Hostname: page-component-cd9895bd7-q99xh Total loading time: 0 Render date: 2024-12-23T04:36:08.610Z Has data issue: false hasContentIssue false

Quantifying changes in the environmental impact of in-crop herbicide use in Saskatchewan, Canada

Published online by Cambridge University Press:  08 March 2024

Elisabeta Lika
Affiliation:
Research Assistant, Department of Agricultural and Resource Economics, University of Saskatchewan, Saskatoon, SK, Canada
Chelsea Sutherland
Affiliation:
Research Associate, Department of Agricultural and Resource Economics, University of Saskatchewan, Saskatoon, SK, Canada
Savannah Gleim
Affiliation:
Research Associate, Department of Agricultural and Resource Economics, University of Saskatchewan, Saskatoon, SK, Canada
Stuart J. Smyth*
Affiliation:
Professor, Department of Agricultural and Resource Economics, University of Saskatchewan, Saskatoon, SK, Canada
*
Corresponding author: Stuart J. Smyth; Email: [email protected]
Rights & Permissions [Opens in a new window]

Abstract

The sustainable management of herbicides is critical to modern agriculture and the environment. This article examines the evolution and environmental implications of herbicide use in Saskatchewan, Canada, agriculture. It quantifies changes in herbicide use and their environmental impacts by analyzing farm-level herbicide use data from 1991 to 1994 and from 2016 to 2019 through the environmental impact quotient. Results confirm significant reductions in both environmental and toxicological impacts of herbicides used, underlining the pivotal shift from tillage-based weed control to herbicide-resistant cropping systems. The environmental impact of the top five herbicides (glufosinate, glyphosate, clethodim, imazamox, and 2,4-D) used from 2016 to 2019 is 65% lower than that for those herbicides (MCPA, 2,4-D, bromoxynil, diclofop-methyl, and trifluralin) used from 1991 to 1994, with a 45% reduction in the active ingredient applied per acre. Despite increased herbicide use due to more crop acres being seeded, the findings highlight a marked improvement in the sustainability of herbicide use, affirming the importance of technological advancements in agriculture. This research contributes valuable insights into long-term trends in herbicide use, offering a practical framework for informed decisions aligning with sustainable agricultural practices as well as reduced biodiversity impacts.

Type
Research Article
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright
© The Author(s), 2024. Published by Cambridge University Press on behalf of Weed Science Society of America

Introduction

The sustainability of chemical applications is a topic of ongoing debate in agricultural and environmental policy discussions for many governments. All chemicals, including herbicides, insecticides, and fungicides, are important technologies in farmers’ tool kits and are an integral part of sustainable crop management and production systems. However, their use is often misunderstood, and uncertainty among the public can result in distrust of technology (Allum et al. Reference Allum, Sturgis, Tabourazi and Brunton-Smith2008; Sutherland et al. Reference Sutherland, Sim, Gleim and Smyth2020). Few sustainable, alternative weed control options to herbicide use are currently available to farmers. Thirty years ago, summer fallow was a common practice, and conventional tillage was the leading form of weed control before planting. Both practices contributed to decreased soil quality and moisture levels (Awada et al. Reference Awada, Lindwall and Sonntag2014) and increased soil erosion (Reference Rust and WilliamsRust and Williams, n.d.; Verity and Anderson Reference Verity and Anderson2011), which resulted in some chemicals and fertilizers leaching into local watersheds.

Reductions in summer fallow acres and tillage applications align with global sustainable practices, contributing to improved soil health, moisture conservation, and carbon sequestration (FAO 2023; Lal et al. Reference Lal, Follett, Stewart and Kimble2007). The adoption of conservation tillage, as seen in Saskatchewan, corroborates these improvements (AAFC 2022; Derpsch et al. Reference Derpsch, Friedrich, Kassam and Li2010; Hobbs et al. Reference Hobbs, Sayre and Gupta2008; Sutherland et al. Reference Sutherland, Gleim and Smyth2021). This research focuses on the region’s herbicide use evolution, particularly through the environmental impact quotient (EIQ), to assess the environmental impact of these changes.

The controversy surrounding the use of glyphosate, evident in various restrictions, illustrates the complex balance between agricultural productivity and environmental stewardship (Cerdeira and Duke Reference Cerdeira and Duke2010; Duke and Powles Reference Duke and Powles2008; Health Canada 2019; Kynetec 2022; Marambe and Herath Reference Marambe and Herath2020; PMRA 2017; Wisner Baum 2022). However, this article’s primary focus is not on individual herbicides but on the broader trends in herbicide use in Saskatchewan, particularly between 1991 to 1994 and 2016 to 2019. Between these periods, a significant increase in seeded acreage and a decrease in summer fallow was observed (Statistics Canada 2023), along with low potential risks from herbicide use (AAFC 2022).

This research extends to the period of herbicide-resistant cropping systems’ introduction, which marked a significant shift from tillage-based weed control to more sustainable practices. The transition to herbicide-resistant crops, such as canola (Brassica napus L.), has been integral to enhancing carbon sequestration in agricultural soils (Sutherland et al. Reference Sutherland, Gleim and Smyth2021; West and Post Reference West and Post2002) and reducing the need for multiple herbicide mixtures (Helling Reference Helling2005; Sikkema and Robinson Reference Sikkema and Robinson2005; Van Acker et al. Reference Van Acker, Rahman and Cici2017). This shift reflects reduced tillage, preserving soil structure and organic content, and highlights a significant improvement in the sustainability of herbicide use.

