Pendimethalin
Pendimethalin is a selective, pre-emergent herbicide belonging to the dinitroaniline chemical class, primarily used to control annual grasses and certain broadleaf weeds in a variety of crops such as field corn, soybeans, cotton, peanuts, potatoes, rice, and tobacco, as well as in turfgrass, ornamentals, and non-crop areas.[1] First registered for use in the United States by the Environmental Protection Agency (EPA) in 1972, it is applied to soil surfaces where it is absorbed by weed roots and shoots shortly after germination, inhibiting cell division and elongation to prevent weed establishment.[2] Chemically known as N-(1-ethylpropyl)-3,4-dimethyl-2,6-dinitroaniline, pendimethalin has the molecular formula C13H19N3O4 and a molecular weight of 281.31 g/mol, with a CAS number of 40487-42-1.[1] Its mode of action involves binding to tubulin proteins, disrupting microtubule assembly essential for mitosis and cell wall formation in susceptible plants, leading to abnormal root and shoot development.[3] Commercial formulations, often as emulsifiable concentrates or water-based suspensions, are produced by companies including BASF under brand names like Prowl H₂O, and it is typically applied at rates of 0.5 to 4 pounds of active ingredient per acre depending on soil type and crop.[4] Pendimethalin exhibits low acute toxicity to mammals via oral, dermal, and inhalation routes (EPA Toxicity Class III), but it is classified as a possible human carcinogen (Group C) based on evidence of thyroid tumors in animal studies.[5] Environmentally, it persists in soil with a half-life of 30 to 90 days, primarily degrading through microbial activity, and can leach into groundwater under certain conditions, though it shows moderate to low mobility due to strong soil adsorption.[6] The EPA's 1997 Reregistration Eligibility Decision confirmed its continued use with label amendments to mitigate risks to applicators and the environment.[2]Chemical Identity and Properties
Chemical Structure and Formula
Pendimethalin possesses the molecular formula \ce{C13H19N3O4} and a molecular weight of 281.31 g/mol.[1] Its systematic IUPAC name is N-(1-ethylpropyl)-3,4-dimethyl-2,6-dinitroaniline.[1] The molecule consists of a central benzene ring substituted at the 1-position with an amino group linked to a 1-ethylpropyl chain (\ce{-NH-CH(CH2CH3)2}), at the 2- and 6-positions with nitro groups (\ce{-NO2}), and at the 3- and 4-positions with methyl groups (\ce{-CH3}). This arrangement can be represented textually as:where the benzene ring (C6H2) bears the specified substituents.[1] As a member of the dinitroaniline herbicide class, pendimethalin is differentiated from structural analogs such as trifluralin by its 3,4-dimethyl substitutions on the ring (versus a 4-trifluoromethyl group in trifluralin) and its secondary N-(1-ethylpropyl) amine (versus a tertiary N,N-dipropyl amine).[7][1]NO2 | CH3 - C6H2 - NH - CH(CH2CH3)2 | | CH3 NO2NO2 | CH3 - C6H2 - NH - CH(CH2CH3)2 | | CH3 NO2
Physical and Chemical Properties
Pendimethalin is a yellow to orange crystalline solid at room temperature.[8] Its melting point ranges from 54 to 58 °C.[8] The vapor pressure is low at 3 × 10^{-5} mm Hg at 25 °C, indicating limited volatility under ambient conditions.[9] Pendimethalin exhibits low water solubility of 0.33 mg/L at 25 °C, which is pH-independent across neutral to slightly acidic or basic ranges.[1] The octanol-water partition coefficient (log K_{ow}) is 5.18, signifying high lipophilicity and a strong preference for partitioning into organic phases over water.[10] Chemically, pendimethalin is stable under neutral, acidic, and alkaline conditions, with no significant hydrolysis observed in sterile aqueous solutions at pH 5, 7, or 9 over 30 days at 25 °C.[1] It shows very high stability during storage but undergoes slow photodegradation upon exposure to light.[1] As a non-ionizable compound under physiological conditions, pendimethalin lacks a relevant pK_a value.[1]History and Development
Discovery and Synthesis
