12.5 cm downstream of the anode reveals a possible “sweet spot” for
398
bacterial proliferation along the flow path where dissolved oxygen is still abundant (likely in the
399
4 - 7 mg/L range) and the distance away from the electrodes was sufficient to avoid deleterious
400
effects. Physicochemical measurements in Table 1 show both locations 12.5 and 22.5 cm
401
downstream of the anode support this hypothesis in that solution ORP was 0.1 V vs SHE and the
402
pH returned to circumneutral (6.5-6.7). Biofilms are dynamic microbial communities capable of
403
interchangeable transitions between sessile and planktonic modes of growth as a response to
404
different environmental cues, including carbon source, oxygen saturation and pH of the
405
media.61,62 The existence of localized maximum cell counts of both biofilm and planktonic forms
406
could indicate that environmentally-tolerant biofilms may be the foundation of a stable CB1190
407
microbial community, with dispersed planktonic cells primarily responsible for higher rates of
408
carbon (1,4-dioxane and transformation products) metabolism. This type of survival strategy has
409
been documented in other bacteria and could warrant further study into the predominance of the
410
role played by these planktonic CB1190 cells dispersed from densely packed and specialized
411
biofilm subpopulations.63,64
412
When a higher potential of 8.0 V was applied, an elevated solution ORP of 4.4 V vs.
413
SHE was measured after the anode, which can be explained by the expected increase in anodic
414
generation of O2 and other reactive oxygen species (ROS) due to the higher voltage and current
415
density.55 We hypothesized that this occurrence, in combination with a drastic drop in pH from
416
6.8 to 3.1, could create conditions less hospitable for microbial growth and/or survival. This was
417
confirmed with measurements between the electrodes showing biofilm levels dropped to below
418
the qPCR detection limit and a substantial 4 order of magnitude decrease in planktonic 17 ACS Paragon Plus Environment
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419
abundance was observed as well (Figure 3 a,b). And although planktonic cells did rebound to
420
2.3×108 cells/mL 12.5 cm downstream from the anode, biofilm counts remained below LOD for
421
the remainder of the column. Thus, the decline in both life cycle modes of CB1190 communities
422
in the 8.0 V column is understood to be the principal reason for why lower overall 1,4-dioxane
423
degradation rates were obtained from the 8.0 V column compared with the 3.0 V column. In
424
addition, the lower degradation rates provide further support for the probable necessity of a
425
critical mass of biofilm being present, acting as a base for planktonic dispersal, in order for
426
optimal degradation rates to be achieved.
427
Finally, we note that ~104 counts (3.0 V) and ~102 counts (8.0 V) of dxmB genes were
428
detected in the non-bioaugmented reactor experiments (Figure S4). However, these data points
429
may be due to the fact that non-bioaugmented experiments were performed after augmented ones
430
for logistical reasons. Thus, we suspect that these detections are the result of extracellular DNA
431
released from lysed CB1190 cells during the column disinfection and sand heat-sterilization
432
process.
433
TCE Co-contaminant Impact on 1,4-Dioxane Degradation. Non-bioaugmented
434
electrolytic experiments performed in the presence of TCE co-contaminant (Figure 2) exhibited
435
1,4-dioxane degradation rates of 0.06 ± 13.9 mg·h-1·m-2 at 3.0 V (maximum ORP 1.7 V vs. SHE)
436
and 6.4 ± 13.9 mg·h-1·m-2 at 8.0 V (maximum ORP 3.7 V vs. SHE). These outcomes were not
437
significantly different from each other (p = 1.0), nor were they significantly different from
438
equivalent experiments spiked solely with 1,4-dioxane (p = 0.79 at 3.0 V, p = 0.92 at 8.0 V)
439
because rates of abiotic (electrolytic) 1,4-dioxane removal were controlled by mass transfer.58,65
440
In addition, 1.4 mg/L TCE (27% of the initial 5 mg/L) was removed at 3.0 V and 3.0 mg/L TCE
441
(60%) at 8.0 V (Figure 2 and Figure S5), showing higher electrolytic removal than for 1,4-
442
dioxane. This is expected because 1,4-dioxane degradation rates are limited to anode-generated
443
•
444
in addition to reductive dechlorination by direct electron transfer at the cathode. Additionally,
445
overall degradation kinetics for TCE can be enhanced by favorable surface chemistry interactions
446
with IrO2 electrode surfaces.47 GC/MS(SIM) analysis of effluent did not detect any DCE isomer
447
or vinyl chloride intermediates. Furthermore, no other organic transformation products appeared
448
as new chromatographic peaks in GC/MS full scan analysis, signifying that TCE was
449
mineralized, or volatilized/stripped by the effervescent oxygen and hydrogen gas bubbles.
