II. The presence of glyphosate in water and its impact on ecosystems

Narratives of how – even whether – pesticides impact (aquatic) ecosystems seem to be neatly aligned with different positions on the role of industrial agriculture.Footnote ¹⁷ This section explores the risks of glyphosate for aquatic ecosystems – chemical impacts on ecosystem functionality or biodiversity – highlighting specific controversies as debated in environmental science and policy.

Pesticides like herbicides (herbicides are here considered a subset of pesticides) applied to crops impact soil, agricultural irrigation channels and runoff.Footnote ¹⁸ Runoff from these applications has different impacts on varying types of aquatic environments, such as ground water, rivers, wetlands and reservoirs. Both direct and indirect runoff can affect water in proportion to the amount of chemicals applied, how focused they are sprayed on plants, the adhesives or adjuvants in the chemical and the size and ecological structure of the water system.

Europe is an outlier globally in terms of peak concentrations for glyphosate in waterbodies. In Europe, there are persistent but low concentrations of glyphosate. In many other global regions, peak concentrations sometimes reach up to 10,000 times the concentration of average EU levels.Footnote ¹⁹ While ecotoxicologists in Europe acknowledge that glyphosate exacerbates and compounds multiple environmental stressors and water quality issues,Footnote ²⁰ they simultaneously fear that likely alternative replacement chemicals, which would make their way through prevailing chemical regulation frameworks, could be even more environmentally harmful – if agricultural production continues unchanged.Footnote ²¹ This suggests that plans to make EU glyphosate-free must also be accompanied by the larger challenge of reducing chemical inputs in agriculture in general; and that failing to address these issues in tandem may land regulators in the same tight spot they find themselves in with glyphosate, only next time with glyphosate’s successor.Footnote ²²

Various statutes and laws in national and EU legislation protect water from chemical runoff, all of which have fundamental strengths and flaws. The central piece of legislation on water quality, with an ambitious schedule and a reporting system that has re-orientated water management approaches throughout Europe, is the EU Water Framework Directive (WFD). Its twin objectives stipulate that European waterbodies should be in good chemical and ecological condition. Pesticides (including herbicides such as glyphosate) can be found to violate these objectives in waterbodies either by exceeding environ mental quality standards (EQSs; chemical status) or by significantly impacting the ecology of a waterbody (ecological status). Notably, glyphosate is not among the substances of the EU WFD’s daughter directive on EQSs for surface waters 2008/105/EC, which sets limits and monitoring obligations for around forty-five specifically hazardous chemical substances (not only pesticides). As it is formally a EU directive that specifies certain substances rather than others, the decision-making process is highly political: if a Member State fails to limit only one of forty-five substances, then the whole regulation of the chemical status is regarded as failed for a specific monitoring period. In other words, to regulate a substance through this directive requires a high degree of consensus on the chemical’s danger to reach the threshold of regulation. Likewise, the directive is predominantly formulated to apply to large waterbodies and the chemicals found therein, which means that smaller streams common in agricultural landscapes are often excluded from river basin management plans. Despite the lack of systematic monitoring of glyphosate residues in water, evidence has emerged as to its presence in Europe. In its Report on Glyphosate, the European Food Safety Authority (EFSA) acknowledges that glyphosate and its metabolite aminomethylphosphonic acid (AMPA; which maintains the same properties of glyphosate but is more persistent) have been found in a number of countries above the parametric limits. Italy is a case in point, where a study by the Italian Higher Institute for Environmental Protection and Research (ISPRA) in the “National Report of Pesticides in Water” found that “[i]n surface waters, 274 points of monitoring (21.3% of the total) show glyphosate concentrations above the limits imposed to guarantee environmental quality standards”.Footnote ²³

