Fact-checked by Grok 2 weeks ago

Mecoprop

Mecoprop, chemically known as 2-(4-chloro-2-methylphenoxy)propanoic acid, is a synthetic belonging to the phenoxy acid class, with the molecular formula C₁₀H₁₁ClO₃. It functions as a selective, post-emergence by mimicking plant growth hormones, thereby disrupting normal and growth in broadleaf weeds, leading to their death. Mecoprop is widely used in turfgrass management, lawns, ornamental , sports fields, and occasionally in such as and fields to control weeds like clovers, chickweed, , and dandelions. It is often formulated as the more active R- (mecoprop-p or MCPP-p) and combined with other herbicides like 2,4-D or for enhanced efficacy in products such as Trimec or Triplet. Physically, it appears as a colorless to brown, odorless crystalline powder with a of 94°C, low , and in , making it suitable for and granular applications. Regarding safety, mecoprop is classified as slightly toxic to humans (EPA III, signal word "Caution"), with potential to cause eye irritation, skin rashes, , , and damage upon exposure; it is corrosive to eyes and may pose carcinogenic risks based on limited evidence. Environmentally, it exhibits moderate persistence in soil ( 3–21 days), high mobility leading to potential , low in aquatic organisms, and slight to birds and bees, prompting regulatory measures like application rate limits to mitigate runoff risks. The U.S. EPA completed its reregistration in 2007, deeming it eligible with amended labeling and use restrictions to protect and the environment.

Chemical Identity

Nomenclature and Formula

Mecoprop, also known as MCPP or methylchlorophenoxypropionic acid, is systematically named 2-(4-chloro-2-methylphenoxy)propanoic acid according to IUPAC nomenclature. The of mecoprop is C₁₀H₁₁ClO₃, with a molecular weight of 214.65 g/. The compound is identified by the 93-65-2 in its racemic form. Structurally, mecoprop features a ring with a substituent at the 4-position, a at the 2-position, and an ether-linked propanoic acid chain (-O-CH(CH₃)-COOH) attached at the 1-position, forming aryloxyalkanoic acid motif characteristic of this class of herbicides. Mecoprop exists as a chiral due to the in the propanoic acid side chain; commercial formulations typically contain the of (R)- and (S)-s, whereas mecoprop-P refers specifically to the herbicidally active (R)-, which has the CAS number 16484-77-8.

Physical and Chemical Properties

Mecoprop, in its form, appears as a white to off-white crystalline solid. The salts and esters of mecoprop, commonly used in commercial formulations, are typically colorless to yellow liquids. Its is 93–95 °C for the pure . Mecoprop decomposes before reaching its boiling point and does not have a defined boiling temperature. The compound exhibits high solubility in water, with a value of 620 mg/L at 20 °C, and is also soluble in organic solvents such as acetone, , and . As a weak acid, mecoprop has a of 3.1, which influences its and behavior in aqueous environments. Its (log Kow) is 2.6 at 5 (20 °C), indicating moderate that affects its partitioning between aqueous and phases. The is low, at 1.3 × 10^{-5} at 20 °C, contributing to its limited under ambient conditions. Mecoprop is a chiral featuring a stereogenic center at the alpha carbon of the propanoic acid chain, resulting in two s: (R)-mecoprop and (S)-mecoprop. The (R)- is the herbicidally active form, while the (S)- exhibits reduced or negligible activity. Mecoprop demonstrates under normal storage and environmental conditions, including hydrolytic stability across values of 5, 7, and 9 at temperatures up to 70 °C.

History and Development

Discovery and Research

Mecoprop was developed as part of the family during the and 1950s, building upon the discoveries of (2,4-D) during , which highlighted the herbicidal potential of synthetic auxins for selective weed management. These compounds were recognized for their ability to mimic plant growth hormones, disrupting normal development in susceptible plants. Initial synthesis and testing of mecoprop occurred in the and the in the early , with a focus on controlling broadleaf s in and turf settings. Mecoprop's auxin-mimicking were identified around 1950 and its as a post-emergence confirmed. Early evaluations emphasized its structural similarities to other phenoxy compounds like , positioning it as a complementary tool for weed suppression. Field trials conducted in the mid-1950s demonstrated mecoprop's selectivity, effectively targeting dicotyledonous weeds such as clovers and chickweed while exhibiting minimal impact on monocotyledonous crops like grasses and cereals. This differential response, attributed to varying auxin sensitivity between plant types, validated its use in agricultural systems without compromising crop yields. Enantioselective research on mecoprop began in the 1980s, revealing that the (R)-enantiomer is primarily responsible for its herbicidal activity, while the (S)-enantiomer shows limited or antagonistic effects. These findings, driven by advances in chiral separation techniques, led to the commercialization of enantiopure formulations like Mecoprop-P by the late 1980s, enhancing efficacy and reducing environmental loading of the inactive isomer.

