DOCSLIB.ORG

Free of Analytes Matrixes

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
Free of Analytes Matrixes FREE OF ANALYTES MATRIXES Matrix: Green beans Description: Green beans in plastic container sealed with pressure lid and screw cap. Approximated weight: 50g Date of analysis: May 2019 Analyzed analytes: Pesticides residues (See annex). Results: There was no presence of any of the target analytes (See annex) above the quantification limit. NOTES The material has been kept in temperature-controlled freezer and is sent frozen. Upon receive store in freezer until analysis. The test material has been analyzed by the TestQual’s collaborator laboratory accredited for the analysis of the annexed pesticides, therefore ensuring the lack of pesticides in concentrations higher than the limit of quantification of the laboratory: 10µg/Kg The list of the analyzed pesticides is the one TestQual works with regularly in our proficiency test of pesticides residues. You can check the full list of analytes in the protocol or request the documentation using the contact data on our website: http://testqual.com/contacto/?lng=en Page 1 / 3 ANNEX 2-Phenylphenol Carbendazim Dichlormid Fenazaquin 3,5-Dichloroaniline Carbophenothion Dichlobenil Fenbuconazole 3-Hydroxy-carbofuran Carbofuran Diclobutrazol Fenbutatin oxide 4,4-Dichlorobenzophenone Chlorantraniliprole Dichlofluanid Fenchlorphos Abamectin Chlorbromuron Diclofop-methyl Fenhexamid Acephate Chlorfenapyr Dicloran Fenitrothion Acetamiprid Chlorfenvinphos Dicrotophos Fenoxycarb Acetochlor Chlormephos Dieldrin Fenpropathrin Aclonifen Chloroneb Diethofencarb Fenpropimorph Acrinathrin Chloropropylate Difenoconazole Fenpyroximate Alachlor Chlorpyrifos Difenoxuron Fensulfothion Aldicarb Chlorpyrifos Methyl Diflubenzuron Fenthion Aldicarb sulfone Chlorthion Diflufenican Phenthoate Aldicarb sulfoxide Chlorthiophos Dimethenamid Fenuron Aldrin Cyanazine Dimethoate Fenvalerate Anthraquinone Cyazofamid Dimethomorph Fipronil Atrazine Cyfluthrin Dimoxystrobin Flonicamid Azaconazole Cymoxanil Diniconazole Fluazifop-P-butyl Azinphos-ethyl Cypermethrin Dioxacarb Fluchloralin Azinphos-methyl Cyproconazole Dioxathion Flucythrinate Azoxystrobin Clethodim Diphenylamine Fludioxinil Benalaxyl Clofentezine Dipropetryn Flufenoxuron Bendiocarb Clomazone Disulfoton Flumetralin Benfluralin Cloquintocet-mexyl Ditalimfos Fluometuron Benfuresate Chlorfenson Diuron Fluotrimazole Bentazone Chlorotoluron Dodine Fluquinconazole Bifenthrin Chloroxuron Emamectin benzoate B1a Flusilazole Bitertanol Chlorpropham Endosulfan-alpha Flutolanil Boscalid Chlorsulfuron Endosulfan-beta Flutriafol Brodifacoum Chlorthal-dimethyl