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Abjean JP and Lahogue V. Planar chromatography for quantitative determination
of ampicillin residues in milk and muscle. Journal of AOAC International,
1997, 80 (6), 1171-1176.
Acacia R, Rey G, Gilberto D, Clementina G, Norma P, Salvador V and Mario N.
High-performance thin-layer chromatography-bioautography for multiple
antibiotic residues in cow's milk. Journal of Chromatography B,
Analytical Technology and Biomedical Life Sciences, 2003, 784 (2), 315-
322.
Adams and Denise W. Restoring American gardens. An Encyclopedia of
Heirloom Ornamental Plants, 2004, 1640-1940.
Agueraa A, Mezcuaa M, Mochol F, Vargas-Berenguel A and Fern´andez-Alba
AR. Application of gas chromatography-hybrid chemical ionization mass
spectrometry to the analysis of diclofenac in wastewater samples. Journal
of Chromatography A, 2006, 1133 (1-2), 287–292.
Agüí L, Guzman A, Pedrero M, Yáñez-Sedeño P and Pingarrón JM. Voltametric
and Flow Injection determination of oxytetracycline residues in food
samples using carbon fiber microelectrodes. Electroanalysis, 2003, 15 (7),
601–607.
Ahmed E, Yousef and Carolyn C. Food microbiology, a laboratory manual,
2003, 153-167.
Ahmet N and Emel N. Phagotrophic protozoa, A new weapon against pathogens.
.Medical Hypotheses, 2008, 70 (1), 141-142.
Akkad R and Schwack W. Multi-enzyme inhibition assay for the detection of
insecticidal organophosphates and carbamates by high-performance thin-
layer chromatography applied to determine enzyme inhibition factors and
residues in juice and water samples. Journal of Chromatography B,
Analytical Technologies in Biomedical Life Sciences, 2010, 878 (17-18),
1337-1345.
Akkad R and Schwack W. Effect of bromine oxidation on high-performance thin-
layer chromatography multi-enzyme inhibition assay detection of
organophosphates and carbamate insecticides. Journal of Chromatography
A, 2011, 1218 (19), 2775–2784.
160
Akkad R and Schwack W. Determination of organophosphorus and carbamate
insecticides in fresh fruits and vegetables by high-performance thin-layer
chromatography-multienzyme inhibition assay, Journal of AOAC
International, 2012, 95 (5), 1371-1377.
Aifang L, Xiaoyu L, Juan K, Rong H and Chengmou W. Chemiluminescence
determination of organophosphorus pesticides chlorpyrifos in vegetable.
Analytical Letters, 2008, 41 (8), 1375-1386.
Alamgir M, Chowdhury Z, Shubhra B, Fakhruddin ANM, Islam MN and Alam
MK. Determination of cypermethrin, chlorpyrifos and diazinon residues in
tomato and reduction of cypermethrin residues in tomato using rice bran.
World Journal of Agricultural Research, 2013, 1 (2), 30-35.
Alexander DD, Cushing CA, Lowe KA, Sceurman B and Roberts MA. Meta-
analysis of animal fat or animal protein intake and colorectal cancer.
American Journal of Clinical Nutrition , 2009, 89 (5), 1402-1409.
Alekseev VN, Kurs kachestvennogo khimicheskogo polumikroanaliza, 4th ed.
Moscow, 1962.
Alekseev VN, Kolichestvennyi analiz, 4th ed. Moscow, 1972.
Alfredsson G, Branzell C, Granelli K and Lundström A. Simple and rapid
screening and confirmation of tetracyclines in honey and egg by a dipstick
test and LC–MS/MS, Analytica Chimica Acta, 2005, 529 (1–2), 47–51.
Alsante KM, Hatajik TD, Lohr LL and Sharp TR. Isolation and identification
of process related impurities and degradation products from
pharmaceutical drug Candidates. American Pharmaceutical Review, 2001,
4 (1), 70-78.
Amber RS, Saima Q, Arfana M and Khuhawar MY. Quantitative separation of
oxytocin, norfloxacin and diclofenac sodium in milk samples using
capillary electrophoresis. Biomedical Chromatography, 2009, 23 (9),
1007–1013.
Amer SM, Ibrahim AAES and El-Sherbeny KM. Induction of chromosomal
aberrations and sister chromatid exchange in vivo and in vitro by the
insecticide cypermethrin. Journal of Applied Toxicology, 1993, 13 (5),
341-345.
