Your search keyword '"Acephate"' showing total 10 results

1. Selective Detection of Paraquat in Adulterated and Complex Environmental Samples Using Raman Spectroelectrochemistry.

Author

Kavazoi, Henry S., Miyazaki, Celina M., Constantino, Carlos J.L., Martin, Cibely S., and Alessio, Priscila

Subjects

*AGRICULTURAL safety, *PARAQUAT, *COMPLEX matrices, *RAMAN spectroscopy, *DRINKING water

Abstract

Growing demand for pesticides has created an environment prone to deceptive activities, where counterfeit or adulterated pesticide products infiltrate the market, often escaping rapid detection. This situation presents a significant challenge for sensor technology, crucial in identifying authentic pesticides and ensuring agricultural safety practices. Raman spectroscopy emerges as a powerful technique for detecting adulterants. Coupling the electrochemical techniques allows a more specific and selective detection and compound identification. In this study, we evaluate the efficacy of spectroelectrochemical measurements by coupling a potentiostat and Raman spectrograph to identify paraquat, a nonselective herbicide banned in several countries. Our findings demonstrate that applying −0.70 V during measurements yields highly selective Raman spectra, highlighting the primary vibrational bands of paraquat. Moreover, the selective Raman signal of paraquat was discernible in complex samples, including tap water, apple, and green cabbage, even in the presence of other pesticides such as diquat, acephate, and glyphosate. These results underscore the potential of this technique for reliable pesticide detection in diverse and complex matrices. [ABSTRACT FROM AUTHOR]

Published

2024

2. Evaluation of Genetic and Reproductive Toxicology of Orally Administered Acephate in Male Wistar Rats

Author

Saloni, Singh, Rajwinder, and Vashishat, Nisha

Published

2024

3. Male mice are susceptible to brain dysfunction induced by early-life acephate exposure.

Author

Takahiro Sasaki, Islam, Jahidul, Kenshiro Hara, Tomonori Nochi, and Kentaro Tanemura

Subjects

CENTRAL nervous system, GUT microbiome, DENTATE gyrus, ENDOCRINE disruptors, IMMUNOHISTOCHEMISTRY

Abstract

Background: Acephate is a widely used organophosphate insecticide. Exposure to endocrine-disrupting chemicals, such as acephate, can interfere with neurodevelopment in childhood, increasing the risk of higher brain dysfunction later in life. Furthermore, brain dysfunction may be related to chemical exposure-related disturbances in the gut microbiota. However, the effects of early acephate exposure on the brains of adult males and females as well as on the adult gut environment remain poorly understood. Methods: This study investigated the effects of perinatal acephate exposure on the central nervous system and gut microbiota of mice, including sex differences and environmentally relevant concentrations. C57BL/6 N pups were exposed to acephate (0, 0.3, 10, and 300 ppm) via the dam in their drinking water from embryonic day (E) 11.5 to postnatal day 14. We examined its effects on the central nervous system of adult males and females. Results: In the male treatment group, impairments in learning and memory were detected. Immunohistochemical analysis revealed a decrease in SOX2-, NeuN-, DCX-, and GFAP-positive cells in the hippocampal dentate gyrus in males compared to the control group, whereas GFAP-positive cells were fewer in females. In addition, gut microbiota diversity was reduced in both sexes in the experimental group. Conclusion: Our study demonstrates that the effects of early-life exposure to acephate are more pronounced in males than in females and can lead to a lasting impact on adult behavior, even at low doses, and that the gut microbiota may reflect the brain environment. [ABSTRACT FROM AUTHOR]

Published

2024

4. Insecticide Susceptibilities and Enzyme Activities of Four Stink Bug Populations in Mississippi, USA.

Author

Du, Yuzhe, Scheibener, Shane, Zhu, Yu-Cheng, Allen, K. Clint, and Reddy, Gadi V. P.