Pendimethalin was identified in the late 1960s as part of ongoing research into dinitroaniline herbicides, building on the success of trifluralin, which was introduced commercially in 1964 by Eli Lilly and Company.[11] This class of compounds had first shown herbicidal potential in the early 1960s, with subsequent efforts focusing on structural modifications to enhance selectivity and efficacy against annual grasses and broadleaf weeds.[12] The compound, chemically known as N-(1-ethylpropyl)-3,4-dimethyl-2,6-dinitroaniline, was discovered and developed by American Cyanamid Company in the early 1970s.[8] Key aspects of its synthesis and herbicidal utility were covered in U.S. Patent 3,920,742, filed on January 12, 1973, and issued on November 18, 1975, to inventors Albert William Lutz and Robert Eugene Diehl.[13] Synthesis of pendimethalin involves the nucleophilic aromatic substitution of 4-chloro-3,5-dinitro-o-xylene with 3-aminopentane (1-ethylpropylamine) in a solvent such as xylene under reflux conditions (typically 50–150°C) for several hours, followed by cooling, filtration, acidification, washing, drying, and crystallization.[13] This method yields the target compound as a yellow-orange solid with high efficiency, often exceeding 85% based on the precursor.[13] Initial herbicidal activity was observed in greenhouse trials conducted by American Cyanamid, where pendimethalin demonstrated selective preemergence control of grass weeds such as crabgrass, barnyardgrass, green foxtail, and wild oats at application rates of 0.25 to 4 pounds per acre.[13] These tests involved planting seeds in potting soil, applying the compound, and evaluating plant response after 3–4 weeks under controlled conditions, confirming its efficacy without significant injury to crops like soybeans and cotton.[13]Commercial Introduction and Usage Trends
Pendimethalin was first registered as a pesticide by the U.S. Environmental Protection Agency (EPA) in 1972 for use on soybeans and cereals.[8] The herbicide was introduced commercially under the trade name Prowl by American Cyanamid, whose agrochemical business was acquired by BASF in 2000, making BASF the primary marketer thereafter.[14] Initial formulations targeted pre-emergence weed control in row crops, establishing pendimethalin as a key tool in early-season herbicide programs. Global adoption followed the U.S. launch, with pendimethalin gaining approval and widespread use in Europe during the 1980s and expanding into Asia by the 1990s, particularly in rice and vegetable production systems in Southeast Asia.[15] In the United States, usage in the 2000s averaged 14-25 million pounds of active ingredient annually across agricultural and non-agricultural sites, driven by its efficacy against annual grasses and broadleaf weeds in crops like corn, cotton, and soybeans.[8] By the 2020s, pendimethalin's role has stabilized within integrated weed management strategies, emphasizing rotation with other herbicides to mitigate resistance development in species such as goosegrass and certain Amaranthus weeds.[16] U.S. Department of Agriculture data indicate usage of approximately 5 million pounds annually as of 2008, with overall demand remaining steady into the 2020s.[17] As of 2024, the EPA continues to approve tolerance expansions for pendimethalin residues, supporting its ongoing agricultural applications.[18]Uses and Applications
Agricultural Applications
Pendimethalin serves as a selective pre-emergent herbicide primarily used in agricultural crop production to inhibit the germination and early growth of weeds, thereby protecting yields without harming established crops when applied correctly. It targets a range of annual grasses, including crabgrass (Digitaria spp.) and foxtails (Setaria spp.), as well as broadleaf weeds such as pigweed (Amaranthus spp.) and common lambsquarters (Chenopodium album).[19] In major field crops like corn, soybeans, cotton, peanuts, and rice, pendimethalin is applied at rates typically ranging from 0.5 to 2.0 kg active ingredient per hectare, depending on soil type, organic matter content, and weed pressure.[20] These applications are most effective when incorporated into the soil shortly after planting, either mechanically or via rainfall or irrigation, to ensure contact with weed seeds in the upper soil layers. Common formulations include emulsifiable concentrates (EC) for spray application and granular forms for broadcast distribution, both designed for soil incorporation to enhance efficacy and minimize volatility.[20][19] The herbicide's long residual activity, lasting 60 to 120 days in soil under typical field conditions, provides extended weed suppression, often reducing the need for subsequent herbicide applications during the growing season.[21] This persistence stems from its binding to soil particles and slow microbial degradation, allowing for season-long control in many systems. For broader-spectrum management, pendimethalin is frequently tank-mixed with other herbicides such as metolachlor, which complements its activity against additional grass and broadleaf species while maintaining crop safety.[19]Non-Agricultural Applications