In Saskatchewan, canola, with its various herbicide-resistant traits, including genetically modified (GM) glyphosate- and glufosinate-resistant and mutagenic imidazoline-resistant varieties, represents a significant shift in agricultural practices (Smyth et al. Reference Smyth, Gusta, Belcher, Phillips and Castle2011). GM crops are plants whose DNA has been altered using genetic engineering methods to introduce traits like increased resistance to pests or herbicides (Turnbull et al. Reference Turnbull, Lillemo and Hvoslef-Eide2021). The increasing reliance on herbicides in Canadian agriculture, with a pronounced increase in cropland treated with herbicides from 1981 to 2016, is particularly notable in the prairie region (Malaj et al. Reference Malaj, Freistadt and Morrissey2020). However, this increase has been accompanied by notable changes in herbicide use efficiency and environmental impact. For instance, a 42.8% decrease in total herbicide use per hectare in canola, particularly in herbicide-resistant varieties, was observed between 1995 and 2000 (Brimner et al. Reference Brimner, Gallivan and Stephenson2005), reflecting a trend toward more sustainable use patterns.

Studies like MacWilliam et al. (Reference MacWilliam, Sanscartier, Lemke, Wismer and Baron2016) and Brookes and Barfoot (Reference Brookes and Barfoot2017) emphasize the significant reduction in herbicide use per metric ton of canola produced and the global environmental benefits of GM crops, respectively. These findings align with the regional trends observed in this research, demonstrating reduced environmental and toxicological impacts of herbicides used in Saskatchewan. This reduction is further evidenced by the decline in herbicide active ingredient (AI) applied to canola in Canada between 1995 and 2006, indicating improved environmental sustainability (Smyth et al. Reference Smyth, Gusta, Belcher, Phillips and Castle2011).

While herbicide-resistant weeds date back to the 1950s in Canada, the environmental impact of herbicide use extends beyond their immediate application, as continuous cropping rotations require greater awareness of chemical variation as part of the strategy to minimize the potential for herbicide-resistant weeds to evolve. The emergence of glyphosate-resistant weeds necessitates integrated weed management strategies (Beckie et al. Reference Beckie, Sikkema, Soltani, Blackshaw and Johnson2014), while studies on herbicide persistence and mobility offer insights into their long-term ecological impacts (Helling Reference Helling2005). Furthermore, international perspectives, such as the use of atrazine, provide a comparative context for understanding herbicide impacts. Recent studies, including those by Gagneten et al. (Reference Gagneten, Regaldo, Carriquiriborde, Reno, Kergaravat, Butinof, Agostini, Alvarez and Harte2023), emphasize the nuanced ecological consequences of atrazine in diverse environments, offering a broader comparative framework that enriches our understanding of its global impact (Hayes et al. Reference Hayes, Anderson, Beasley, De Solla, Iguchi, Ingraham, Kestemont, Kniewald, Kniewald, Langlois, Luque, McCoy, Muñoz-De-Toro, Oka, Oliveira, Orton, Ruby, Suzawa, Tavera-Mendoza, Trudeau, Victor-Costa and Willingham2011; de Souza et al. Reference de Souza, Burgess, Doran, Hansen, Manukyan, Maryn, Gotarkar, Leonelli, Niyogi and Long2022).

The evolving dynamics of agricultural practices, particularly in the context of modern herbicide use, are crucial given the increasing scrutiny and regulatory actions of herbicides. The European Union’s Farm to Fork Strategy illustrates these global policy shifts with its ambitious targets for chemical reduction (FAO 2023). Meanwhile, in Canada, regulatory reviews like the Pest Management Regulatory Agency’s reassessment of glyphosate (Health Canada 2019) reflect the ongoing scientific balance between agricultural productivity and environmental sustainability.

Saskatchewan’s experience as a significant agricultural producer highlights the importance of understanding the environmental impact of herbicides within the broader Canadian agricultural policy framework. This article’s focus on quantifying the changes in in-crop herbicide use and their environmental impacts in Saskatchewan offers valuable insights for informed decision-making, aligning with sustainable agricultural practices.

Materials and Methods

This research aims to calculate the field use environmental impact quotient (EIQ-FU) for herbicides used postemergence in the crop rotation periods of 1991 to 1994 and 2016 to 2019. The EIQ, a comprehensive tool developed by Kovach et al. (Reference Kovach, Petzoldt, Degni and Tette1992), evaluates the environmental impacts of pesticides. It encompasses three key components: farmworker impact, consumer impact, and ecological impact. These components account for the direct and indirect effects of pesticide use on human health and the environment. The farmworker component considers factors like dermal and respiratory exposure, while the consumer component assesses the potential impact of pesticide residues on food. The ecological component evaluates the broader environmental consequences, including effects on nontarget species and ecosystems (Reference Eshenaur, Grant, Kovach, Petzoldt, Degni and TetteEshenaur et al., n.d.).

Each component of the EIQ is quantified by considering various subcomponents, such as acute and chronic toxicity, and rates of dispersion and degradation in the environment. These subcomponents reflect a range of factors influencing pesticide toxicity and exposure levels, providing a nuanced approach to assessing environmental and health impacts. The combined scores of these components yield the overall EIQ-FU value, which offers a comparative measure of the potential environmental impact of different pesticides.

Although the EIQ-FU provides valuable insights into the environmental footprint of pesticide use, it is important to recognize its limitations. One of these is the potential oversimplification of complex environmental dynamics. The EIQ formula (Reference GrantGrant, n.d.) generally does not account for the development of pest resistance, which is a significant factor in long-term pesticide management and environmental impact. Additionally, the EIQ’s method of combining a large amount of quantitative data into a single qualitative value can result in the loss of valuable information. This approach can obscure the nuances of pesticide application, such as the cumulative impacts of repeated application over time. Furthermore, the EIQ framework has been criticized for not adequately incorporating exposure into its calculations. The tool includes components meant to serve as proxies for exposure, such as plant surface half-life, runoff potential, and leaching potential, but these do not accurately estimate the potential exposure (Dushoff et al. Reference Dushoff, Caldwell and Mohler1994; Kniss and Coburn Reference Kniss and Coburn2015; Peterson and Schleier Reference Peterson and Schleier2014).

