DOCSLIB.ORG

List of Organic Pollutants Screened

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
List of Organic Pollutants Screened LIST OF ORGANIC POLLUTANTS SCREENED Screening of organic pollutants in LC-QTOF: Coupled Liquid Chromatography Analyser for quadripolar tandem mass spectrometry and flight time (Dichloromethoxy)benzene 3-(trimethoxyl silylylyl)propylidimethyloctadecylammo- (Z,E)-9,12-tetradecadienyl acetate nium 1.3-Bistrichloromethylbenzene (Hexacloromethiaxylol) 3,4,5-Trimetacarbees 1-Methylbenzotriazol (1-Tolyltriazol) 3,4-DCA / 3,4-Dichloroaniline 1-Methylnonyl N-phenyl-carbamate 3.4-Dichlorophenol 1-Actamide Naphthalene 3.5.5-Trimethylcyclohexenona (isophorona) 1-Naftol 3.5-DCA / 3.5-Dichloroaniline Acido 1-Naphthylacitico (Acido 1-Naphthylenacitico) 3.5-Dichlorophenol 2-(1-Naphthyl)acetamide (a-Naphthylacetamide) 3-Chloro-4-methoxyetanilide 2-(2-Hydroxiphenyl)-1,3-dioxolan (Dioxacarb artefate) 3-chlorophenoxyacetic acid 2.2’-Bipiridil 3-Hydroxycarbofuran 2,3,4,6-Tetrachlorophenol 3-methyl-4-chlorophenyl-N-methyl carbamate 2,3,5,6-Tetrachlorophenol Acido 3-piridinepropitnico 2,3,5-Trimetacarbe (Landrin) 4.4’-Bipiridil 2.3.6-TBA / 2.3.6-Trichlorobenzoic acid 4.4’-Dibromobenzophenone 2,3-DCA / 2,3-Dichloroaniline 4.4’-Dichlorobenzophenone 2.3-Dichlorophenol 4-Aminopyridine Acido 2,4,5-T / 2,4,5-Trichlorophenoxiacitico 4-Chloro-2-methylaniline (4-Chloro-o-toluidine) 2,4,5-T isopropyl ister isopropyl ister 4-Chlorophenyl dimethyl carbamate 2,4,5-TCP / 2,4,5-Trichlorophenol 4-CPA / Acido 4-chlorophenoxiacitico 2,4,5-TP / Silvex (Fenoprop) 4-Methylphenol (p-Cresol) 2,4,5-Trichlorophenyl carbanylate 4-Nitrophenol 2,4,6-TCP / Trichlorophenol, 2,4,6- 4-Octylphenol Acido 2,4-D / 2,4-dichlorophenoxiacitico 4-phenylphenol (Biphenylol) 2,4-D ister butmlico 5-Hydroxi-Dimethylsulfone 2,4-D isopropyl ister isopropyl ister 5-Hidroxiimidacloprid 2.4-D Metmlic Esther 5-Hidroxi-tiabendazol Acido 2,4-DB / 2,4-Dichlorophenoxibutmrico 8-Hydroxycinoline (8-Hydroxiquinoline) 2,4-DCP / 2,4-Dichlorophenol Abbot oxon 1 2.4-DEB / Sesin Abbot oxon 2 2.4-dichloroanisol Abbot oxon 2 sulfsxido 2,4-dichlorobenzoic acid Abbot sulfsxido (Temephos sufloxide) 2.4-Dinitrophenol Absynthin 2,4-DP / Dichloroprop Acemetacin 2,5-Dichlorophenol Acephate 2,6-Xylidine (2,6-Dimethylaniline) (Lidocamna-M) Acequinocyl (AKD-2033) 2-Aminobenzimidazol Acetamiprid 2-Chloroacetamide Acetazolamide 2-Chloroalyl dimethylthiocarbamate Acetochlor 2-Chlorophenoxyacetic acid ESA Vinegar 2-EEEBC / Debacarb Vinegar OXA (Acetochlor OA) 2-Ethylhexyl diphenyl diphosphate (Octicizador) Acetyl-Senecifiline Acido 2-naphthylacitico a-Chaconine 2-phenoxibenzolic acid Acibenzolar-S-methyle (BTH) 2-phenoxipropionic acid Acifluorfen 2-phenylphenol (2-hioxibiphenyl) Acifluorfene-methylene 2020 © toxSeek - List updated in 02/2020 Aclonifen Aspon (NDP) Acrinathrin (Rufast) Astaxanthin Acrylamide Asulam ADBI (ABDI) (Celestolide) Athidathion Affin Atraton AKH-7088 Atraton-desisopropyl Akton Atrazina O boi de bncton Atrazine-2-ethoxy Alachlor Atrazine-2-ethylamine Alachlor ESA Atrazine-2-hidroxi (hidroxiatrazine) Alachlor OXA (Alachlor OA) Atrazine-d5 Alantolactone Atrazine-desetil (Desetilatrazine) Alanycarb Atrazine-desetil-2-OH Albendazole Atrazine-desetil-dexopropyl Albendazole sulfoxide (sxido de albendazole) Atrazine-Desisopropyl (Deisopropylatrazine) Aldicarb Atrazine-desisopropyl-2-OH Sulfsxido de aldicarbe (Sulfsxido de aldicarbe) Avermectin B1a (Abamectin B1a) Aldicarb-oxime Avermectin B1b (Abamectin B1b) Aldimorph Avobenzone (BM-DBM) Aldoxicarbe (Aldicarbe Sulfone) Azaconazole Aldrin Azadirachtin Allethrin I Azafenidin Allethrin II Azamethiphos Allidochlor Azaperol Alloxydim Azaperone Allyltrimethylammonium cation Azidithion (Menazon) Allyxycarb Azimsulfuron (IN A8947) Alfamethrin (a-Cypermethrin) Azinfos-ethyl (Guthion ethyl) Ametoctradin Azinfos-methyle (Guthion) Ametridione Azinphos-methyl-oxon Ametrex