Spatiotemporal Trends Analysis of Pyrethroid Sediment Concentrations Spanning 10 Years in a Residential Creek in California

Aquatic Science Center (2012) The pulse of the delta: monitoring and managing water quality in the Sacramento and San Joaquin Delta. Rethinking water quality monitoring. Contribution 630. Aquatic Science Center, Oakland

Davidson PC, Jones RL, Harbourt CM, Hendley P, Goodwin G, Sliz BA (2014) Major transport mechanisms of pyrethroids in residential settings and effects of mitigation measures. Environ Toxicol Chem 33:52–60

Hall LW Jr, Anderson RD (2012) Historical trends analysis of 2004 to 2009 toxicity and pesticide data for Califonnia’s Central Valley. J Environ Sci Health A 47:801–811

Hall LW Jr, Anderson RD, Killen WD (2012a) Mapping the spatial extent of depositional areas in agricultural, urban and residential California streams: implications for pyrethroid toxicity. Hum Ecol Risk Assess 18:368–392

Hall LW Jr, Killen WD, Anderson RD (2012b) Mapping of depositional and non-depositional areas in Pleasant Grove Creek with concurrent pyrethroid and benthic macroinvertebrate assessments in 2012. Final report prepared for the Pyrethroid Working Group prepared by the University of Maryland, Wye Research and Education Center, Queenstown

Hall LW Jr, Anderson RD, Killen WD, Alden RW (2014a) A summary of case studies designed to determine the influence of multiple stressors on benthic communities in urban California streams. In: Jones RL, Shamim M, Jackson SH (eds) Describing the behavior and effects of pesticides in urban and agricultural settings. American Chemical Society, Washington, DC, pp 135–152

Hall LW Jr, Killen WD, Anderson RD, Alden RW (2014b) An assessment of benthic communities with concurrent physical habitat, pyrethroids, and metals analysis in Pleasant Grove Creek in 2014. Progress Report for the Pyrethroid Working Group prepared by the University of Maryland, Wye Research and Education Center, Queenstown

Hirsch RM, Slack JR, Smith RA (1982) Techniques of trend analysis for monthly water quality data. Water Resour Res 18:107–121

Howitt RD, MacEwan D, Medellin-Azuara J, Lund J, Sumner D (2015) Economic analysis of the 2015 drought for California agriculture. Report. University of California at Davis Center for Watershed Sciences, ERA Economics, UC Agricultural Issues Center, Davis

Jones RL, Davidson PC, Harbourt CM, Hendley P (2014) Factors affecting residential runoff transport of pyrethroids. In: Jones RL, Shamim M, Jackson SH (eds) Describing the behavior and effects of pesticides in urban and agricultural settings. American Chemical Society, Washington, DC, pp 13–25

Karickofff SW, Brown DS, Scott TA (1979) Sorption of hydrophobic pollutants on natural sediments. Water Res 13:241–248

Laskowski DA (2002) Physical and chemical properties of pyrethroids. Rev Environ Contam Toxicol 174:49–170

Luo Y (2014) Review of modeling approaches for pesticide washoff from impervious surfaces. In: Jones RM, Shamim M, Jackson SH (eds) Describing the behavior and effects of pesticides in urban and agricultural settings. American Chemical Society, Washington, DC, pp 65–68

Northern California Water Association Newsletter (2015) NCWA week in review. Sacramento, 24 Aug 2015

Puckett M (2002) Quality assurance management plan for the state of California’s surface water ambient monitoring program. Report prepared for California State Water Resources Control Board, Division of Water Quality, Sacramento

Reed RL (2006) Laboratory validation: validation of the residue analytical method: residue analytical for the determination of residues of bifenthrin, cypermethrin, cyfluthrin, deltamethrin, esfenvalerate, fenpropathrin, lambda-cyhalothrin and permethrin in sediment. Final Report. Protocol No. MLI-06-02. Morse Labs Project No. ML06-1286-PWG, Morse Laboratories, Inc., Sacramento

Shamim MT, Hoffmann MD, Melendez J, Ruhman MA (2008) Ecological risk characterization for synthetic pyrethroids. In: Gan J, Spurlock F, Hendley P, Weston D (eds) Synthetic pyrethroids: occurrence and behavior in aquatic environments. American Chemical Society, Washington, DC, pp 257–309

Siegler K, Phillips BM, Anderson BS, Voorhees JP, Tjeertdema RS (2015) Temporal and spatial trends in sediment contaminants associated with toxicity in California watersheds. Environ Pollut 206:1–6

Spurlock F, Lee M (2008) Synthetic pyrethroid use patterns, properties, and environmental effects. In: Gan J, Spurlock F, Hendley P, Weston D (eds) Synthetic pyrethroids: occurrence and behavior in aquatic environments. American Chemical Society, Washington, DC, pp 3–25

U.S. EPA (United States Environmental Protection Agency) (2004) SW-846, method 9060A: total organic carbon report. U.S. EPA Office of Water, Washington

Weston DP, Holmes RW, You J, Lydy MJ (2005) Aquatic toxicity due to residential use of pyrethroid insecticides. Environ Sci Technol 39:9778–9784

Weston DP, Holmes RW, Lydy MJ (2009) Residential runoff as a source of pyrethroid pesticides to urban creeks. Environ Pollut 157:287–294