These data describe the results of a controlled laboratory experiment evaluating the effect of pesticides on the development of zebrafish. Parameters described include the length of the fish and the pericardial area of the fish.

Figure S1: BMC curves. Table S1: Fish assessments. Table S2: Data to make visualization of toxicity (Figure 3). Table S3: Data to make BMC curves. This dataset is associated with the following publication: Britton, K., R. Judson, B. Hill, K. Jarema, J. Olin, B. Knapp, M. Lowery, M. Feshuk, J. Brown, and S. Padilla. Using Zebrafish to Screen Developmental Toxicity of Per- and Polyfluoroalkyl Substances (PFAS). Toxics. MDPI, Basel, SWITZERLAND, 12(7): 501, (2024).

These data consists of three related tables describing in-situ field conditions including pesticide concentration, water quality, and post-treatment survival of crayfish associated with the application of a pesticide to a stormwater retention pond and burrows to suppress or eradicate an invasive crayfish species, Procambarus clarkii, in support of high-priority research developing control methods to mitigate impacts of invasive crayfish within the Great Lakes Basin. Effectiveness of the treatment was accessed using an in-situ bioassay and by measuring pesticide concentrations in water, sediment, and caged crayfish. Water quality data, including temperature, pH, specific conductance, dissolved oxygen, alkalinity, hardness, ammonia, and turbidity, in stormwater ponds was collected to evaluate whether environmental conditions may impact treatment effectiveness and persistence of pesticide. Pesticide concentrations in pond water were assessed prior to chemical application of the treatment pond and monitored for 88 days post application. Pesticide concentrations in burrows and adjacent pond were monitored prior to treating burrows and for up to three days post application. Research will assist management and regulatory agencies in interpretating laboratory acute and chronic data relative to field-based treatment and effects data, and in developing permitting requirements and best management practices for open-water and burrowed invasive crayfish populations.

These data consists of three related tables describing in-situ field conditions including pesticide concentration, water quality, and post-treatment survival of crayfish associated with the application of a pesticide to a stormwater retention pond and burrows to suppress or eradicate an invasive crayfish species, Procambarus clarkii, in support of high-priority research developing control methods to mitigate impacts of invasive crayfish within the Great Lakes Basin. Effectiveness of the treatment was accessed using an in-situ bioassay and by measuring pesticide concentrations in water, sediment, and caged crayfish. Water quality data, including temperature, pH, specific conductance, dissolved oxygen, alkalinity, hardness, ammonia, and turbidity, in stormwater ponds was collected to evaluate whether environmental conditions may impact treatment effectiveness and persistence of pesticide. Pesticide concentrations in pond water were assessed prior to chemical application of the treatment pond and monitored for 88 days post application. Pesticide concentrations in burrows and adjacent pond were monitored prior to treating burrows and for up to three days post application. Research will assist management and regulatory agencies in interpretating laboratory acute and chronic data relative to field-based treatment and effects data, and in developing permitting requirements and best management practices for open-water and burrowed invasive crayfish populations.

These data consists of three related tables describing in-situ field conditions including pesticide concentration, water quality, and post-treatment survival of crayfish associated with the application of a pesticide to a stormwater retention pond and burrows to suppress or eradicate an invasive crayfish species, Procambarus clarkii, in support of high-priority research developing control methods to mitigate impacts of invasive crayfish within the Great Lakes Basin. Effectiveness of the treatment was accessed using an in-situ bioassay and by measuring pesticide concentrations in water, sediment, and caged crayfish. Water quality data, including temperature, pH, specific conductance, dissolved oxygen, alkalinity, hardness, ammonia, and turbidity, in stormwater ponds was collected to evaluate whether environmental conditions may impact treatment effectiveness and persistence of pesticide. Pesticide concentrations in pond water were assessed prior to chemical application of the treatment pond and monitored for 88 days post application. Pesticide concentrations in burrows and adjacent pond were monitored prior to treating burrows and for up to three days post application. Research will assist management and regulatory agencies in interpretating laboratory acute and chronic data relative to field-based treatment and effects data, and in developing permitting requirements and best management practices for open-water and burrowed invasive crayfish populations.

This dataset contains 60-min locomotor response data for all control, chemical and particulate-extract-treated zebrafish. This dataset is associated with the following publication: Stevens, J., S. Padilla, D. DeMarini, D. Hunter, K. Martin, L. Thompson, I. Gilmour, M. Hazari, and A. Farraj. Zebrafish Locomotor Responses Reveal Irritant Effects of Fine Particulate Matter Extracts and a Role for TRPA1. TOXICOLOGICAL SCIENCES. Society of Toxicology, RESTON, VA, 161(2): 290-299, (2018).