Aziprotryne Amibuzin Azobenzene (artifate de Bumadizone) Amidantel Azocyclotin Em meio a Azoluron Amidosulfuron Azothoate Starchthioate Azoxistrobina Aminocarb Aztreonam Aminopyralid BAM / Diclorbenzamide Amiprophos-methyl Barban Amisulbrom Barthrin Amitraz BBIT / n-Butyl-1 ,2-benzisothiazolinone Amitrole (Aminotriazole) BBP / benzyl butyl phthalate (Butylbenzylphthalate) Ammeline (Atrazine-desetil-dexopropyl-2-OH) BDMC / 4-Bromo-3,5-dimethylphenyl methylcarbamate AMPA Beflubutamid Ampropylfos Benalaxil Anabasine Benalaxyl M Ancymidol (Ancimidol) Benazolin Anilazine Benazolin-ethyle Anilofos Bendiocarb Anisuron Benfluralin Antafenito Benfuracarb Antazonita Benfuresate Antraquinona Benodanil Antienita Benoxacor ANTU (Naftilthiourea) Benquinox Aramite Bensulfuron Arecoline Bensulfuron-methyl (Bianmihuanglong) Arnoscanate Bensulide Ascaridole Bensulide oxon Aspidinol Bensultap 2020 © toxSeek - List updated in 02/2020 Bentaluron Bromothymol (Vermella) Bentazone Bromoxamida Artefate de bentazona Bromoxinil Bentazona-8-Hidroxi Bromoxinyl octanoate Benthiavalicarb Bromuconazol(I) Bentranil Bromuconazol(II) Benzadox Bromuron Benzimidazole Bronopol Benzofenap Brotianmdeo Benzofluor BTA / Benzotriazole Benzoximate BTS 27271 Benzoylprop BTS 27919 (N-(2,4-dimethylphenyl)formamide) Benzoylprop-ethyl Bucarpolate Benzthiazuron Bufencarb Benzyl Benzoate Bulan Benzyladenine (6-Benzylaminopurine) Buminafos Bethoxazin Bunamidine BHA/ Hidroxianisol Butilado Bupirimate BHT/ Hidroxitolueno Butilado Buprofezin Bifenazate (D 2341) Butacarb Bifenox Butachlor (Machete) Bifenthrin Butafenacil Bilanafos Butamben (4-aminobenzoate de butyl) Binapacryl Butamifos Bioalletrin (Esbiothrin) Butamisole Bioresmethrin (Isatrin) Butenacloro Bifenyle Buthidazole Bis(trichloromethyl)sulfone (Chlorosulfone) Buthiobate Bisbendazol Buthiuron Bispyribac Butocarboxim Bisthiosemi Butocarboxima-sulfsxido Bistrichloromethylbenzene (Hexachloro-4-xylene) Butonate BIT / Benzisothiazolinone Butopyronoxyl Bitertanol Butoxicarboxim Bithionol Butralina (Sutralina) Bithionolsulfsxido Butroxydim Bitoscanate Buturon Bixafen 4-Hydroxybenzoate de butyl (Butylparaben) Blasticidine S Butylated butylate (Sutan) Bomyl Cacodyl acid (dimethylarsenic acid) Boscalid (Nicobifen) Cadusafos BPA / Bisphenol A Cafenstrole Brodifacoum Calciferol (Ergocalciferol) (Vitamin D2) Bromacil Cambendazole Bromadiolona Captafol Bromethalin Captafol Artefate Bromfenvinphos Carbanola (Banol) Bromfenvinphos-methyl Carbaryl Brometo Carbasulam Bromobutide Carbendazim (Azole) Bromocholine Carbetamida Bromociclen Carbofuran Bromofenofos Carbofuranphenol (Carbofuranphenol) Bromofenoxim Carbofuran-3-keto Bromofos Carbofuran-3-OH-7-fenol Bromofos sxido de etilo Carbofuranphenol-3-keto Bromofos oxon (Bromoxon) Carbofenothion Bromofos-ethanol Carbofenothion-methyl-sulphone Bromopropylate (dibromobenzylate de isopropylene) Carbofenothion-methyl-sulfoxide Bromopyrazon (Brompyrazon) Carbosulfan 2020 © toxSeek - List updated in 02/2020 Carboxin Chloropropylate Carfentrazone Chlorothalonil Carfentrazone-ethyle Chloroxuron Carpropamide (KTU 3616) Chloroxynil Cartap Chlorfenprop-methyle (Fatex) Carvacrol (Isopropyl cresol) Chlorphoxim Carvone Chlorprocarb CBBP / Phosfon (chlorftnium cloreto) Chlorpropham CDEC / Sulphalate Chlorpyriphos (Chlorpyriphos) Cevadin Chlorpyriphos oxon Chlorpyrifos oxon Phenodeoxicslic acid (Chenodiol) Chlorpyriphos-methyl (Chlorpyriphos-methyl) Chinomethionate Chlorsulfuron Clomethoxyfen Chlorsulfuron-5-OH Chloral ethyl hemiacetal (Chloral semiacetal) (Chloral Chlorthal alcohol) Clortal-dimethyl Chloral methyl hemiacetal Chlorthiamid Chloralose Chlorthion Chloramben (Amiben) Chlorthiophos Chloraniformethan Chlorthiophos-sulphone Chloranil Chlorofos-sulfsxido Chloranic acid Chlorotolurco (Chlorotoluron) Chlorantraniliprole Chlozolinate Chlorazifop Chromafenozida Chlorbenside Cyclobendazol (Cyclobendazol) Chlorbenside-sulphone Cinerin