Despite these limitations, our methodology, informed by Kovach et al. (Reference Kovach, Petzoldt, Degni and Tette1992), aims to provide a fair and accurate comparison of the EIQ-FU values of different herbicides across the studied periods. However, we emphasize that the EIQ-FU should be interpreted within the context of these acknowledged limitations and as part of a broader integrated pest management strategy.

In selecting herbicides for our study periods, the primary criterion was the frequency of use reported by farmers, specifically the percentage of respondents indicating the application of these herbicides during the in-crop phase. The most frequently reported herbicides were cross-referenced with scientific data on the most used or sold herbicides in Saskatchewan or, if Saskatchewan data were unavailable, neighboring provinces. This two-step verification process led to the selection of MCPA, 2,4-D (ethyl ester), diclofop-methyl, trifluralin, and bromoxynil for 1991 to 1994 and glyphosate, glufosinate, imazamox, 2,4-D, and clethodim for 2016 to 2019.

Additionally, for the period 2016 to 2019, our herbicide selection was guided by the prevalent agricultural practices in Saskatchewan and Alberta, substantiated by empirical sales data and weed control strategies. Notably, glyphosate, glufosinate, and 2,4-D were among the top-selling AIs in Alberta in 2018, as indicated by the Alberta pesticides sales report (Environment and Parks 2020). This report highlights the widespread use of these herbicides in regional agriculture, justifying their inclusion in our analysis for this period.

Furthermore, the relevance of imazamox in this time frame is underscored by its documented efficacy in controlling broadleaf and grassy weeds, particularly in pea (Cicer spp., Lathyrus spp.) and soybean [Glycine max (L.) Merr.] crops. It is claimed that imazamox’s tank mixability, residual control, and flexible recropping options have made it a preferred herbicide in western Canadian agriculture (ADAMA West Canada 2021). This aligns with our research’s focus on herbicides with significant agricultural impact in the region. The reevaluation of imazamox by Health Canada’s Pest Management Regulatory Agency further solidifies its significance. The reevaluation, which assesses the risks and benefits of pesticides to ensure compliance with modern health and environmental standards, confirms the continued relevance of imazamox in contemporary agricultural practices (PMRA 2017). Similarly, herbicide selection for 1991 to 1994 was also based on their extensive use in Saskatchewan. This assertion is supported by environmental studies in the region, such as research by Waite et al. (Reference Waite, Cessna, Grover, Kerr and Snihura2004), which reported on the environmental concentrations of these herbicides near Regina, Saskatchewan. The study’s findings demonstrate the significant presence of these herbicides in various environmental media, indicating their widespread application and potential environmental impact.

In evaluating the changes in herbicide use and their impact on the EIQ of farming systems, we acknowledge the increased diversity in herbicide use in the later period (2016 to 2019) compared to the earlier period (1991 to 1994). This diversity reflects evolving agricultural practices and is an important factor in our analysis. However, our primary objective is to assess overall trends and environmental impacts of herbicide use, rather than focusing on acreage-specific comparisons. This approach allows us to provide broader insights into the dynamic nature of herbicide application and its environmental implications in Saskatchewan.

The first step in determining the EIQ-FU for each herbicide involved identifying the EIQ value for each individual AI. This value, which remains constant, was derived from a comprehensive assessment that includes factors such as the pesticide’s inherent toxicity, its potential for runoff, and its impact on nontarget organisms. The EIQ values are sourced from the EIQ database provided by Cornell University (2023).

In the second step of this analysis, we used the application rates for each commercial herbicide product as reported by farmers, measured in liters per acre. If these application rates significantly deviated from the label-recommended rate or were not specified, we utilized the highest recommended rate for the seeded crop as a standard reference. For glyphosate, we adopted a commonly reported rate of 1 L acre−1 for the 540 g ae formulation.

In the third step, we utilized the Cornell University EIQ calculator to determine the EIQ-FU for each herbicide, using the application rates reported by farmers and concentrations of AIs from the list of herbicides identified for both the 1991 to 1994 and 2016 to 2019 periods. The EIQ-FU values, generated by the calculator, provide an overview of the environmental impact per unit area. It must be noted that the EIQ-FU value reported in our results, while related to EIQ, is a distinct measure. This value extends the EIQ by considering the actual field use conditions of the pesticides and factoring in the application rates, which can vary over time and between different herbicide formulations. As a result of these differences in application rates and concentrations of the AI in herbicide formulations across the two periods, the EIQ-FU values for the same AI, such as 2,4-D, may vary over time. The field use EIQ calculator provides unitless relative safety ratings, standardized to pounds per acre, based on product weight and application area provided by user.

The research utilizes primary data generated from the Crop Rotation Survey, which was developed and administered online to Saskatchewan crop farmers. Farmers were asked to report on a single field throughout the survey and, if possible, to report on the same field for both the 1991 to 1994 and 2016 to 2019 time periods. The questions were open, closed, and partially open, with space provided for farmers to include additional information to clarify their answers.

The Crop Rotation Survey is divided into four components: seeding and harvest, tillage, fertilizer use, and chemical use. For the purpose of this study, we use the survey section that focused on chemical use, which asked respondents to record the timing, application rates, equipment used, and chemicals applied for all chemical applications. The survey asked farmers to report the product names of the chemicals they used, such as Roundup® Ultra 2 (Bayer Crop Science, St. Louis, MO, USA), instead of the chemical name, such as glyphosate, as well as the rate at which they applied the chemical either in kg/acre or in l/acre. Acres were used as farmers’ fields have been surveyed using imperial measurements, such that a section of land is 1 mi2, or 640 acres.

