David Harper Isabelle M. Cozzarelli Douglas B. Kent Adam C. Mumford Denise M. Akob Travis W. Schaeffer Luke R. Iwanowicz Aida Farag 2022 <div id="Abs1-section" class="c-article-section c-article-content-visibility"><div id="Abs1-content" class="c-article-section__content"><p>A pipeline carrying unconventional oil and gas (OG) wastewater spilled approximately 11 million liters of wastewater into Blacktail Creek, North Dakota, USA. Flow of the mix of stream water and wastewater down the channel resulted in storage of contaminants in the hyporheic zone and along the banks, providing a long-term source of wastewater constituents to the stream. A multi-level&nbsp;investigation was used to&nbsp;assess&nbsp;the potential effects&nbsp;of&nbsp;oil&nbsp;and&nbsp;brine spills&nbsp;on aquatic life. In this study, we used a combination of experiments using a native fish&nbsp;species, Fathead Minnow (<i>Pimephales&nbsp;promelas</i>), field sampling of the microbial community structure, and measures of estrogenicity. The fish investigation included in situ experiments and experiments with collected site water. Estrogenicity was measured in collected site water samples, and microbial community analyses were conducted on collected sediments. During&nbsp;the initial post-spill investigation, February 2015, performing&nbsp;in situ fish bioassays was impossible because of ice conditions. However, microbial community&nbsp;(e.g., the presence of&nbsp;members of the&nbsp;Halomonadaceae, a family that is indicative&nbsp;of&nbsp;elevated salinity) and&nbsp;estrogenicity&nbsp;differences were compared to reference sites&nbsp;and point to&nbsp;early&nbsp;biological effects of the spill. We noted water column effects on in situ fish survival 6&nbsp;months post-spill during June 2015. At that time, total dissolved ammonium (sum of ammonium and ammonia, TAN) was 4.41&nbsp;mg&nbsp;NH₄/L with an associated NH₃&nbsp;of 1.09&nbsp;mg/L, a concentration greater than the water quality criteria established to protect aquatic life. Biological measurements in the sediment defined early and long-lasting effects of&nbsp;the spill on aquatic resources. The microbial community structure was&nbsp;affected during all sampling events. Therefore, sediment may act as a sink for constituents spilled and as such provide an indication of continued&nbsp;and cumulative&nbsp;effects post-spill. However, lack of later water column effects may reflect pulse hyporheic flow of ammonia from shallow ground water. Combining fish toxicological, microbial community structure&nbsp;and&nbsp;estrogenicity information&nbsp;provides a complete&nbsp;ecological&nbsp;investigation that defines potential influences&nbsp;of contaminants&nbsp;at&nbsp;organismal, population, and community levels. In general, in situ bioassays have implications for the individual&nbsp;survival&nbsp;and&nbsp;changes at the&nbsp;population level, microbial community structure defines potential changes at the community level, and&nbsp;estrogenicity&nbsp;measurements define changes at the&nbsp;individual and&nbsp;molecular&nbsp;level. By understanding effects at these various levels of biological organization, natural resource managers can interpret how a course of action, especially for remediation/restoration, might affect a larger group of organisms in the system. The current work also reviews potential effects of additional constituents defined during chemistry investigations on aquatic resources.</p></div></div> application/pdf 10.1007/s00244-022-00943-6 en Springer Using biological responses to monitor freshwater post-spill conditions over 3 years in Blacktail Creek, North Dakota, USA article