Pendimethalin is widely employed in turfgrass management to control grassy weeds in non-crop settings such as residential lawns, golf courses, parks, and sod farms. It is applied preemergently at rates typically ranging from 1.1 to 4.5 kg active ingredient per hectare to prevent weed germination without harming established turf species like Kentucky bluegrass, tall fescue, or perennial ryegrass.[22][23] Applications are most effective when followed by rainfall or irrigation of about 0.5 inches within a few days to activate the herbicide in the soil.[23] In ornamental and nursery settings, pendimethalin serves as a preemergent herbicide to inhibit weed emergence in flower beds, shrub plantings, and tree nurseries, maintaining aesthetic and healthy landscapes. It is suitable for use around a variety of woody and herbaceous ornamentals, including azaleas, hollies, and annual flowers, when applied according to label specifications to avoid phytotoxicity.[24] Granular or liquid formulations are incorporated into the soil surface or mulch layer, with irrigation required shortly after application to ensure efficacy.[24] For industrial sites, pendimethalin is utilized in non-cropped areas such as rights-of-way, fence lines, and highway edges to achieve bare-ground weed control. In roadside vegetation management, it is applied preemergently at rates of 100–200 pounds per acre for granular formulations or 64–128 ounces per acre for liquid ones, targeting annual grasses and broadleaf weeds while minimizing erosion and maintenance costs.[25] Homeowner products containing pendimethalin are available in granular formulations, often combined with fertilizers, for easy application on residential lawns using spreaders. These consumer-grade options, such as those labeled for preemergence crabgrass control, allow safe use on established turf with rates adjusted for smaller areas, typically not exceeding 2.0 pounds active ingredient per acre per application.[26][22] Due to its potential for runoff and high toxicity to aquatic organisms, pendimethalin applications should be avoided near water bodies, with precautions such as buffer zones recommended to prevent contamination of surface waters.[10][27]Mechanism of Action
Biochemical Target
Pendimethalin, a dinitroaniline herbicide, primarily targets microtubule assembly in susceptible plants by binding to α- and β-tubulin proteins, which are essential components of the cytoskeleton. This binding occurs at a specific site on α-tubulin beneath the N-loop, involving key residues such as Arg2, Glu3, Val4, Trp21, Phe24, His28, Ile42, Asp47, Arg64, Cys65, Thr239, Arg243, and Phe244, disrupting the interaction between the N-loop and M-loop of adjacent protofilaments. As a result, pendimethalin inhibits the polymerization of tubulin dimers into microtubules, preventing the formation of the mitotic spindle and cortical microtubules necessary for cell division.[28] The disruption of microtubule dynamics by pendimethalin halts mitosis during the metaphase stage and impairs cell elongation in meristematic tissues, leading to the cessation of root and shoot growth. In meristematic regions, where rapid cell division occurs, this interference causes abnormal cell plate formation and disorganized microtubule arrays, ultimately arresting plant development at early stages. Experimental studies with purified plant tubulin have quantified this interaction, showing inhibition constants (Ki) in the range of 95–117 nM, indicating high affinity for plant tubulin.[28][29] Pendimethalin exhibits selectivity due to its higher binding affinity for plant tubulin compared to animal tubulin, with over 50-fold lower affinity for vertebrate tubulin, rendering it ineffective against mammalian cells at typical application rates. This plant-specific targeting stems from structural differences in the tubulin binding site, such as variations in the M-loop region, and pendimethalin shows no activity against fungal or bacterial cells, which lack sensitive tubulin isoforms.[28][29] In susceptible weeds, the biochemical disruption manifests as visible symptoms including stunting of growth, thickened and brittle roots with swollen tips, and secondary inhibition of shoot development, typically appearing 7–14 days after application. These effects begin in root tips and meristems, with initial inhibition of lateral root development, followed by limited shoot emergence as the plant fails to establish.[30]Selectivity and Application Methods