Endosulfan-sulfate Folpet Bromacil Clothianidin Endrin Fonofos Bromocyclen Coumaphos EPN Formothion Bromophos-ethyl Kresoxim-methyl Epoxiconazole Phosalone Bromophos Crimidine Etaconazole Phosphamidon Bromopropylate Cyanofenphos Ethion Phosmet Bromuconazole Cyanophos Ethoprophos Furalaxyl Bupirimate Cycloxydim Etoxazole Furathiocarb Buprofezin Cyprodinil Ethiofencarb HCH-Alpha Butafenacil Deltamethrin Ethiofencarb -sulfone HCH-Beta Butamifos Demeton-S-methyl Ethiofencarb -sulfoxide HCH-Delta Demeton-S-methyl Butoxycarboxim Etofenprox HCH-Gamma (lindane) sulfone Ethofumesate Heptachlor Butralin Desmetryn Etrimfos Heptachlor-epoxide Buturon Dialifos Famoxadone Heptenophos Cadusafos Diazinon Famphur (Famophos) Hexachlorobenzene Captan Dicapthon Fenarimol Hexaconazole Carbaryl Dichlofenthion Page 2 / 3 Hexaflumuron Metribuzin Pyraclostrobin Spiroxamine Hexazinone Mevinphos Pyrazphos Sulfotep Hexythiazox Myclobutanil Pyridaben Sulprofos Imazalil Molinate Pyrifenox Tebuconazole Imazamethabenz-methyl Monocrotophos Pirimicarb Tebufenozide Imidacloprid Monolinuron Pirimicarb-desmethyl Tebufenpyrad Indoxacarb Monuron Pirimiphos-ethyl Tebupirimfos Iprobenfos Napropamide Pirimiphos-methyl Tecnazene Iprodione Neburon Pyriproxyfen Teflubenzuron Iprovalicarb Nitenpyram pp-DDE Tefluthrin Isazofos Nitrofen pp-TDE(DDD) Terbacil Isocarbophos Nitrothal-isopropyl Prochloraz Terbufos Isofenphos Norflurazon Procymidone Terbumeton Isofenphos-methyl Nuarimol Propham Terbuthylazine Isoproturon Ofurace Profenofos Terbutryn Lambda-Cyhalothrin Omethoate Profluralin Tetraconazole Lenacil op-TDE (DDD) Promecarb Tetradifon Leptophos Oxadiazon Prometryn Tetramethrin Linuron Oxadixyl Propachlor Tetrasul Lufenuron Oxamyl Propamocarb Thiabendazole Malaoxon Oxamyl-oxime Propanil Thiacloprid Malathion Oxydemeton-methyl Propargite Thiamethoxam Mecarbam Oxyfluorfen Propetamphos Thiodicarb Mefenpyr-diethyl Paclobutrazol Propiconazole Thiobencarb Mepanipyrim Parathion Propyzamide Thiometon Mepronil Parathion-methyl Propoxur Tolclofos-methyl Metalaxyl Pebulate Prosulfocarb Triadimefon Metamitron Penconazole Prothiofos Triadimenol Metazachlor Pendimethalin Pyridafenthion Triazophos Methacrifos Pentachloroanisole Pyrimethanil Trichloronate Methamidophos Permethrin Quinalpho Tridemorph Methidathion Quinoxyfen Trifloxystrobin 1,1-(2,2- Methomyl Quintozene Triflumuron dichloroethylidene) bis(4- Methoxychlor methoxybenzene) Rotenone Trifluralin Methoxyfenozide Simazine Vinclozolin (methoxychlor Metobromuron Simetryn Yodofenfos metabolite) Metolachlor Phenmedipham Spinosad A+D Zoxamide Methoprotryne Picoxystrobin Spirodiclofen Metoxuron Piperonyl butoxide Spiromesifen Page 3 / 3 .