The initial data set for the 1991 to 1994 period consisted only of respondents who reported to have farmed for this crop rotation period (n = 75), and similarly, the 2016 to 2019 data set consisted of people who farmed during that period (n = 107). However, the number of respondents who reported to have applied in-crop herbicides varied from one year to another and from one crop rotation to another. A third subset is formed when narrowing the analysis to only those respondents who reported having used chemical products that contain the AIs selected for this analysis. Estimates of EIQs and application rates for the five main herbicides for each crop rotation period are drawn from this last subset and are limited to in-crop herbicide timing. These calculations represent an average of each calculated EIQ-FU and its components, taken over the number of respondents who reported having applied each individual product that contains the selected herbicide for analysis.

In terms of geographical distribution, respondents hailed from all nine provincial regions of Saskatchewan, with a pronounced concentration in the northwest region. Figure 1 is a map of Saskatchewan indicating where the survey participants were located, grouped by rural municipality. The colors on the map indicate how many participants were located in each rural municipality, as shown in the map legend. Although our study’s respondent concentration could imply regional bias, this does not significantly undermine the generalizability of our findings. The overall trends in herbicide use and environmental impacts, as analyzed, align with broader agricultural practices across Saskatchewan. It is unlikely that herbicide use patterns differ dramatically across regions to a degree that would substantially skew our results as crop production and rotations are similar throughout the province. However, we suggest that future research could further explore regional variations to enhance understanding.

Figure 1. Map of provincial survey participant locations.

When benchmarked against the 2016 Canadian Census of Agriculture, our sample’s demographics generally aligned, though with a younger age and a higher educational attainment. This alignment suggests that our sample, despite its unique characteristics, remains representative of the broader Saskatchewan farming community. The data’s granularity and the comprehensive nature of the survey ensure that our findings are both robust and policy relevant, providing valuable insights into the evolving agricultural practices in Saskatchewan. Table 1 provides more detailed information on the full survey sample.

Table 1. Total participant demographics compared to Saskatchewan 2016 Census of Agriculture.

Results and Discussion

The data from the two distinct crop rotation periods reveal significant trends in herbicide use in Saskatchewan. In the 1991 to 1994 period, the top five herbicides by use were MCPA, 2,4-D, diclofop-methyl, bromoxynil, and trifluralin, each with distinct environmental impacts based on use patterns and intrinsic properties. Table 2 provides baseline data on the EIQ quotients of each herbicide and shows the grams of AI per acre and the percentage of seedable acres applied. Diclofop-methyl has the highest EIQ-FU at 16.9, closely followed by MCPA at 15.6, while bromoxynil had the lowest at 6.1. Concerning the environmental impact on farmers and farmworkers (EIQf), trifluralin, MCPA, and diclofop-methyl exhibited similar values, with diclofop-methyl slightly higher at 11.2. The impacts on consumers (EIQc) are lowest, assessing herbicide residues in food and watershed. Notably, MCPA’s higher solubility and lower soil adsorption, as discussed by Hiller et al. (Reference Hiller, Krascsenits and Čerňanský2008), indicate its greater potential for leaching and aquatic ecosystem impact compared to 2,4-D, which exhibits different degradation rates and mobility. These properties, combined with the application rate per acre, influence the ecological impact of these herbicides in Saskatchewan’s specific environmental and agricultural conditions. Bromoxynil had the least ecological impact (EIQe) at 12.1.

Table 2. Baseline EIQs for in-crop herbicides applied in Saskatchewan (1991 to 1994): analysis of active ingredient use, EIQ factors, and ecological impacts. a

a Abbreviations: ai, active ingredient; EIQ, environmental impact quotient; EIQc, EIQ on consumers; EIQe, EIQ on the ecology; EIQf, EIQ on farmers and farmworkers; EIQ-FU, field use EIQ.

b Proportion of area to which each herbicide was applied. The annual percentages were summed for the 1991 to 1994 period.

Table 3 extends the analysis from Table 2, providing deeper insight into the overall and per acre environmental impact of the herbicides. It highlights the cumulative effect of these herbicides, with a significant emphasis on their ecological impact, constituting 66% of the total EIQ-FU, followed by the impact on farmers and farmworkers (25%) and, lastly, on consumers (9%). Trifluralin shows the highest EIQ-FU per acre, constituting 37% of the total impact, emphasizing its substantial ecological footprint. Conversely, bromoxynil, despite its wide use, had the least impact at 5%. The rates of the top three chemicals applied, trifluralin (37%), MCPA (24%), and diclofop-methyl (23%), reflect evolving patterns in herbicide application.

Table 3. Detailed environmental impact assessment of in-crop herbicides in Saskatchewan (1991 to 1994): cumulative and per acre impacts on ecology, farmers, and consumers. a

a Abbreviations: EIQ, environmental impact quotient; EIQc, EIQ on consumers, reflecting the potential impact of herbicide residues on consumers; EIQe, EIQ on the ecology, indicating effects on biodiversity and environmental health; EIQf, EIQ on farmers and farmworkers, quantifying occupational exposure; EIQ-FU, field use EIQ.

b Proportion of the total ecological, farmworker, and consumer impacts attributed to each individual herbicide. It helps in understanding the relative significance of each herbicide within each impact category.

c Encompasses the total environmental impact of all herbicides combined, across all impact categories, over the 1991 to 1994 period. This indicator is essential for assessing the overall ecological footprint of herbicide use.

d Proportion of the total environmental impact attributable to each impact category (ecological, farmworker, and consumer) for all herbicides combined. The percentages in this row indicate the overall distribution of total environmental impact across these three categories.