Ana A, Mariano C, Juan C and Amadeo RFA. Multiresidue method for the
analysis of multiclass pesticides in agricultural products by gas
161
chromatography-tandem mass spectrometry. Analyst, 2002, 127 (3), 347–
354.
Anderson KL, Moats WA, Rushing JE, Wesen DP and Papich MG. Ampicillin
and amoxicillin residue detection in milk, using microbial receptor assay
(Charm II) and liquid chromatography methods, after extra-label
administration of the drugs to lactating cows. American Journal of
Veterinary Research, 1996, 57(1), 73-78.
Angelo LG and Kenneth GS. Febuxostat- the evidence for its use in the treatment
of hyperuricemia and gout. Dovepress Journal, 2009, 4(1), 25-36.
Angelina P, Celeste ML, Rosa A and Damia B. Determination of tetracycline
antibiotic residues in edible swine tissues by liquid chromatography with
spectrofluorometric detection and confirmation by mass spectrometry.
Journal of Agriculture and Food Chemistry, 2007, 55 (13), 4973–4979.
Anna YK, Jung HP, Sergey AE, Sung JK and Duck HC. Fluorescence polarization
immunoassay based on a monoclonal antibody for the detection of the
organophosphorus pesticide parathion-methyl. Journal of Agriculture and
Food Chemistry, 2003, 51 (5), 1107–1114.
Anna G, Andrzej P, Andrzej B, Tomasz B and Jan ś. Oxytetracycline residues in
honey analyzed by liquid chromatography with UV detection. Journal of
Apicultural Science, 2013, 57 (1), 25-31.
Anonyme, FQPA’s impact on agriculture. American Vegetable Grower, May,
1998, First edition, 43-58.
Anne PV, Brian B, Anna R, Ecevit Y, Thomas EH, Peter EK, Sherry TG and
Jeffrey NM. Analysis of permethrin isomers in composite diet samples by
molecularly imprinted solid-phase extraction and isotope dilution gas
chromatography-ion trap mass spectrometry. Journal of Chromatography
A, 2009, 1216 (22), 4633-4640.
Anakalo S, and Gathoni K. Laboratory evaluation of the improved tube test
detection limits for β-lactam residues in Kenyan milk. African Journal of
Biotechnology, 2004, Vol. 3 (1), 82-87.
Anna G, Andrzej P, Jan Z, Malgorzata G and Tomasz B. Determination of
(fluoro)quinolones in eggs by liquid chromatography with fluorescence
detection and confirmation by liquid chromatography-tandem mass
spectrometry. Food Chemistry, 2012, 135 (2), 430-439.
162
Anne CH, Caroline C, Sheryl AT, Gurmit S, Samuel B and Philippe D.
Simultaneous determination of (fluoro)quinolone antibiotics in kidney,
marine products, eggs, and muscle by enzyme-linked immunosorbent
assay (ELISA). Journal of Agriculture and Food Chemistry, 2006, 54 (8),
2822–2827.
Anping D, Markus H, Qing-Zhi Z, Siegfried F, Manfred S, Wolfgang B, Reinhard
N and Dietmar K. Residue analysis of the pharmaceutical diclofenac in
different water types using ELISA and GC−MS. Environmental Science
and Technology, 2003, 37 (15), 3422–3429.
Anumantha G, Kanthasamy RJ, Yun BN and Daniel D. Truong effect of riluzole
on the neurological an neuro pathological changes in an animal model of
cardiac arrest-induced movement disorder. Journal of Pharmacology,
1999, 288 (3), 1340-1348.
Arayne1 MS, Najma S and Fida H. Validated RP-HPLC method for determination
of permethrin in bulk and topical preparations using UV–VIS detector.
Journal of Chromatographic Science, 2011, 49 (4), 287-291.
Argauer RJ and Moats WA. Degradation of oxytetracycline in honey as measured
by fluorescence and liquid chromatographic assays. Apidologie, 1991, 22
(2), 109 – 115.
Barbara KN, Jeffrey AH and Walter H. LC/MS/MS analysis of chloramphenicol
in shrimp, FDA/ORA/DFS No. 4290, 2002 Pages 1-18.
Bard AJ and Faulkner LR. Electrochemical methods, Fundamentals and
applications. New York, John Wiley & Sons, 2nd Ed, 2000, 63-72.