I (Cinerin I) Chlorbromuron Cinerin II (Cinerin II) Chlorbufam Cinidon-ethyl Chlordane Cinmethylin Chlordecone Cinosulfuron Chlordimeform Chocolate (Crotoxyphos) Chlorethoxyfos Ciprofloxacin Chlorfenapyr Hidrato de Citronelal Clorfenazol Clenpirin Chlorfenson (Ovex) Clethodim Chlorfensulphide Clethodim-sulfone Chlorfenvinphos(I) Clethodim-sulfoxide Chlorfenvinphos(II) Climbazole Chlorflurazurona (Chlorfluazurone) Clioxanida Chlorflurenol Clodinafop Chlorflurenol-methyle Clodinafop-propargyl Chloridazon (PAC) Cloethocarb Chloridazon-desphenyl Clofencet Chloridazon-desphenyl-methyl Clofentezine Chlorimuron Clofop-isobutyl Chlorimuron-ethylenol Clomazone Chlorlenethol Clomeprop Chlormefos (Chlormefos) Cloprop Chlormequat Cloproxidim Chlornitrofen Clopyralid Chloraceptic acid Cloquintocet-mexyl Chlorobenzilate Cloransulam Chlorobenzuron Chloransulam-methyle Chlorofenprop (Chlorfenprop) Closantel Chloromebuform Clothianidin Chloromethiuron Clotrimazole Chloroneb Cloxyfonac Chlorofacinona (Rozol) Codlemon Chlorophenoxipropionamide Bis(1-cyclohexyl-2-oxo-hidrazinolate) de cobre(2+) Chloropicrin Cos-Oga Chloropropham (Chlorpropham) Coumachlor 2020 © toxSeek - List updated in 02/2020 Coumafuryl Daminozide Coumaphos Danifos (Boi de carbofenotico) Coumaphos-oxon (Coroxon) DAS / Diacetoxyscirpenol Coumatetralyl Dazomet Coumithoate DBDCB / Dibromodicanobutane CPA / Acido ciclopiaztnico DBNPA / 2,2-Dibromo-3-nitrilopropionamide Benzoate de Cresol (p) DCHP / Dicyclohexyl phthalate Crimidine DCIP / Iter bis(2-chloro-1-methylethyl)iter Crufomate (Ruelene) DCOIT (Kathon) Cumyluron DCU / Dichloralurea Cyanamide DDD Cyanatryn DDM / Dichlorophenum Cyanazine (Fortrol) Decarbofuran Cyanazine acid DEET / Diethyltoluamide Cyanazine starch Deethylametryn Cyanofenphos (Cyanofenphos) Deethylcyanazine Oxygen analgesic cyanophenphos Acido desethylcianazine Cyanofos Dexethylcianazine
Load more

Recommended publications
  • Research Journal of Pharmaceutical, Biological and Chemical Sciences
    ISSN: 0975-8585 Research Journal of Pharmaceutical, Biological and Chemical Sciences Risk Alleviation Of Pesticides In Agriculture: From History To Analytical Techniques. Jojiya Grace George, and Aneesh TP*. Amrita School of Pharmacy, Amrita University, Amrita Vishwa Vidyapeetham,AIMS Health Sciences Campus, Kochi, Kerala, India. ABSTRACT Population explosion leads to the exploitation of agricultural field to meet the supply of food products (mainly vegetables and fruits). Before first century onwards the usage of pesticide was started to promote the growth of food products and in the present, biotechnological strategies are adopted for pest control along with synthetic pesticides. The demand for maximization of productivity is achieved by the application of synthetic pesticides. Apart from its benefits, its misuse predominates and generates serious consequences. The categorization of pesticides can be done according to their source, mode of action, nature of pest and also on their chemical nature. Excessive and inappropriate usage of pesticides undoubtfully leads to poisoning and various instances of pesticide poisoning are being reported every year. These incidences of pesticide poisoning tragedy include Endosulphan poisoning, Tragedy of Tauccamarca, Seveso disaster etc. These pesticides create serious health hazards ranging from short term effects like vomiting to long term effects including cancer and neurological problems. Analytical laboratories contribute for reducing its intensity to humans and to environment through preliminary screening techniques and comprehensive screening procedures like HPLC, LCMS, GC and GCMS. These are efficient and powerful methods of pesticide determination in vegetables and fruits. The scenario of pesticide usage is complex and hence, care has to be taken by the government and public to lower its usage and to promote environmental stability and social health.