Load more

Recommended publications
  • Historical Perspectives on Apple Production: Fruit Tree Pest Management, Regulation and New Insecticidal Chemistries
    Historical Perspectives on Apple Production: Fruit Tree Pest Management, Regulation and New Insecticidal Chemistries. Peter Jentsch Extension Associate Department of Entomology Cornell University's Hudson Valley Lab 3357 Rt. 9W; PO box 727 Highland, NY 12528 email: [email protected] Phone 845-691-7151 Mobile: 845-417-7465 http://www.nysaes.cornell.edu/ent/faculty/jentsch/ 2 Historical Perspectives on Fruit Production: Fruit Tree Pest Management, Regulation and New Chemistries. by Peter Jentsch I. Historical Use of Pesticides in Apple Production Overview of Apple Production and Pest Management Prior to 1940 Synthetic Pesticide Development and Use II. Influences Changing the Pest Management Profile in Apple Production Chemical Residues in Early Insect Management Historical Chemical Regulation Recent Regulation Developments Changing Pest Management Food Quality Protection Act of 1996 The Science Behind The Methodology Pesticide Revisions – Requirements For New Registrations III. Resistance of Insect Pests to Insecticides Resistance Pest Management Strategies IV. Reduced Risk Chemistries: New Modes of Action and the Insecticide Treadmill Fermentation Microbial Products Bt’s, Abamectins, Spinosads Juvenile Hormone Analogs Formamidines, Juvenile Hormone Analogs And Mimics Insect Growth Regulators Azadirachtin, Thiadiazine Neonicotinyls Major Reduced Risk Materials: Carboxamides, Carboxylic Acid Esters, Granulosis Viruses, Diphenyloxazolines, Insecticidal Soaps, Benzoyl Urea Growth Regulators, Tetronic Acids, Oxadiazenes , Particle Films, Phenoxypyrazoles, Pyridazinones, Spinosads, Tetrazines , Organotins, Quinolines. 3 I Historical Use of Pesticides in Apple Production Overview of Apple Production and Pest Management Prior to 1940 The apple has a rather ominous origin. Its inception is framed in the biblical text regarding the genesis of mankind. The backdrop appears to be the turbulent setting of what many scholars believe to be present day Iraq.
    [Show full text]
  • Environmental Properties of Chemicals Volume 2
    1 t ENVIRONMENTAL 1 PROTECTION Esa Nikunen . Riitta Leinonen Birgit Kemiläinen • Arto Kultamaa Environmental properties of chemicals Volume 2 1 O O O O O O O O OO O OOOOOO Ol OIOOO FINNISH ENVIRONMENT INSTITUTE • EDITA Esa Nikunen e Riitta Leinonen Birgit Kemiläinen • Arto Kultamaa Environmental properties of chemicals Volume 2 HELSINKI 1000 OlO 00000001 00000000000000000 Th/s is a second revfsed version of Environmental Properties of Chemica/s, published by VAPK-Pub/ishing and Ministry of Environment, Environmental Protection Department as Research Report 91, 1990. The pubiication is also available as a CD ROM version: EnviChem 2.0, a PC database runniny under Windows operating systems. ISBN 951-7-2967-2 (publisher) ISBN 952-7 1-0670-0 (co-publisher) ISSN 1238-8602 Layout: Pikseri Julkaisupalvelut Cover illustration: Jussi Hirvi Edita Ltd. Helsinki 2000 Environmental properties of chemicals Volume 2 _____ _____________________________________________________ Contents . VOLUME ONE 1 Contents of the report 2 Environmental properties of chemicals 3 Abbreviations and explanations 7 3.1 Ways of exposure 7 3.2 Exposed species 7 3.3 Fffects________________________________ 7 3.4 Length of exposure 7 3.5 Odour thresholds 8 3.6 Toxicity endpoints 9 3.7 Other abbreviations 9 4 Listofexposedspecies 10 4.1 Mammais 10 4.2 Plants 13 4.3 Birds 14 4.4 Insects 17 4.5 Fishes 1$ 4.6 Mollusca 22 4.7 Crustaceans 23 4.8 Algae 24 4.9 Others 25 5 References 27 Index 1 List of chemicals in alphabetical order - 169 Index II List of chemicals in CAS-number order
    [Show full text]