Pendimethalin demonstrates selectivity primarily through differential metabolism and sequestration in tolerant crops, allowing effective weed control while minimizing injury to desirable plants. In crops such as cotton, pendimethalin is rapidly metabolized into non-toxic polar compounds, with 30-40% conversion occurring within days, compared to only about 20% in susceptible weeds like redroot pigweed and johnsongrass.[31] This metabolic detoxification contributes to crop tolerance by accelerating herbicide breakdown.[31] Additionally, sequestration in cotton's lysigenous glands further reduces phytotoxicity by immobilizing the parent compound. However, sensitive crops like lettuce face higher injury risk, exhibiting stunted growth and limited lateral root development even at standard application rates.[32] Application methods for pendimethalin emphasize pre-emergence timing to target germinating weeds before crop establishment, typically applied immediately after sowing but before crop emergence to prevent early competition.[33] Surface applications are common, followed by incorporation into the top 2-5 cm of soil via mechanical tilling, such as harrow passes at 8-13 km/h, or natural processes like 12-25 mm of rainfall or overhead irrigation within 7-10 days to position the herbicide in the weed germination zone.[19][34] Post-emergence applications are possible on small weeds (up to 5 cm tall) but are less common and require directed sprays to avoid crop contact.[35] Efficacy of pendimethalin depends on adequate soil moisture for activation and root absorption, as dry conditions delay herbicide movement into the soil profile and reduce weed control.[36] Performance is also diminished in sandy soils due to lower organic matter content, which leads to reduced adsorption (Kd values typically >25 mL/g but lower in sandy soils), and potential leaching, necessitating adjusted rates or enhanced incorporation.[31][37]Environmental Fate
Soil Behavior and Mobility
Pendimethalin strongly adsorbs to soil particles, primarily binding to organic matter and clay components, which restricts its availability for transport. The organic carbon-normalized adsorption coefficient (Koc) for pendimethalin typically ranges from 10,241 to 36,604 mL/g, indicating high affinity for soil solids and low solubility in soil pore water.[38] This adsorption is largely independent of soil pH, as pendimethalin remains in its neutral form across typical soil pH ranges, minimizing ionic interactions that could alter binding.[38] Due to this strong sorption, pendimethalin is classified as immobile in most soils, with a Groundwater Ubiquity Score (GUS) index of -0.28, well below the threshold of 1.8 for low leaching potential.[38] Consequently, the risk of groundwater contamination from pendimethalin is low under standard agricultural conditions.[6] Mobility increases in soils with low organic matter content, such as sandy textures, where reduced binding sites allow greater potential for vertical movement during heavy rainfall or irrigation.[39] Runoff represents a moderate transport pathway for pendimethalin, primarily through soil erosion rather than dissolved transport, with losses amplified on slopes greater than 5%.[40] Field studies on loamy soils have shown that pendimethalin remains largely confined to the top 5 cm of the soil profile even after 30 days, with no detectable leaching below this depth in undisturbed conditions.[41] In one lysimeter study on sloped soybean fields, erosion-driven runoff accounted for 3.9% to 10.8% of applied pendimethalin, highlighting the role of surface flow in off-site movement.[42]Degradation Pathways and Persistence
