Ron S. Tjeerdema’s research while affiliated with University of California, Davis and other places

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Publications (39)


Acute and Chronic Effects of Clothianidin, Thiamethoxam and Methomyl on Chironomus dilutus
  • Article
  • Full-text available

May 2022

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84 Reads

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4 Citations

Bulletin of Environmental Contamination and Toxicology

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Jennifer P. Voorhees

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[...]

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Ron S. Tjeerdema

Organism tolerance thresholds for emerging contaminants are vital to the development of water quality criteria. Acute (96-h) and chronic (10-day) effects thresholds for neonicotinoid pesticides clothianidin and thiamethoxam, and the carbamate pesticide methomyl were developed for the midge Chironomus dilutus to support criteria development using the UC Davis Method. Median lethal concentrations (LC50s) were calculated for acute and chronic exposures, and the 25% inhibition concentrations (IC25) were calculated for the chronic exposures based on confirmed chemical concentrations. Clothianidin effect concentrations were 4.89 µg/L, 2.11 µg/L and 1.15 µg/L for 96-h LC50, 10-day LC50 and 10-day IC25, respectively. Similarly, thiamethoxam concentrations were 56.4 µg/L, 32.3 µg/L and 19.6 µg/L, and methomyl concentrations were 244 µg/L, 266 µg/L and 92.1 µg/L. Neonicotinoid effect concentrations compared favorably to previously published 96-h and 14-day LC50 concentrations, and methomyl effect concentrations were within the acute survival range reported for Chironomus species and other organisms.

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Aerial view of forebay and multi-channel bioreactor, and locations of mobile filter and sampling locations. Arrows indicate water flow from forebay, through the filter, through the bioreactor channel, and into the wetland
Trailer-mounted mobile filter. Forebay pictured in background
Daily filtration rates. Dates indicate three-week sampling periods. Nine-week trial ended and 12-week trial began on 8/12/2020
Treating Agricultural Runoff with a Mobile Carbon Filtration Unit

May 2022

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60 Reads

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2 Citations

Archives of Environmental Contamination and Toxicology

Several classes of pesticides have been shown to impair water quality in California, including organophosphates, pyrethroids and neonicotinoids. Vegetative treatment systems (VTS) can reduce pesticide loads and associated toxicity in agricultural runoff, but many water-soluble pesticides such as neonicotinoids are not effectively treated by VTS, and VTS installation is not always an option for growers required to remove non-crop vegetation for food safety concerns. Recent studies have shown that biochar filtration can be used to remove soluble contaminants, especially when coupled with other VTS components. We evaluated a mobile carbon filter system consisting of a trailer-mounted tank containing approximately 600L (~ 180 kg) of biochar. Input water from a 437-hectare agricultural drainage was pre-filtered and treated with biochar during two multi-week study periods. Laboratory toxicity tests and chemical and nutrient analyses were conducted on input and output water. Pesticide concentrations were initially reduced by greater than 99%. Treatment efficacy declined linearly and was expected to remain at least 50% effective for up to 34 weeks. Toxicity was assessed with Ceriodaphnia dubia , Hyalella azteca and Chironomus dilutus . Significant input toxicity was reduced to non-toxic levels in 6 of 16 samples. Some input concentrations of the neonicotinoid imidacloprid and the pyrethroid cypermethrin exceeded organism-specific toxicity thresholds and benchmarks, but the overall causes of toxicity were complex mixtures of agricultural chemicals. Nutrients were not reduced by the biochar. Results demonstrate the utility of biochar in treating agricultural runoff and provide measures of the longevity of biochar under field conditions.