  • Determination of Age-Related Differences in Activation and Detoxication of Organophosphates in Rat and Human Tissues
    Mississippi State University Scholars Junction Theses and Dissertations Theses and Dissertations 8-10-2018 Determination of Age-Related Differences in Activation and Detoxication of Organophosphates in Rat and Human Tissues Edward Caldwell Meek Follow this and additional works at: https://scholarsjunction.msstate.edu/td Recommended Citation Meek, Edward Caldwell, "Determination of Age-Related Differences in Activation and Detoxication of Organophosphates in Rat and Human Tissues" (2018). Theses and Dissertations. 1339. https://scholarsjunction.msstate.edu/td/1339 This Dissertation - Open Access is brought to you for free and open access by the Theses and Dissertations at Scholars Junction. It has been accepted for inclusion in Theses and Dissertations by an authorized administrator of Scholars Junction. For more information, please contact [email protected]. Template A v3.0 (beta): Created by J. Nail 06/2015 Determination of age-related differences in activation and detoxication of organophosphates in rat and human tissues By TITLE PAGE Edward Caldwell Meek A Dissertation Submitted to the Faculty of Mississippi State University in Partial Fulfillment of the Requirements for the Degree of Doctor of Philosophy in Environmental Toxicology in the College of Veterinary Medicine Mississippi State, Mississippi August 2018 Copyright by COPYRIGHT PAGE Edward Caldwell Meek 2018 Determination of age-related differences in activation and detoxication of organophosphates in rat and human tissues By APPROVAL PAGE Edward Caldwell Meek
    [Show full text]
  • Genetically Modified Baculoviruses for Pest
    INSECT CONTROL BIOLOGICAL AND SYNTHETIC AGENTS This page intentionally left blank INSECT CONTROL BIOLOGICAL AND SYNTHETIC AGENTS EDITED BY LAWRENCE I. GILBERT SARJEET S. GILL Amsterdam • Boston • Heidelberg • London • New York • Oxford Paris • San Diego • San Francisco • Singapore • Sydney • Tokyo Academic Press is an imprint of Elsevier Academic Press, 32 Jamestown Road, London, NW1 7BU, UK 30 Corporate Drive, Suite 400, Burlington, MA 01803, USA 525 B Street, Suite 1800, San Diego, CA 92101-4495, USA ª 2010 Elsevier B.V. All rights reserved The chapters first appeared in Comprehensive Molecular Insect Science, edited by Lawrence I. Gilbert, Kostas Iatrou, and Sarjeet S. Gill (Elsevier, B.V. 2005). All rights reserved. No part of this publication may be reproduced or transmitted in any form or by any means, electronic or mechanical, including photocopy, recording, or any information storage and retrieval system, without permission in writing from the publishers. Permissions may be sought directly from Elsevier’s Rights Department in Oxford, UK: phone (þ44) 1865 843830, fax (þ44) 1865 853333, e-mail [email protected]. Requests may also be completed on-line via the homepage (http://www.elsevier.com/locate/permissions). Library of Congress Cataloging-in-Publication Data Insect control : biological and synthetic agents / editors-in-chief: Lawrence I. Gilbert, Sarjeet S. Gill. – 1st ed. p. cm. Includes bibliographical references and index. ISBN 978-0-12-381449-4 (alk. paper) 1. Insect pests–Control. 2. Insecticides. I. Gilbert, Lawrence I. (Lawrence Irwin), 1929- II. Gill, Sarjeet S. SB931.I42 2010 632’.7–dc22 2010010547 A catalogue record for this book is available from the British Library ISBN 978-0-12-381449-4 Cover Images: (Top Left) Important pest insect targeted by neonicotinoid insecticides: Sweet-potato whitefly, Bemisia tabaci; (Top Right) Control (bottom) and tebufenozide intoxicated by ingestion (top) larvae of the white tussock moth, from Chapter 4; (Bottom) Mode of action of Cry1A toxins, from Addendum A7.