Pendimethalin demonstrates moderate persistence in soil, with field half-lives ranging from 30 to 90 days under aerobic conditions depending on environmental factors such as temperature, moisture, and soil type.[43] In laboratory aerobic soil metabolism studies, half-lives extend from 95 to 1,322 days, reflecting slower degradation in controlled settings compared to field dissipation, where half-lives often fall below 20 days in regions like Louisiana and Mississippi.[6] Under anaerobic conditions, such as water-logged or flooded soils like those in rice fields, degradation accelerates, with reported half-lives ranging from 6 to 105 days.[6] The main degradation pathways involve photodegradation and microbial metabolism. Photodegradation in aqueous environments proceeds with a half-life of 17 to 21 days at neutral pH, primarily yielding nitroso derivatives and other polar photoproducts through reduction of nitro groups.[8] On soil surfaces, photodegradation is limited due to strong adsorption, but it contributes to initial breakdown under sunlight exposure.[6] Microbial metabolism, dominant in soils, initiates via nitroreduction of the C-6 nitro group to form 6-aminopendimethalin, followed by N-dealkylation to generate 3,4-dimethyl-2,6-dinitroaniline and subsequent oxidative steps releasing pentane as a byproduct.[44] These processes are mediated by soil bacteria such as Bacillus circulans and Bacillus subtilis, which express specific nitroreductases and N-dealkylases.[44][3] Key metabolites, including 3,4-dimethyl-2,6-dinitroaniline and various amino and polar derivatives, typically constitute less than 10% of the applied radioactivity each and are considered less toxic than pendimethalin.[6] Full mineralization to CO₂ remains minimal, with fewer than 10% conversion observed after one year in aerobic soil incubations.[6] Volatilization represents a minor dissipation route, accounting for 1–5% loss, limited by pendimethalin's low vapor pressure of 9.4 × 10⁻⁶ Torr at 25°C.[6] Overall environmental persistence is influenced by prior adsorption to soil organic matter that reduces bioavailability for degradation.[45]Toxicology and Health Effects
Acute and Chronic Toxicity in Mammals
Pendimethalin exhibits low acute toxicity in mammals across multiple exposure routes. The oral LD50 in rats exceeds 5000 mg/kg body weight, classifying it as Toxicity Category III by the U.S. Environmental Protection Agency (EPA).[5] Dermal LD50 values in rabbits are greater than 2000 mg/kg, also Category III, indicating minimal skin absorption and systemic effects.[5] Inhalation LC50 in rats is greater than 5.3 mg/L over a 4-hour exposure, with low systemic absorption observed, placing it in Toxicity Category IV.[46] Pendimethalin is a mild eye and skin irritant (EPA Category III) but not a skin sensitizer.[20] Chronic exposure to pendimethalin primarily affects the liver and thyroid in mammals. In a 2-year rat study, the no-observed-adverse-effect level (NOAEL) was 12.5 mg/kg/day, with liver and thyroid hypertrophy observed at higher doses exceeding 50 mg/kg/day.[20] A chronic dog study established a NOAEL of 12.5 mg/kg/day, based on liver effects at 50 mg/kg/day.[46] These organ-specific changes, including increased liver weights and thyroid follicular cell hypertrophy, occur at elevated doses but do not indicate broad systemic toxicity at environmentally relevant levels. Reproductive and developmental toxicity studies show no teratogenic effects in mammals. In rat developmental studies, the NOAEL was 500 mg/kg/day, with no fetal abnormalities observed up to the highest tested dose.[5] Rabbit studies confirmed a NOAEL of 60 mg/kg/day for developmental effects.[5] Slight maternal toxicity, such as reduced body weight gain, was noted at 250 mg/kg/day in rats, but no reproductive impairments were evident in two-generation studies (NOAEL 25-43 mg/kg/day for parental and offspring effects).[5] Human exposure to pendimethalin occurs primarily through dermal contact and inhalation during application by agricultural workers, with low dietary residues typically below 0.01 mg/kg in food commodities.[20] Systemic absorption via these routes is limited, contributing to the overall low toxicity profile.[46]Carcinogenicity Concerns