The Molera Road Experimental Treatment Wetland study site located in Monterey County, California, USA. Composite samples were collected at the wetland channel inflow (Station A), upstream of the pennywort (Station B, Trials 1 and 2), the channel outflow (Station C), and the outflow of the GAC filtration installation (Station D).
Adapted from Hunt et al. (2007)
Difference in log-transformed pesticide concentrations across all trials within the wetland channel, between Stations A (channel inflow) and C (channel outflow), related to log Kow values of detected pesticides
Difference in log-transformed pesticide concentrations by trial within the GAC filtration component, between Stations C (channel outflow) and D (post-GAC), related to log Kow values of detected pesticides
Effectiveness of a Constructed Wetland with Carbon Filtration in Reducing Pesticides Associated with Agricultural Runoff

April 2022

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237 Reads

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6 Citations

Archives of Environmental Contamination and Toxicology

The Salinas Valley in Monterey County, California, USA, is a highly productive agricultural region. Irrigation runoff containing pesticides at concentrations toxic to aquatic organisms poses a threat to aquatic ecosystems within local watersheds. This study monitored the effectiveness of a constructed wetland treatment system with a granulated activated carbon (GAC) filter installation at reducing pesticide concentrations and associated toxicity to Ceriodaphnia dubia, Hyalella azteca, and Chironomus dilutus. The wetland was supplied with water pumped from an impaired agricultural and urban drainage. Across five monitoring trials, the integrated system’s average pesticide concentration reduction was 52%. The wetland channel and GAC filtration components individually provided significant treatment, and within each, pesticide solubility had a significant effect on changes in pesticide concentrations. The integrated treatment system also reduced nitrate by 61%, phosphate by 73%, and turbidity by 90%. Input water was significantly toxic to C. dubia and H. azteca in the first trial. Toxicity to C. dubia persisted throughout the system, whereas toxicity to H. azteca was removed by the channel, but there was residual toxicity post-GAC. The final trial had significant input toxicity to H. azteca and C. dilutus. The channel reduced toxicity to H. azteca and removed toxicity to C. dilutus. GAC filtration reduced H. azteca toxicity to an insignificant level. There was no input toxicity in the other three trials. The results demonstrate that a wetland treatment system coupled with GAC filtration can reduce pesticide concentrations, nutrients, suspended particles, and aquatic toxicity associated with agricultural runoff.


Fig. 1 Aerial view of forebay and multi-channel bioreactor, and locations of mobile filter and sampling locations. Arrows indicate water flow from forebay, through the filter, through the bioreactor channel, and into the wetland
Fig. 2 Trailer-mounted mobile filter. Forebay pictured in background
Fig. 3 Daily filtration rates. Dates indicate three-week sampling periods. Nine-week trial ended and 12-week trial began on 8/12/2020
Treating Agricultural Runoff With A Mobile Carbon Filtration Unit

February 2022

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24 Reads

Several classes of pesticides have been shown to impair water quality in California, including organophosphates, pyrethroids and neonicotinoids. Vegetative treatment systems (VTS) can reduce pesticide loads and associated toxicity in agricultural runoff, but many water soluble pesticides such as neonicotinoids are not effectively treated by VTS, and VTS installation is not always an option for growers required to remove non-crop vegetation for food safety concerns. Recent studies have shown that biochar filtration can be used to remove soluble contaminants, especially when coupled with other VTS components. We evaluated a mobile carbon filter system consisting of a trailer-mounted tank containing approximately 600L of biochar. Input water from a 1080 acre agricultural drainage was pre-filtered and treated with biochar during two multi-week study periods. Laboratory toxicity tests, and chemical and nutrient analyses were conducted on input and output water. Pesticide concentrations were initially reduced by greater than 99%. Treatment efficacy declined linearly and was expected to remain at least 50% effective for up to 34 weeks. Toxicity was assessed with Ceriodaphnia dubia , Hyalella azteca and Chironomus dilutus . Significant input toxicity was reduced to non-toxic levels in 6 of 16 samples. Some input concentrations of the neonicotinoid imidacloprid and the pyrethroid cypermethrin exceeded organism-specific toxicity thresholds and benchmarks, but the overall causes of toxicity were complex mixtures of agricultural chemicals. Nutrients were not reduced by the biochar. Results demonstrate the utility of biochar in treating agricultural runoff, and provide measures of the longevity of biochar under field conditions.