OH radical oxidation pathways, whereas oxidation of TCE can occur via •OH radical pathways
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450
Previous studies on the electrochemical treatment of TCE have reported carbon dioxide, carbon
451
monoxide, chloride, formate, acetate, and chloroxyanions as stable products, but failed to detect
452
organochlorine intermediates, indicating that these may be too short-lived to accumulate in the
453
bulk solution.27,35
454
In the 0 V biological control column at 46 cm/d flow velocity, the addition of 5 mg/L
455
TCE to the 100 mg/L 1,4-dioxane feedstock lowered 1,4-dioxane biodegradation rates from 68.7
456
mg·h-1·m-2 (in the absence of TCE) to 37.5 mg·h-1·m-2 (Figure 2). This outcome is supported by
457
previously mentioned studies that show inhibitory effects of TCE on the biodegradation rates of
458
CB1190.22 Steady-state analysis revealed that no TCE removal had occurred, confirming
459
previous reports that CB1190 is not capable of biodegrading TCE20 and serving as an
460
experimental control that sorption did not contribute to TCE removal from the aqueous phase
461
after steady-state flow-through conditions had been achieved. The pH of 6.8 remained constant
462
throughout the entire biological control column and the solution ORP decreased from 0.5 in the
463
influent down to -0.1 V vs. SHE, analogous to our earlier experiments performed in the absence
464
of TCE (Table 1).
465
In the mixed contaminant experiments, 1,4-dioxane oxidation rates were again highest
466
when both abiotic and biodegradation processes were combined, achieving rates of 98.4 mg·h-
467
1
468
was minor in non-bioaugmented experiments; thus, the vast majority of 1,4-dioxane oxidation
469
observed here can be attributed to electrolytic enhancement of aerobic biodegradation rates. The
470
improved treatment is understood to be the result of increased biodegradation kinetics stimulated
471
by anodic production of molecular oxygen and the simultaneous benefit from electrochemical
472
removal of the inhibitive TCE co-contaminant. This claim is supported by DO measurements. As
473
stated above, O2 concentrations between the electrodes at port L1 increased to 11.0 mg/L at 3.0 V
474
and 15.6 mg/L at 8.0 V compared to 2.4 mg/L in the hypoxic bioaugmented control column, and
475
remained above 6 mg/L throughout the entire column reactors, while the biological control
476
experiment showed steadily decreasing DO values down to 1.9 mg/L along the flow path (Table
477
S2). Although DO measurements were not made in the experimental treatments of 1,4-dioxane in
478
the absence of TCE, the similarly decreasing trend in ORP values correlated to distances farther
479
downstream of the electrodes (Table S2) would signify that DO concentrations would also
480
decrease downstream. However, it may be critically important to note that when TCE is present
·m-2 at 3.0 V and 94.5 mg·h-1·m-2 at 8.0 V. Abiotic electrochemical oxidation of 1,4-dioxane
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481
as an inhibitor to CB1190 metabolism, it appears that the decreased DO levels along the flow
482
path could cause the precipitous drop in planktonic populations to below 2.0×108 cells/mL
483
measured at the effluent ports in 0V, 3V and 8.0 V reactors (Figure 3 c). Therefore, in situ
484
treatment of hypoxic waters (e.g. groundwater and wastewater), with much longer hydraulic
485
retention times would benefit from repeating intervals of electrodes to maintain high levels of
486
dissolved oxygen and high biodegradation rates.
487
At the higher stimulation voltage (8.0 V), 3.1 mg/L (62%) of TCE was removed (Figure
488
2 and Figure S5), minimizing adverse effects on biodegradation by CB1190 such that 1,4-
489
dioxane removal rates were nearly equivalent to rates when TCE was not present (94.5 compared
490
to 101 mg·h-1·m-2, p = 0.90). The recovery in metabolic biodegradation rates observed here is
491
consistent with conclusions by Zhang and co-workers (2016) that inhibition was dose-dependent
492
and reversible once chlorinated compounds were removed.22 Despite the removal of 2.05 mg/L
493
TCE (41%) with 3.0 V applied, the remaining 2.9 mg/L TCE appeared to decrease 1,4-dioxane
494
biodegradation efficiency by 40% under these conditions. Overall, our data demonstrate that
495
aerobic biodegradation rates can be enhanced by upstream electrolysis, and that complete
496
removal of TCE is not required to obtain effective electro-biodegradation of 1,4-dioxane;
497
although more investigation is needed to better understand whether a certain low threshold
498
concentration for TCE relative to CB1190 abundance may be needed to eliminate any noticeable
499
inhibition effects.