The U.S. Environmental Protection Agency (EPA) classifies pendimethalin as a Group C possible human carcinogen, based on evidence of thyroid follicular cell adenomas observed in male and female rats in chronic feeding studies.[5] This classification stems from statistically significant increases in tumor incidence at doses up to 1,000 mg/kg/day, but the agency has determined that the carcinogenic effects follow a nonlinear mode of action related to thyroid-pituitary disruption, which is not genotoxic and considered protective under chronic dietary risk assessments without requiring quantitative cancer risk modeling.[5] Genotoxicity studies, including in vitro mammalian cell assays and in vivo micronucleus tests, show no evidence of mutagenic potential, supporting the view that pendimethalin does not pose a genotoxic carcinogenic risk to humans.[5] Epidemiological evidence from the Agricultural Health Study (AHS) cohort of pesticide applicators indicates a potential association between high lifetime exposure to pendimethalin and increased risk of pancreatic cancer, with an odds ratio (OR) of 3.0 (95% CI: 1.3-7.2) for those in the top half of exposure compared to non-users, alongside a significant exposure-response trend (p=0.01).[47] Proposed mechanisms include induction of pancreatic inflammation or activation of metabolites that promote cellular damage, though direct causation remains unestablished due to limited sample sizes and confounding factors in occupational exposures.[48] Associations with other cancers are weaker and inconsistent across studies. In the AHS cohort, pendimethalin exposure showed some elevated risk for lung cancer (OR 1.7, 95% CI: 0.9-3.1), but without a clear dose-response relationship, and a small number of rectal cancer cases (n=19) suggested possible increased risk, though statistical power was low.[49] No compelling evidence links pendimethalin to overall cancer incidence or most specific sites in large applicator cohorts.[50] Lifetime rodent carcinogenicity studies demonstrate no tumor induction in mice at dietary doses up to 75 mg/kg/day over 18 months, and in rats, while thyroid adenomas occurred, they were attributed to a rodent-specific, non-genotoxic mechanism not relevant to human physiology, with no oncogenic effects at doses up to 375 mg/kg/day in other tissues.[45][46] The International Agency for Research on Cancer (IARC) has not classified pendimethalin as of 2025, as it has not been evaluated, though it is on the priority list for future review due to positive findings in animal studies.[51] In the European Union, ongoing peer reviews as of 2025, including EFSA's evaluation of confirmatory data, affirm low carcinogenic risk for approved uses but require labeling for potential reproductive toxicity and environmental persistence, with no new evidence warranting reclassification. The EFSA peer review in July 2025 of confirmatory data confirmed that pendimethalin presents no critical areas of concern with respect to human health for the representative uses, including low carcinogenic risk.[52]Weed Resistance
Mechanisms of Resistance
Weed resistance to pendimethalin, a dinitroaniline herbicide that inhibits microtubule polymerization by binding to α- and β-tubulin subunits, primarily arises through target-site resistance (TSR) mechanisms. The most common form involves point mutations in the α-tubulin gene that alter the herbicide's binding affinity without severely disrupting tubulin function. For instance, a threonine-to-isoleucine substitution at position 239 (Thr-239-Ile) in the α-tubulin protein has been identified in resistant biotypes of goosegrass (Eleusine indica), conferring high-level resistance to pendimethalin and related compounds.[53] Similar mutations, such as arginine-to-methionine at position 243 (Arg-243-Met) in rigid ryegrass (Lolium rigidum), have been documented, leading to altered microtubule dynamics that reduce herbicide efficacy.[53] Non-target-site resistance (NTSR), particularly enhanced metabolism, also contributes to pendimethalin resistance in several weed species. Overexpression or upregulation of detoxification enzymes, including cytochrome P450 monooxygenases (e.g., CYP81A10 in L. rigidum) and glutathione S-transferases (GSTs), enables rapid breakdown of the herbicide into non-toxic metabolites.[53] In black nightshade (Solanum nigrum), cytochrome P450-mediated metabolism has been confirmed as the primary NTSR mechanism against pendimethalin, with resistant biotypes showing significantly faster degradation rates compared to susceptible ones.[54] Although less frequently reported in goosegrass, GST activity has been implicated in metabolic resistance to dinitroaniline herbicides in this species, often acting in concert with TSR.