    [Show full text]
  • Development of a Heterologous Enzyme-Linked Immunosorbent Assay for Organophosphorus Pesticides with Phage-Borne Peptide
    HHS Public Access Author manuscript Author Manuscript Author ManuscriptRSC Adv Author Manuscript. Author manuscript; Author Manuscript available in PMC 2015 August 17. Published in final edited form as: RSC Adv. 2014 January 1; 4(80): 42445–42453. doi:10.1039/C4RA07059C. Development of a heterologous enzyme-linked immunosorbent assay for organophosphorus pesticides with phage-borne peptide Xiude Huaa,b, Xiaofeng Liua,b, Haiyan Shia,b, Yanru Wangc, Hee Joo Kimc, Shirley J. Geec, Minghua Wanga,b,*, Fengquan Liud,*, and Bruce D. Hammockc aCollege of Plant Protection (State & Local Joint Engineering Research Center of Green Pesticide Invention and Application), Nanjing Agricultural University, Nanjing 210095, China bKey Laboratory of Integrated Management of Crop Diseases and Pests (Nanjing Agricultural University), Ministry of Education cDepartment of Entomology and UCD Cancer Center, University of California, Davis, California 95616, United States dInstitute of Plant Protection, Jiangsu Academy of Agricultural Science, Nanjing 210014, China Abstract An enzyme-linked immunosorbent assay (ELISA) was developed to detect organophosphorus pesticides using a phage-borne peptide that was isolated from a cyclic 8-residue peptide phage −1 library. The IC50 values of the phage ELISA ranged from 1.4 to 92.1 μg L for eight organophosphorus pesticides (parathion-methyl, parathion, fenitrothion, cyanophos, EPN, paraoxon-methyl, paraoxon, fenitrooxon). The sensitivity was improved 120- and 2-fold compared to conventional homologous and heterologous ELISA, respectively. The selectivity of the phage ELISA was evaluated by measuring its cross-reactivity with 23 organophosphorus pesticides, among which eight were the main cross-reactants. The spike recoveries were between 66.1% and 101.6% for the detection of single pesticide residues of parathion-methyl, parathion and fenitrothion in Chinese cabbage, apple and greengrocery, and all of the coefficient of variation were less than or equal to 15.9%.
    [Show full text]
  • US5264213.Pdf
    ||||||||||||||| US005264213A United States Patent (19) 11) Patent Number: 5,264,213 Shibahara et al. 45 Date of Patent: Nov. 23, 1993 (54) PROCESS FOR PREPARING HIGHLY 57-145,861, published Sep. 9, 1982 (Derwent Abstract ACTIVE WATER-DESPERSIBLE PESTC DES 82-8883i E/42). (75) Inventors: Tetsuya Shibahara, Hatano; Naohiko Shimazaki, et al., Japanese Patent Application Kondo, Atsugi; Jun Kato, Susono, all 59-212,462, published Dec. 1, 1984 (Derwent Abstract of Japan 85-015809/03). Haga, et al., Japanese Patent Application 60-193,960, 73) Assignee: Dowelanco, Indianapolis, Ind. published Oct. 2, 1985 (Derwent Abstract (21) Appl. No.: 377,026 85-285507/46). Haga, et al., Japanese Patent Application 62-155,248, (22 Filed: Jul. 7, 1989 published Jul. 10, 1987 (Derwent Abstract (30) Foreign Application Priority Data 87-231613/33). Jul. 8, 1988 (JP) Japan ................................ 63-168672 Haga, et al., Japanese Patent Application 62-155,249, published Jul. 10, 1987 (Derwent Abstract 51) Int. Cl........................ CO7C 127/22; A01N 9/20 87-231614/33). 52 U.S.C. .................................... 424/409; 514/351; Nagasaki, et al., Japanese Patent Application 514/522; 514/594; 546/300; 564/44 58) Field of Search .......................... 546/300; 564/44; 62-195,365, published Aug. 28, 1989 (Derwent Abstract 514/351, 522,554; 424/409 87-280996/40). (56) References Cited Primary Examiner-Lester L. Lee U.S. PATENT DOCUMENTS Attorney, Agent, or Firm-D. Wendell Osborne 3,989,842 11/1976 Wellinger et al. 3,989,942 11/1976 Wellinga et al..................... 424/322 (57) ABSTRACT 4,139,636 2/1979 Sirrenberg et al.