500
Adverse microbial impacts are observed with the presence of TCE since qPCR analyses
501
for the bioaugmented experiments revealed that mean planktonic cell counts under all voltage
502
conditions were generally orders of magnitude lower than comparable experiments in the absence
503
of TCE (Figure 3 a-d, Table S4).20-22 In contrast, the mean biofilm counts in the presence of TCE
504
tended to be higher than mean values when TCE was not present, possibly indicating a stress
505
response to toxicity posed by the presence of chlorinated solvents.66 Physicochemical
506
measurements also reinforced our expectation for less-viable conditions near the 8.0 V electrode.
507
For mixed contaminant experiments, the 8.0 V bioaugmented reactor recorded a highly oxidative
508
ORP of 5.3 V vs. SHE, along with highly alkaline pH levels of 12.0, 11.3 and 9.5 being
509
measured at 2.5, 12.5, and 22.5 cm downstream of the anode; whereas, in the 0 and 3.0 V
510
bioaugmented reactors the ORP values did not exceed 1.6 V vs. SHE and the pH remained
511
between 7.0 - 7.3 (Table 1). Much lower CB1190 planktonic abundance (5.2 x 103 cells/mL) was 20 ACS Paragon Plus Environment
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512
observed between the electrodes when 8.0 V was applied, when compared to the 0 V (1.7 x 105
513
cells/mL) and 3.0 V (1.6 x 105 cells/mL) treatments (Figure 3 c,d). Thus, it is plausible that
514
sparse CB1190 populations in the 8.0 V experiment are caused by TCE inhibition of
515
growth/metabolism compounded by the rapid increase in pH and ORP levels, and potential for
516
greater abundance of reactive oxygen species.18 The high pH level does not appear to be caused
517
by reaction pathways isolated to having TCE present, since both of the non-bioaugmented
518
experiments without TCE had alkaline pH values of 8.4 and 11.0 for 3.0 and 8.0 V, respectively.
519
Our experimental results were not able to produce a definitive trend or explanation for why some
520
experiments were acidic at the 2.5 cm sampling location while others were basic. Since the pH
521
continuum from the acidic anode to the alkaline cathode just 5.0 cm away is very steep
522
(especially with higher voltages), it is conceivable that variability in flow and/or mixing in the
523
inter-electrode space could contribute to the range of pH values observed. It is also feasible that
524
a high inter-electrode pH may arise when CO2 gas, present in the influent or generated from
525
organic carbon mineralization, is effervescently released through the gas vents at the acidic
526
anodes, and thus no longer has the buffering capacity provided by carbonic acid.
527
The sessile CB1190 counts for bioaugmented columns at 0 V and 3.0 V were able to
528
maintain dense biofilms between the electrodes, measuring 3.4 x 107 and 2.1 x 106 cells/g,
529
respectively. The higher biofilm counts relative to the planktonic counts in this region between
530
the electrodes can be explained by biofilms generally having a greater ability to withstand pH
531
changes and short-lived reactive oxygen species.67 The aqueous conditions within the 8.0 V
532
experiment appear to have been too harsh to establish stable biofilm communities, such that
533
sessile counts were below LOD between the electrodes (and at 22.5 cm downstream) with
534
biofilm counts only being observed at the 12.5 cm “sweet spot” reaching 2.3 x 106 cells/g (Figure
535
3 d). This becomes a disadvantage if biodegradation activity is dependent on newly dispersed
536
planktonic cells from biofilms as the primary source of active cells. Interestingly, there was a
537
substantial spike in sessile cell abundance at 12.5 cm downstream experienced in both the 3.0
538
and 8.0 V electro-bioreactors, reaching 107-108 cells/g. This would lend further support to our
539
“sweet spot” hypothesis for optimum bacterial growth. Based upon the consistency of the
540
location of peak sessile cell counts just downstream of the electrodes, it appears that biofilm
541
formation is being used as a strategy of colonization in a nutrient-dense (1,4-dioxane carbon
542
source), oxygen-enriched, and circumneutral pH region (usually pH 6.4 ± 0.6), where dispersion 21 ACS Paragon Plus Environment
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543
of actively metabolizing planktonic cells can then occur, providing the majority of observable
544
biodegradation.67
545
Technological
Implications.
Our
results
demonstrate
that
the
coupling
of
546
electrochemical oxidation with aerobic biodegradation is an effective, synergistic approach for
547
the treatment of waters contaminated with 1,4-dioxane, and may provide an effective solution to
548
the problems associated with co-occurring inhibitors. We did not experience clogging in any of
549
the experiments, indicating that bioaugmentation of aquifers with CB1190 is a viable strategy.