Similar to the political debate around glyphosate,Footnote ²⁴ aspects of the scholarly debate within ecotoxicology have been extraordinarily heated regarding the extent to which glyphosate-containing products harm aquatic ecosystems.Footnote ²⁵ In an unusually hostile academic exchange in the journal Ecological Applications, two groups of authors have accused each other of unscientific behaviour – claiming that Roundup^® is either generally harmful or generally safe for amphibians. Contributors to this and subsequent debates have sought to disqualify the other’s research by pointing out the role of corporate or non-governmental organisation (NGO) funding influencing the neutrality of their assessments.Footnote ²⁶ At the centre of the controversy were claims regarding Roundup^®, the top-selling herbicide product containing glyphosate as its active compound, as well as the surfactant polyoxyethyleneamine (POEA) and its impact on lethality to tadpoles (with the claim being: “Amphibians Are Not Ready for Roundup^®”).Footnote ²⁷ Here, the discussion has focused on the so-called “inert” ingredients/additives that are part of commercial formulations of herbicides. To penetrate leaves and to stick to them rather than washing off, Monsanto (now Bayer) has insisted on the need for such additives.Footnote ²⁸ Inert ingredients are typically trade secrets, and the academic discussion has focused on the core issue that the products used outside the laboratory and in the field are a combination of a highly scrutinised substance (glyphosate) and under-regulated additives that makes the product highly toxic to amphibians (eg which penetrate through tadpole gill cells). Critics see a pattern in the risk assessment systematically underestimating the harm of adjuvants.Footnote ²⁹ Similar intra-scientific controversies have occurred related to a different herbicide, atrazine, where a similar drama unfolded with accusations of corporate sponsoring of “industrial product defence research” and eco-activist research.Footnote ³⁰ While the glyphosate and atrazine cases may be the most notable discussions in the literature, in mainstream ecotoxicology building on field studies, it is increasingly clear that there are negative effects on aquatic biodiversity or freshwater ecosystem functions from pesticides more generally.Footnote ³¹

A non-systematic search demonstrates the range of ecological effects for which glyphosate has been implicated in the toxicology literature. Glyphosate’s direct toxic effects have been described as lethalFootnote ³² to affected organisms such as amphibians or pollywogs, or sub-lethalFootnote ³³ but leading to dysergistic (negative synergy) impairment to affected organisms such as honeybees, spiders and lacewings.Footnote ³⁴ As described by the German Federal Agency for Nature Protection (BfN) in their remarkable position paper on glyphosate,Footnote ³⁵ the two main ways glyphosate can impact biodiversity are through: (1) direct toxic effects on non-target organisms; or (2) indirect effects on non-target organisms. Direct toxic effects on non-target organisms are further subdivided into lethal and sub-lethal effects. Because of its chemical structure, from a purely theoretical analysis, it is widely assumed – correctly or not – that there are no direct effects of glyphosate on insects. Most biologists indicate that glyphosate’s principal effects on insects result from harms to food webs that negatively impact the agricultural landscape and organisms. Thus, the German environmental ministry claims: “The use of broad spectrum herbicides such as glyphosate does not kill insects directly”.Footnote ³⁶ The tricky part, however, is that the complicated indirect effects (as well as a range of conceptions of what counts as an indirect effect) actually do end up harming a variety of insects.Footnote ³⁷ The complexity of these effects is exploited by various actors to give vastly contrastive interpretations about the scale of the problem and the chemical’s safety. The impact of glyphosate in water includes indirect harms to the insects and other lifeforms that inhabit it.

The most influential EU agency in this sphere is EFSA, which advises the Commission and has been at the centre of European glyphosate regulation through its risk assessment.Footnote ³⁸ EFSA notes that glyphosate acts as a broad-spectrum herbicide against all plants that are not protected by a specific genetic modification. The active ingredient stops the synthesis of certain amino acids that are essential for plant growth, leading to plant death. As an individual substance, glyphosate has a relatively low (eg chronic) toxicity compared to the worst agrochemicals historically – such as DDT – and appears much less immediately toxic; here, most ecotoxicologists and regulatory agencies agree.