    [Show full text]
  • The List of Extremely Hazardous Substances)
    APPENDIX A (THE LIST OF EXTREMELY HAZARDOUS SUBSTANCES) THRESHOLD REPORTABLE INVENTORY RELEASE QUANTITY QUANTITY CAS NUMBER CHEMICAL NAME (POUNDS) (POUNDS) 75-86-5 ACETONE CYANOHYDRIN 500 10 1752-30-3 ACETONE THIOSEMICARBAZIDE 500/500 1,000 107-02-8 ACROLEIN 500 1 79-06-1 ACRYLAMIDE 500/500 5,000 107-13-1 ACRYLONITRILE 500 100 814-68-6 ACRYLYL CHLORIDE 100 100 111-69-3 ADIPONITRILE 500 1,000 116-06-3 ALDICARB 100/500 1 309-00-2 ALDRIN 500/500 1 107-18-6 ALLYL ALCOHOL 500 100 107-11-9 ALLYLAMINE 500 500 20859-73-8 ALUMINUM PHOSPHIDE 500 100 54-62-6 AMINOPTERIN 500/500 500 78-53-5 AMITON 500 500 3734-97-2 AMITON OXALATE 100/500 100 7664-41-7 AMMONIA 500 100 300-62-9 AMPHETAMINE 500 1,000 62-53-3 ANILINE 500 5,000 88-05-1 ANILINE,2,4,6-TRIMETHYL- 500 500 7783-70-2 ANTIMONY PENTAFLUORIDE 500 500 1397-94-0 ANTIMYCIN A 500/500 1,000 86-88-4 ANTU 500/500 100 1303-28-2 ARSENIC PENTOXIDE 100/500 1 THRESHOLD REPORTABLE INVENTORY RELEASE QUANTITY QUANTITY CAS NUMBER CHEMICAL NAME (POUNDS) (POUNDS) 1327-53-3 ARSENOUS OXIDE 100/500 1 7784-34-1 ARSENOUS TRICHLORIDE 500 1 7784-42-1 ARSINE 100 100 2642-71-9 AZINPHOS-ETHYL 100/500 100 86-50-0 AZINPHOS-METHYL 10/500 1 98-87-3 BENZAL CHLORIDE 500 5,000 98-16-8 BENZENAMINE, 3-(TRIFLUOROMETHYL)- 500 500 100-14-1 BENZENE, 1-(CHLOROMETHYL)-4-NITRO- 500/500 500 98-05-5 BENZENEARSONIC ACID 10/500 10 3615-21-2 BENZIMIDAZOLE, 4,5-DICHLORO-2-(TRI- 500/500 500 FLUOROMETHYL)- 98-07-7 BENZOTRICHLORIDE 100 10 100-44-7 BENZYL CHLORIDE 500 100 140-29-4 BENZYL CYANIDE 500 500 15271-41-7 BICYCLO[2.2.1]HEPTANE-2-CARBONITRILE,5-
    [Show full text]
  • Organophosphate Insecticides
    CHAPTER 4 HIGHLIGHTS Organophosphate Insecticides Acts through phosphorylation of the acetylcholinesterase enzyme Since the removal of organochlorine insecticides from use, organophosphate at nerve endings insecticides have become the most widely used insecticides available today. More Absorbed by inhalation, than forty of them are currently registered for use and all run the risk of acute ingestion, and skin and subacute toxicity. Organophosphates are used in agriculture, in the home, penetration in gardens, and in veterinary practice. All apparently share a common mecha- Muscarinic, nicotinic & CNS nism of cholinesterase inhibition and can cause similar symptoms. Because they effects share this mechanism, exposure to the same organophosphate by multiple routes or to multiple organophosphates by multiple routes can lead to serious additive Signs and Symptoms: toxicity. It is important to understand, however, that there is a wide range of Headache, hypersecretion, toxicity in these agents and wide variation in cutaneous absorption, making muscle twitching, nausea, specific identification and management quite important. diarrhea Respiratory depression, seizures, loss of consciousness Toxicology Miosis is often a helpful Organophosphates poison insects and mammals primarily by phosphory- diagnostic sign lation of the acetylcholinesterase enzyme (AChE) at nerve endings. The result is a loss of available AChE so that the effector organ becomes overstimulated by Treatment: the excess acetylcholine (ACh, the impulse-transmitting substance) in the nerve Clear airway, improve tissue ending. The enzyme is critical to normal control of nerve impulse transmission oxygenation from nerve fibers to smooth and skeletal muscle cells, glandular cells, and Administer atropine sulfate autonomic ganglia, as well as within the central nervous system (CNS).