550
Successful establishment of CB1190 biofilm is expected to be possible in a range of flow
551
regimes. Although tests at different flow rates were outside the scope of this study, other research
552
results have shown that bacterial biofilm thickness and survivability did not change significantly
553
with altered flow rates.57,68 In the absence of a co-contaminant, where the enhancement is mainly
554
based on oxygen generation, low voltages (i.e., 3.0 V) slightly above the oxygen evolution
555
potential of the electrode are preferable to avoid extreme pH and redox conditions unfavorable
556
for microbial growth, and may be a viable strategy to limit DBP formation. Furthermore, lower
557
voltages are preferable due to longer electrode service life, reduced power cost, and more
558
uniform flow with less gas bubbles.37,54,55
559
When microbially-inhibiting co-contaminants such as TCE are present, more electrodes
560
may be required in order to mineralize or transform the additional contaminants into less toxic or
561
more readily biodegradable intermediates.33,69 If the chlorinated co-contaminants are not fully
562
removed during electrolytic treatment, a subsequent reductive treatment step may be effective,
563
which could also aid in the removal of any generated DBPs.70
564
This study provides convincing evidence that 1,4-dioxane metabolism by CB1190 can be
565
electrochemically enhanced despite the production of strong oxidants at the anode. Our data
566
suggest that microbial abundance is lowest between the electrodes, likely due to destructive
567
effects of short-lived chemical oxidants, and highest just downstream of the trailing cathode (near
568
12.5 cm downstream of the anode) where dissolved oxygen concentrations stimulate microbial
569
metabolism. Thus, microbial populations are able to thrive downstream of the electrodes, and the
570
generation of strong oxidants (e.g., •OH) can provide significant concomitant benefits of
571
oxidizing recalcitrant and/or toxic co-pollutants in addition to 1,4-dioxane.
572
For technology implementation, specific aquifer conditions (e.g., contaminant
573
concentrations, water quality parameters, soil composition, and indigenous microbial 22 ACS Paragon Plus Environment
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Environmental Science & Technology
574
communities) or wastewater composition need to be taken into consideration and tested to
575
validate contaminant degradation efficiencies. These preliminary test results and specific
576
treatment targets would guide decisions regarding the number of sequential electrodes required
577
(more electrode surface area for more contaminant mass removal), but our results suggest that
578
sufficient spacing between electrode pairs should be arranged to promote maximum microbial
579
activity in the favorable downstream conditions. It is conceivable that additional synergistic
580
mechanisms could also be promoted, such as stimulation of other intrinsic microbes capable of
581
metabolizing transformation products and co-contaminant parent compounds71 or electrolytic
582
transformation
of
a
27,33,72-74
persistent
parent
compound
into
more
readily
biodegradable
583
intermediates.
Although other mixed contaminants waters were not explored in this
584
study, the capability of this technology being effective in a flow-through system could lend itself
585
to feasible treatment applications for landfill leachate, domestic wastewater, and industrial
586
effluent as well.69,75 The joint benefits of having tunable electrolysis to degrade recalcitrant
587
pollutants while simultaneously supporting intrinsic or augmented contaminant-degraders may be
588
one innovative approach needed to overcome the technological and cost limitations faced when
589
treating waters with mixed, persistent contaminants.
590 591 592 593
AUTHOR INFORMATION
594
Corresponding Author* E-mail:
[email protected]. Phone: +1-970-491-8880. Fax:
595
+1-970-491-8224.
596
Notes: The authors declare no competing financial interest.
597 598 599
ACKNOWLEDGMENTS
600
Funding for this work was provided by The Chemours Company (to J.B.), E. I. du Pont de
601
Nemours and Company (to J.B. and contract no. MA-03653-13 to S.M.) and The Dow Chemical
602
Company (contract no. 244633 to S.M.). We thank Maria Irianni-Renno for assistance with ATP
603
analysis, and Michelle Myers and Shu Zhang for assisting with DNA extractions.
604 23 ACS Paragon Plus Environment
Environmental Science & Technology
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605
ASSOCIATED CONTENT
606
Supporting Information. The Supporting Information is available free of charge on the ACS
607
Publications website at DOI: …
608
It includes schematics and photos of the experimental design, details on analytical procedures
609
and CB1190 inoculation procedures, and calculations used to determine flow-through
610
degradation rates and instrumental uncertainty. Additional plots and tables show TCE removal,
611
DO measurements, and pH values along the column reactor path.