Barkat AK, Ahmad Z, Sher AK and Zahoor UD. Monitoring pesticide residues in
fruits and vegetables grown in Khyber Pakhtoonkhwa. International
Journal of Green and Herbal Chemistry, 2012, 1 (3), 302-313.
Barry S, Russman Susan T, Iannaccone Frederick J and Samaha A. Phase 1 Trial
of riluzole in spinal muscular atrophy. Arch Neurology, 2003, 60 (11),
1601-1603.
Bassil KL, Vakil C, Sanborn M, Cole DC, Kaur JS and Kerr KJ. Cancer health
effects of pesticides: systematic review. Canadian Family Physician,
2007, 53 (10), 1704-11.
Baxter RM, Ganoza MC, Zahid N and Chung DG. Reconstruction of
peptidyltransferase activity on 50S and 70S ribosomal particles by peptide
163
fragments of protein L16. European Journal of Biochemistry, 1987,
163(3), 473-479.
Baybutt RC, Hu L and Molteni A. Vitamin A deficiency injures lung and liver
parenchyma and impairs function of rat type II pneumocytes. Journal of
Nutrition, 2000, 130 (5), 1159-65.
Bin H, Yun Y, Lei L, Hai D, Lin W, Ting Y, Jia-jin Z, Xiao-dong Z and Yan-
zhen Z. Preparation of high-affinity rabbit monoclonal antibodies for
ciprofloxacin and development of an indirect competitive ELISA for
residues in milk. Journal of Zheijang University Science B, 2010, 11 (10),
812–818.
Biswas AK, Rao GS, Kondaiah N, Anjaneyulu ASR and Malik JK. Simple
multiresidue method for monitoring of trimethoprim and sulfonamide
residues in buffalo meat by High-Performance Liquid Chromatography,
Journal of Agricultural and Food Chemistry, 2007, 55 (22), 8845-8850.
Blasco C and Picó Y. Development of an improved method for trace analysis of
quinolones in eggs of laying hens and wildlife species using molecularly
imprinted polymers. Journal of Agriculture and Food Chemistry, 2012, 60
(44), 11005-11014.
Blaschke M, Gremmels D, Everts I, Weigand E, Heinemann SF, Hollmann
M and Keller BU. Pharmacological differentiation between neuronal
and recombinant glutamate receptor channels expressed in Xenopus
oocytes. Neuropharmacology, 1997, 36 (11-12), 1489-1501.
Boelee E, (Ed) Ecosystems for water and food security, IWMI, UNEP, 2011, 1-
194.
Bonta V, Mărghitaş LA, Dezmirean D, Moise A, Bobiş O and Maghear O.
Optimization of HPLC method for quantifying tetracycline residue in
honey. Bulletin of University of Agricultural Sciences and Veterinary
Medicine, 2007, 63/64, 186-190.
Botoglou NA and Fletouris DJ. Anti-Bacterial drugs: Drug residues in foods,
Marcel Dekker, New York, 2001, 85–87.
Boison JO and Keng LJ. Determination of sulfadimethoxine and sulfamethazine
residues in animal tissues by liquid chromatography and thermospray mass
spectrometry. Journal of AOAC International, 1995, 78(3), 651-658.
164
Borràs S, Ríos-Kristjánsson JG, Companyó R and Prat MD. Analysis of
fluoroquinolones in animal feeds by liquid chromatography with
fluorescence detection. Journal of Separation Science, 2012, 35 (16),
2048-2053.
Boppana VK and Swanson BN. Determination of norfloxacin, a new nalidixic
acid analog, in human serum and urine by high-performance liquid
chromatography. Antimicrobial Agents and Chemotherapy, 1982, 21 (5),
808-810.
Bourquea CL, Duguaya MM and Gautreaua ZM. The determination of reducible
pesticides by adsorptive stripping voltammetry. International Journal of
Environmental Analytical Chemistry, 1989, 37 (3), 187-197.
Bouwman H, Sereda B and Meinhardt HM. Simultaneous presence of DDT
and pyrethroid residues in human breast milk from a malaria-endemic area
in south Africa. Environmental Pollution, 2006, 144 (3), 902–917.
Brisa MFM, Angelica EP, Silvia GJ, Alonso ALZ, Haydé HGC and María del
CBA. Accumulation and elimination of enrofloxacin and ciprofloxacin in
tissues of shrimp Litopenaeus vannamei under laboratory and farm
conditions. ISRN Pharmaceutics, 2012, 2012, article ID 374212, 1-6.