[55] Cross-resistance is a hallmark of pendimethalin resistance, typically extending to other dinitroaniline herbicides such as trifluralin, due to shared binding sites on tubulin or overlapping metabolic pathways. Resistant biotypes of E. indica and L. rigidum exhibit 10- to 30-fold resistance to both pendimethalin and trifluralin, but cross-resistance to herbicides targeting non-microtubule sites (e.g., ACCase or ALS inhibitors) is rare.[53][56] The first confirmed case of pendimethalin resistance was reported in the mid-1980s in goosegrass (Eleusine indica) populations in the United States, marking an early instance of TSR to this specific herbicide.[57] As of 2025, resistance has been documented in 7 weed species globally, including E. indica, L. rigidum, P. annua, Setaria viridis, Amaranthus palmeri, Sorghum halepense, Alopecurus myosuroides, and Solanum nigrum, with cases spanning multiple continents. Recent reports as of 2025 include confirmed resistance in Poa annua populations in Oregon's hazelnut production systems.[57][53][58] Resistance to pendimethalin is inherited as a nuclear trait, typically controlled by a single semi-dominant gene for TSR mutations, though metabolic resistance often involves multiple genes.[59] In L. rigidum, the Arg-243-Met mutation displays semi-dominance, with heterozygous plants showing intermediate resistance levels.[60] Associated fitness costs are common, including reduced plant competitiveness, slower growth, and lower seed production; for example, homozygous Arg-243-Met mutants in L. rigidum exhibit up to 20% yield penalties due to distorted cell division and helical growth patterns.[61] These costs can limit the spread of resistant biotypes in the absence of selection pressure.[53]Resistance Management
Effective resistance management for pendimethalin, a HRAC Group 3 herbicide that inhibits microtubule assembly in susceptible weeds, is essential to prolong its utility and prevent the spread of resistant biotypes. Integrated weed management (IWM) approaches emphasize rotating pendimethalin with herbicides from different modes of action, such as ALS inhibitors (HRAC Group 2), to reduce selection pressure on Group 3 targets. Tank mixtures with complementary herbicides, like those from Group 5 or 14, can enhance control of emerged and germinating weeds while minimizing the risk of resistance development.[62][63][64] Cultural practices play a critical role in reducing weed pressure and supporting chemical controls. Crop rotation diversifies herbicide options and disrupts weed life cycles, while incorporating cover crops suppresses weed emergence through competition and allelopathy. Narrow row spacing enhances crop competitiveness, limiting light and resources available to weeds. These non-chemical methods, combined with tillage, help maintain low weed densities and delay resistance evolution.[65][66][67] Regular field monitoring is vital for early detection of resistance. Growers should scout fields throughout the season for surviving weed biotypes and collect seed samples for resistance testing using bioassay or molecular kits available through extension services. Best practices include limiting pendimethalin applications to no more than two per year, applying at labeled rates, and integrating mechanical controls to prevent seed set of potential resistant plants.[68][62][63] Globally, the Herbicide Resistance Action Committee (HRAC) classifies pendimethalin as Group 3 and promotes stewardship through guidelines that encourage IWM adoption. Manufacturers, via organizations like CropLife International, support resistance management programs as of 2025, including educational resources and labeled resistance warnings to foster sustainable use.[69][63][70]Regulatory Status
Global Approvals and Restrictions