Yet, as debated as the dysergistic toxicity of glyphosate plus its adjuvants has been for EFSA, less recognised or accounted for in toxicity regulation has been glyphosate’s indirect effects on aquatic ecosystems. Because of the complexities of chemically dependent agricultural production systems and land use configurations impacting biodiversity, these often delayed or indirect processes have received less focus in chemical regulation. Agrochemical use is linked to reduced biodiversity through cascading ecosystem effects involving freshwater contamination, even if biodiversity loss may not be directly caused by it.Footnote ³⁹ “Indirect effects” are usually described as the deterioration of plant and microbial life in agricultural landscapes; these effects are especially demonstrable on food webs. The influential 2019 Leopoldina report describes how, at the community level, herbicides doing damage to plants will have indirect food chain effects (glyphosate was explicitly named), and that these processes have not been adequately accounted for in regulatory approval procedures (which focus on individual populations instead).Footnote ⁴⁰ Yet different disciplines and even different schools of thought within ecology disagree over the implications of “indirect” ecological effects. We designate “indirect effects” here to encompass the notion of indirect toxicological and ecological effects that can result from dysergistic amplification through other effluents and exposures stemming from industrialised agricultural production. Concretely, glyphosate enables and furthers the usage of vast monocultural landscapes (and hence, inter alia, limits crop rotation and locks in specific economics activities and food supply and land use arrangements). These indirect effects from use on production processes have knock-on effects that potentiate the actual direct biochemical risks of glyphosate and its adjuvants. As the most used herbicide worldwide (total historical use globally until 2016 amounts to 6.1 billion kilograms),Footnote ⁴¹ whatever glyphosate’s determined indirect effects, by virtue of the volume of use, these indirect effects will likely be more pronounced and varied. The paradox that glyphosate is relatively inexpensive and putatively efficacious for crop protection in the dominant high-input agrichemical industrial food production model may render regulators reluctant to directly confront the other costs of the chemical, such as the ecological ones.Footnote ⁴²

Worldwide, glyphosate enables genetically modified (GM) plants to be bred to be glyphosate-resistant. In Europe, glyphosate is authorised for specific uses (in the context of GM crops being generally prohibited). In the case of Germany, for example, it is used mostly for stubble management (with uses such as siccation – the pre-harvest application of pesticides to quicken the crop-drying process – increasingly being outlawed), while in select countries glyphosate is also approved for aquatic or semi-aquatic use. Broad agreement among the regulators involved in the two authorisation procedures at the European and national levels exists that glyphosate and glyphosate-based products themselves do not constitute major problems for biodiversity in Europe according to the metrics of the prevailing risk assessment system.

The seeming consensus on the lack of direct biodiversity problems of glyphosate is surprising, as for some pesticides, such as neonicotinoids, achieving scientific consensus regarding clearly demonstrated biodiversity impacts has been swift and effective for establishing the case for regulatory action.Footnote ⁴³ Yet for glyphosate, scientists and policymakers by and large have agreed that, for the purposes of the European authorisation processes, glyphosate should not be outlawed for ecological reasons. It should be noted, however, that the risk assessment system unnecessarily confines itself to single-substance analysis only, as discussed below. Agencies such as Germany’s BfN, for example, which are not directly involved in the authorisation system or risk assessment, have been much more critical of the biodiversity effects of glyphosate than the responsible regulatory agencies involved in the two-tier authorisation system, claiming that “the current state of science indicates that indirect effects of glyphosate or glyphosate-containing herbicides on non-target species in particular pose a high risk to biodiversity”.Footnote ⁴⁴ Such statements contrast with industry assessments that argue that a ban on glyphosate is associated with increased environmental pressures from agriculture due to compensating by deploying more intensive agribusiness practices requiring higher volumes of potentially more toxic chemicals, leading to worse biodiversity outcomes.Footnote ⁴⁵