    [Show full text]
  • Liste Des Pesticides
    Pesticides azotés Atrazine Hexazinone Terbutylazine Terbumeton-déséthyl Terbutylazine-déséthyl Amétryne Cyromazine Clofentezine Metribuzine Prometryne Pymetrozine Terbumeton Prometon Secbumeton Terbutryne Methoprotryne Simazine Simetryne Cyanazine Atrazine-déisopropyl Pesticides organochlorés Methoxychlore Chlorothalonil Quintozène (pentachloronitrobenzène) 2,4' DDD 2,4' DDE 4,4' DDD 4,4' DDE 4,4' DDT Aldrine Dicofol Dieldrine Endosulfan alpha Endosulfan béta Endosulfan sulfate Endrine HCB (hexachlorobenzène) HCH alpha HCH béta HCH delta Heptachlore Heptachlore époxyde Lindane (HCH gamma) Tetradifon Nitrofen Mirex Tolclofos-méthyl Dicloran 2,4' DDT Folpel (folpet) Somme des heptachlore et heptachlore epoxyde Chlordane cis (alpha) Chlordane cis (alpha) Oxychlordane Tecnazene HCH epsilon Chlorthal-diméthyl (DCPA méthyl ester) Pentachlorobenzène Isodrine Chloroneb Chlorbenzide Chlorobenzilate Endrine cétone Nonachlor trans Chlordane gamma 4,4'-dichlorobenzophénone Endosulfan-éther Heptachlore epoxyde exo Pentachlorobenzonitrile Nonachlor cis 4,4'-méthoxychlore oléfine Perthane Heptachlore epoxyde endo Somme quintozène+PCA (exprimée en quintozène) Pesticides organophosphorés Carbophénothion Chlorfenvinphos Chlorpyriphos éthyl Chlorpyriphos méthyl Diazinon Dichlorvos Disulfoton Ethion Ethoprophos Fenitrothion Fenthion Fonofos Formothion Isazofos Isofenphos Malathion Methidathion Mevinphos Parathion éthyl Parathion méthyl Phorate Phosalone Pyrimiphos méthyl Profenofos Pyrazophos Quinalphos Terbufos Tetrachlorvinphos Etrimfos EPN Fenamiphos Mecarbam
    [Show full text]
  • Con Fundamento En Los Artículos 32 Bis, 34, 35 Y 39 De La Ley Orgánica
    SECRETARÍA DE MEDIO AMBIENTE Y RECURSOS NATURALES SECRETARÍA DE ECONOMÍA SECRETARÍA DE AGRICULTURA Y DESARROLLO RURAL SECRETARÍA DE SALUD Con fundamento en los artículos 32 Bis, 34, 35 y 39 de la Ley Orgánica de la Administración Pública Federal; 4o., fracción III, 5o., fracción III, 15, fracción VI, 16, fracción VI, 17 y 20 de la Ley de Comercio Exterior; 142, 144 segundo párrafo y 153 de la Ley General del Equilibrio Ecológico y la Protección al Ambiente; 3o., fracción XXII, 17 bis, 283, 284, 285, 289, 298, 368 y 375, fracción VIII de la Ley General de Salud; 9, fracciones III y IV de la Ley Federal para el Control de Sustancias Químicas Susceptibles de Desvío para la Fabricación de Armas Químicas; 5, fracción XVII del Reglamento Interior de la Secretaría de Economía; 2, apartado C, fracción X y 7, fracción XVI del Reglamento Interior de la Secretaría de Salud; 1 y 3, fracciones I, VII y XI del Reglamento de la Comisión Federal para la Protección contra Riesgos Sanitarios; 3 fracciones I, II y III y 24 al 38 del Reglamento en Materia de Registros, Autorizaciones de Importación y Exportación y Certificados de Exportación de Plaguicidas, Nutrientes Vegetales y Sustancias y Materiales Tóxicos o Peligrosos, y 3o., fracción III del Reglamento Interior de la Comisión Intersecretarial para el Control del Proceso y Uso de Plaguicidas, Fertilizantes y Sustancias Tóxicas, y CONSIDERANDO Que el 26 de junio de 1945, el Gobierno de los Estados Unidos Mexicanos suscribió la Carta de las Naciones Unidas por la que se creó la Organización de las Naciones Unidas (ONU), instrumento que fue aprobado por el Senado de la República el 5 de octubre de 1945 y publicado en el Diario Oficial de la Federación el día 17 del mismo mes y año.