612 613 614
REFERENCES
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(1) Mohr, T. K.; Stickney, J. A.; DiGuiseppi, W. H. Environmental investigation and remediation: 1,4dioxane and other solvent stabilizers. CRC Press: Boca Raton, FL, 2010. (2) USEPA. United States Environmental Protection Agency. Technical fact sheet--1,4-dioxane. Office of solid waste and emergency response. 2014, EPA-505-F-14-011. (3) Adamson, D. T.; Mahendra, S.; Walker, K. L.; Rauch, S. R.; Sengupta, S.; Newell, C. J. A multisite survey to identify the scale of the 1,4-dioxane problem at contaminated groundwater sites. Environmental Science & Technology Letters 2014, 1, 254-258. (4) Chiang, S. Y. D.; Mora, R.; Diguiseppi, W. H.; Davis, G.; Sublette, K.; Gedalanga, P.; Mahendra, S. Characterizing the intrinsic bioremediation potential of 1,4-dioxane and trichloroethene using innovative environmental diagnostic tools. Journal of Environmental Monitoring 2012, 14, 2317-2326. (5) Anderson, R. H.; Anderson, J. K.; Bower, P. A. Co-occurrence of 1,4-dioxane with trichloroethylene in chlorinated solvent groundwater plumes at us air force installations: Fact or fiction. Integrated Environmental Assessment and Management 2012, 8, 731-737. (6) Zenker, M. J.; Borden, R. C.; Barlaz, M. A. Occurrence and treatment of 1,4-dioxane in aqueous environments. Environmental Engineering Science 2003, 20, 423-432. (7) Isaka, K.; Udagawa, M.; Sei, K.; Ike, M. Pilot test of biological removal of 1,4-dioxane from a chemical factory wastewater by gel carrier entrapping Afipia sp. Strain d1. Journal of Hazardous Materials 2016, 304, 251-258. (8) Han, T. H.; Han, J. S.; So, M. H.; Seo, J. W.; Ahn, C. M.; Min, D. H.; Yoo, Y. S.; Cha, D. K.; Kim, C. G. The removal of 1,4-dioxane from polyester manufacturing process wastewater using an up-flow biological aerated filter (UBAF) packed with tire chips. Journal of Environmental Science and Health Part a-Toxic/Hazardous Substances & Environmental Engineering 2012, 47, 117-129. (9) Stefan, M. I.; Bolton, J. R. Mechanism of the degradation of 1,4-dioxane in dilute aqueous solution using the UV hydrogen peroxide process. Environmental Science & Technology 1998, 32, 1588-1595. (10) Coleman, H. M.; Vimonses, V.; Leslie, G.; Amal, R. Degradation of 1,4-dioxane in water using TiO2 based photocatalytic and H2O2/UV processes. Journal of Hazardous Materials 2007, 146, 496-501. (11) Maurino, V.; Calza, P.; Minero, C.; Pelizzetti, E.; Vincenti, M. Light-assisted 1,4-dioxane degradation. Chemosphere 1997, 35, 2675-2688. (12) Canizares, P.; Paz, R.; Saez, C.; Rodrigo, M. A. Costs of the electrochemical oxidation of wastewaters: A comparison with ozonation and fenton oxidation processes. Journal of Environmental Management 2009, 90, 410-420. (13) Mahendra, S.; Alvarez-Cohen, L. Kinetics of 1,4-dioxane biodegradation by monooxygenaseexpressing bacteria. Environmental Science & Technology 2006, 40, 5435-5442.
24 ACS Paragon Plus Environment
Page 25 of 28
648 649 650 651 652 653 654 655 656 657 658 659 660 661 662 663 664 665 666 667 668 669 670 671 672 673 674 675 676 677 678 679 680 681 682 683 684 685 686 687 688 689 690 691 692 693 694 695 696 697
Environmental Science & Technology
(14) Vainberg, S.; McClay, K.; Masuda, H.; Root, D.; Condee, C.; Zylstra, G. J.; Steffan, R. J. Biodegradation of ether pollutants by Pseudonocardia sp. strain ENV478. Applied and Environmental Microbiology 2006, 72, 5218-5224. (15) Lan, R. S.; Smith, C. A.; Hyman, M. R. Oxidation of cyclic ethers by alkane-grown Mycobacterium vaccae JOB5. Remediation Journal 2013, 23, 23-42. (16) Nakamiya, K.; Hashimoto, S.; Ito, H.; Edmonds, J. S.; Morita, M. Degradation of 1,4-dioxane and cyclic ethers by an isolated fungus. Applied and Environmental Microbiology 2005, 71, 1254-1258. (17) Parales, R. E.; Adamus, J. E.; White, N.; May, H. D. Degradation of 1,4-dioxane by an actinomycete in pure culture. Applied and Environmental Microbiology 1994, 60, 4527-4530. (18) Mahendra, S.; Alvarez-Cohen, L. Pseudonocardia dioxanivorans sp nov., a novel actinomycete that grows on 1,4-dioxane. International