Such outsider opinions to established regulatory systems circumvent entrenched risk assessment paradigms and criticise regulatory agencies for regulating only individual chemicals in isolation rather than the admixtures used in practice.Footnote ⁴⁶ Likewise, cocktail effects and multiple stressors are at the same time observed as being understudiedFootnote ⁴⁷ and are thought to be under-regulated, as certain substances are potentiated by others (eg atrazine and glyphosate amplifying each other’s toxicological affects).Footnote ⁴⁸ One study looking at how sunlight can potentiate the toxicity of certain pesticides assaying cell micronuclei found pesticides, including glyphosate, to be twenty-fold more toxic when mixed, and the mixture became 100 times more toxic after light irradiation due to oxidative stress.Footnote ⁴⁹ Prevailing environmental risk assessment methods are widely acknowledged to be deficient for accurately measuring the unintended cocktail effects of pesticides.Footnote ⁵⁰ It is no simple matter, however, to resolve this issue: complications regarding risk assessments of pesticides are controversial and receive a high level of scrutiny.Footnote ⁵¹

In addition to the discrepancy of regulatory assessments focusing on single isolated chemicals and the cocktail mixtures of chemicals actually applied in situ are the problems of so-called “higher tiered” risk assessments. Higher-tiered issues coalesce around the deficiency of pesticide risk assessments based on models of predicted exposure concentration (PEC) in the environment as required within legal bounds of certain concentrations in order to be designated safe for non-target organisms in EU as well as US risk assessment. In this system, the regulatory acceptable concentration (RAC) is the cornerstone of the risk assessment process. This threshold has been problematised as a “controlled experimental tiered risk assessment approach, giving results that are difficult to extrapolate to a real-world situation”.Footnote ⁵² Reliance on ecotoxicity data from “laboratory and semifield (so-called mesocosm) studies”Footnote ⁵³ alone is particularly problematic, as safety concentrations are established through “[s]tandard toxicity tests, i. e., tests performed with single chemicals and single species under laboratory conditions without additional stressors”.Footnote ⁵⁴ A Pesticides Action Network (PAN) report notes the following: “Microcosm and mesocosm systems are widely used in pesticide approvals; their attractiveness can easily be explained because the standards for aquatic toxicity can be made less strict [emphasis added] in numerous ways compared to the lower tier studies. This is partly due to the system itself (clean water, no pollution, variety of organisms) and statistical methods applied but also because uncertainty factors are lowered or not used anymore in higher tier”.Footnote ⁵⁵

Such toxicity analyses are a far cry from the other threshold, which operationalises “[s]afety factors (also called assessment factors) that account for uncertainties in the extrapolation to real ecosystems”.Footnote ⁵⁶ This evident mismatch between results from field studiesFootnote ⁵⁷ (showing that the “relationship between pesticide exposure and community composition is causal”) and experimental tests relevant for regulation excludes the key ingredient for regulations: actual outcomes rather than theoretical safety. Apart from underspecified protection goals, Schäffer et al argue that there is no “scientifically validated prediction framework” that combines “ecological context, landscape context, farmer behaviour” and other non-laboratory aspects needed to predict exposure and effects.Footnote ⁵⁸ Instead, provisional authorisation solutions have been proposed (similar to suggestions to include post-monitoring of pesticide vigilance as guiding principles).

The relative problems with the tiered risk assessment system are less significant for unambiguously toxic pesticides where predicted exposure exceeds “safe concentrations”, but they are greater for pesticides where the gap between predicted and actual exposure widens. Agrochemicals that are less predictable in terms of their field toxicity can nonetheless be authorised “if the producer can show through further data that its environmental and human health impacts are acceptable”.Footnote ⁵⁹ The virtue of tiered frameworks is that they allow for extending assessment to further ecological safety analysis encompassing more complex scenarios where “[h]igher tiers integrate processes and characteristics occurring in natural ecosystems, such as multi-species semi-field test systems in the EU, as well as reduction of exposure through mitigation measures in risk management”.Footnote ⁶⁰ These aggregating assessments can usefully be fed back into reassessing risk at more core levels. Such analyses provide for water issues and ensuing biodiversity harms becoming more legible and weighty in risk assessments than they otherwise might.