Commercialization and Registration

Mecoprop was introduced commercially in 1956 in , initially as a selective for turf and lawns to control broadleaf weeds. This launch followed its identification as a herbicidal agent in 1953, marking an early application in non-crop areas like sports fields and ornamental turf. The compound, a phenoxypropionic acid derivative, was developed through research on related phenoxy acids in the early , building on the success of earlier auxinic herbicides like 2,4-D. In the United States, mecoprop received its first federal registration from the Environmental Protection Agency (EPA) in May 1964 as a general-use , primarily for post-emergence control of broadleaf weeds in turf and non-crop sites. Early formulations were available as the free acid, but to improve solubility and handling, salt forms such as the salt and esters like the isooctyl ester were introduced during the and , facilitating broader application in sprays and mixtures with other herbicides. By the 1970s, mecoprop saw widespread adoption in and turf management across and , often combined with and 2,4-D for enhanced efficacy against resistant weeds in cereals and lawns. This global expansion reflected its reliability as a selective mimic, with annual usage reaching significant levels in arable and non-arable settings. In the late , the enantiopure form, mecoprop-P (the herbicidally active R-enantiomer), was commercialized to reduce dosage rates and environmental load, with EPA registrations for technical mecoprop-P beginning in 1996.

Synthesis and Production

Industrial Manufacturing

The primary industrial manufacturing process for mecoprop employs a variant of the , wherein 4-chloro-2-methylphenol reacts with 2-chloropropionic acid under alkaline conditions catalyzed by . This forms the ether linkage essential to the herbicide's structure, typically yielding a of the (R)- and (S)-enantiomers. The reaction proceeds via of the phenol to generate the , which displaces the chloride from the alpha-position of 2-chloropropionic acid in an SN2 mechanism. The process involves heating the reactants to 80–100°C to facilitate , often in an aqueous or mixed system to enhance and efficiency. Following completion, the mixture is acidified with a such as to protonate the and isolate the mecoprop as a solid product through or . This step-by-step approach allows for high yields, typically exceeding 90% in optimized industrial setups. The balanced reaction equation is: \ce{C7H7ClO + ClCH(CH3)CO2H ->[NaOH] C10H11ClO3 + HCl} Mecoprop is manufactured on a large scale, with annual production in the ranging from 1,000 to 10,000 tonnes to meet agricultural demands. While the standard process produces the racemic form, enantioselective manufacturing for the more active (R)-, mecoprop-P, incorporates techniques such as selective or enzymatic post-synthesis, or asymmetric synthesis using chiral auxiliaries. Byproducts from the reaction primarily consist of and , arising from the neutralization of HCl by NaOH. Industrial operations emphasize waste minimization through recycling of aqueous streams, solvent recovery, and reuse of inorganic salts to reduce environmental impact and operational costs.

Key Precursors and Reactions

The primary precursor for mecoprop synthesis is 4-chloro-2-methylphenol, which is obtained through the selective chlorination of (2-methylphenol) in an aqueous medium using or hypochlorite sources such as and , under controlled (5-9) and temperature (0-50°C) conditions to favor para-chlorination. Another key reagent is 2-chloropropionic acid, derived from the chlorination of in the presence of or catalysts at elevated temperatures (110-120°C). The core reaction involves the where the phenoxide ion from 4-chloro-2-methylphenol, generated using as the base, attacks the alpha-carbon of 2-chloropropionic acid, displacing chloride to form the ether linkage in 2-(4-chloro-2-methylphenoxy)propanoic acid (mecoprop). This typically occurs in aqueous or ethanolic solvents at temperatures ranging from 50-120°C, yielding the racemic form in 80-90% efficiency. An alternative route proceeds via esterification of 4-chloro-2-methylphenol with an alkyl ester of 2-chloropropionic acid (e.g., ethyl 2-chloropropionate) in the presence of a base like and a such as , in at around 100°C, achieving over 95% conversion to the ester intermediate, followed by alkaline to the free acid. For production of the enantiopure (R)-mecoprop (mecoprop-P), via or is applied post-synthesis, or chiral auxiliaries and catalysts are incorporated to enhance enantioselectivity during the substitution step.