    [Show full text]
  • Environmental Health Criteria 63 ORGANOPHOSPHORUS
    Environmental Health Criteria 63 ORGANOPHOSPHORUS INSECTICIDES: A GENERAL INTRODUCTION Please note that the layout and pagination of this web version are not identical with the printed version. Organophophorus insecticides: a general introduction (EHC 63, 1986) INTERNATIONAL PROGRAMME ON CHEMICAL SAFETY ENVIRONMENTAL HEALTH CRITERIA 63 ORGANOPHOSPHORUS INSECTICIDES: A GENERAL INTRODUCTION This report contains the collective views of an international group of experts and does not necessarily represent the decisions or the stated policy of the United Nations Environment Programme, the International Labour Organisation, or the World Health Organization. Published under the joint sponsorship of the United Nations Environment Programme, the International Labour Organisation, and the World Health Organization World Health Orgnization Geneva, 1986 The International Programme on Chemical Safety (IPCS) is a joint venture of the United Nations Environment Programme, the International Labour Organisation, and the World Health Organization. The main objective of the IPCS is to carry out and disseminate evaluations of the effects of chemicals on human health and the quality of the environment. Supporting activities include the development of epidemiological, experimental laboratory, and risk-assessment methods that could produce internationally comparable results, and the development of manpower in the field of toxicology. Other activities carried out by the IPCS include the development of know-how for coping with chemical accidents, coordination
    [Show full text]
  • Decontamination of Cyanophos Residues from Water Containing Catfish (Clarias Lazera) Using Activated Charcoal and Rice Husk Ash
    Journal of Applied Sciences Research 5(7): 820-826, 2009 © 2009, INSInet Publication Decontamination of Cyanophos Residues from Water Containing Catfish (Clarias Lazera) Using Activated Charcoal and Rice Husk Ash 1 Ahmed A. Romeh, 2 Mohamed B. Ashour, 2 Mohamed Y.Hendawi and 1Rady A. Ramadan 1Plant Protection Depart. Efficient Productivity. Inst., Zagazig Univ., Egypt. 2 Plant Protection Dept. Faculty of Agriculture. Zagazig Univ. Egypt. Abstract: The effect of activated charcoal and rice husk ash addition on the residues of cyanophos in water and some organs of catfish (clarias lazera) and their effect on some biochemical changes in blood serum were studies under laboratory conditions. The obtained results indicated that cyanophos showed high degradation in aquaria water compared with tap water. This was pronounced with the all considered post- treatment intervals. The average concentration of cyanophos in tap water and in water containing fish 2hrs after treatment was 8.73 and 6.60 Ug/ml respectively. These amounts were significantly decreased by time till reached 4.13 and 1.20 Ug/ml after 144hrs, representing 55.73and 87.14% dislodges of the initial amounts, respectively. Penetrated amount of cyanophos significantly increased and accumulated in the inner organs as time lapsed to reach the maximum level in the gills after 24 hrs (17.39 ug/gm) and in the liver during 48 hrs (24.51 ug/gm) while in muscles during 96 hrs (7.98 ug/gm) of experimental span. Thereafter, cyanophos began to disappear from the gills, liver and muscles gradually till the end of the experimental period (144 hrs).Addition of activated charcoal and rice husk ash to water contaminated with anilophos reduced clearly levels of residues in water and in fish gills, liver and muscles.