Schäffer et al point out that the issue with this framework is that by default “authorization is given as long as the predicted exposure concentration (PEC) does not exceed the predicted no-effect concentration identified by single tiers, multiplied by the respective safety factor. Only substances that fail all tiers are not authorized”.Footnote ⁶¹ The most likely result of the safety threshold system is a no-effect judgment, because the regulatory edifice is built on laboratory toxicity testing and the format of tiered studies with little initial input from field studies. Such systematic underestimations (or type II biases) can lead to “inaccurate predictions of both exposure and effects in tiered system”.Footnote ⁶² This critique by ecotoxicologists of the existing risk assessment framework is shared by other scientists critical of glyphosate’s ecological harms.Footnote ⁶³ Likewise, the German Federal Environmental Agency (Umweltbundesamt, UBA) criticises tiered risk assessment as often counterproductive for ecosystems, unnecessarily expensive and too difficult to communicate to the public.Footnote ⁶⁴ The recent Leopoldina report entitled “The Silent Spring” also delineates problematic details of the tiered risk assessment as practised today, such as deliberately not double-checking pesticide effects that have been vetted at other levels.Footnote ⁶⁵ The very few experts on these issues are in consensus: “[C]ritical revisions of related pesticide regulations and effective mitigation measures are urgently needed to substantially reduce the environmental risks arising from agricultural insecticide use”.Footnote ⁶⁶

In recent months, the pan-European politicisation of glyphosate as a problematic chemical has brought the entire risk assessment framework under serious scrutiny.Footnote ⁶⁷ Nonetheless, possibly because there are only a handful of people who understand the intricacies of the issues at hand, or due to a lack of political interest groups advocating for the rights of aquatic ecosystems, the specific issue of harm to aquatic ecosystems as a result of omissions in the risk assessment framework has not been made.

Defenders of the status quo risk assessment procedures note that regulatory tools, especially the guidance recommendations used by EFSA, undergo continuous development, and already include indirect effects (albeit in the limited sense described above). New test and reference organisms can be specified and extended, and as climate conditions continue to change, updates to the pre-existing models can occur. Similarly, different models to calculate PECs are being constructed, with much effort being spent to coordinate such approaches across scientific and regulatory institutions. Even with these updates and addenda, however, the tiered framework does not consider aggregate pressure, and it uses laboratory tests as approximations of real-world effects. For these reasons, the tiering system prevents ecosystem effects from being material in decision-making by isolating pertinent cross-effect observations through unnecessarily complex regulatory stringencies that are inscrutable to most involved parties. Glyphosate in its pure form (which occurs only in the laboratory) is paradoxically then assessed as low toxicity and perfectly “adapted” for regulatory systems unwilling or unable to capture real-world indirect effects – especially in aquatic systems.

III. Much more than glyphosate (or how risk assessment marginalises the assessment of environmental risk)

Bernhard Url, EFSA’s executive director, responded in a recent interview with news media Euractiv that he views the conflation of science and politics in the glyphosate saga as “unreasonable”:

Url is correct in assessing that glyphosate has ballooned into a banner representing a host of structural issues. Arguably, the glyphosate case is not just a symbol of “much more”, but an epiphenomenon of “much more”; it reflects that current risk regulation compartmentalises risk diagnoses in such a way that critical questions are eluded or “back-staged”.Footnote ⁶⁹ In fact, glyphosate is always excessive in its significance; there is no such a thing as raw glyphosate in its actual use. Glyphosate as actually applied in any of its over 700 commercial formulations used in the physical environment is blended with an array of compounds (such as adjuvants and co-formulants) and typically receives little scrutiny by domestic regulators, as mentioned above.Footnote ⁷⁰ The chemical imaginary of glyphosate as a pure product, divorced from its adjuvants and co-formulants, does not exist, and, as has been argued, should not be treated as if it did for regulatory purposes. Yet, risk assessments code current law to individually assessed chemicals without assessing them in the light of real-world chemistry, in which they are blended together. Treating chemicals separately from a regulatory perspective, instead of informing regulation by the science of chemistry and chemical interactions, is an expedient legal artifice. At this point, it is worth recalling that the European legal framework establishes a two-track system for the approval of pesticides: the active substance, in this case glyphosate, is assessed and approved at the EU level, whereas the different formulations are approved at the level of individual Member States and further circulated in the internal markets through mutual recognition.Footnote ⁷¹