    [Show full text]
  • WHO VBC 80.766 Eng.Pdf (‎1.320
    5E:e Ai::>b ./ /fj S€f>ARAT£ t=".::.c..·l:::.c--Q WORLD HEALTH ORGANIZATION ~ WHO/VBC/80.766 VBC/BCDS/80.09 ORGANISATION MONDIALE DE LA SANTE ENGLISH ONLY DATA SHEET ON THE BIOLOGICAL CONTROL AGENT(l) INDEXED Romanomermis culicivorax (Ross and Smith 1976) Romanomermis culicivorax is an obligatory endoparasitic nematode, the parasitic larvae of which develop inside larval mosquitos. It has little genus and species specificity within the Culicidae faplily. A total of 87 species (including Anopheles stephensi, An. albimanus, An. gambiae and many other vector species) have been exposed to it either in the laboratory or in the field and were infected. R. culicivorax has been extensively studied for the past 10 years. It can be easily mass produced, is safe to mammals and other non-target organisms, and its environmental limitations are well documented. This parasite is effective when used in water habita~s with the following characteritstics: fresh and non polluted, semi-permanent or permanent, temperature rarely exceeding 40°C, and little water movement. Several natural predators among the aquatic organisms likely to dwell in mosquito pools have been shown to prey on R. culicivorax; but the size, amounts of open water, pH, vegetation densities and host densitie; are not significant factors in the successful use of this biological control agent. This nematode should now be operationally evaluated against vectors during large scale field trials in endemic areas. 1. Identification and Synonymy Nematoda: Mermithidae Romanomermis culicivorax (Ross and Smith, 1976), is a segregate of a complex known previously as Reesimermis nielseni (Tsai and Grundmann, 1969).
    [Show full text]
  • Responses of Antioxidant in Rainbow Trout Exposed to Temephos Veysel PARLAK1* Arzu UCAR1 Gonca ALAK1 Muhammed ATAMANALP1
    Araştırma Makalesi / Research Article Iğdır Üniversitesi Fen Bilimleri Enstitüsü Dergisi, 9(2): 1156-1163, 2019 Su Ürünleri / Fisheries Journal of the Institute of Science and Technology, 9(2): 1156-1163, 2019 DOI: 10.21597/jist.446624 ISSN: 2146-0574, eISSN: 2536-4618 Responses of Antioxidant in Rainbow Trout Exposed to Temephos Veysel PARLAK1* Arzu UCAR1 Gonca ALAK1 Muhammed ATAMANALP1 ABSTRACT: In this study, rainbow trout was exposed to temephos (TE) during 96h acute toxicity conditions. The toxic compound was given in doses of 3 mg L-1 and 6 mg L-1. Furthermore, we assessment antioxidant enzymes activity (glucose-6-phosphate dehydrogenase (G6PD), catalase (CAT), glutathione reductase (GR), superoxide dismutase (SOD), malondialdehyde (MDA) level in liver and acetylcholinesterase (AChE) in brain. CAT, SOD, GR, G6PD, and MDA in liver were demonstrated significant effects by the treatments (P<0.05). TE exposure resulted in the inhibition of AChE activity, which, compared with the control group, decreased in all doses (P<0.05). The results showed that temephos inhibited liver tissue’s enzyme activities and increased MDA levels. In the light of these data, we can say that temephos toxicity should be taken into consideration in aquatic environments. Key words: Pesticide; oxidative stress; AChE; rainbow trout Temefos’a Maruz Kalan Gökkuşağı Alabalıklarında, Antioksidan Cevaplar ÖZET: Çalışmamızda gökkuşağı alabalıkları temefosun 3 ve 6 mg L-1 dozlarına akut uygulama ile maruz bırakılmıştır. Uygulama sonrasında karaciğer dokusunda antioksidan enzim aktiviteleri (Süperoksitdismutaz (SOD), katalaz (CAT), glutatyon redüktaz (GR), glukoz 6 fosfat dehidrogenaz (G6PD)), malondialdehit seviyesi ve beyin dokusunda asetilkolin esteraz (AChE) aktivitesi değerlendirildi. Karaciğer dokusunda SOD, CAT, GR, G6PD aktivitelerinde ve MDA seviyesinde önemli seviyede değişiklikler belirlendi (P<0.05).