Journal of Systematic and Evolutionary Microbiology 2005, 55, 593598. (19) Sekar, R.; DiChristina, T. J. Microbially driven fenton reaction for degradation of the widespread environmental contaminant 1,4-dioxane. Environmental Science & Technology 2014, 48, 12858-12867. (20) Mahendra, S.; Grostern, A.; Alvarez-Cohen, L. The impact of chlorinated solvent co-contaminants on the biodegradation kinetics of 1,4-dioxane. Chemosphere 2013, 91, 88-92. (21) Hand, S.; Wang, B. X.; Chu, K. H. Biodegradation of 1,4-dioxane: Effects of enzyme inducers and trichloroethylene. Science of the Total Environment 2015, 520, 154-159. (22) Zhang, S.; Gedalanga, P. B.; Mahendra, S. Biodegradation kinetics of 1,4-dioxane in chlorinated solvent mixtures. Environmental Science & Technology 2016, 50, 9599–9607. (23) Gedalanga, P. B.; Pornwongthong, P.; Mora, R.; Chiang, S.-Y. D.; Baldwin, B.; Ogles, D.; Mahendra, S. Identification of biomarker genes to predict biodegradation of 1,4-dioxane. Applied and Environmental Microbiology 2014, 80, 3209-3218. (24) Adamson, D. T.; Anderson, R. H.; Mahendra, S.; Newell, C. J. Evidence of 1,4-dioxane attenuation at groundwater sites contaminated with chlorinated solvents and 1,4-dioxane. Environmental Science & Technology 2015, 49, 6510-6518. (25) Gedalanga, P.; Madison, A.; Miao, Y. R.; Richards, T.; Hatton, J.; DiGuiseppi, W. H.; Wilson, J.; Mahendra, S. A multiple lines of evidence framework to evaluate intrinsic biodegradation of 1,4-dioxane. Remediation Journal 2016, 27, 93-114. (26) Li, M.; van Orden, E. T.; DeVries, D. J.; Xiong, Z.; Hinchee, R.; Alvarez, P. J. Bench-scale biodegradation tests to assess natural attenuation potential of 1,4-dioxane at three sites in california. Biodegradation 2015, 26, 39-50. (27) Chen, G.; Betterton, E. A.; Arnold, R. G. Electrolytic oxidation of trichloroethylene using a ceramic anode. Journal of Applied Electrochemistry 1999, 29, 961-970. (28) Sale, T.; Petersen, M.; Gilbert, D. Electrically induced redox barriers for treatment of groundwater; ESTCP Final Report CU-0112. U.S. Department of Defense: 2005. (29) Petersen, M. A.; Sale, T. C.; Reardon, K. F. Electrolytic trichloroethene degradation using mixed metal oxide coated titanium mesh electrodes. Chemosphere 2007, 67, 1573-1581. (30) Choi, J. Y.; Lee, Y. J.; Shin, J.; Yang, J. W. Anodic oxidation of 1,4-dioxane on boron-doped diamond electrodes for wastewater treatment. Journal of Hazardous Materials 2010, 179 (1-3), 762-768. (31) De Clercq, J.; Van de Steene, E.; Verbeken, K.; Verhaege, M. Electrochemical oxidation of 1,4dioxane at boron-doped diamond electrode. Journal of Chemical Technology and Biotechnology 2010, 85, 1162-1167. (32) Jasmann, J. R.; Borch, T.; Sale, T. C.; Blotevogel, J. Advanced electrochemical oxidation of 1,4dioxane via dark catalysis by novel titanium dioxide (TiO2) pellets. Environmental Science & Technology 2016, 50, 8817-8826. (33) Adams, C. D.; Scanlan, P. A.; Secrist, N. D. Oxidation and biodegradability enhancement of 1,4dioxane using hydrogen-peroxide and ozone. Environmental Science & Technology 1994, 28, 1812-1818. (34) Suh, J. H.; Mohseni, M. A study on the relationship between biodegradability enhancement and oxidation of 1,4-dioxane using ozone and hydrogen peroxide. Water Research 2004, 38, 2596-2604. 25 ACS Paragon Plus Environment
Environmental Science & Technology
698 699 700 701 702 703 704 705 706 707 708 709 710 711 712 713 714 715 716 717 718 719 720 721 722 723 724 725 726 727 728 729 730 731 732 733 734 735 736 737 738 739 740 741 742 743 744 745 746 747 748