Pendimethalin has been reregistered by the United States Environmental Protection Agency (EPA) under the Federal Insecticide, Fungicide, and Rodenticide Act, with the Reregistration Eligibility Decision completed in 1997, confirming its eligibility for continued use subject to mitigation measures.[2] Tolerances for pendimethalin residues vary by commodity, with many at 0.1 mg/kg (e.g., for vegetables and grains) but higher for others (e.g., up to 15 mg/kg for hops), covering combined residues of pendimethalin and its metabolites in or on raw agricultural commodities to ensure consumer safety.[71] Use near aquatic areas requires precautions to minimize runoff and drift, with product-specific buffer zones (often 100-200 feet or more) to protect non-target aquatic organisms like fish and invertebrates.[8] In the European Union, pendimethalin is approved as an active substance under Regulation (EC) No 1107/2009, with the most recent renewal extending its validity until 15 January 2027, classified as a candidate for substitution due to potential concerns over persistence and toxicity.[72] Maximum residue levels (MRLs) for pendimethalin in food and feed range from 0.05 mg/kg (limit of quantification for many commodities) to 0.5 mg/kg for specific crops like herbal infusions from roots, harmonized across member states to protect consumer health. Recent EFSA assessments (2023) modified MRLs for certain crops, such as increasing levels for peas (with pods) to 0.08 mg/kg.[73] Its use is banned for non-professional applications, including home gardens, limiting it to agricultural and professional settings only.[1] Pendimethalin is approved for use in other regions, including Canada where Health Canada has established maximum residue limits through ongoing evaluations, Australia via the Australian Pesticides and Veterinary Medicines Authority with active registrations for herbicide formulations, and India under the Central Insecticides Board and Registration Committee for various crop protections.[74][75] In China, pendimethalin is registered for use under national pesticide regulations, with ongoing environmental protection policies aiming to reduce high-risk pesticide applications in sensitive areas. The Joint FAO/WHO Meeting on Pesticide Residues (JMPR) has reviewed pendimethalin, establishing an acceptable daily intake (ADI) of 0–0.1 mg/kg body weight and an acute reference dose (ARfD) of 1 mg/kg body weight based on toxicological data from long-term studies in animals.[46] Over time, regulatory labels have been revised globally to include reduced application rates and mandatory setbacks from aquatic habitats, driven by evidence of high ecotoxicity to aquatic organisms, such as LC50 values below 1 mg/L for fish and invertebrates.[20]Trade Names and Formulations
Pendimethalin is marketed under various trade names globally, with major brands including Prowl and Pendulum from BASF, Stomp from Syngenta, and generics such as Corral and Aquacap.[45][76][77] Other notable trade names include Sipaxol, Sovereign, Way-Up, and regional variants like Affirm and Pendant.[45][75] Common formulations of pendimethalin include emulsifiable concentrates (EC), wettable powders (WP), and granular forms, with concentrations typically ranging from 330 to 600 g/L active ingredient in liquid formulations.[20][78] EC formulations often contain 30–41.3% pendimethalin, such as the 3.3 EC (approximately 330 g/L) in Prowl and Pendulum, while WP versions reach up to 50%, as in Lesco PRE-M.[77][33] Granular formulations vary from 2% to 4% active ingredient, including 2G and 2.68G options applied at rates of 75–200 lb per acre.[76] Global variations emphasize reduced-volatility options, such as the water-based capsule suspension (CS) in Prowl H2O (3.8 CS, approximately 455 g/L), which minimizes odor and staining while enhancing storage stability compared to traditional ECs.[79][77] Combination products are also available, including Squadron (pendimethalin with imazethapyr), RiceOne CS (with clomazone at 2.61 lb/gal pendimethalin), and Tripzin ZC (with metribuzin at 2.9 lb/gal pendimethalin), designed for broader-spectrum weed control.[75][77] Over 100 pendimethalin-based products are registered worldwide, reflecting its widespread use in agriculture across diverse formulations and markets.[20] Product labeling consistently includes the HRAC Group 3 classification (microtubule assembly inhibitors) and warnings on resistance management, advising rotation with herbicides of different modes of action to prevent weed resistance development.[45][77]| Formulation Type | Common Concentrations | Example Products |
|---|---|---|
| Emulsifiable Concentrate (EC) | 30–41.3% (330–500 g/L) | Prowl 3.3 EC, Pendulum 3.3 EC, Stomp 33% EC |
| Wettable Powder (WP) | 50% | Lesco PRE-M 50 WP |
| Granular (G) | 2–4% | Pendulum 2G, Corral 2.68G |
| Capsule Suspension (CS) | 38–45% (455 g/L) | Prowl H2O 3.8 CS, Pendulum AquaCap 3.8 CS |