    [Show full text]
  • List of Criteria and Selected Air Contaminants to Be Used for Public Notice, with Spanish Translations. COMMON AIR CONTAMINANTS
    List of Criteria and Selected Air Contaminants To Be Used for Public Notice, with Spanish Translations. COMMON AIR CONTAMINANTS: English Spanish NOX NOX (óxidos de nitrógeno) CO monóxido de carbono PM materia en partículas SO2 or SOX SO2 or SOX (óxidos de azufre) Halogens halógenos Hydrocarbons hidrocarburos Inorganic Acids ácidos inorgánicos Inorganic Bases bases inorgánicas Metals metales Carbon Compounds compuestos de carbono Carbon compounds including (but not limited to) : Benzene, Methyl Ethyl Ketone and Freon 11. Compuestos de carbono incluyendo (pero no limitándose a): Benceno, Metiletilcetona y Freón 11. OTHER AIR CONTAMINANTS English - Spanish Air Contaminant Glossary for Spanish Public Notice This list contains numerous air contaminants, mostly as listed in the ESL (= Effects Screening Levels) lists of 6/22/92 and updates of 1994. The Spanish translated names are capitalized for trademarks. In many such cases, there is no translation and the English word must be used. English Name Spanish Name Abamectin Abamectin Abate Abate acenaphthene acenafteno acetal acetal acetaldehyde acetaldehído acetamide acetamida acetic acid acido acético acetic anhydride anhídrido acético acetoacetoxyethyl methacrylate,2- 2-metacrilato acetoacetoxietílico acetone acetona acetone cyanohydrin cianohidrina de acetona acetonitrile acetonitrilo acetophenone acetofenona acetylaminofluorene,2- 2-acetilaminofluoreno acetyl chloride cloruro acetílico [AOAQG01/962 v2] Page 1 of 52 acetylene acetileno acetylene dichloride dicloruro de acetileno (1,2-dichloroethylene)
    [Show full text]
  • Niveles De Susceptibilidad a Temefos En El Vector Transmisor Del Dengue En Trujillo, Perú
    Anales de la Facultad de Medicina Niveles de susceptibilidad a temefos ISSN 1025 - 5583 Universidad Nacional Mayor de San Marcos Págs. 53-56 Niveles de susceptibilidad a temefos en el vector transmisor del dengue en Trujillo, Perú Julio Chávez 1, Ofelia Córdova 1, Franklin Vargas 1 Resumen Objetivo: Determinar los niveles de resistencia a temefos en poblaciones de Aedes aegypti de la provincia de Trujillo. Material y Métodos: Los bioensayos en larvas siguieron la metodología de la Organización Mundial de la Salud. Se empleó larvas del tercer o cuarto estadio temprano de cada población, incluyendo la cepa de referencia Rockefeller. Se usó 5 réplicas de cada concentración del insecticida, produciéndose mortalidades entre 2 y 98 %. Resultados: Se encontró susceptibles a temefos a todas las poblaciones evaluadas, mostrando mayor factor de resistencia la población de Florencia de Mora, con un valor de 3,05 X. Conclusión: Se sugiere realizar monitoreos continuos de resistencia a temefos en poblaciones de A. aegypti para brindar información necesaria que ayude a la toma de decisiones sobre el uso correcto de este insecticida. Palabras clave Aedes; dengue; temefos; bioensayos. Dengue’s transmitting vector susceptibility to INTRODUCCIÓN temephos, Trujillo, Peru Dentro del gran número de especies de Abstract mosquitos resistentes a la acción de insecticidas, Objective: To determine resistance levels to temephos in se encuentra Aedes aegypti Linnaeus, que Aedes aegypti strains from Trujillo. Material and desempeña una importante función en la Methods: The larvae bioassays were done according to transmisión de enfermedades víricas. El dengue, the World Health Organization’s methodology. Third or early fourth stage larvae from each population were used, fiebre del dengue hemorrágico y la fiebre including the reference Rockefeller stock.
    [Show full text]
  • ) (51) International Patent Classification: Declarations Under
    ) ( (51) International Patent Classification: Declarations under Rule 4.17: A01N 43/56 (2006.0 1) C07D 401/04 (2006.0 1) — as to applicant's entitlement to apply for and be granted a (21) International Application Number: patent (Rule 4.17(H)) PCT/US20 19/033099 Published: (22) International Filing Date: — with international search report (Art. 21(3)) 20 May 2019 (20.05.2019) (25) Filing Language: English (26) Publication Language: English (30) Priority Data: 62/682,248 08 June 2018 (08.06.2018) US (71) Applicant: DOW AGROSCIENCES LLC [—/US]; 9330 Zionsville Road, Indianapolis, Indiana 46268 (US). (72) Inventors: ZHANG, Yu; 9330 Zionsville Road, Indi¬ anapolis, Indiana 46268 (US). TRULLINGER, Tony K.; 9330 Zionsville Road, Indianapolis, Indiana 46268 (US). KLITTICH, Carla J.R.; 5201 N . Placita Cresta Loma, Tucson, Arizona 85704 (US). HUNTER, Ricky; 9330 Zionsville Road, Indianapolis, Indiana 46268 (US). (74) Agent: CUDWORTH, Denise P.; 9330 Zionsville Road, Indianapolis, Indiana 46268 (US). (81) Designated States (unless otherwise indicated, for every kind of national protection available) : AE, AG, AL, AM, AO, AT, AU, AZ, BA, BB, BG, BH, BN, BR, BW, BY, BZ, CA, CH, CL, CN, CO, CR, CU, CZ, DE, DJ, DK, DM, DO, DZ, EC, EE, EG, ES, FI, GB, GD, GE, GH, GM, GT, HN, HR, HU, ID, IL, IN, IR, IS, JO, JP, KE, KG, KH, KN, KP, KR, KW, KZ, LA, LC, LK, LR, LS, LU, LY, MA, MD, ME, MG, MK, MN, MW, MX, MY, MZ, NA, NG, NI, NO, NZ, OM, PA, PE, PG, PH, PL, PT, QA, RO, RS, RU, RW, SA, SC, SD, SE, SG, SK, SL, SM, ST, SV, SY, TH, TJ, TM, TN, TR, TT, TZ, UA, UG, US, UZ, VC, VN, ZA, ZM, ZW.