The top five herbicides for the 2016 to 2019 period were glyphosate, glufosinate, imazamox, 2,4-D, and clethodim. Glufosinate had the highest combined EIQ-FU at 11.6, followed closely by glyphosate at 10.5. Clethodim and imazamox had significantly lower EIQ-FU values at 1.2 and 0.9, respectively. Table 4 provides detailed information on the comparative EIQs of the top in-crop herbicides used between 2016 and 2019.

Table 4. Comparative EIQs of top in-crop herbicides in Saskatchewan (2016 to 2019): glyphosate, glufosinate, imazamox, 2,4-D, and clethodim. a

a Abbreviations: ai, active ingredient; EIQ, environmental impact quotient; EIQc, EIQ on consumers; EIQe, EIQ on the ecology; EIQf, EIQ on farmers and farmworkers; EIQ-FU, field use EIQ.

b Proportion of area to which each herbicide was applied. The annual percentages were summed for the 2016 to 2019 period.

In the 2016 to 2019 period, ecological impacts dominate the environmental impact, slightly more so than in the 1991 to 1994 period, as presented in Table 5. These impacts account for 73% of the total EIQ-FU, with glyphosate contributing 41% and glufosinate 34% to the total. Our results highlight the significant environmental footprint of these herbicides during this period.

Table 5. Comprehensive environmental impact assessment of in-crop herbicides in Saskatchewan (2016 to 2019): ecological, farmer, and consumer effects. a

a Abbreviations: EIQ, environmental impact quotient; EIQc, EIQ on consumers; EIQe, EIQ on the ecology; EIQf, EIQ on farmers and farmworkers; EIQ-FU, field use EIQ.

b Proportion of the total ecological, farmworker, and consumer impacts attributed to each individual herbicide. It helps in understanding the relative significance of each herbicide within each impact category.

c Encompasses the total environmental impact of all herbicides combined, across all impact categories, over the 1991 to 1994 period. This indicator is essential for assessing the overall ecological footprint of herbicide use.

d Proportion of the total environmental impact attributable to each impact category (ecological, farmworker, and consumer) for all herbicides combined. The percentages in this row indicate the overall distribution of total environmental impact across these three categories.

Comparing the environmental impacts of the top five herbicides across the two periods, as shown in Table 6, indicates a general decrease in the EIQ-FU per acre by 65%. This includes a 74% reduction in impact on farmers and farmworkers, a 68% decrease in the impact on consumers, and a 63% decrease in ecological impact. This trend suggests a general reduction in the potential adverse effects of herbicides on the environment, biodiversity, and individuals. Additionally, there is a 45% reduction in the number of grams of AI applied per acre, which reflects a change in herbicide use patterns rather than a direct measure of efficiency.

Table 6. Environmental impact trends of top five in-crop herbicides from 1991 to 1994 and from 2016 to 2019: reductions in EIQ-FU and effects on farmers, consumers, and ecology. a

a Abbreviations: ai, active ingredient; EIQ, environmental impact quotient; EIQc, EIQ on consumers; EIQe, EIQ on the ecology; EIQf, EIQ on farmers and farmworkers; EIQ-FU, field use EIQ.

Statistical analysis confirms strong correlations between the different EIQ components for both periods. In the 1991 to 1994 period, the correlations were r = 0.983 (EIQf − EIQc), r = 0.951 (EIQf − EIQe), and r = 0.977 (EIQc − EIQe). For the 2016 to 2019 period, these values were r = 0.976, r = 0.960, and r = 0.875, respectively. These strong positive correlations for both periods suggest that enhancements in one aspect of environmental impact are closely associated with improvements in others. The paired t-test, with a P-value of 0.0652, indicates that while there are notable decreases in EIQ values between the two periods, the differences are not statistically significant at the conventional 5% level. This means that, statistically, we cannot be confident that the differences observed are not due to random choice. Thus, although the trends are promising, they are not statistically conclusive, underlining the need for continued research.

The results provide a view on the evolution of herbicide use and the resulting environmental impacts prior to the commercialization of GM crops compared to recent crop production and herbicide use. Initially, herbicides like MCPA and diclofop-methyl were predominant, but by 2016 to 2019, there was a noticeable shift toward substances like glyphosate and glufosinate, known for their lower environmental impact (Dennis et al. Reference Dennis, Kukulies, Forstner, Orton and Pattison2018; Duke Reference Duke2020). This transition aligns with the broader adoption of GM crops and the consequent reduction in tillage for weed control (Brookes Reference Brookes2022; Sutherland et al. Reference Sutherland, Gleim and Smyth2021). Despite an increase in the number of acres sprayed, the environmental impact of herbicides has decreased, underlining the role of GM crops and technological advancements in introducing less toxic herbicides (Bonny Reference Bonny2016). This shift has been crucial in replacing older, more harmful soil-incorporated and residual herbicides with more benign alternatives (Gunstone et al. Reference Gunstone, Cornelisse, Klein, Dubey and Donley2021).

Smyth et al. (Reference Smyth, Gusta, Belcher, Phillips and Castle2011) reported a 53% decrease in in-crop herbicide EIQ following a decade of GM crop commercialization. The results from this research contradict predictions that the environmental benefits of GM crops would be fleeting, as our data extend the benefits to 20 yr, showing not only consistent but increased benefits.

The shift away from tillage to herbicide use aligns with the reduced environmental impacts observed over the past 30 yr. Studies have shown the negative effects of tillage on soil quality and greenhouse gas emissions (Awada et al. Reference Awada, Lindwall and Sonntag2014; Aziz et al. Reference Aziz, Mahmood and Islam2013; McConkey et al. Reference McConkey, Liang, Campbell, Curtin, Moulin, Brandt and Lafond2003; Nath and Lal Reference Nath and Lal2017; Sutherland et al. Reference Sutherland, Gleim and Smyth2021; West and Post Reference West and Post2002). The preference for herbicides in no-tillage systems represents a more sustainable weed management approach. However, it is important to clarify that our analysis is confined to the use of in-crop herbicides. This is a critical distinction, as conservation tillage impacts primarily the use of preseed herbicides, not in-crop ones. Our study’s insights should not be interpreted as covering the broad spectrum of herbicide use influenced by conservation tillage practices.