Mechanism of Action

Herbicidal Effects

Mecoprop functions as a synthetic , mimicking the plant growth hormone (IAA) to disrupt normal growth regulation in susceptible plants, particularly broadleaf weeds. By binding to receptors, it induces uncontrolled and elongation, leading to abnormal physiological responses that ultimately cause plant death. Visible symptoms of mecoprop exposure in affected plants include epinasty (downward bending of leaves and stems), stem curling, and excessive , which result in tissue distortion and . These effects typically manifest within days of application, with complete death occurring 1–3 weeks later, depending on environmental conditions and weed . Mecoprop exhibits high selectivity for dicotyledonous (broadleaf) weeds, where it effectively mimics IAA to overwhelm the plant's hormonal balance, while showing minimal activity on monocotyledonous like grasses due to differences in auxin metabolism and receptor sensitivity. The herbicide is effective at application rates of 0.5–2 kg/ha, with efficacy varying by weed type and growth stage; the (R)-enantiomer is approximately 10 times more potent than the (S)-enantiomer in herbicidal activity. Mecoprop is primarily applied post-emergence to both annual and broadleaf weeds, allowing targeted after weeds have emerged but before they compete significantly with desired crops or turf.

Molecular Interactions

Mecoprop acts as a synthetic mimic, primarily interacting with the signaling pathway by binding to the TIR1/AFB family of F-box proteins, which serve as receptors. This binding promotes the formation of a co-receptor with Aux/IAA proteins, facilitating the ubiquitination and proteasomal degradation of Aux/IAA . Consequently, this derepresses auxin response factors (ARFs), leading to the overexpression of auxin-responsive genes, including those encoding (IAA)-inducible proteins. Mecoprop also interferes with plant metabolism by modulating ethylene biosynthesis and peroxidase activity. It stimulates ethylene production through upregulation of 1-aminocyclopropane-1-carboxylate synthase, contributing to abnormal growth responses such as epinasty. Furthermore, mecoprop enhances peroxidase-mediated reactive oxygen species generation, which exacerbates cellular damage and oxidative stress in susceptible plants. The herbicidal efficacy of mecoprop exhibits enantiomer specificity, with the (R)-enantiomer demonstrating stronger binding affinity to TIR1/AFB receptors and greater activation of ARFs compared to the (S)-enantiomer. This stereoselectivity results in differential auxin signaling strength, where (R)-mecoprop more effectively promotes Aux/IAA degradation and subsequent gene derepression. Resistance to mecoprop has been observed in weeds such as , primarily through enhanced metabolic detoxification via enzymes.

Applications

Agricultural and Crop Uses

Mecoprop serves as a selective post-emergence primarily employed in agricultural settings to control broadleaf weeds, such as dandelions () and (Trifolium spp.), in cereal crops including (Triticum aestivum), (Hordeum vulgare), and oats (Avena sativa). This application targets weeds that compete with crops for nutrients, water, and light, thereby supporting higher productivity in grass-based cereal systems. Its selectivity stems from the herbicide's mimicry of plant growth hormones, which induces uncontrolled growth and eventual death in susceptible broadleaf species while sparing grasses. Typical application rates range from 1 to 1.5 kg per , often applied in tank mixes with complementary herbicides like to broaden the spectrum of and manage resistant populations. Mecoprop exhibits high tolerance in crops due to inherent grass resistance, allowing safe use without significant to the target plants. Historically, it ranked among the most widely used active ingredients on arable crops in regions like , contributing to effective weed management in production across Europe. In modern agricultural practices, mecoprop is frequently formulated in combinations with ioxynil or bromoxynil to enhance efficacy against tougher or resistant broadleaf weeds, such as cleavers () and speedwells ( spp.), in intensive farming. These mixtures, applied during the crop's tillering to stages, help minimize weed interference and have demonstrated yield benefits by reducing competition-related losses, helping to mitigate yield losses caused by weeds, which can reach 20-25% in untreated plots. In contemporary practices, mecoprop is integrated into IWM programs, including rotation and varied application timings, to combat emerging in weed populations. Such integrated use supports sustainable intensification in cultivation while aligning with strategies.