    [Show full text]
  • 81 2020 Cz Whole Cai Pdf.Pdf
    Příloha je nedílnou součástí osvědčení o akreditaci č.: 81/2020 ze dne: 6. 2. 2020 Akreditovaný subjekt podle ČSN EN ISO/IEC 17025:2018: ALS Czech Republic, s.r.o. Na Harfě 336/9, 190 00 Praha 9 Pracoviště zkušební laboratoře: 1 Praha Na Harfě 336/9, 190 00 Praha 9 2 Česká Lípa Bendlova 1687/7, 470 01 Česká Lípa 3 Pardubice V Ráji 906, 530 02 Pardubice 10 Praha Na Harfě 916/9a, 190 00 Praha 9 11 Praha Kolbenova 942/38a, 190 00 Praha 9 Kontaktní a odběrová místa 4 Brno Vídeňská 134/102, 619 00 Brno 5 Ostrava Vratimovská 11, 718 00 Ostrava 6 Plzeň Lobezská 15, 301 46 Plzeň 7 Lovosice U Zdymadel 827, 410 02 Lovosice 8 Rožnov pod Radhoštěm 1. Máje 823, budova C6, 756 61 Rožnov pod Radhoštěm 9 Kroměříž Konojedská 2588/91, 767 01 Kroměříž Laboratoř uplatňuje flexibilní přístup k rozsahu akreditace upřesněný v dodatku. Aktuální seznam činností prováděných v rámci flexibilního rozsahu má laboratoř k dispozici na webových stránkách laboratoře www.alsglobal.cz nebo u manažera kvality. Laboratoř poskytuje odborná stanoviska a interpretace výsledků zkoušek. Laboratoř je způsobilá provádět samostatné vzorkování. Zkoušky: OBECNÁ CHEMIE Pořadové Přesný název Identifikace Předmět zkoušky číslo 1 zkušebního postupu/metody zkušebního postupu/metody 2 Stanovení prvků47) metodou atomové emisní CZ_SOP_D06_02_001 Vody, výluhy, kapalné spektrometrie s indukčně vázaným plazmatem a (US EPA 200.7, ČSN EN ISO 11885, vzorky stechiometrické výpočty obsahů sloučenin ČSN EN 16192, US EPA 6010, 1.1 1) z naměřených hodnot51) včetně výpočtu celkové SM 3120, ČSN 75 7358 mineralizace a výpočtu sumy CAM příprava vzorku dle CZ_SOP_D06_02_J02kap.10.1 a 10.2) Stanovení prvků47) metodou atomové emisní CZ_SOP_D06_02_001 Pevné vzorky, materiály spektrometrie s indukčně vázaným plazmatem a (US EPA 200.7, ČSN EN ISO 11885, staveb, stavební stechiometrické výpočty obsahů sloučenin US EPA 6010, SM 3120, příprava materiály 1.2 1) z naměřených hodnot52) vzorku dle CZ_SOP_D06_02_J02 (US EPA 3050, ČSN EN 13657, ISO 11466) kap.
    [Show full text]
  • UNIVERSIDADE DE SÃO PAULO Neuropatia Retardada
    UNIVERSIDADE DE SÃO PAULO FACULDADE DE CIENCIAS FARMACÊUTICAS DE RIBEIRÃO PRETO Neuropatia retardada induzida por organofosforados: estudo in vitro dos mecanismos de neurotoxicidade do organofosforado triclorfom e estratégias de neuroproteção Tese de Doutorado apresentada ao Programa de Pós Graduação em Toxicologia para a obtenção do título de Doutora em Ciências Área de Concentração: Toxicologia Orientada: Lais Silva Fernandes Orientador: Prof. Dr. Antonio Cardoso dos Santos Coorientador: Prof. Dr. Guilherme Luz Emerick Versão corrigida da Tese de Doutorado apresentada ao Programa de Toxicologia em 10/03/2017. A versão original encontra-se disponível na Faculdade de Ciências Farmacêuticas de Ribeirão Preto-USP. Ribeirão Preto 2017 i RESUMO FERNANDES, L.S. Neuropatia retardada induzida por organofosforados: estudo in vitro dos mecanismos de neurotoxicidade do organofosforado triclorfom e estratégias de neuroproteção. 2017. 148f. Tese (Doutorado). Faculdade de Ciências Farmacêuticas de Ribeirão Preto – Universidade de São Paulo, Ribeirão Preto, 2017. Os praguicidas organofosforados (OPs) são amplamente utilizados na indústria química e na agricultura em todo o mundo. Muitos deles são potenciais causadores da “Neuropatia Retardada Induzida por Organofosforados” (NRIOP), caracterizada pela degeneração distal de axônios do sistema nervoso central e periférico (degeneração do tipo Walleriana). O praguicida triclorfom (dimetil 2,2,2-tricloro–1– hidroxietil fosfonato) tem sido utilizado em larga escala na produção agrícola e também no controle de vetores transmissores de várias doenças. Há relatos de efeitos neuropáticos em seres humanos expostos ao triclorfom, mas apesar disso, o seu potencial neuropático e seus mecanismos de neurotoxicidade ainda não foram elucidados. Assim, no presente estudo foram avaliados os mecanismos de toxicidade do praguicida OP triclorfom utilizando linhagem SH-SY5Y de neuroblastoma humano como modelo, e também foram avaliados possíveis agentes neuroprotetores em células tratadas com o bem estabelecido indutor da neuropatia mipafox.