Inflow and outflow water volumes, insecticide and total suspended solid concentrations, and relative concentration (Conc.) and load reductions. ND indicates non-detect.
Toxicity test results and related imidacloprid and permethrin toxic unit (TU) values based on insecticide concentrations measured in simulated runoff. Shaded cells indicate significant toxicity or toxic unit values greater than 0.5.
Inflow and outflow water volumes for the 12 November trial, as well as insecticide and total suspended solid concentrations, and relative concentration and load reductions for all trials. Load reductions for the 24 September and 8 October trials were estimated (*) based on flow measurements taken during the 12 November trial. ND indicates non-detect. NR indicates not recorded due to equipment malfunction.
Results of toxicity tests and related imidacloprid and permethrin toxic unit values based on insecticide concentrations measured during lettuce field runoff events. Shaded cells indicate significant toxicity or toxic unit values greater than 0.5.
Cont.
An Integrated Vegetated Treatment System for Mitigating Imidacloprid and Permethrin in Agricultural Irrigation Runoff

January 2021

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184 Reads

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9 Citations

Toxics

Pyrethroid and neonicotinoid pesticides control an array of insect pests in leafy greens, but there are concerns about the off-site movement and potential water quality impacts of these chemicals. Effective on-farm management practices can eliminate aquatic toxicity and pesticides in runoff. This project evaluated an integrated vegetated treatment system (VTS), including the use of polyacrylamide (PAM), for minimizing the toxicity of imidacloprid and permethrin pesticides in runoff. The VTS incorporated a sediment trap to remove coarse particles, a grass-lined ditch with compost swales to remove suspended sediment and insecticides, and granulated activated carbon (GAC) or biochar to remove residual insecticides. Runoff was sampled throughout the VTS and analyzed for pesticide concentrations, and aquatic toxicity using the midge Chironomusdilutus and the amphipod Hyalella azteca. In simulated runoff experiments, the VTS reduced suspended sediment load by 88%, and imidacloprid and permethrin load by 97% and 99%, respectively. In runoff events from a conventionally grown lettuce field, suspended sediment load was reduced by 98%, and insecticide load by 99%. Toxicity was significantly reduced in approximately half of the simulated runoff events, and most of the lettuce runoff events. Integrated vegetated treatment systems that include components for treating soluble and hydrophobic pesticides are vital tools for reducing pesticide load and occurrence of pesticide-related toxicity.


Comparison of the Relative Efficacies of Granulated Activated Carbon and Biochar to Reduce Chlorpyrifos and Imidacloprid Loading and Toxicity Using Laboratory Bench Scale Experiments

March 2020

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41 Reads

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12 Citations

Bulletin of Environmental Contamination and Toxicology

Pesticide loads and associated toxicity can be significantly reduced using integrated vegetated treatment systems, which remove moderately soluble and hydrophobic pesticides, but need a sorbent material to remove more soluble pesticides. Neonicotinoids such as imidacloprid are widely used insecticides, acutely toxic, and have been linked to a range of ecological effects. Laboratory experiments were conducted to test the sorptive capacity of granulated activated carbon and biochar for removing imidacloprid and the organophosphate insecticide chlorpyrifos in a scaled-down treatment system. Simulated irrigation water spiked with individual pesticides was treated with a bench-top system designed to mimic a 600 L carbon installation receiving 108,000 L of flow per day for sixteen days. Biochar reduced insecticides to less than detectable and non-toxic levels. Granulated activated carbon similarly reduced chlorpyrifos, but allowed increasing concentrations of imidacloprid to break through. Both media treated environmentally relevant concentrations, and would be effective if used under conditions with reduced particle loads.