Turf and Non-Crop Uses

Mecoprop, also known as MCPP, is predominantly applied in turf settings , accounting for approximately 96% of its total usage on lawns, courses, and sod farms to target broadleaf weeds such as () and common chickweed (). These applications are particularly effective in maintaining the aesthetic and functional quality of recreational and commercial turf areas, where mecoprop selectively disrupts growth in dicotyledonous weeds while sparing monocotyledonous cool-season grasses like Kentucky bluegrass () and perennial ryegrass (). Its efficacy extends to controlling a wide range of over 50 broadleaf species common in these environments, including clovers, dandelions, and ground ivy, without significant injury to established turf when used as directed. In turf management, mecoprop is commonly incorporated into "weed-and-feed" products that combine the with fertilizers, applied at rates of 0.5–1 kg/ha to ensure even distribution and enhanced nutrient uptake alongside suppression. These formulations allow for convenient, single-pass treatments on residential lawns, athletic fields, and fairways, promoting dense turf cover that naturally resists invasion. Since the , mecoprop has been a staple in consumer household herbicides, often formulated as or amine salts (such as or ) for improved solubility and handling in ready-to-use sprays or concentrates. Beyond turf, mecoprop finds application in non-crop areas for controlling broadleaf weeds, including along roadsides, ditches, and industrial sites where is essential for safety and maintenance. In these settings, it is typically used in selective mixtures to target persistent species like thistles and , preventing overgrowth that could impede infrastructure or pose hazards, while minimizing impact on surrounding grasses. Such uses represent a smaller portion of overall application, emphasizing mecoprop's versatility in urban and industrial landscapes.

Environmental Behavior

Fate and Transport

Mecoprop demonstrates high mobility in owing to its low adsorption affinity, characterized by an organic carbon-normalized distribution coefficient (Koc) of approximately 20 mL/g. This weak to and clay particles results in limited retention and a substantial potential for through soil profiles, particularly in sandy or low-organic-carbon soils. In , mecoprop degrades relatively quickly under aerobic conditions, with half-lives ranging from 8 to 21 days, influenced by microbial activity, , and . Under conditions, such as in waterlogged or subsurface environments, degradation slows significantly, with half-lives extending beyond 30 days and sometimes showing minimal . These persistence differences affect its vertical transport, allowing greater downward movement in oxygen-poor zones. The herbicide's high water solubility, around 880 mg/L at 25°C, promotes its dissolution and transport in aqueous phases, facilitating runoff from treated fields into surface waters during events, with detections up to 103 μg/L in freshwaters as of 2021. Consequently, mecoprop has been detected in at concentrations of 0.1–10 µg/L, often linked to from agricultural applications or landfill leachates. Volatilization of mecoprop from or surfaces is negligible due to its low of 1.2 × 10^{-5} mm at 25°C, limiting atmospheric transport pathways. In tiled-drained agricultural fields, mecoprop is particularly susceptible to off-site movement via preferential flow through drains, exacerbating contamination risks in adjacent bodies.