    [Show full text]
  • Eurasia Economic Union - New Pesticide Mrls Report Categories: Sanitary/Phytosanitary/Food Safety Approved By: Jonathan P Gressel Prepared By: FAS Moscow/Staff
    THIS REPORT CONTAINS ASSESSMENTS OF COMMODITY AND TRADE ISSUES MADE BY USDA STAFF AND NOT NECESSARILY STATEMENTS OF OFFICIAL U.S. GOVERNMENT POLICY Voluntary - Public Date: GAIN Report Number: Russian Federation Post: Moscow Eurasia Economic Union - New Pesticide MRLs Report Categories: Sanitary/Phytosanitary/Food Safety Approved By: Jonathan P Gressel Prepared By: FAS Moscow/Staff Report Highlights: On November 10, 2015, the Eurasian Economic Commission adopted the Amendments to the Unified Sanitary-Epidemiological and Hygiene Requirements for Commodities Subject to Sanitary- Epidemiological Surveillance (Control). Adopted amendments concern requirements for pesticides and agrochemicals and Maximum Residue Limits (MRLs) for pesticides and chemicals in external entities, such as human body, soil, reservoir water, working air, open air, and in agricultural raw materials and food products. The document was published on November 18, 2015, and will come to force in a month after publication. The U.S. Government commented on the draft regulations in 2012. General Information: On November 10, 2015, the Eurasian Economic Commission, the working body of the Eurasian Economic Union (EAEU), adopted the Decision No. 149 “On Amendments to the Decision of the Customs Union Commission No. 299 of May 28, 2010”. The Decision 299 of 2010 concerns the Unified Sanitary-Epidemiological and Hygiene Requirements for Commodities Subject to Sanitary-Epidemiological Surveillance (Control). Amendments that were made by the Decision No. 149 of November 10, 2015 cover the following: - Requirements for pesticides and agrochemicals (the non-official translation of these requirements is in Annex 2 to this report); - Maximum Residue Limits (MRLs) for pesticides and chemicals (573 chemicals) in external entities, such as human body, soil, reservoir water, working air, open air, and in agricultural raw materials and food products.
    [Show full text]
  • Modo De Herencia De La Resistencia a Temefos (Abate) En Aedes Aegypti (Diptera: Culicidae) De Cuba
    142 REV CUBANA MED TROP 2006;58(2):142-7 INSTITUTO DE MEDICINA TROPICAL “PEDRO KOURÍ” Modo de herencia de la resistencia a temefos (abate) en Aedes aegypti (Diptera: Culicidae) de Cuba Lic. María Magdalena Rodríguez,1 Lic. Juan A. Bisset,2 Dra. Omayda Pérez,3 Téc. Francisco Ramos4 y Dra. Grisel E. Risco5 RESUMEN Se realizó el estudio sobre el modo de herencia de la resistencia al insecticida organofosforado temefos, a partir de una cepa de Aedes aegypti de referencia (SAN-F6), resistente, con un valor de factor de resistencia de 200x, comparado con la cepa de Aedes aegypti susceptible a insecticidas (ROCKEFELLER). Se llevaron a cabo cruces genéticos entre la cepa resistente y la susceptible a temefos, obteniéndose una F1 (cruce). Las hembras de esta F1 del cruzamiento se cruzaron con machos de la cepa ROCKEFELLER (retrocruce) y como resultado se obtuvo que la resistencia a temefos se heredó de forma semidominante, mediada por un solo factor. La actividad de Est-A4, observada en la electroforesis en gel de poliacrilamida y medida mediante ensayos bioquímicos, fue mayor en la cepa resistente a temefos (SAN-F6), menor en la cepa susceptible (ROCKEFELLER) e intermedia en el cruce de estas 2 cepas. Un menor efecto del parental resistente fue observado en el retrocruce tanto en la mortalidad con temefos, como en la actividad de la Est. A4. Estos resultados sugieren que la actividad de esterasas pudiera heredarse también, al igual que la resistencia a temefos, como un carácter semidominante. Palabras clave: Aedes aegypti, resistencia, modo de herencia, temefos, esterasa, y glutation transferasa.
    [Show full text]