Brunton SA, Slama TG, Amin A, File TM Jr, Milkovich G, Rodvold KA, Sahm
DF, Varon J and Weiland D Jr. Council for appropriate and rational
antibiotic therapy (CARAT), A clinician's guide to the appropriate and
accurate use of antibiotics: the council for appropriate and rational
antibiotic therapy (CARAT) criteria. American Journal of Medicine, 2005,
118 (Suppl, 7A), 1S-6S.
Buzby JC and Skees JR. Consumers want reduced exposure to pesticides on food.
Food review, the magazine of food economics. 1994, 19-22. U.S.D.A.,
Economic research service.
Cabrera HAP, Menezes HC, Oliveira JV and Batista RFS. Evaluation of residual
levels of benomyl, methyl parathion, diuron, and vamidothion in pineapple
pulp and bagasse (Smooth Cayenne). Journal of Agricultural and Food
Chemistry, 2000, 48 (11), 5750–5753.
Carrasco PA, Casado TS, Segura CA and Fernández GA. Reversed-phase high-
performance liquid chromatography coupled to ultraviolet and electrospray
time-of-flight mass spectrometry on-line detection for the separation of
165
eight tetracyclines in honey samples. Journal of Chromatography A, 2008,
1195 (1-2), 107-116.
Carol A, Gonzalez and Karyn M. Usher, Determination of sulfonamides in milk
using solid-phase extraction and liquid chromatography-tandem mass
Spectrometry. http://www.chem.agilent.com/Library/applications/5990-
3713EN.pdf
Carla B, The detection of C4 sugars in honey. Canadian Honey Council, 1999,
12 (1), 37-40.
Caroline D, Joëlle W, Edwin de P, Guy MR and Marie LS. Determination of
chloramphenicol in honey, shrimp, and poultry meat with liquid
chromatography–mass spectrometry: Validation of the method according
to commission decision 2002/657/EC. Food Analytical Methods, 2013, in
press Doi: 10.1007/s12161-013-9596-6.
Casado TS, Segura CA, Busi S, Dinelli G and Fernández GA. Determination of
tetracycline residues in honey by CZE with ultraviolet absorbance
detection. Electrophoresis, 2007, 28(16), 2882-2887.
Cerkvenik FV. Performance characteristics of an analytical procedure for
determining chloramphenicol residues in muscle tissue by gas
chromatography-electron capture detection. Biomedical Chromatography,
2006, 20 (10), 985-992.
Cetinkayaa F, Yibara A, Soyutemiza GE, Okutanb B, Ozcanc A and Karacac MY.
Determination of tetracycline residues in chicken meat by liquid
chromatography-tandem mass spectrometry, Food Additives and
Contaminants: Part B: : Surveillance, 2012, 1–5.
Charaka Samhitam, Hand book on Ayurveda, volume I, edited by Gabriel van
Loon.(1), 559-564.
Chiara C, Roberta C, Antonio DC, Manuela N and Roberto S. A simple and
sensitive Liquid Chromatography−Mass Spectrometry confirmatory
method for analyzing sulfonamide antibacterials in milk and egg. Journal
of Agricultural and Food Chemistry, 2003, 51 (3), 558–566.
Chen CL and Gu X. Determination of tetracycline residues in bovine milk, serum,
and urine by capillary electrophoresis. Journal of AOAC International,
1995, 78(6), 1369-1377.
166
Chen H, O'Reilly E, McCullough ML, Rodriguez C, Schwarzschild MA, Calle
EE, Thun MJ and Ascherio A. Consumption of dairy products and risk of
parkinson's disease. American Journal of Epidemiology, 2007, 165 (9),
998–1006.
Chen G and Schneider MJ. A rapid spectrofluorometric screening method for
enrofloxacin in chicken muscle. Journal of Agricultural and Food
Chemistry, 2003, 51(11), 3249-3253.
Chen G and Li Q. Luminescence screening of enrofloxacin and ciprofloxacin
residues in swine liver after dispersive liquid-liquid microextraction
cleanup, Journal of Agricultural and Food Chemistry, 2013, 61(1), 98-
102.
Chen TB, Deng WH, Lu WH, Chen RM and Rao PF. Detection of residual
antibiotics in honey with capillary electrophoresis. Se Pu (Chinese Journal
of Chromatography), 2001, 19 (1), 91-93.