Degradation Processes

Mecoprop primarily undergoes microbial degradation in aerobic and environments through cleavage of its side chain, often described as a beta-oxidation-like process, yielding 4-chloro-2-methylphenol (also known as 2-methyl-4-chlorophenol) and as key products. This transformation is mediated by such as those in the genera Variovorax and , which utilize mecoprop as a carbon source, leading to further mineralization of the intermediate under favorable conditions. The rate of this process varies with environmental factors, including oxygen availability and prior exposure of the microbial community to phenoxy herbicides, with half-lives typically ranging from 12 to 100 days in aerobic soils. Photodegradation of mecoprop in natural waters is relatively slow, with a half-life (DT50) of approximately 14–30 days under simulated sunlight conditions, primarily involving direct UV absorption and indirect reactions with hydroxyl radicals generated by dissolved organic matter. This process is more pronounced in shallow, sunlit surface waters but contributes minimally to overall dissipation compared to microbial pathways, producing 4-chloro-2-methylphenol and minor unidentified intermediates. Hydrolysis of mecoprop is negligible under neutral environmental conditions (e.g., 7), as the compound remains stable in aqueous buffers, but rates increase slightly under alkaline conditions ( 9), though still not a dominant route. The primary metabolite from all major pathways, 2-methyl-4-chlorophenol, is more toxic than the parent compound, necessitating monitoring during remediation efforts. Degradation of mecoprop exhibits enantioselectivity, particularly under aerobic microbial conditions, where the (S)- is typically broken down faster than the herbicidally active (R)-, resulting in enrichment of the (R)-form in aged environmental samples such as soils and aquifers. This dynamic can alter the effective persistence and bioactivity of mecoprop residues over time.

Ecotoxicology

Impacts on Aquatic and Terrestrial Life

Mecoprop exhibits moderate acute toxicity to aquatic organisms, with a 96-hour LC50 of 124 mg/L reported for rainbow trout (Oncorhynchus mykiss), indicating low risk at typical environmental concentrations. For invertebrates, the 48-hour EC50 for Daphnia magna is greater than 91 mg/L, classifying mecoprop as slightly toxic to this species and suggesting limited direct impacts on zooplankton populations under standard exposure scenarios. Algal communities face potential disruption, as evidenced by a 72-hour EbC50 of 237 mg/L for biomass inhibition in green algae, where higher concentrations impair photosynthesis and primary production in freshwater systems. In terrestrial ecosystems, mecoprop shows low to birds, with an oral LD50 exceeding 2,250 mg/kg body weight in species such as the bobwhite quail and mallard duck (Anas platyrhynchos), minimizing risks to avian populations from direct ingestion. (Eisenia foetida) experience effects at concentrations above 100 mg/kg, with an acute 14-day LD50 of 988 mg/kg, potentially altering aeration and nutrient cycling in treated areas through sublethal impacts on burrowing and reproduction. Chronic exposure to mecoprop can induce reproductive effects in amphibians, such as reduced hatching success in wood frogs (Rana sylvatica) at concentrations around 216 mg/L in formulations containing mecoprop, highlighting vulnerabilities during sensitive developmental stages. Field studies in agricultural and turf settings demonstrate reduced diversity following mecoprop application, particularly through indirect effects like alteration from , which diminishes food resources and shelter for non-target arthropods in field margins. These impacts underscore mecoprop's role in potentially disrupting ecosystem balance, though persistence in may exacerbate long-term effects on community structure. Recent assessments as of 2023 classify risks to aquatic and terrestrial organisms as low, with chronic NOECs for ≥11.1 mg/L and no significant concerns.

Bioaccumulation and Persistence

Mecoprop demonstrates low potential in aquatic organisms, primarily due to its hydrophilic nature at environmentally relevant levels and rapid excretion rates. Measured factors (BCF) in , such as bluegill sunfish (Lepomis macrochirus), are typically below 10, with values around 3 reported from 28-day flow-through exposure studies at concentrations of 1 mg/L. This limited uptake is consistent across whole- tissues, where steady-state concentrations remain low relative to water exposure, indicating negligible risk of significant accumulation in primary consumers. The compound's persistence varies by environmental compartment, but it generally exhibits moderate to low durability in while showing greater in sediments. In aqueous systems, DT50 values range from 24 to under typical or stream conditions, reflecting hydrolysis stability and limited at neutral . The Ubiquity Score (GUS) index, calculated from soil DT50 (approximately 8–14 days under aerobic lab conditions at 20°C) and organic carbon partitioning (Koc around 20–30 mL/g), yields a value of 2.3–2.9, classifying mecoprop as a transitional to high leacher prone to migration in permeable soils. In sediments, persistence is notably higher, with DT50 exceeding 100 days in or low-microbial-activity settings, contributing to prolonged environmental presence. Enantiomeric differences influence persistence, with the (R)-enantiomer proving more recalcitrant to microbial than the herbicidally active (S)-form. Studies in aerobic soils report half-lives of about 4 days for the (S)- versus 8 days for the (R)-, representing up to a 100% extension in stability for the latter, which can lead to enantiomeric enrichment over time. This asymmetry arises from enantioselective bacterial metabolism, where (S)-mecoprop is preferentially degraded by phenoxy acid-utilizing microbes. Transfer through the is minimal, as evidenced by the compound's neutral log Kow of 3.1, which, combined with low BCF, precludes in aquatic or terrestrial trophic levels. No factors (BMF) greater than 1 have been observed in available studies, underscoring limited trophic transfer despite occasional detection in primary producers or . Environmental monitoring confirms mecoprop's capacity for extended residence, with detections reported up to one year post-application in agricultural catchments and runoff-impacted sites. Such findings, from and surveys in regions like the , highlight sporadic long-term persistence under low-dissipation conditions, though concentrations typically decline below detection limits (0.1 μg/L) within months in dynamic systems.