Changing patterns in water toxicity associated with current use pesticides in three California agriculture regions

November 2017

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105 Reads

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41 Citations

Integrated Environmental Assessment and Management

Regulation of agriculture irrigation water discharges in California, USA, is assessed and controlled by its 9 Regional Water Quality Control Boards under the jurisdiction of the California State Water Resources Control Board. Each Regional Water Board has developed programs to control pesticides in runoff as part of the waste discharge requirements implemented through each region's Irrigated Lands Regulatory Program. The present study assessed how pesticide use patterns differ in the Imperial (Imperial County) and the Salinas and Santa Maria (Monterey County) valleys, which host 3 of California's prime agriculture areas. Surface-water toxicity associated with current use pesticides was monitored at several sites in these areas in 2014 and 2015, and results were linked to changes in pesticide use patterns in these areas. Pesticide use patterns appeared to coincide with differences in the way agriculture programs were implemented by the 2 respective Regional Water Quality Control Boards, and these programs differed in the 2 Water Board Regions. Different pesticide use patterns affected the occurrence of pesticides in agriculture runoff, and this influenced toxicity test results. Greater detection frequency and higher concentrations of the organophosphate pesticide chlorpyrifos were detected in agriculture runoff in Imperial County compared to Monterey County, likely due to more rigorous monitoring requirements for growers using this pesticide in Monterey County. Monterey County agriculture runoff contained toxic concentrations of pyrethroid and neonicotinoid pesticides, which impacted amphipods (Hyalella azteca) and midge larvae (Chironomus dilutus) in toxicity tests. Study results illustrate how monitoring strategies need to evolve as regulatory actions affect change in pesticide use and demonstrate the importance of using toxicity test indicator species appropriate for the suite of contaminants in runoff in order to accurately assess environmental risk.


Carbon Treatment as a Method to Remove Imidacloprid from Agriculture Runoff

August 2017

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67 Reads

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15 Citations

Bulletin of Environmental Contamination and Toxicology

Use of neonicotinoid pesticides is increasing worldwide and there is growing evidence of surface water contamination from this class of insecticide. Due to their high solubility, traditional mitigation practices may be less effective at reducing neonicotinoid concentrations in agricultural runoff. In the current study, laboratory experiments were conducted to determine if granulated activated carbon (GAC) reduces concentrations of the neonicotinoid imidacloprid in water under simulated flow conditions. Imidacloprid was pumped through columns packed with GAC using flow rates scaled to mimic previously reported field studies. Treatments were tested at two different flow rates and samples were collected after 200 and 2500?mL of treated water were pumped through the column. Chemical analysis of the post-column effluent showed the GAC removed all detectable imidacloprid from solution at both flow rates and at both sample times. These results demonstrate the efficacy of GAC for treating neonicotinoids and the results are discussed in the context of incorporating this treatment into integrated vegetated treatment systems for mitigating pesticides in agricultural runoff. Future studies are being designed to evaluate this technology in full scale field trials.


An integrated vegetated ditch system reduces chlorpyrifos loading in agricultural runoff: Strategies for Reducing Chlorpyrifos in Irrigation Runoff

July 2016

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53 Reads

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21 Citations

Integrated Environmental Assessment and Management

Agricultural runoff containing toxic concentrations of the organophosphate pesticide chlorpyrifos has led to impaired water body listings and Total Maximum Daily Load restrictions in California's central coast watersheds. Chlorpyrifos use is now tightly regulated by the Central Coast Regional Water Quality Control Board. This study evaluated treatments designed to reduce chlorpyrifos in agricultural runoff. Initial trials evaluated the efficacy of three different drainage ditch installations individually: compost filters, granulated activated carbon filters, and native grasses in a vegetated ditch. Treatments were compared to bare ditch controls, and experiments were conducted with simulated runoff spiked with chlorpyrifos at a 1.9 L/s flow rate. Chlorpyrifos concentrations and toxicity to Ceriodaphnia dubia were measured at the input and output of the system. Input concentrations of chlorpyrifos ranged from 858 ng/L to 2840 ng/L. Carbon filters and vegetation provided the greatest load reduction of chlorpyrifos (99% and 90%, respectively). Toxicity was completely removed in only one of the carbon trials. A second set of trials evaluated an integrated approach combining all three treatments. Three trials were conducted each at 3.2 L/s and 6.3 L/s flow rates at input concentrations ranging from 282 ng/L to 973 ng/L. Chlorpyrifos loadings were reduced by an average of 98% at the low flow rate and 94% at the high flow rate. Final chlorpyrifos concentrations ranged from non-detect (<50 ng/L) to 82 ng/L. Toxicity to C. dubia was eliminated in three of the six integrated trials. Modeling of the ditch and its components informed design alterations that are intended to eventually remove up to 100% of pesticides and sediment. Future work includes investigating the adsorption capacity of granulated activated carbon, costs associated with carbon disposal, and real-world field trials to further reduce model uncertainties and confirm design optimization. Trials with more water-soluble pesticides such as neonicotinoids are also recommended. This article is protected by copyright. All rights reserved