(35) Carter, K. E.; Farrell, J. Electrochemical oxidation of trichloroethylene using boron-doped diamond film electrodes. Environmental Science & Technology 2009, 43, (21), 8350-8354. (36) Klecka, G. M.; Gonsior, S. J. Removal of 1,4-dioxane from waste-water. Journal of Hazardous Materials 1986, 13, 161-168. (37) Radjenovic, J.; Sedlak, D. L. Challenges and opportunities for electrochemical processes as nextgeneration technologies for the treatment of contaminated water. Environmental Science & Technology 2015, 49, 11292-11302. (38) Park, H.; Vecitis, C. D.; Hoffmann, M. R. Electrochemical water splitting coupled with organic compound oxidation: The role of active chlorine species. The Journal of Physical Chemistry C 2009, 113, 7935-7945. (39) Deborde, M.; Von Gunten, U. Reactions of chlorine with inorganic and organic compounds during water treatment - kinetics and mechanisms: A critical review. Water Research 2008, 42, 13-51. (40) Cho, K.; Hoffmann, M. R. Urea degradation by electrochemically generated reactive chlorine species: Products and reaction pathways. Environmental Science & Technology 2014, 48, 11504-11511. (41) Martinez-Huitle, C. A.; Andrade, L. S. Electrocatalysis in wastewater treatment: Recent mechanism advances. Quimica Nova 2011, 34, 850-858. (42) Sun, M.; Reible, D. D.; Lowry, G. V.; Gregory, K. B. Effect of applied voltage, initial concentration, and natural organic matter on sequential reduction/oxidation of nitrobenzene by graphite electrodes. Environmental Science & Technology 2012, 46, 6174-6181. (43) Sun, M.; Yan, F.; Zhang, R. L.; Reible, D. D.; Lowry, G. V.; Gregory, K. B. Redox control and hydrogen production in sediment caps using carbon cloth electrodes. Environmental Science & Technology 2010, 44, 8209-8215. (44) Fierro, S.; Nagel, T.; Baltruschat, H.; Comninellis, C. Investigation of the oxygen evolution reaction on Ti/IrO2 electrodes using isotope labelling and on-line mass spectrometry. Electrochemistry Communications 2007, 9, (8), 1969-1974. (45) Comninellis, C.; Kapalka, A.; Malato, S.; Parsons, S. A.; Poulios, L.; Mantzavinos, D. Advanced oxidation processes for water treatment: Advances and trends for R&D. Journal of Chemical Technology and Biotechnology 2008, 83, 769-776. (46) Bagastyo, A. Y.; Radjenovic, J.; Mu, Y.; Rozendal, R. A.; Batstone, D. J.; Rabaey, K. Electrochemical oxidation of reverse osmosis concentrate on mixed metal oxide (MMO) titanium coated electrodes. Water Research 2011, 45, 4951-4959. (47) Rodgers, J. D.; Jedral, W.; Bunce, N. I. Electrochemical oxidation of chlorinated phenols. Environmental Science & Technology 1999, 33, 1453-1457. (48) Xie, W.; Yuan, S.; Mao, X.; Hu, W.; Liao, P.; Tong, M.; Alshawabkeh, A. N. Electrocatalytic activity of Pd-loaded Ti/ TiO2 nanotubes cathode for TCE reduction in groundwater. Water Research 2013, 47, 3573-3582. (49) Sale, T.; Olson, M.; Gilbert, D.; Petersen, M. Field demonstration/validation of electrolytic barriers for energetic compounds at Pueblo Chemical Depot. ESTCP ER-0519. U.S. Department of Defense: 2010. (50) Mahendra, S.; Petzold, C. J.; Baidoo, E. E.; Keasling, J. D.; Alvarez-Cohen, L. Identification of the intermediates of in vivo oxidation of 1,4-dioxane by monooxygenase-containing bacteria. Environmental Science & Technology 2007, 41, 7330-7336. (51) Shah, A.; Jorne, J. Mass-transfer under combined gas evolution and forced-convection. Journal of the Electrochemical Society 1989, 136, 153-158. (52) Petersen, M. A.; Reardon, K. F. Effect of gas evolution on mixing and conversion in a flow-through electrochemical reactor. AICHE Journal 2009, 55, 2468-2476. (53) Cabiscol, E.; Tamarit, J.; Ros, J. Oxidative stress in bacteria and protein damage by reactive oxygen species. International Microbiology 2010, 3, 3-8. (54) Schaefer, C. E.; Andaya, C.; Urtiaga, A. Assessment of disinfection and by-product formation during electrochemical treatment of surface water using a Ti/IrO2 anode. Chemical Engineering Journal 2015, 264, 411-416. 26 ACS Paragon Plus Environment
Page 26 of 28
Page 27 of 28
749 750 751 752 753 754 755 756 757 758 759 760 761 762 763 764 765 766 767 768 769 770 771 772 773 774 775 776 777 778 779 780 781 782 783 784 785 786 787 788 789 790 791 792 793 794 795 796 797 798
Environmental Science & Technology