Human Health and Safety

Toxicity and Exposure Routes

Mecoprop exhibits moderate in mammals, with an oral LD50 of 775 mg/kg in rats, classifying it as slightly toxic under EPA Category III. Dermal LD50 values exceed 2000 mg/kg in rats, indicating low acute dermal toxicity, while data suggest potential but limited systemic effects at relevant exposure levels. Acute exposure primarily manifests as gastrointestinal distress, including and , along with and hypoactivity in animal models. High doses may also depress synthesis, contributing to cellular disruptions observed in toxicological studies. Chronic exposure to mecoprop raises concerns for potential carcinogenicity, with the EPA classifying it as having suggestive evidence but insufficient data to fully assess human carcinogenic potential based on studies. Long-term effects include decreased body weights, increased liver and weights, and nephropathy in rats and dogs, with a (NOAEL) of 4 mg/kg/day in chronic dietary studies. Additionally, mecoprop shows potential for endocrine disruption, though assessments indicate it is unlikely to act as an in mammals at relevant doses. The primary exposure routes for humans are dermal contact during application, of spray mist, and incidental via contaminated water or food residues. Applicators and residential users face the highest dermal and risks, while general population exposure occurs mainly through . The , via JMPR evaluations, has established an (ADI) of 0.01 mg/kg body weight per day for mecoprop-P, reflecting chronic dietary exposure limits. As of the 2023 EFSA update, the ADI remains 0.01 mg/kg bw per day, with new acute acceptable operator exposure level (AAOEL) and acute reference dose (ARfD) set at 0.2 mg/kg bw. Mecoprop-P is proposed as a Category 2 developmental , though this classification is disputed by the . No endocrine disruption potential was identified under the , , , and steroidogenesis (EATS) criteria. risk assessment remains unfinalized pending additional residue data in and matrices.

Risk Assessment and Mitigation

Risk assessment for mecoprop involves evaluating potential human health hazards through exposure pathways such as contamination, particularly in vulnerable areas with permeable soils or high potential. As of the 2023 EFSA assessment, potential exceedance of the EU trigger value of 0.1 μg/L for mecoprop-P in persists in the FOCUS scenario for winter cereals, indicating ongoing concern for exposure (previously calculated PEC of 0.115 μg/L in 2017, yielding RQ >1). This assessment uses the hazard quotient () method, where HQ = estimated exposure / reference dose; values exceeding 1 suggest risks that warrant mitigation to protect populations reliant on affected sources. To mitigate these risks, strategies include establishing s of 5–10 meters adjacent to water bodies to reduce spray drift and into , with vegetative buffer strips up to 20 m where needed. Integration into (IPM) programs emphasizes targeted applications, while use of low-drift nozzles and shields can reduce buffer zone widths by up to 70% for field sprayers. These measures minimize off-target deposition and environmental transport, ensuring mecoprop applications align with site-specific vulnerability assessments. Occupational exposure risks for handlers are addressed through mandatory (PPE), including chemical-resistant gloves, long-sleeved shirts, long pants, and respirators during mixing, loading, and application to prevent dermal and uptake. Re-entry intervals () of 24–48 hours post-application are required, during which treated areas must remain inaccessible to unprotected workers to allow residue dissipation. Children represent a vulnerable group due to their hand-to-mouth behaviors and close contact with treated lawns during play, leading to incidental oral and dermal exposures. 2023 EFSA assessments using the bystander/resident calculator indicate that resident children exposure exceeds the AOEL (up to 111% at the 75th ) even with measures, highlighting a critical area of concern. Monitoring exposed workers involves through urinary mecoprop levels, as the compound is rapidly excreted unchanged in , serving as a direct of recent exposure. This non-invasive method allows quantification of absorbed doses in occupational settings, with elevated levels correlating to handling activities and informing adherence to PPE and REI protocols.