Choma I, Grenda D, Malinowska I and Suprynowciz Z. Determination of
flumequine and doxycycline in milk by a simple thin-layer
chromatographic method. Journal of Chromatography B: Biomedical
Sciences and Applications, 1999, 734 (1), 7-14.
Chonan T, Fujimoto T, Inoue M, Tazawa T and Ogawa H. Multiresidue
determination of quinolones in animal and fishery products by HPLC.
Shokuhin Eiseigaku Zasshi, 2008, 49 (3), 244-248.
Cháfer-Pericás C, Maquieira A, Puchades R, Miralles J, Moreno A, Pastor-
Navarro N and Espinós F. Immunochemical determination of
oxytetracycline in fish: comparison between enzymatic and time-resolved
fluorometric assays. Analytica Chimica Acta, 2010, 662 (2), 177-185.
Christine MK, Lori EC, Sherri BT, Wendy CA and Keith EM. Determination of
quinolone residues in shrimp using liquid chromatography with
fluorescence detection and residue confirmation by mass spectrometry.
Analytica Chimica Acta, 2007, 596 (2), 257-263.
Christodoulou EA and Samanidou VF. Multiresidue HPLC analysis of ten
quinolones in milk after solid phase extraction: Validation according to the
European Union Decision 2002/657/EC. Journal of Separation Science,
2007, 30 (15), 2421–2429.
167
Chui SC, Wei HW and Chin ET. Simultaneous determination of 18 quinolone
residues in marine and livestock products by liquid chromatography/
tandem mass spectrometry. Journal of Food and Drug Analysis, 2010, 18
(2), 87-97.
Cinquina AL, Longo F, Anastasi G, Giannetti L and Cozzani R. Validation of a
high-performance liquid chromatography method for the determination of
oxytetracycline, tetracycline, chlortetracycline and doxycycline in bovine
milk and muscle. Journal of Chromatography A, 2003, 987(1-2), 227-233.
Cinquina AL, Roberti P, Giannetti L, Longo F, Draisci R, Fagiolo A and Brizioli
NR. Determination of enrofloxacin and its metabolite ciprofloxacin in goat
milk by high-performance liquid chromatography with diode-array
detection: Optimization and validation. Journal of Chromatography A,
2003, 987(1-2), 221-226.
Clark SB, Turnipseed SB, Madson MR, Hurlbut JA, Kuck LR and Sofos JN.
Confirmation of sulfamethazine, sulfathiazole, and sulfadimethoxine
residues in condensed milk and soft-cheese products by liquid
chromatography/tandem mass spectrometry. Journal of AOAC
International, 2005, 88 (3), 736-743.
Članjak E, Smajlović1 M, Čaklovica1 F, Alagić D, Čaklovica1 K and
Smajlović A. Detection of enrofloxacin residues in chicken meat by
microbiological (growth inhibition test) and ELISA method after
experimental prophylactic and therapeutic application. Svibanj - Lipanj |
Broj, 2011, XIII (3), 198-205.
Clemente M, Hermo MP, Barrón D and Barbosa J. Confirmatory and quantitative
analysis using experimental design for the extraction and liquid
chromatography–UV, liquid chromatography–mass spectrometry and
liquid chromatography–mass spectrometry/mass spectrometry
determination of quinolones in turkey muscle. Journal of Chromatography
A, 2006, 1135 (2), 170–178.
Crawford GW and Gyoung-Ah L. Agricultural origins in the korean peninsula.
Antiquity, 2003, 77 (295), 87-95.
Colin ME, Bonmatin JM and Moineau I. A method to quantify and analyze the
foraging activity of honey bees, relevance to the sublethal effects induced
168
by systemic insecticides. Archives of Environmental Contamination and
Toxicology, 2004, 47 ( 3), 387–395.
Cozma A, Bota S, Caraban A, Toderas M, Domuta C and Borza I. The study for
determination chlorpyrifos residual from fruit samples. Analele
Universitatii din Oradea, Fascicula Protectia Mediului, 2011, XVII, 635-
640.
Cutting JH, Kiessling WM, Bond FL, McCarron JE, Kreuzer KS, Hurlbut JA and
Sofos JN. Agarose gel electrophoretic detection of six beta-lactam
antibiotic residues in milk. Journal of AOAC International, 1995, 78(3),
663-667.
Dai Q, Borenstein AR, Wu Y, Jackson JC and Larson EB. Fruit and vegetable
juices and alzheimer's disease, the Kame Project. American Journal of
Medicine, 2006, 119 (9), 751-579.