Citations (34)


... However, a practical approach for application to small streams is needed. After use the biochar could be redeployed onto farmland supporting carbon sequestration and a circular economy, recycling nutrients and further preventing run-off (Catizzone et al., 2021;Phillips et al., 2022;Kamali et al., 2021); (3) Riparian buffer zones are recommended between crops and rivers. In Scotland, General Binding Rule 20 requires a buffer strip at least 2 m wide to be left between surface waters and wetlands and cultivated land (SEPA, 2009). ...

Reference:

Urban landscapes and legacy industry provide hotspots for riverine greenhouse gases: A source-to-sea study of the River Clyde
Treating Agricultural Runoff with a Mobile Carbon Filtration Unit

Archives of Environmental Contamination and Toxicology

... Thus, it serves as an effective adsorbent for pollutant removal from aquatic systems (Lee et al., 2013;Abhishek et al., 2022;Jagadeesh and Sundaram, 2022;Sinha et al., 2022). Applying biochar to soil is an emergent practice and potentially cost-effective method to replenish nutrients, increase agricultural yields, remove contaminants, and sequester carbon (Kuppusamy et al., 2016;McCalla et al., 2022;Dong et al., 2023). Biochar has also been used to remove pollutants, including heavy metals, persistent organic compounds, and, most recently, MPs, from aquatic systems (Wang et al., 2020b;Siipola et al., 2020;Wang et al., 2021a;Magid et al., 2021;Dong et al., 2023;. ...

Effectiveness of a Constructed Wetland with Carbon Filtration in Reducing Pesticides Associated with Agricultural Runoff

Archives of Environmental Contamination and Toxicology

... During the experiment, all three compounds degraded rapidly in the water column (median dissipation time 15 for IMI to 32 days for THM), but dissipation in our mesocosms was higher than the photolysis measured in shallow waters with greater light penetration (DT50 <1 days for imidacloprid and clothianidin, and between 2.7 and 39.5 days for thiamethoxam; Morrissey et al., 2015). However, low recovery of CLO has been observed in experimental samples (Phillips et al., 2022;Tomšič et al., 2020). A rapid degradation of CLO by photolysis in water could explain the low recovered concentration (42%) of the compound on day 0 of our experiment. ...

Acute and Chronic Effects of Clothianidin, Thiamethoxam and Methomyl on Chironomus dilutus

Bulletin of Environmental Contamination and Toxicology

... Perhaps the best example of technologies incorporated within VADD is research recently published by Phillips et al. (2021) describing an integrated vegetated treatment system (VTS) which included a sediment trap, vegetated ditch, compost swales, and a granulated activated carbon (GAC) or biochar polishing filter. Each component of the VTS was designed with a specific purpose in mind: coarse particulates would be removed by the sediment trap, while suspended sediment and insecticides would be removed by the vegetated ditch and compost swales. ...