The EU Parliament, in its 2018 Report on the Union’s authorisation procedure for pesticides, has noted the difficulties of approval procedures at the national level as follows: “… understaffing and/or underfunding may result in over-reliance on the assessment conducted for the approval of the active substances in the context of decisions for plant protection products”.Footnote ⁷² Assessing the numerous pesticide products containing glyphosate with the same degree of granularity as for active substances (~700 commercial formulations versus a single active substance) could in fact prove to be a daunting task and disrupt industrial agriculture. In this context, scholars have criticised the fact that “[p]esticide co-formulants considered to be inert are generally exempt from the requirement for establishing a tolerance limit, and for this reason, end-use commercial pesticide formulations escape from being subjected to chronic toxicity testing, despite the fact that the vast majority that have been tested are actually more toxic than the declared active ingredients alone”.Footnote ⁷³

In this respect, it warrants note that in the process for the 2017 re-authorisation of glyphosate, the EU Commission took the unprecedented decision to propose a ban on one of the main co-formulants used in glyphosate-based pesticides: POEA. Yet, POEA continues to be used in other pesticides (without glyphosate) and can be bought in the market “as a separate adjuvant mixture (product name Regain, authorization 9300433) to mix with a glyphosate formulation in the spray tank”.Footnote ⁷⁴ The fact that a specific co-formulant found to be dangerous at the EU level continues to be used in non-glyphosate-based pesticides is further evidence of how formulations containing toxic “ingredients” could more easily go undetected at the domestic level.

Against this background, one can agree with Dr Url in emphasising the importance of distinguishing “what is policy and what is science”. The choice to assess only the active substance (glyphosate) at the EU level cannot be separated from political choices. More generally, risk assessment is a practice that is deeply embedded in law. As one participant to an EFSA Management Board meeting said: “[I]t should be emphasized also that it is legally-binding evidence-based risk assessment [that EFSA is following] … that EFSA, by its mandate, will not take into consideration all available information for legal reasons”.Footnote ⁷⁵ The difficulty with agencies such as EFSA making risk assessments on chemicals such as glyphosate is that often such assessments become interpreted by the general public, as well as scientists, as scientific findings or official consensus rather than as hybrid practices rooted in science as well as in policy processes.Footnote ⁷⁶

The decision to structure risk assessment around the identification and measurement of certain risks by a single isolated substance is another notable political choice. The main health lens applied so far, for example, has been on carcinogenic risk. This is arguably because the EU Regulation establishes that carcinogenicity is a cut-off criterion to decide when a substance should be banned.Footnote ⁷⁷ Much less attention is paid, however, to environmental risks, and by extension the downstream environmental health threats, despite this regulation equally protecting the environment.Footnote ⁷⁸ The case of water is a representative example. A report by the NGO Pesticide Action Network alleges several instances of weakened protective standards throughout the EU regulatory framework through controversial risk assessment methodologies, highlighting specifically the treatment of potentially harmful metabolites in ground water as “non-relevant”.Footnote ⁷⁹ Generally, it is the description of data requirements in the sections on ecotoxicology and environmental fate and behaviour that is determinative.

When the risk to aquatic environments is considered, the EFSA report lacks clarity. The report’s conclusions mention that “[g]lyphosate and AMPA have been detected in Europe above the parametric limit of 0.1 μg/L in a number of instances. Detailed groundwater monitoring studies demonstrating that glyphosate exceeded the limit of 0.1 μg/L were available from Italy, Germany, the Netherlands, Sweden, France and Spain”. The assessors explain that these contaminations may be due to “misuse” of the product and that drinking water can be treated using chlorinating procedures.Footnote ⁸⁰ But even if “misuse” would be the primary case of the violation of parametric limits, should such “misuse” not be considered as part of the embodied risk?