(55) Chaplin, B. P. Critical review of electrochemical advanced oxidation processes for water treatment applications. Environmental Science-Processes & Impacts 2014, 16, 1182-1203. (56) Sercu, B.; Jones, A. D. G.; Wu, C. H.; Escobar, M. H.; Serlin, C. L.; Knapp, T. A.; Andersen, G. L.; Holden, P. A. The Influence of In Situ Chemical Oxidation on Microbial Community Composition in Groundwater Contaminated with Chlorinated Solvents. Microbial Ecolology 2013, 65, 39-49. (57) Stewart, P. S. Mini-review: Convection around biofilms. Biofouling 2012, 28, 187-198. (58) Donaghue, A.; Chaplin, B. P. Effect of select organic compounds on perchlorate formation at boron-doped diamond film anodes. Environmental Science & Technology 2013, 47, 12391-12399. (59) Mascia, M.; Vacca, A.; Palmas, S.; Polcaro, A. M. Kinetics of the electrochemical oxidation of organic compounds at BDD anodes: Modelling of surface reactions. Journal of Applied Electrochemistry 2007, 37, 71-76. (60) Kapalka, A.; Fóti, G.; Comninellis, C. The importance of electrode material in environmental electrochemistry: Formation and reactivity of free hydroxyl radicals on boron-doped diamond electrodes. Electrochimica Acta 2009, 54, 2018-2023. (61) Gibbs, P. A.; Seviour, R. J. Does the agitation rate and/or oxygen saturation influence exopolysaccharide production by Aureobasidium pullulans in batch culture? Applied Microbiology and Biotechnology 1996, 46 (5-6), 503-510. (62) Uppuluri, P.; Chaturvedi, A. K.; Srinivasan, A.; Banerjee, M.; Ramasubramaniam, A. K.; Köhler, J. R.; Kadosh, D.; Lopez-Ribot, J. L. Dispersion as an important step in the Candida albicans biofilm developmental cycle. PLoS Pathog. 2010, 6, e1000828. (63) LaFleur, M. D.; Kumamoto, C. A.; Lewis, K. Candida albicans biofilms produce antifungaltolerant persister cells. Antimicrobial Agents and Chemotherapy 2006, 50, 3839-3846. (64) Pareilleux, A.; Sicard, N. Lethal effects of electric current on Escherichia coli. Applied Microbiology 1970, 19, 421. (65) Zaky, A. M.; Chaplin, B. P. Porous substoichiometric TiO2 anodes as reactive electrochemical membranes for water treatment. Environmental Science & Technology 2013, 47, 6554-6563. (66) Manefield, M.; Lee, M.; Koenig, J. The Nature and Relevance of Solvent Stress in Microbes and Mechanisms of Tolerance. In: Chénard C., Lauro F. (Eds.) Microbial Ecology of Extreme Environments. Springer, Cham, 2017. ISBN 978-3-319-51686-8. (67) Jefferson, K. K. What drives bacteria to produce a biofilm? Fems Microbiology Letters 2004, 236, 163-173. (68) Bishop, P.; Gibbs, J.; Cunningham, B. Relationship between concentration and hydrodynamic boundary layers over biofilms. Environmental Technology 1997, 18, 375-385. (69) Chu, Y. Y.; Zhu, M. H.; Liu, C. Electrochemical treatment of biotreated landfill leachate using a porous carbon nanotube-containing cathode: Performance, toxicity reduction, and biodegradability enhancement. Environmental Engineering Science 2015, 32, 445-450. (70) Schaefer, C. E.; Andaya, C.; Burant, A.; Condee, C. W.; Urtiaga, A.; Strathmann, T. J.; Higgins, C. P. Electrochemical treatment of perfluorooctanoic acid and perfluorooctane sulfonate: Insights into mechanisms and application to groundwater treatment. Chemical Engineering Journal 2017, 317, 424432. (71) Arp, D. J.; Yeager, C. M.; Hyman, M. R. Molecular and cellular fundamentals of aerobic cometabolism of trichloroethylene. Biodegradation 2001, 12, 81-103. (72) Tseng, N.; Wang, N.; Szostek, B.; Mahendra, S. Biotransformation of 6:2 fluorotelomer alcohol (6:2 FTOH) by a wood-rotting fungus. Environmental Science & Technology 2014, 48, 4012-4020. (73) Barndok, H.; Hermosilla, D.; Cortijo, L.; Torres, E.; Blanco, A. Electrooxidation of industrial wastewater containing 1,4-dioxane in the presence of different salts. Environmental Science and Pollution Research 2014, 21, 5701-5712. (74) Grostern, A.; Sales, C. M.; Zhuang, W. Q.; Erbilgin, O.; Alvarez-Cohen, L. Glyoxylate metabolism is a key feature of the metabolic degradation of 1,4-dioxane by Pseudonocardia dioxanivorans strain CB1190. Applied and Environmental Microbiology 2012, 78, 3298-3308. 27 ACS Paragon Plus Environment
Environmental Science & Technology
799 800
(75) Lenker, C.; Harclerode, M.; Aragona, K.; Fisher, A.; Jasmann, J.; Hadley, P. W. Integrating groundwater conservation and reuse into remediation projects. Remediation Journal 2014, 24, 11-27.
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