Regulation and Policy

Global Approval Status

In the United States, mecoprop-P was reregistered by the Environmental Protection Agency (EPA) in 2007 under the Federal Insecticide, Fungicide, and Rodenticide Act (FIFRA), confirming its eligibility for continued use as a primarily on turfgrass and crops, with the enantiopure form (mecoprop-P) preferred over the due to improved and reduced environmental impact. As of 2025, no cancellations have been issued, and products containing mecoprop-P remain actively registered for these applications. In the , mecoprop-P is approved as an active substance under Regulation (EC) No 1107/2009, with the current approval renewed and extended until October 15, 2027, allowing its use in authorized plant protection products across most member states for in cereals and non-crop areas. The racemic form of mecoprop (mecoprop sodium) is not approved under this regulation due to concerns over the less active enantiomer's potential risks. In , mecoprop-P is registered by Health Canada's Pest Management Regulatory Agency (PMRA) for use as a on turf, ornamentals, and certain field crops, subject to periodic re-evaluations to ensure ongoing compliance with safety standards, with the most recent assessments confirming its status as of 2025. Mecoprop-P is approved for agricultural and turf uses in by the Australian Pesticides and Veterinary Medicines Authority (APVMA) and in by the Authority (EPA), where it is listed under hazardous substance approvals for selective . In , approvals are country-specific. As of November 2025, no major global phase-outs of mecoprop-P have occurred, though regulatory trends in several markets, including the and , increasingly mandate the use of enantiopure formulations to minimize ecological exposure from the inactive .

Restrictions and Phase-Outs

In the , mecoprop and its purified enantiomer mecoprop-P are subject to strict use restrictions under Regulation (EC) No 1107/2009, with approval extended until October 15, 2027, but requiring member states to implement risk mitigation measures in groundwater vulnerable zones due to the compound's high leaching potential. applications are prohibited, and use near surface waters is limited by buffer zones to prevent runoff and contamination, as mecoprop has been frequently detected in exceeding the EU drinking water standard of 0.1 μg/L in regions like and the . These measures stem from assessments highlighting mecoprop's mobility in and persistence under certain conditions, leading to programs that prioritize reduced application rates in high-risk areas. In the United States, the Environmental Protection Agency (EPA) reregistered mecoprop-P in 2007 with mandatory label precautions prohibiting direct application to water bodies or intertidal areas and requiring setbacks from habitats to minimize drift and runoff risks. Residue tolerances for mecoprop in or on food crops, such as grains and , are established at levels as low as 0.1 mg/kg for many commodities to protect consumer health, reflecting conservative assessments of dietary exposure. These restrictions align with broader efforts to address potential ecological impacts, including to non-target organisms. Phase-outs of the racemic mecoprop formulation occurred in several countries during the and early for environmental reasons, including reduced and higher environmental loads from the inactive S-enantiomer; for instance, and the recommended transitioning to the more selective mecoprop-P to lower overall inputs and risks. In , all racemic mecoprop products were fully phased out by 2004 following re-evaluation, favoring the enantiopure form. As of 2025, ongoing EU renewal reviews, including a 2023 EFSA peer assessment, evaluate potential endocrine-disrupting effects, though current data indicate low concern, with decisions pending full compliance by 2027. Groundwater contamination remains a primary driver for these restrictions, with mecoprop's detection in aquifers prompting preferences for alternatives like fluroxypyr, which exhibits lower mobility and reduced persistence in . Internationally, while mecoprop is not listed under the Stockholm Convention on Persistent Organic Pollutants, the convention's principles influence trade restrictions on formulations banned domestically, requiring prior for exports to prevent global environmental spread.