The trend of restricting modern herbicides like glyphosate presents challenges. Such restrictions could revert farmers to older, more toxic chemicals and increased tillage, countering sustainability efforts. Sustainable management is crucial for long-term environmental and economic health, and farmers are motivated to reduce their operations’ environmental impacts. The shift to no-till management since the 1990s indicates a preference for chemical use within these systems as a sustainable weed management strategy (AAFC 2014; Haak Reference Haak2005; Sutherland et al. Reference Sutherland, Gleim and Smyth2021).

Continued sustainability requires proper crop rotation and avoiding an overreliance on a single herbicide mode of action to prevent the development of herbicide resistance in weeds. Ongoing research for new herbicides with reduced ecological impacts is crucial. This research’s findings on EIQ changes are beneficial to agricultural and environmental policy, underscoring the need for robust evidence in policy debates about herbicide use and the importance of ongoing herbicide development.

Practical Implications

These results underscore the significant evolution in herbicide use and its environmental impacts in Saskatchewan agriculture, particularly highlighting the transition from tillage to herbicide-resistant cropping systems. This shift, predominantly toward less environmentally impactful herbicides like glyphosate and glufosinate, illustrates a strategic adaptation by farmers to enhance sustainability. Our analysis, grounded in comprehensive EIQ data across different crop rotation periods, demonstrates a notable reduction in the environmental and toxicological impacts of herbicides used. This affirms the role of technological advancements in agriculture, such as the development of more environmentally and biodiversity-friendly herbicide formulations and the adoption of precision agriculture techniques.

For practitioners, these insights emphasize the need to adopt herbicide-resistant crops as a sustainable approach to weed management, potentially offering environmental benefits. This is especially relevant in the context of increasing global concerns about environmental sustainability and the need for more efficient farming practices. Additionally, the study highlights the importance of balancing chemical use with environmental stewardship, suggesting a continued need for innovation in agricultural practices. This balance is key to ensuring long-term soil health and ecosystem stability, which are essential for sustainable agriculture.

For those in the field, this research provides a valuable perspective on the long-term trends in herbicide use, offering a framework to make informed decisions that align with agricultural practices. The shift toward using herbicides with a lower EIQ, as demonstrated in our findings, reflects an ongoing effort to minimize the environmental footprint of crop production. It is important for practitioners to stay informed about these evolving trends and to integrate such insights into their weed management strategies to maintain both crop productivity and environmental integrity.

Funding

This research was funded through the Canada First Research Excellence Fund (CFREF) grant that established the Plant Phenotyping and Imaging Research Centre (P2IRC) project.

Competing interests

The authors declare no conflicts of interest.