An Integrated Vegetated Treatment System for Mitigating Imidacloprid and Permethrin in Agricultural Irrigation Runoff

Toxics

... For the experimental setup activated carbon, Aquacarb® NS, a reactivated coal/ coconut shell charcoal and biochar derived from organic sustainably grown yellow pine wood which was pyrolyzed at 900°C was utilized. For conducting the experiments irrigation water spiked with imidacloprid was utilized to further monitor the real time applications of the experimental set up. [57] In 2021, Du et al. developed a method for the removal of imidacloprid pesticide from tea infusion using activated carbon named YQPB. The removal rate of imidacloprid was monitored using High Performance Liquid Chromatography (HPLC) by quantifying the imidacloprid pesticide. ...

Comparison of the Relative Efficacies of Granulated Activated Carbon and Biochar to Reduce Chlorpyrifos and Imidacloprid Loading and Toxicity Using Laboratory Bench Scale Experiments

Bulletin of Environmental Contamination and Toxicology

... • Some taxa are more sensitive to specific insecticides, such as cladocerans to OPs, midge to fipronil and neonicotinoids, Hyalella azteca to pyrethroids (Anderson et al., 2018;Giddings et al., 2019;Morrissey et al., 2015;Sanchez-Bayo, 2012). Variations in taxon sensitivity are related to insecticide MoA and biochemical traits of organisms (Rico and Van den Brink, 2015;Rubach et al., 2010;Sanchez-Bayo, 2012). ...

Changing patterns in water toxicity associated with current use pesticides in three California agriculture regions
  • Citing Article
  • November 2017

Integrated Environmental Assessment and Management

... Granulated activated carbon (GAC) is a commonly used adsorbent to treat agrochemicals and organic contaminants in water due to its wide availability (Adeola et al., 2022). Voorhees et al. (2017) demonstrated the efficacy of GAC in removing IMI from agricultural runoff through a simple filtration experiment. Given the high cost and regeneration difficulty of activated carbons, another carbon-based adsorbent, biochar, has gained increasing attention. ...

Carbon Treatment as a Method to Remove Imidacloprid from Agriculture Runoff

Bulletin of Environmental Contamination and Toxicology

... Most models only consider the possibility of sorption onto sediments, whether they are 4 80 85 90 deposited as a layer below the water column or remain in suspension. To our knowledge, only TOXSWA and VSFMOD consider sorption onto other materials, with explicit consideration of sorption onto macrophytes in TOXSWA and implicit and undifferentiated consideration of material contribution by fitting an overall sorption coefficient for the entire ditch in VSFMOD (Phillips et al., 2017). ...

An integrated vegetated ditch system reduces chlorpyrifos loading in agricultural runoff: Strategies for Reducing Chlorpyrifos in Irrigation Runoff
  • Citing Article
  • July 2016

Integrated Environmental Assessment and Management

... A Fenpropatrina no sistema aquático dissipa-se rapidamente da fase aquosa dissolvida e liga-se ao carbono orgânico em partículas de sedimentos (Fojut;Young, 2011). Este agrotóxico representa um risco para os organismos não visados que habitam os sedimentos, mas também atuam como uma fonte secundária de contaminantes que se libertam para as águas superficiais e causam efeitos adversos nas espécies da coluna de água (Siegler et al., 2015). Segundo Denver, v.83, n. 6, p. 48-55, 1991 EMBRAPA -Empresa Brasileira de Pesquisa Agropecuária. ...

Temporal and spatial trends in sediment contaminants associated with toxicity in California watersheds
  • Citing Article
  • November 2015

Environmental Pollution

... However, there is concern that continuous dosing in a creek may have chronic effects to aquatic organisms located downstream. Phillips et al. were able to demonstrate that continuous dosing of the Landguard™ enzyme for 30 days in a creek receiving agricultural runoff from vegetable fields was not toxic to benthic macroinvertebrates downstream in the Salinas river (56). ...

The Effects of the Landguard™ A900 Enzyme on the Macroinvertebrate Community in the Salinas River, California, United States of America
  • Citing Article
  • June 2015

Archives of Environmental Contamination and Toxicology