Interestingly, in different contexts, other EU legal representatives consider the use or misuse of potentially toxic products as part of risk and hence of “risk assessment”. This has been an issue in the Hormones dispute between the EU and the USA. The World Trade Organization (WTO) Appellate Body has concluded that “abuse” or “misuse” of potentially toxic products can be considered as part of risk assessment.Footnote ⁸¹ In this context, the EU has tried to defend its precautionary policies (eg vis-à-vis the use of hormones in food chains for growth-promotion purposes), which, to be fully realised, may need a more holistic conceptualisation of risk assessment. It could be argued that by considering real harms as products of misuse rather than design or inaccurate modelling, both companies and regulatory agencies, across industries, effectively externalise actual risk.Footnote ⁸²

As mentioned above, another major limit to the type of risk assessment used for regulatory purposes is that it does not examine chemical mixtures and their synergistic (dysergistic) impacts.Footnote ⁸³ Yet, the aquatic environment is exposed to these mixtures together rather than single substances sequentially. Risk assessment practices also fail to retrospectively look at the data produced through environmental monitoring that examines the manifold ways through which chemicals are transformed by the substrate through which they travel and react.Footnote ⁸⁴ In this respect, the European Court of Auditors has issued a Special Report that criticises – among others – the deficient status of the environmental monitoring of pesticides.Footnote ⁸⁵

To fully understand how environmental risk is further side-lined in contemporary practices of risk assessment, we need to take a step back and look at how pesticides are regulated in Europe through Regulation 1107/2009 concerning the placing of PPPs on the market and Directive 2009/128/EC on the sustainable use of pesticides.Footnote ⁸⁶ The European legal framework can be seen as a dual system. As briefly mentioned above, on the one hand, active substances (such as glyphosate) are to be assessed and approved by EU institutions; on the other hand, the commercial products to be placed on the market (including co-formulants) are approved by national authorities and can further circulate in Europe by virtue of mutual recognition. Next to the authorisation process, this dual system is reproduced in how issues of sustainability are addressed. In this context, Directive 2009/128, which has the general goal of achieving “a sustainable use of pesticides by reducing the risks and impacts [not necessarily the amount] of pesticide [like glyphosate] use on human health and the environment and promoting the use of integrated pest management and of alternative approaches or techniques such as non-chemical alternatives to pesticides” (see Article 1, Directive 2009/128), establishes only few specific obligations on Member States (eg prohibition of aerial spraying, per Article 9). For the rest, it delegates to the Member States the enactment of specific measures through the adoption of National Action Plans (NAPs; see Article 4, Directive 2009/128). As a result, the question of whether the use of pesticides like RoundUp^® is reduced and/or used more sustainably depends on the measures adopted by individual Member States. In this context, it is worth mentioning that reduction targets are absent from virtually all NAPs (the main exception being France).Footnote ⁸⁷

NAPs have been widely criticised by environmental groups. Looking at the Directive itself, it becomes clear that, at the heart of the EU Directive, a vague political compromise ends up eliding concrete policy objectives: the Directive leaves slack in interpreting whether the absolute quantities of pesticides should be reduced, or “merely” the associated risk of pesticide use: “… risk reduction or use targets shall be set at times and targets for the restriction of use, in particular where the restriction of use is an appropriate instrument to achieve risk reduction in relation to the priority topics referred to in Article 15(2)(c)”. According to EU law, NAPs require stakeholder participation and, in principle, the possibility to publicly scrutinise pesticide-related plans. The inadequacy of these plans has been nowhere as clear as in Germany, where, in 2011, stakeholders that aligned with environmental interests left the NAP in protest (surprisingly, this included the commercial German association of energy and water industries, BDEW). NGOs report that a lack of transparency and a dubious selection of indicators were the reasons for their withdrawal from the NAP, noting that the ministry-led process would – in the end – strengthen the current system of agricultural use of chemical PPPs rather than reduce dependency on agrochemicals.Footnote ⁸⁸

In this way, the NAPs demonstrate power imbalances in participatory processes of environmental entrenched interests that contradict those of protectors of aquatic ecosystem health, and instead do not address issues such as the excessive use of glyphosate. In this context, PAN criticises the Dutch NAP as an example of private actors drawing up guidelines for agricultural application without broad stakeholder participation.Footnote ⁸⁹ The binding nature of the NAPs varies from country to country, but is extremely weak overall. In Denmark, for example, the ban of chemical pesticides in certain areas for urban drinking water falls into abstraction due to the lack of concretisation in determining an “overall pesticide load indicator”. In addition to countless unambitious declarations of intent, as in Germany or Poland, there are also processes of silent adoption of binding targets, as in the Netherlands in terms of plant protection plans, where plant protection monitors have been suddenly introduced.