Dang PK, Degand G, Danyi S, Pierret G, Delahaut P, Ton VD, Maghuin RG and
Scippo ML. Validation of a two-plate microbiological method for
screening antibiotic residues in shrimp tissue. Analytica Chimica Acta,
2010, 672(1-2), 30-39.
Data NK, Annadurai S, Mazumdar K, Dastidar SG, Kristiansen JE, Molnar J,
Martins M and Amaral L. Potential management of resistant microbial
infections with a novel non-antibiotic, the anti-inflammatory drug
diclofenac sodium. International Journal of Antimicrobial Agents, 2007,
30 (3), 242–249.
Dasenbrock CO and LaCourse WR. Assay for cephapirin and ampicillin in raw
milk by high-performance liquid chromatography--integrated pulsed
amperometric detection. Analytical chemistry, 1998, 70 (11), 2415-2420.
Davarani SS, Pourahadi A, Nojavan S, Banitaba MH and Nasiri-Aghdam M.
Electro membrane extraction of sodium diclofenac as an acidic compound
from wastewater, urine, bovine milk, and plasma samples and
quantification by high-performance liquid chromatography. Analytica
Chimica Acta, 2012, 722 (13 April), 55-62.
David P, Acquay H, Biltonen M, Rice R and Silva M. Environmental and
economic costs of pesticide use. BioScience, 1992, 42 (10), 750-60.
Davidson A, Tom J, Jane D and Helen S. The oxford companion to food. Oxford.
Oxford university Press, 2006, 387-388.
169
Davis CD. Low dietary copper increases fecal free radical production, fecal
water alkaline phosphatase activity and cytotoxicity in healthy men.
Journal of Nutrition, 2003, 133 (2), 522-527.
Deborah C, Lorraine L, Kennedya DG and McCaugheya WJ. Evaluation of a
modified EC four plate method to detect antimicrobial drugs. Food
Additives and Contaminants, 1998, 15 (6), 651-660.
Denise ZB and Igor V. HPLC Determination of flumethrin, deltamethrin,
cypermethrin, and cyhalothrin residues in the milk and blood of lactating
dairy cows. Journal of Analytical Toxicology, 1997, 21 (5), 397-402.
Denobile, M and Elizabeth de Souza N. Method validation for the determination
of the antibiotics residues oxytetracycline, tetracycline, chlortetracycline
and doxycycline in milk by high performance liquid chromatography.
Revista Brasileira de Ciências Farmacêuticas, 2004, 40 (2), 209-218.
De Ruyck H and De Ridder H. Determination of tetracycline antibiotics in cow's
milk by liquid chromatography/tandem mass spectrometry. Rapid
Communications in Mass Spectrometry, 2007, 21(9), 1511-1120.
Devendra K, Sharma RC and Pratibha C. Estimation of multiclass pesticide
residues in tomato (lycopersicon esculentum) and radish (raphanus
sativus) vegetables by chromatographic methods. Research Journal of
Agricultural Sciences, 2011, 2 (1), 40-43.
De Wasch K, Okerman L, Croubels S, De Brabander H, Van Hoof J and De
Backer P. Detection of residues of tetracycline antibiotics in pork and
chicken meat: correlation between results of screening and confirmatory
tests. Analyst, 1998, 123(12), 2737-2741.
Dhundhe RS and Rai MK. A newly sensitive method for the determination of
cypermethrin in various samples. Asian Journal of Biochemical and
Pharmaceutical Research, 2011, 1 (3), 381-390.
Diserens JM and Savoy MC. Nestlé research center, personal communication,
2000.
Dowling G, Gallo P, Fabbrocino S, Serpe L and Regan L. Determination of
ibuprofen, ketoprofen, diclofenac and phenylbutazone in bovine milk by
gas chromatography-tandem mass spectrometry. Food Additives
Contaminants. Part A, Chemistry, Analysis, Control, Exposure Risk
Assessment, 2008, 25 (12), 1497-508.
170
Dowling G, Gallo P, Malone E and Regan L. Rapid confirmatory analysis of non-
steroidal anti-inflammatory drugs in bovine milk by rapid resolution liquid
chromatography tandem mass spectrometry. Journal of Chromatography
A, 2009, 1216 (46), 8117-8131.
Dreier JP and Endres M. Statin-associated rhabdomyolysis triggered by
grapefruit consumption. Neurology, 2004 , 62 (4), 670-674.
