Your search keyword '"Muehlebach, Michel"' showing total 3 results

1. Fate of synthetic chemicals in the agronomic insect pest Spodoptera littoralis: experimental feeding-contact assay and toxicokinetic model.

Author

Römer, Clara I, Ashauer, Roman, Escher, Beate I, Höfer, Kristin, Muehlebach, Michel, Sadeghi-Tehran, Pouria, Sherborne, Neil, and Buchholz, Anke

Abstract

Insecticides prevent or reduce insect crop damage, maintaining crop quality and quantity. Physiological traits, such as an insect's feeding behavior, influence the way insecticides are absorbed and processed in the body (toxicokinetics), which can be exploited to improve species selectivity. To fully understand the uptake of insecticides, it is essential to study their total uptake and toxicokinetics independent of their toxic effects on insects. We studied the toxicokinetics (TK) of insecticidally inactive test compounds incorporating agro-like structural motifs in larvae of the Egyptian cotton leafworm (Spodoptera littoralis, Lepidoptera), and their distribution across all biological matrices, using laboratory experiments and modeling. We measured Spodoptera larval behavior and temporal changes of whole-body concentrations of test compounds during feeding on treated soybean leaf disks and throughout a subsequent depuration period. Differences in the distribution of the total quantities of compounds were found between the biological matrices leaf, larva, and feces. Rate constants for uptake and elimination of test compounds were derived by calibrating a toxicokinetic model to the whole-body concentrations. Uptake and elimination rate constants depended on the physicochemical properties of the test compounds. Increasing hydrophobicity increased the bioaccumulation potential of test compounds. Incomplete quantities in larval matrices indicated that some compounds may undergo biotransformation. As fecal excretion was a major elimination pathway, the variable time of release and number of feces pellets led to a high variability in the body burden. We provide quantitative models to predict the toxicokinetics and bioaccumulation potential of inactive insecticide analogs (parent compounds) in Spodoptera. [ABSTRACT FROM AUTHOR]

Published

2024

2. Spiro N‐methoxy piperidine ring containing aryldiones for the control of sucking insects and mites: discovery of spiropidion.

Author

Muehlebach, Michel, Buchholz, Anke, Zambach, Werner, Schaetzer, Juergen, Daniels, Miriam, Hueter, Ottmar, Kloer, Daniel P, Lind, Rob, Maienfisch, Peter, Pierce, Andy, Pitterna, Thomas, Smejkal, Tomas, Stafford, David, and Wildsmith, Laura

Subjects

INSECT pest control, INSECT growth, MITES, INSECT development, ARTHROPOD pests, NEONICOTINOIDS, INTEGRATED pest control

Abstract

BACKGROUND: Crop protection solutions for the control of key economic sucking pests derive essentially from neuronal and muscular acting chemistries, wherein neonicotinoid uses largely dominated for the last two decades. Anticipating likely resistance development of some of those arthropod species to this particular class, we intensified research activities on a non‐neuronal site of action targeting insect growth and development some 10 years ago. RESULTS: Our innovation path featured reactivation of a scarcely used and simple building block from the 1960s, namely N‐methoxy‐4‐piperidone 3. Its judicious incorporation into the 2‐aryl‐1,3‐dione scaffold of IRAC group 23 inhibitors of fatty acid biosynthesis resulted in novel tetramic acid derivatives acting on acetyl‐coenzyme A carboxylase (ACCase). The optimization campaign focused on modulation of the aryl substitution pattern and understanding substituent options at the lactam nitrogen position of those spiroheterocyclic pyrrolidine‐dione derivatives towards an effective control of sucking insects and mites. This work gratifyingly culminated in the discovery of spiro N‐methoxy piperidine containing proinsecticide spiropidion 1. Following in planta release, its insecticidally active dione metabolite 2 is translaminar and two‐way systemic (both xylem and phloem mobile) for a full plant protection against arthropod pests. CONCLUSION: Owing to such unique plant systemic properties, growing shoots and roots actually not directly exposed to spiropidion‐based chemistry after foliar application nevertheless benefit from its long‐lasting efficacy. Spiropidion is for use in field crops, speciality crops and vegetables controlling a broad range of sucking pests. In light of other performance and safety profiles of spiropidion, an IPM fit may be expected. © 2020 Society of Chemical Industry [ABSTRACT FROM AUTHOR]

Published

2020

3. Aryldiones incorporating a [1,4,5]oxadiazepane ring. Part 2: Chemistry and biology of the cereal herbicide pinoxaden.

Author

Muehlebach, Michel, Cederbaum, Fredrik, Cornes, Derek, Friedmann, Adrian A, Glock, Jutta, Hall, Gavin, Indolese, Adriano F, Kloer, Daniel P, Le Goupil, Gael, Maetzke, Thomas, Meier, Hans, Schneider, Rudolf, Stoller, André, Szczepanski, Henry, Wendeborn, Sebastian, and Widmer, Hansjuerg

Subjects

IMMUNOLOGICAL adjuvants, HERBICIDES, PEST control, AGRICULTURAL chemicals, SPRAYING & dusting in agriculture

Abstract

BACKGROUND: Pinoxaden is a new cereal herbicide that provides outstanding levels of post-emergence activity against a broad spectrum of grass weed species for worldwide selective use in both wheat and barley. RESULTS: Factors influencing activity and tolerance to pinoxaden were in part linked to distinct structural parts of the active ingredient. Three complementary contributions that decisively impact upon the herbicidal potency against grasses were identified: a preferred 2,6-diethyl-4-methyl aromatic substitution pattern, a dione area suitable for proherbicide formation and beneficial adjuvant effects. The uptake and translocation pattern of pinoxaden when coapplied with its tailored adjuvant were analysed by autoradiography, indicating extensive and rapid penetration, followed by effective distribution throughout the plant. Crop injury reduction on incorporation of the [1,4,5]oxadiazepane ring into the aryldione template was reinforced with safener technology. Comparative studies on the behaviour of pinoxaden applied either alone or in combination with the safener cloquintocet-mexyl demonstrated that addition of the safener resulted in significant enhancement of metabolic degradation in wheat and barley, providing excellent crop tolerance and a substantial selectivity margin without adverse effects on weed control. CONCLUSION: The biological potential of pinoxaden and its active principle pinoxaden dione in terms of grass weed control and tolerance in cereals was fully exploited by inclusion of the safener cloquintocet-mexyl in the formulation in combination with a specific and tailor-made tank-mix adjuvant based on methylated rape seed oil. Copyright © 2011 Society of Chemical Industry [ABSTRACT FROM AUTHOR]

Published

2011