Subjects

*STINKBUGS, *INSECTICIDES, *GREENBUG, *CYTOCHROME P-450, *BIFENTHRIN, *HOST plants

Abstract

Simple Summary: In Mississippi, the stink bug complex infesting soybean is mainly composed of the brown stink bug, southern green stink bug, green stink bug, and redbanded stink bug. This study conducted spray bioassays to assess the susceptibilities of these stink bugs to seven commonly used formulated insecticides. Stinks bugs were collected from soybeans in Leland, MS, USA, at the Southern Insect Management Research Unit (SIMRU) Farm during 2022 and 2023, as well as from wild host plants in Clarksdale, MS. While the green stink bug exhibited consistent susceptibility across two years, the redbanded stink bug showed slightly increased susceptibility to neonicotinoids in 2023 compared to 2022. In 2022, the susceptibility ranking among species was redbanded stink bug ≤ green stink bug ≈ southern green stink bug, whereas in 2023, it was redbanded stink bug ≤ green stink bug ≤ brown stink bug. Enzyme activity analysis revealed no significant differences between the southern green and the green stink bug. However, compared to SIMRU-2023, populations of brown stink bug and redbanded stink bug from SIMRU-2022 and Clasksdale-2023 exhibited elevated enzyme activities, indicating potential variations in resistance mechanisms. These findings provide valuable insights for monitoring and managing insecticide resistance in Mississippi soybean. In Mississippi, the Pentatomidae complex infesting soybean is primarily composed of Euschistus servus, Nezara viridula, Chinavia hilaris, and Piezodorus guildinii. This study employed spray bioassays to evaluate the susceptibilities of these stink bugs to seven commonly used formulated insecticides: oxamyl, acephate, bifenthrin, λ-cyhalothrin, imidacloprid, thiamethoxam, and sulfoxaflor. Stinks bugs were collected from soybeans in Leland, MS, USA during 2022 and 2023, as well as from wild host plants in Clarksdale, MS. There was no significant difference in the susceptibility of C. hilaris to seven insecticides between two years, whereas P. guildinii showed slightly increased susceptibility to neonicotinoids in 2023. Among all four stink bug species, susceptibility in 2022 was ranked as P. guildinii ≤ C. hilaris ≈ N. viridula, while in 2023, it was ranked as P. guildinii ≤ C. hilaris ≤ E. Servus. Additionally, populations of E. servus and P. guildinii collected from Clarksdale exhibited high tolerance to pyrethroids and neonicotinoids. Moreover, populations of E. servus and P. guildinii from SIMRU-2022 and Clarksdale-2023 showed elevated esterase and cytochrome P450 activity, respectively. These findings from spray bioassays and enzyme activity analyses provide a baseline for monitoring insecticide resistance in Pentatomidae and can guide insecticide resistance management strategies for Mississippi soybean. [ABSTRACT FROM AUTHOR]

Published

2024

5. Acephate

Author

Pant, AB

Published

2024

6. Insecticide Susceptibilities and Enzyme Activities of Four Stink Bug Populations in Mississippi, USA

Author

Yuzhe Du, Shane Scheibener, Yu-Cheng Zhu, K. Clint Allen, and Gadi V. P. Reddy

Subjects

Pentatomidae complex, insecticide susceptibility, acephate, pyrethroids and neonicotinoids, spray bioassay, detoxification enzymes, Science

Abstract

In Mississippi, the Pentatomidae complex infesting soybean is primarily composed of Euschistus servus, Nezara viridula, Chinavia hilaris, and Piezodorus guildinii. This study employed spray bioassays to evaluate the susceptibilities of these stink bugs to seven commonly used formulated insecticides: oxamyl, acephate, bifenthrin, λ-cyhalothrin, imidacloprid, thiamethoxam, and sulfoxaflor. Stinks bugs were collected from soybeans in Leland, MS, USA during 2022 and 2023, as well as from wild host plants in Clarksdale, MS. There was no significant difference in the susceptibility of C. hilaris to seven insecticides between two years, whereas P. guildinii showed slightly increased susceptibility to neonicotinoids in 2023. Among all four stink bug species, susceptibility in 2022 was ranked as P. guildinii ≤ C. hilaris ≈ N. viridula, while in 2023, it was ranked as P. guildinii ≤ C. hilaris ≤ E. Servus. Additionally, populations of E. servus and P. guildinii collected from Clarksdale exhibited high tolerance to pyrethroids and neonicotinoids. Moreover, populations of E. servus and P. guildinii from SIMRU-2022 and Clarksdale-2023 showed elevated esterase and cytochrome P450 activity, respectively. These findings from spray bioassays and enzyme activity analyses provide a baseline for monitoring insecticide resistance in Pentatomidae and can guide insecticide resistance management strategies for Mississippi soybean.

Published

2024

7. Comparative transcriptome profiling of two pesticides, Acephate and Chlorantraniliprole in non-targeted insect model, Drosophila melanogaster.

Author

Rahila, K. and Shibu Vardhanan, Y.