Drlica K and Zhao X. DNA gyrase, topoisomerase IV, and the 4-quinolones.
Microbiology and Molecular Biology Reviews, 1997, 61 (3), 377-392.
Dubreil-Chéneau E, Pirotais Y, Bessiral M, Roudaut B and Verdon E.
Development and validation of a confirmatory method for the
determination of 12 non steroidal anti-inflammatory drugs in milk using
liquid chromatography-tandem mass spectrometry. Journal of
Chromatography A, 2011, 1218 (37), 6292-6301.
Dufresne G, Fouquet A, Forsyth D and Tittlemier SA. Multiresidue determination
of quinolone and fluoroquinolone antibiotics in fish and shrimp by liquid
chromatography/tandem mass spectrometry. Journal of AOAC
International, 2007, 90 (2), 604-612.
Du WX, Marshall MR, Wheeler WB, Mathews M, Gatlin D, Rawles SD, Xu DH,
Rodgers WA and Wei CI. Oxytetracycline, sulfadimethoxine, and
ormetoprim residues in channel catfish by HPLC. Journal of Food
Science, 1995, 60 (6), 1220–1224.
Dumonta V, Hueta AC, Traynor I, Elliott C and Delahaut P. A surface plasmon
resonance biosensor assay for the simultaneous determination of
thiamphenicol, florefenicol, florefenicol amine and chloramphenicol
residues in shrimps. Analytica Chimica Acta, 2006, 567 (2), 179–183.
Durden DA and Fernandes G. Quantitation of fluoroquinolones in honey using
tandem mass spectrometry (LC-MS/MS): nested validation with two mass
spectrometers. Journal of AOAC International, 2010, 93 (5), 1633-1655.
Durden DA and MacPherson T. Quantitation and validation of fluoroquinolones
in eggs using liquid chromatography/tandem mass spectrometry. Journal
of AOAC International, 90 (2), 613-625.
Edder P, Cominoli A and Corvi C. Determination of streptomycin residues in
food by solid- phase extraction and liquid chromatography with post-
171
column derivatization and fluorometric detection. Journal of
Chromatography A, 1999, 830 (2), 345-351.
Eliseo P, Francisca S, Uma Y and Peter K. Febuxostat. Nature reviews drug
discovery, 2009, 8, 191-192.
Elizabeth R, De Oliveira S, Cynthia E, Seidman, Jason J, Tian, Lisa C, Hudgins
FM, Sacks and Jan LB. Effects of shrimp consumption on plasma
lipoproteins. American Journal of Clinical Nutrition, 1996, 64 (5), 712–
717.
Emmerson AM and Jones AM. "The quinolones: Decades of development and
use" . The Journal of Antimicrobial Chemotherapy, 2003, 51 (Suppl 1),
13–20.
Ensminge AH and Esminger MK. Food for health, A nutrition encyclopedia,
clovis, california, pegus press, 1986.
Eric V, Pierrick C, Brigitte R and Pascal S. Multiresidue method for simultaneous
determination of ten quinolone antibacterial residues in
multimatrix/multispecies animal tissues by liquid chromatography with
fluorescence detection: single laboratory validation study. Journal of
AOAC International, 2005, 88 (4), 1179-1192.
El-Shorbagy, MM, Maha MM and Noha MES. Some bacteriological and chemical
attributes of milk and milk products. Egyptian Journal of
comparative Pathology and Clinical Pathology, 2009, 22 (2), 138 – 154.
European Union-MRLs, Regulation (EC) No 396/2005, MRLs updated on
06/06/2013. A database of EU MRLs and pesticide authorisation status
(Dir 91/414/EEC).
Evanthia PT, Victoria FS and Ioannis NP. Development and validation of an
HPLC method for the determination of ten sulfonamide residues in milk
according to 2002/657/EC. Journal of Separation Science, 2011, 34 (14),
1627-1635.
Evaggelopoulou EN and Samanidou VF. HPLC confirmatory method
development for the determination of seven quinolones in salmon tissue
(Salmo salar L.) validated according to the European Union Decision
2002/657/EC. Food Chemistry, 2013, 136 (2), 479-484.
Evangelos G, Pigi K, Despina T and Anthony T. Development of a rapid and
sensitive SPE-LC-ESI MS/MS method for the determination of
172
chloramphenicol in seafood. Journal of Agriculture and Food Chemistry,
2004, 52 (5), 1025–1030.