Data were collected associated with the application of a pesticide to a stormwater retention pond and burrows to suppress or eradicate an invasive crayfish species, Procambarus clarkii, in support of high-priority research developing control methods to mitigate impacts of invasive crayfish within the Great Lakes Basin. Effectiveness of the treatment was accessed using an in-situ bioassay and by measuring pesticide concentrations in water, sediment, and caged crayfish. Water quality data, including temperature, pH, specific conductance, dissolved oxygen, alkalinity, hardness, ammonia, and turbidity, in stormwater ponds was collected to evaluate whether environmental conditions may impact treatment effectiveness and persistence of pesticide. Pesticide concentrations were assessed prior to chemical application of ponds and monitored for 88 days post application. Pesticide concentrations in burrows and adjacent pond were monitored prior to treating burrows and for up to three days post application. Research will assist management and regulatory agencies in interpretating laboratory acute and chronic data relative to field-based treatment and effects data, and in developing permitting requirements and best management practices for open-water and burrowed invasive crayfish populations. Data associated with laboratory studies were collected to determine 24-hr acute lethal concentrations of two pesticides containing pyrethrin or cypermethrin for two crayfish species, Procambarus clarkii and Faxonius virilis. Tests investigated whether two nominal temperatures (10 and 22 °C) and total suspended solid affected pesticide toxicity. Water quality monitoring during testing followed standard testing protocols and included temperature, pH, specific conductance, dissolved oxygen, alkalinity, hardness, ammonia, turbidity, and total suspended solids in test jars with sediment from West Bearskin Lake, MN (about 2% Total Organic Carbon (TOC)). Water was collected from water treatments with and without sediment for pesticide concentrations. Pesticide concentrations are reported for water and for filters plus sediment. Test organisms were exposed to pesticides for 24-hr before being assessed for survival.

Data were collected associated with the application of a pesticide to a stormwater retention pond and burrows to suppress or eradicate an invasive crayfish species, Procambarus clarkii, in support of high-priority research developing control methods to mitigate impacts of invasive crayfish within the Great Lakes Basin. Effectiveness of the treatment was accessed using an in-situ bioassay and by measuring pesticide concentrations in water, sediment, and caged crayfish. Water quality data, including temperature, pH, specific conductance, dissolved oxygen, alkalinity, hardness, ammonia, and turbidity, in stormwater ponds was collected to evaluate whether environmental conditions may impact treatment effectiveness and persistence of pesticide. Pesticide concentrations were assessed prior to chemical application of ponds and monitored for 88 days post application. Pesticide concentrations in burrows and adjacent pond were monitored prior to treating burrows and for up to three days post application. Research will assist management and regulatory agencies in interpretating laboratory acute and chronic data relative to field-based treatment and effects data, and in developing permitting requirements and best management practices for open-water and burrowed invasive crayfish populations. Data associated with laboratory studies were collected to determine 24-hr acute lethal concentrations of two pesticides containing pyrethrin or cypermethrin for two crayfish species, Procambarus clarkii and Faxonius virilis. Tests investigated whether two nominal temperatures (10 and 22 °C) and total suspended solid affected pesticide toxicity. Water quality monitoring during testing followed standard testing protocols and included temperature, pH, specific conductance, dissolved oxygen, alkalinity, hardness, ammonia, turbidity, and total suspended solids in test jars with sediment from West Bearskin Lake, MN (about 2% Total Organic Carbon (TOC)). Water was collected from water treatments with and without sediment for pesticide concentrations. Pesticide concentrations are reported for water and for filters plus sediment. Test organisms were exposed to pesticides for 24-hr before being assessed for survival.

These data consist of three related tables describing test conditions including pesticide concentration, water quality, and post-treatment survival of crayfish associated with laboratory studies conducted to determine 24-hr acute lethal concentrations of two pesticides containing pyrethrin or cypermethrin for two crayfish species, Procambarus clarkii and Faxonius virilis. Tests investigated whether two nominal temperatures (10 and 22 °C) and total suspended solids in water affected pesticide toxicity. Laboratory data will be used to design field treatments for open-water populations of invasive P. clarkii. Water quality monitoring during testing followed standard testing protocols and included temperature, pH, specific conductance, dissolved oxygen, alkalinity, hardness, ammonia, turbidity, and total suspended solids in test jars with sediment from West Bearskin Lake, MN (about 2% Total Organic Carbon (TOC)). Water samples were collected from water treatments with and without sediment for pesticide concentrations. Pesticide concentrations are reported for water and for filters plus sediment. Test organisms were exposed to pesticides for 24-hr prior before being assessed for survival.

These data consist of three related tables describing test conditions including pesticide concentration, water quality, and post-treatment survival of crayfish associated with laboratory studies conducted to determine 24-hr acute lethal concentrations of two pesticides containing pyrethrin or cypermethrin for two crayfish species, Procambarus clarkii and Faxonius virilis. Tests investigated whether two nominal temperatures (10 and 22 °C) and total suspended solids in water affected pesticide toxicity. Laboratory data will be used to design field treatments for open-water populations of invasive P. clarkii. Water quality monitoring during testing followed standard testing protocols and included temperature, pH, specific conductance, dissolved oxygen, alkalinity, hardness, ammonia, turbidity, and total suspended solids in test jars with sediment from West Bearskin Lake, MN (about 2% Total Organic Carbon (TOC)). Water samples were collected from water treatments with and without sediment for pesticide concentrations. Pesticide concentrations are reported for water and for filters plus sediment. Test organisms were exposed to pesticides for 24-hr prior before being assessed for survival.