Subjects

*CHLORANTRANILIPROLE, *AGRICULTURE, *DROSOPHILA melanogaster, *GENETIC transcription, *RNA sequencing

Abstract

Acephate and chlorantraniliprole are two insecticides widely used in agricultural applications. Several studies were focused on the mode of action and related biological and cellular level expressions. However, the sub-lethal dose and related molecular expression level of acephate and chlorantraniliprole have not been evaluated or studied to the same degree. In this study, we investigated the sub-lethal toxicity of acephate and chlorantraniliprole in Drosophila melanogaster. The EC 50 value was recorded with high difference, and is found to be 1.9 μg/ml and 0.029 μg/ml respectively for acephate and chlorantraniliprole, the difference is simply because of the different modes of action. The 1/5th EC 50 concentration was selected for studying the pesticide induced transcriptomics in D. melanogaster. Both pesticides significantly altered the expression profile of several transcripts which are involved in proteolysis, detoxification, chromosome associated proteins and immune response genes and so on. The effect of both pesticides on D. melanogaster was further explored by screening the genes involved in toxicity, which were analyzed using, GO and KEGG pathways. The results revealed that the sub-lethal exposure of both pesticides caused significant changes in the global gene transcription profiles and each pesticide had their unique mode of alteration in the D. melanogaster. [Display omitted] • Transcriptomic analysis of D. melanogaster treated by 1/5th EC 50 of acephate and chlorantraniliprole was investigated. • Sub-lethal exposure of both pesticides resulted in significant changes in the global gene transcription profiles. • Acephate is more toxic than chlorantraniliprole, downregulating vital genes involved in growth, physiology, molecular-cellular signaling. [ABSTRACT FROM AUTHOR]

Published

2024

8. Semi-rational design for enhancing thermostability of Culex pipiens acetylcholinesterase and sensitivity analysis of acephate.

Author

Jiang, Shuoqi, Zhang, Zhuangwei, Gu, Qiuya, and Yu, Xiaobin

Published

2024

9. Male mice are susceptible to brain dysfunction induced by early-life acephate exposure.

Author

Sasaki T, Islam J, Hara K, Nochi T, and Tanemura K

Abstract

Background: Acephate is a widely used organophosphate insecticide. Exposure to endocrine-disrupting chemicals, such as acephate, can interfere with neurodevelopment in childhood, increasing the risk of higher brain dysfunction later in life. Furthermore, brain dysfunction may be related to chemical exposure-related disturbances in the gut microbiota. However, the effects of early acephate exposure on the brains of adult males and females as well as on the adult gut environment remain poorly understood., Methods: This study investigated the effects of perinatal acephate exposure on the central nervous system and gut microbiota of mice, including sex differences and environmentally relevant concentrations. C57BL/6 N pups were exposed to acephate (0, 0.3, 10, and 300 ppm) via the dam in their drinking water from embryonic day (E) 11.5 to postnatal day 14. We examined its effects on the central nervous system of adult males and females., Results: In the male treatment group, impairments in learning and memory were detected. Immunohistochemical analysis revealed a decrease in SOX2-, NeuN-, DCX-, and GFAP-positive cells in the hippocampal dentate gyrus in males compared to the control group, whereas GFAP-positive cells were fewer in females. In addition, gut microbiota diversity was reduced in both sexes in the experimental group., Conclusion: Our study demonstrates that the effects of early-life exposure to acephate are more pronounced in males than in females and can lead to a lasting impact on adult behavior, even at low doses, and that the gut microbiota may reflect the brain environment., Competing Interests: The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest., (Copyright © 2024 Sasaki, Islam, Hara, Nochi and Tanemura.)

Published

2024

10. The Effects of the Pesticide Acephate on PG19 Mouse Amelanotic Melanoma Cells.

Author

Kuhaneck, Kaley

Subjects

*ACEPHATE, *MELANOMA, *CANCER cells, *LABORATORY mice

Abstract

The pesticide Acephate is commonly used across the United States as a popular insecticide. The U.S. Environmental Protection Agency classifies Acephate as a possible human carcinogen. Other studies have addressed the possible carcinogenicity of Acephate in living mice and other cell lines, but none have evaluated the amelanotic mouse melanoma PG19 cell line. PG19 cells were used to evaluate the effects of Acephate because individuals most at risk of exposure to Acephate are also at risk of developing melanoma. The effects of short-term exposure to various concentrations of Acephate (10, 100, and 1000µg/ml) were investigated on PG19 cells through trypan blue exclusion cell viability and scratch wound healing assays. Based on experimental evidence, treatment with Acephate was expected to increase proliferation and migration rates indicating a role in carcinogenesis and metastasis within a PG19 melanoma cell model. Treatment with Acephate resulted in significant decreases in cell viability of PG19 cells at 24 hours. Exposure to 1000µg/mL of Acephate had a cytotoxic effect. At 24 hours, there were no significant differences in scratch wound width between Acephate treatments. Comparison and evaluation of the mechanisms of previously published findings of pro-carcinogenic effects in longer-term assays compared to the cell toxicity in the short-term experiments performed in these studies is important in determining the risk assessment of the continued usage of Acephate in the United States. [ABSTRACT FROM AUTHOR]

Published

2024