Footnotes

Associate Editor: Charles Geddes, Agriculture and Agri-Food Canada

References

ADAMA West Canada (2021) The Grower’s Guide to Imazamox. https://www.adama.com/west-canada/en/news/the-growers-guide-to-imazamox. Accessed: December 15, 2023Google Scholar
[AAFC] Agriculture and Agri-Food Canada (2014) Flexibility of no till and reduced till systems ensures success in the long term. https://agriculture.canada.ca/en/agricultural-production/soil-and-land/soil-management/flexibility-no-till-and-reduced-till-systems-ensures-success-long-term. Accessed: December 15, 2023Google Scholar
[AAFC] Agriculture and Agri-Food Canada (2022) Pesticides Indicator. https://agriculture.canada.ca/en/agricultural-production/water/pesticides-indicator. Accessed: April 11, 2023Google Scholar
Allum, N, Sturgis, P, Tabourazi, D, Brunton-Smith, I (2008) Science knowledge and attitudes across cultures: a meta-analysis. Publ Understand Sci 17:3554 CrossRefGoogle Scholar
Awada, L, Lindwall, CW, Sonntag, B (2014) The development and adoption of conservation tillage systems on the Canadian prairies. Int Soil Water Conserv Res 2:4765 CrossRefGoogle Scholar
Aziz, I, Mahmood, T, Islam, KR (2013) Effect of long term no-till and conventional tillage practices on soil quality. Soil Till Res 13:2835 CrossRefGoogle Scholar
Beckie, HJ, Sikkema, PH, Soltani, N, Blackshaw, RE, Johnson, EN (2014) Environmental Impact of glyphosate-resistant weeds in Canada. Weed Sci 62:385392 CrossRefGoogle Scholar
Bonny, S (2016) Genetically modified herbicide-tolerant crops, weeds, and herbicides: overview and impact. Environ Manag 57:3148 CrossRefGoogle ScholarPubMed
Brimner, TA, Gallivan, GJ, Stephenson, GR (2005) Influence of herbicide-resistant canola on the environmental impact of weed management. Pest Manag Sci 61:4752 CrossRefGoogle ScholarPubMed
Brookes, G (2022). Genetically modified (GM) crop use 1996–2020: impacts on carbon emissions. GM Crops Food 13:242261 CrossRefGoogle ScholarPubMed
Brookes, G, Barfoot, P (2017) Environmental impacts of genetically modified (GM) crop use 1996–2015: impacts on pesticide use and carbon emissions. GM Crops Food 8:117147 CrossRefGoogle ScholarPubMed
Cerdeira, AL, Duke, SO (2010) Effects of glyphosate-resistant crop cultivation on soil and water quality. GM Crops 1:1624 CrossRefGoogle ScholarPubMed
de Souza, AP, Burgess, SJ, Doran, L, Hansen, J, Manukyan, L, Maryn, N, Gotarkar, D, Leonelli, L, Niyogi, KK, Long, SP (2022) Soybean photosynthesis and crop yield are improved by accelerating recovery from photoprotection. Science 377:851854 CrossRefGoogle ScholarPubMed
Dennis, PG, Kukulies, T, Forstner, C, Orton, TG, Pattison, AB (2018) The effects of glyphosate, glufosinate, paraquat and paraquat-diquat on soil microbial activity and bacterial, archaeal and nematode diversity. Sci Rep 8:2119 CrossRefGoogle ScholarPubMed
Derpsch, R, Friedrich, T, Kassam, A, Li, H (2010) Current status of adoption of no-till farming in the world and some of its main benefits. Int J Agric Biol Eng 3:125 Google Scholar
Duke, SO (2020) Glyphosate: environmental fate and impact. Weed Sci 68:201207 CrossRefGoogle Scholar
Duke, SO, Powles, SB (2008) Glyphosate: a once-in-a-century herbicide. Pest Manag Sci 64:319325 CrossRefGoogle ScholarPubMed
Dushoff, J, Caldwell, B, Mohler, CL (1994) Evaluating the environmental effect of pesticides: a critique of the environmental impact quotient. Am Entomol 40:180184 CrossRefGoogle Scholar
Environment and Parks (2020) Overview of 2018 pesticide sales in Alberta. https://open.alberta.ca/publications/9781460148167. Accessed: December 10, 2023Google Scholar
Eshenaur, B, Grant, J, Kovach, J, Petzoldt, C, Degni, J, Tette, J (n.d.) Environmental impact quotient: “a method to measure the environmental impact of pesticides.” New York State Integrated Pest Management Program, Cornell Cooperative Extension. https://ecommons.cornell.edu/items/2feca8d7-3889-4a41-aae9-a2ce0f16a6e2. Accessed: March 15, 2024Google Scholar
[FAO] Food and Agriculture Organization (2023) European Union’s farm to fork strategy—for a fair, healthy and environmentally-friendly food system. https://www.fao.org/agroecology/database/detail/en/c/1277002/. Accessed: April 06, 2023Google Scholar
Gagneten, AM, Regaldo, L, Carriquiriborde, P, Reno, U, Kergaravat, SV, Butinof, M, Agostini, H, Alvarez, M, Harte, A (2023) Atrazine characterization: an update on uses, monitoring, effects, and environmental impact, for the development of regulatory policies in Argentina. Integr Environ Assess Manag 19:684697 CrossRefGoogle ScholarPubMed
Grant, JA (n.d.) Calculator for field use EIQ (environmental impact quotient). New York State Integrated Pest Management Program, Cornell Cooperative Extension. https://cals.cornell.edu/new-york-state-integrated-pest-management/risk-assessment/eiq/eiq-calculator. Accessed: December 20, 2023Google Scholar
Gunstone, T, Cornelisse, T, Klein, K, Dubey, A, Donley, N (2021) Pesticides and soil invertebrates: a hazard assessment. Front Environ Sci 9:643847 CrossRefGoogle Scholar
Haak, D (2005) Issues, management problems and solutions for maintaining a zero-tillage system and other beneficial soil management practices. https://agriculture.canada.ca/en/agricultural-production/soil-and-land/soil-management/issues-management-problems-and-solutions-maintaining-zero-tillage-system-and-other-beneficial-soil. Accessed: July 25, 2023Google Scholar
Hayes, TB, Anderson, LL, Beasley, VR, De Solla, SR, Iguchi, T, Ingraham, H, Kestemont, P, Kniewald, J, Kniewald, Z, Langlois, VS, Luque, EH, McCoy, KA, Muñoz-De-Toro, M, Oka, T, Oliveira, CA, Orton, F, Ruby, S, Suzawa, M, Tavera-Mendoza, LE, Trudeau, VL, Victor-Costa, AB, Willingham, E (2011) Demasculinization and feminization of male gonads by atrazine: consistent effects across vertebrate classes. J Steroid Biochem Mol Biol 127:6473 CrossRefGoogle ScholarPubMed
Health Canada (2019) Statement from Health Canada on glyphosate. https://www.canada.ca/en/health-canada/news/2019/01/statement-from-health-canada-on-glyphosate.html. Accessed: July 25, 2023Google Scholar
