The Acetochlor Registration Partnership Surface Water Monitoring Program for Four Corn Herbicides

Hackett, Amy G.; Gustafson, David I.; Moran, Sharon J.; Hendley, Paul; Wesenbeeck, Ian van; Simmons, Nick D.; Klein, Andrew J.; Kronenberg, Joel M.; Fuhrman, John D.; Honegger, Joy L.; Hanzas, John P.; Healy, David A.; Stone, Christopher T.

doi:10.2134/jeq2003.0411

Cited by 36 publications

(30 citation statements)

References 23 publications

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“…We had access to three additional data sets of atrazine concentrations in finished drinking water in Indiana, each of which contained records from biweekly sampling for periods of several months to several years. These data were collected as part of the Acetochlor Registration Partnership (Hackett et al 2005), Novartis Atrazine Public Water System Voluntary Monitoring (Tierney et al 1999), and the Atrazine and Simazine Re-registration Program (U.S. EPA 2006).…”

Section: Methodsmentioning

confidence: 99%

Drinking-Water Herbicide Exposure in Indiana and Prevalence of Small-for-Gestational-Age and Preterm Delivery

Ochoa‐Acuña

Frankenberger

Hahn³

et al. 2009

Environ Health Perspect

114

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BackgroundAtrazine and other corn herbicides are routinely detected in drinking water. Two studies on potential association of atrazine with small-for-gestational-age (SGA) and preterm birth prevalence found inconsistent results. Moreover, these studies did not control for individual-level potential confounders.ObjectivesOur retrospective cohort study evaluated whether atrazine in drinking water is associated with increased prevalence of SGA and preterm birth.MethodsWe developed atrazine concentration time series for 19 water systems in Indiana from 1993 to 2007 and selected all births (n = 24,154) based on geocoded mother’s residences. Log-binomial models were used to estimate prevalence ratios (PRs) for SGA and preterm delivery in relation to atrazine concentrations during various periods of the pregnancy. Models controlled for maternal demographic characteristics, prenatal care and reproductive history, and behavioral risk factors (smoking, drinking, drug use).ResultsAtrazine in drinking water during the third trimester and the entire pregnancy was associated with a significant increase in the prevalence of SGA. Atrazine in drinking water > 0.1 μg/L during the third trimester resulted in a 17–19% increase in the prevalence of SGA compared with the control group (< 0.1 μg/L). Mean atrazine concentrations over the entire pregnancy > 0.644 μg/L were associated with higher SGA prevalence than in the control group (adjusted PR = 1.14; 95% confidence interval, 1.03–1.24). No significant association was found for preterm delivery.ConclusionsWe found that atrazine, and perhaps other co-occurring herbicides in drinking water, is associated with an increased prevalence of SGA, but not preterm delivery.

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Section: Methodsmentioning

confidence: 99%

Drinking-Water Herbicide Exposure in Indiana and Prevalence of Small-for-Gestational-Age and Preterm Delivery

Ochoa‐Acuña

Frankenberger

Hahn³

et al. 2009

Environ Health Perspect

114

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“…It is reported that herbicides sometimes appear in surface or ground water (2,37,39); corresponding risk assessments of (S)-metolachlor resulted in positive registrations in the United States (in 1997) and other countries. This agent and several materials containing (S)-metolachlor and some additives have been marketed by the Syngenta company under the trade names Dual Gold, Dual Magnum, Gardo Gold, Primextra Gold, and others.…”