    [Show full text]
  • Use Date Issued: September 2006 ______
    United States Environmental Protection Agency Office of Prevention, Pesticides and Toxic Substances (7505P) _______________________________________________________ Pesticide Fact Sheet Name of Chemical: Metofluthrin Reason for Issuance: New Chemical Nonfood Use Date Issued: September 2006 _______________________________________________________ Description of Chemical IUPAC name: 2,3,5,6-tetrafluoro-4-(methoxymethyl)benzyl (EZ)- (1RS,3RS;1RS,3SR)-2,2-dimethyl-3-prop-1- enylcyclopropanecarboxylate CAS name: [2,3,5,6-tetrafluoro-4-(methoxymethyl)phenyl]methyl 2,2-dimethyl-3-(1-propenyl)cyclopropanecarboxylate Common Name: Metofluthrin Empirical Formula: C18H20F4O3 EPA Chemical Code: 109709 Chemical Abstracts Service (CAS) Number: 240494-70-6 Chemical Class: Pyrethroid ester Registration Status: New Chemical, nonfood use Pesticide Type: Insecticide repellent not applied to human skin U.S.Technical Registrant : Sumitomo Chemical Company, LTD. 1330 Dillon Hghts. Ave. Baltimore, MD 21228 Use Pattern and Formulations Currently there are two end use products being proposed for metofluthrin. DeckMate ™ Mosquito Repellent Strip is an impregnated paper strip (~3,528 cm2) containing 1.82 percent metofluthrin as the active ingredient. The product also contains Bitrex ™ to discourage oral exposure to children or animals. The product is for use on patios, campsites, decks, cabanas, and other outdoor areas. One strip is applied per 10 ft × 10 ft outdoor area. Indoors the application rate is two strips per 50 m3. There are approximately 200 mg of metofluthrin initially in the strip. The strips can provide up to one week of protection Metofluthrin evaporates readily and therefore requires no external heat. Norm 1- is a personal outdoor insect repellent product consisting of a holder containing a replaceable cartridge insert coated with up to 50 mg of metofluthrin.
    [Show full text]
  • Pesticide Resistance in Bed Bugs Everywhere!!!!!
    2/24/2018 Pesticide Resistance in Bed bugs were virtually eradicated from the U.S. in Bed Bugs the post WWII era due to DDT and other powerful Shujuan (Lucy) Li insecticides. University of Arizona Alvaro Romero New Mexico State University 2 By the 1960s, bed bugs had developed resistance Public housing Apartments to DDT, methoxychlor and analogues, BHC, Schools dieldrin and analogues , and pyrethrins ( Busvine 1958, Hospitals Nursing homes Cwilich & Mer 1957, Mallis and Miller 1964 ) . Homes Transportation Child care Medical facilities Hotels & motels Health care facilities Airports Movie theaters Department stores Products, vendors, or commercial services mentioned or pictured in this seminar are for Everywhere!!!!! illustrative purposes only and are not meant to be endorsements. 3 4 University of Arizona; Arizona Pest Management Center 1 2/24/2018 Possible reasons for treatment failure? Missed some Clutter Reintroduction Have you seen these after treatments? 5 6 Dose - response assays for field - collected strains Bed bugs survived direct insecticide sprays 99 deltamethrin 90 Ft. Dix F1 50 ) e l a c 10 s t CIN1 i b o 1.0 r p ( y t i l a t r 99 - cyhalothrin o m e 90 g a t n Resistance ratio (RR) at least 6,000 !!! e c Ft. Dix r 50 e P 10 CIN1 Suspend® ( Deltamethrin ) 1.0 10 -7 10 -6 10 -5 10 -4 10 -3 10 -2 10 -1 10 0 10 1 10 2 10 3 10 4 Treatment (mg active ingredient/cm 2 ) Products, vendors, or commercial services mentioned or pictured in this seminar are for illustrative purposes only and are not meant Romero et al.
    [Show full text]