Helling, CS (2005) The science of soil residual herbicides. Pages 3–22 in Van Acker RC, ed. Soil Residual Herbicides: Science and Management. Volume 3. Quebec, ON: Canadian Weed Science Society/Société canadienne de malherbologieGoogle Scholar
Hiller, E, Krascsenits, Z, Čerňanský, S (2008) Sorption of acetochlor, atrazine, 2,4-D, chlorotoluron, MCPA, and trifluralin in six soils from Slovakia. Bull Environ Contam Toxicol 80:412416 CrossRefGoogle ScholarPubMed
Hobbs, PR, Sayre, K, Gupta, R (2008) The role of conservation agriculture in sustainable agriculture. Philos Trans R Soc London Ser B 363:543555 CrossRefGoogle ScholarPubMed
Kniss, AR, Coburn, CW (2015) Quantitative evaluation of the environmental impact quotient (EIQ) for comparing herbicides. PLoS One 10:e0131200 CrossRefGoogle ScholarPubMed
Kovach, J, Petzoldt, C, Degni, J, Tette, J (1992) A method to measure the environmental impact of pesticides. NY Food Life 139:18 Google Scholar
Kynetec (2022) Sri Lanka: impact assessment study of 2021—ban on conventional pesticides and fertilizers. St. Louis, MO: Kynetec. 8 pGoogle Scholar
Lal, R, Follett, RF, Stewart, BA, Kimble, JM (2007) Soil carbon sequestration to mitigate climate change and advance food security. Soil Sci 172:943956 CrossRefGoogle Scholar
MacWilliam, S, Sanscartier, D, Lemke, R, Wismer, M, Baron, V (2016) Environmental benefits of canola production in 2010 compared to 1990: a life cycle perspective. Agric Syst 145:106115 CrossRefGoogle Scholar
Malaj, E, Freistadt, L, Morrissey, CA (2020) Spatio-temporal patterns of crops and agrochemicals in Canada over 35 years. Front Environ Sci 8:556452 CrossRefGoogle Scholar
Marambe, B, Herath, S (2020) Banning of herbicides and the impact on agriculture: the case of glyphosate in Sri Lanka. Weed Sci 68:246252 CrossRefGoogle Scholar
McConkey, BG, Liang, BC, Campbell, CA, Curtin, D, Moulin, A, Brandt, SA, Lafond, GP (2003) Crop rotation and tillage impact on carbon sequestration in Canadian prairie soils. Soil Till Res 74:8190 CrossRefGoogle Scholar
Nath, AJ, Lal, R (2017) Effects of tillage practices and land use management on soil aggregates and soil organic carbon in the North Appalachian region, USA. Pedosphere 27:172176 CrossRefGoogle Scholar
[PMRA] Pest Management Regulatory Agency (2017) Re-evaluation decision RVD2017-01, glyphosate. https://publications.gc.ca/collections/collection_2017/sc-hc/H113-28/H113-28-2017-1-eng.pdf. Accessed: March 15, 2024Google Scholar
Peterson, RKD, Schleier, JJ (2014) A probabilistic analysis reveals fundamental limitations with the environmental impact quotient and similar systems for rating pesticide risks. PeerJ 2:e364 CrossRefGoogle ScholarPubMed
Rust, B, Williams, JD (n.d.) How tillage affects soil erosion and runoff. http://soils.usda.gov/sqi/publications/files/Infiltration.pdf. Accessed: December 17, 2023Google Scholar
Sikkema, PH, Robinson, DE (2005) Residual herbicides: an integral component of weed management systems in eastern Canada. Pages 89–100 in Van Acker RC, ed. Soil Residual Herbicides: Science and Management. Volume 3. Quebec, ON: Canadian Weed Science Society/Société canadienne de malherbologieGoogle Scholar
Smyth, SJ, Gusta, M, Belcher, K, Phillips, PWB, Castle, D (2011) Changes in herbicide use after adoption of HR canola in western Canada. Weed Technol 25:492500 CrossRefGoogle Scholar
Statistics Canada (2023) Estimated areas, yield, production, average farm price and total farm value of principal field crops, in metric and imperial units. https://www150.statcan.gc.ca/t1/tbl1/en/tv.action?pid=3210035901. Accessed: February 25, 2023Google Scholar
Sutherland, C, Gleim, S, Smyth, SJ (2021) Correlating genetically modified crops, glyphosate use and increased carbon sequestration. Sustainability 13:11679 CrossRefGoogle Scholar
Sutherland, C, Sim, C, Gleim, S, Smyth, SJ (2020) Canadian consumer insights on agriculture: addressing the knowledge-gap. J Agric Food Inf 21:5072 CrossRefGoogle Scholar
Turnbull, C, Lillemo, M, Hvoslef-Eide, TAK (2021) Global regulation of genetically modified crops amid the gene edited crop boom—a review. Front Plant Sci 12:630396 CrossRefGoogle Scholar
Van Acker, R, Rahman, MM, Cici, SZH (2017) Pros and cons of GMO crop farming. In Oxford Research Encyclopedia of Environmental Science. https://oxfordre.com/environmentalscience/view/10.1093/acrefore/9780199389414.001.0001/acrefore-9780199389414-e-217. Accessed: March 8, 2024Google Scholar
Verity, GE, Anderson, DW (2011) Soil erosion effects on soil quality and yield. Can J Soil Sci 70:471484 CrossRefGoogle Scholar
Waite, DT, Cessna, AJ, Grover, R, Kerr, LA, Snihura, AD (2004) Environmental concentrations of agricultural herbicides in Saskatchewan, Canada: bromoxynil, dicamba, diclofop, MCPA, and trifluralin. J Environ Qual 33:16161628 CrossRefGoogle ScholarPubMed
West, TO, Post, WM (2002) Soil organic carbon sequestration rates by tillage and crop rotation. Soil Sci Soc Am J 66:19301946 CrossRefGoogle Scholar
Wisner Baum (2022) Where is glyphosate banned? https://www.wisnerbaum.com/toxic-tort-law/monsanto-roundup-lawsuit/where-is-glyphosate-banned-/. Accessed: August 13, 2023Google Scholar
Figure 0

Figure 1. Map of provincial survey participant locations.

Figure 1

Table 1. Total participant demographics compared to Saskatchewan 2016 Census of Agriculture.

Figure 2

Table 2. Baseline EIQs for in-crop herbicides applied in Saskatchewan (1991 to 1994): analysis of active ingredient use, EIQ factors, and ecological impacts.a

Figure 3

Table 3. Detailed environmental impact assessment of in-crop herbicides in Saskatchewan (1991 to 1994): cumulative and per acre impacts on ecology, farmers, and consumers.a

Figure 4

Table 4. Comparative EIQs of top in-crop herbicides in Saskatchewan (2016 to 2019): glyphosate, glufosinate, imazamox, 2,4-D, and clethodim.a

Figure 5

Table 5. Comprehensive environmental impact assessment of in-crop herbicides in Saskatchewan (2016 to 2019): ecological, farmer, and consumer effects.a

Figure 6

Table 6. Environmental impact trends of top five in-crop herbicides from 1991 to 1994 and from 2016 to 2019: reductions in EIQ-FU and effects on farmers, consumers, and ecology.a