Section: (S)-metolachlor As a Herbicidementioning

confidence: 99%

The Metolachlor Herbicide: An Exercise in Today's Stereochemistry

Mannschreck

Angerer

2009

J. Chem. Educ.

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In the ClassroomMany plants such as cereals are cultivated for the nutrition of humans and animals. The output of these crops would be considerably diminished if they were not protected against a variety of detrimental weeds. The latter compete successfully with the cultivated plants for space, sunlight, water, and nutrients in the soil. Chemicals used to selectively inactivate or kill weeds are called herbicides (1a). One of the most used representatives, (particularly in the United States) is metolachlor (Figure 1), an anilide registered for the protection of many different types of plants worldwide (2). This molecule forms stereoisomers 1 that have been analyzed separately and as a mixture for their bioactivity in reference to weed extermination. Such experiments are required because of environmental aspects (2) and the necessity to optimize the agronomic use. The compositions of stereoisomeric mixtures must also be taken into account for the industrial preparation. The present article deals with the three-dimensional structures, the syntheses, and the bioactivities of metolachlor stereoisomers.An overview of the following topics is beneficial to the comprehension of this manuscript: racemic and chiral nonracemic (3a) samples; zigzag formulas (3b); the principle of NMR and chromatography with a nonracemic auxiliary or sorbent, respectively (4); crystallization of diastereomeric derivatives (5a, 6a); and the elements of enantioselective reactions (7a). The content of this article can be integrated into a lecture on advanced organic agrochemistry. The present manuscript describes facts related to metolachlor, such as its stereoisomers or its syntheses. These specific facts are proposed as examples to illustrate general stereochemical aspects, such as axial and central chirality or enantioselective hydrogenation of achiral substrates. These topics are often taught in the third (or a later) year of university chemistry curriculum. The general aspects will be summarized in the conclusion of the article. Several Metolachlor Stereoisomers Two Elements of ChiralityMetolachlor, 1, has a stereocenter in one of the N substituents but, in addition, it exhibits a second, less usual element of chirality, the axial one (3c, 7b). Before looking at metolachlor, we shall consider a similar molecule, the model anilide 2, showing this element exclusively. We focus for a moment on formulas (M)-and (P)-2 ( Figure 2) representing the enantio mers; the descriptors (M) and (P) will be explained later. (M)-2 contains two planar π systems: the arene ring and the O=C−N fragment 1 with O=C and C−N partial double bonds. When considering rotation about the aryl-nitrogen bond, one sees that conformations with noncoplanar π systems such as (M)-2 are sterically less hindered than coplanar ones. (M)-2 shows neither an internal plane of symmetry nor a center of symmetry; thus two enantiomers must exist (6b, 8). These stereoisomers were experimentally separated and characterized (9).The descriptors (M) and (P) will be briefly explained with the e...

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“…In India this herbicide is available as Lasso, used both as pre and post emergent herbicide. The herbicide is available as emulsifiable concentration (Garrett et al, 1986;Kiely et al, 2004 andHackett et al, 2005). The herbicide alachlor absorbed by emerging plant shoots, inhibits fatty acid and lipid biosynthesis; as well as gibberellins synthesis and protein synthesis (Chang et al, 1985).…”

Section: Introductionmentioning

confidence: 99%

Seed Germination and Morphological Behavior of Maize (NAC-6002, NAC-6004 and NAH- 2049) Seedlings under Abiotic Stress (Alachlor) Condition

K¹,

Jagannath²

2015

Int J Life Sci

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Article InformationHerbicides are the most flourishing weed control knowledge eternally developed. To appraise the possessions of herbicides on maize, a study was carried out to evaluate the effect of alachlor on different maize cultivars on germination and early growth parameters. The studies were carried out in hydroponic conditions supplemented with different concentrations (1.0, 2.5 5.0, 7.5 and 10.0 ppm) of alachlor. All the three cultivars of maize were found to be significantly affected with increasing herbicide concentration. Percent germination, vigour index, tolerance index, fresh and dry weight, plumule and radicle length were found to be decreased as the herbicide concentration increased, however the dry weight increased slightly at higher concentration when compared to other concentrations. The percent toxicity increased as the concentration of herbicide increased. The current study clearly implies that higher concentration of alachlor is toxic to maize, resulted in a decline in seed germination and early growth parameters.

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The Acetochlor Registration Partnership Surface Water Monitoring Program for Four Corn Herbicides

Cited by 36 publications

References 23 publications

Drinking-Water Herbicide Exposure in Indiana and Prevalence of Small-for-Gestational-Age and Preterm Delivery

Drinking-Water Herbicide Exposure in Indiana and Prevalence of Small-for-Gestational-Age and Preterm Delivery

The Metolachlor Herbicide: An Exercise in Today's Stereochemistry

Seed Germination and Morphological Behavior of Maize (NAC-6002, NAC-6004 and NAH- 2049) Seedlings under Abiotic Stress (Alachlor) Condition

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