In Germany, the coalition government announced a national insect protection programme that calls for the reduction of pesticides, especially glyphosate, with a specific stipulation of phasing out the herbicide completely by 2023.Footnote ⁹⁰ Polls in Germany suggested that more than seven out of ten people favour a ban on the substance,Footnote ⁹¹ which was cited to be a factor in the agreement of both agricultural and environmental ministries to this phase-out.Footnote ⁹² But Germany’s responsible agency BVL authorised its use until 15 December 2020 for another year, without any changes to application rules, or even regulation of private usage, or any type of minimisation/reduction strategy.Footnote ⁹³ And the Glyphosate Renewal Group – a group of agrochemical producers – has already submitted applications for renewal of the substance after 2023.Footnote ⁹⁴ The battle around glyphosate was the catalyst for the inception of the PEST Committee of the European Parliament in 2018.Footnote ⁹⁵

Regrettably, beyond the obligation of developing NAPs, the question of how Member States can and should assess the risks of pesticides remains elusive. As mentioned above, the Directive itself remains ambiguous as to the necessity (if not the urgency) of addressing the absolute quantities of pesticides discharged in the environment. In the Anthropocene, quantity is crucial to safety. But in a market-driven society, decreasing the quantity of agricultural inputs results in a net loss of income for the supplying manufactures. In this sense, it is remarkable how the regulatory framework marginalises questions of quantity. The fact that glyphosate is the most widely used active substance in pesticides worldwide is masterfully eclipsed by elusive NAPs. The words of Dr Url, which dissociate safety from use, may then reflect the resistance of a regulatory system that tends to privilege the protection of capital over the protection of the environment. At the very least, methodological assumptions baked into the system bias risk assessments towards the assumption of non-toxicity for all of the configurations of toxicity that are not known.

The case of water is exemplary in displaying how this disassociation seems to underpin the current EU legal framework, which marginalises sound appraisal and management of environmental risks. On the one hand, the legal framework recognises the importance of water; for example, Paragraph 15 of the Preamble of Directive 2009/128 explicitly refers to the fact that the “aquatic environment is especially sensitive to pesticides”, and that “[i]t is … necessary for particular attention to be paid to avoiding pollution of surface water and groundwater by taking appropriate measures, such as the establishment of buffer and safeguard zones or planting hedges along surface waters to reduce exposure of waterbodies to spray drift, drain flow and run-off”. Moreover, according to Article 11, Member States shall establish specific measures to protect the aquatic environment and drinking water. On the other hand, the legal framework fails to establish the institutions to systematically collect information and monitor the effects of pesticides on aquatic environments and to protect the aquatic environment in effective ways.Footnote ⁹⁶ Numerous reasons contribute to the undercutting of these principles, and critical NGOs admonish that crucial information is overlooked, hidden in guidance documents or circumvented through undetected non-compliance with such documents, with a further issue being the political process surrounding the nomination of experts to relevant committees.Footnote ⁹⁷

In short, the legal architecture by which most attention is directed towards assessing the carcinogenic risk of the active substance diverts attention away from other important risks deserving of consideration, such as the risk to surface water and ground water. Despite the acknowledgment in the legal text that the (aquatic) environment should be protected (eg Article 4 Regulation 1107/2009 and Paragraph 15 of the Preamble of Directive 2009/128), the legal framework lacks strong and well-coordinated provisions to address this issue. This is not only evidenced by the weak NAPs of individual Member States, but also by the proven pollution of watercourses by glyphosate and the absence of (planned) corrective measures.Footnote ⁹⁸ Regrettably, the concrete rules relating to the protection of surface and ground waters remain aspirational at best.