Evershed RP, Payne S, Sherratt AG, Copley MS, Coolidge J, Urem-Kotsu D,
Kotsakis K and Ozdoğan M. Earliest date for milk use in the near east and
southeastern europe linked to cattle herding. Nature, 2008, 455 (7212),
528–531.
Faridah S, Hazana R, Gayah AR, Norzaili Z, Azima A, Nur Azura MS and Zamri
I. Electrochemical sensors for detection of tetracycline antibiotics.
Malaysian Society of Animal Production, 2012, 15 (1), 67-80.
Fernández M, Picó Y, Girotti S and Mañes J. Analysis of organophosphorus
pesticides in honeybee by liquid chromatography−atmospheric pressure
chemical ionization−mass spectrometry. Journal of Agriculture and Food
Chemistry, 2001, 49 (8), 3540–3547.
FAO, Responsible uses of Antibiotics in Aquaculture – 469. Food and Agriculture
Organization of the United Nations, Rome, 2005.
Faqir M, Ijaz J, Masood A, Zia-ur-Rahman, Mian MA, Muhammad KS and
Muhammad IA. Quantitative structure activity relationship and risk
analysis of some pesticides in the cattle milk. Pakistan Veterinary Journal,
2012, 32(4), 589-592.
Finotti E, Bertone A and Vivanti V. Balance between nutrients and anti-
nutrients in nine italian potato cultivars. Food Chemistry, 2006, 99 (4),
698-702.
Fitzgerald GA and Patrono C. The coxibs, selective inhibitors of cyclooxygenase-
2. The New England Journal of Medicine, 2001, 345(6), 433-442.
Flemming HF. Analysis of residues of seven pesticides in some fruits and
vegetables by means of high pressure liquid chromatography. Zeitschrift
für Lebensmittel-Untersuchung und Forschung, 1981, 173 (2), 95-98.
Francisco JL, Ana MGC, Fermín AB, Juan MBS and Luis EGA. Multiresidue
method for the determination of quinolone antibiotics in bovine raw milk
by capillary electrophoresis-tandem mass spectrometry. Analytical
Chemistry, 2006, 78 (22), 7665-7673.
Food safety and standards act, 2006 ,no. 34 of 2006, ministry of law and justice
(Legislative Department) New Delhi, 24th August, 2006/Bhadra2, 1928
Saka)
173
Food safety and standards (food products standards and food additives)
regulations, 2011, Regulations, Chapter-1, 227-448.
Forti AF and Scortichini G. Determination of ten sulphonamides in egg by liquid
chromatography-tandem mass spectrometry. Analytica Chimica Acta,
2009, 637 (1-2), 214-219.
Fuh MR and Chan SA. Quantitative determination of sulfonamide in meat by
liquid chromatography-electrospray-mass spectrometry. Talanta, 2001,
55(6), 1127-1139.
Funian Z, Xuezhu Z and Yiru G. Determination of tetracyclines in bovine milk by
high-performance liquid chromatography with a coulometric electrode
array system. Journal of Chromatography A, 2004, 1055 (1–2), 109–114.
Furusawa N. Simplified determining procedure for routine residue monitoring of
sulphamethazine and sulphadimethoxine in milk. Journal of
Chromatography A, 2000, 898 (2), 185-191.
Furusawa N. Determination of sulfonamide residues in eggs by liquid
chromatography. Journal of AOAC International, 2002, 85(4), 848-852.
Fytianos K, Drimaropoulou G, Raikos N, Theodoridis G and Tsoukali H.
Headspace solid-phase microextraction for the gas chromatographic
analysis of organophosphorus insecticides in vegetables. Journal of AOAC
International, 2007, 90 (6), 1677-1681.
Fytianos K, Raikos N, Theodoridis G, Velinova Z and Tsoukali H. Solid phase
microextraction applied to the analysis of organophosphorus insecticides
in fruits. Chemosphere, 2006, 65 (11), 2090-2095.
Gabaldón JA and Maquieira A. Development of a simple extraction procedure
for chlorpyrifos determination in food samples by immunoassay. Talanta,
2007, 71 (3), 1001-1010.
Gabriel VL. Charaka samhitam, Hand book on Ayurveda, Volume I, 2003.
Gale JC, Richard RG and Jewell WS. Comparison of ultraviolet and reductive
amperometric detection for the determination of ethyl and methyl
parathion in green vegetables and surface water using high-performance
liquid chromatography. Analytical Chemistry, 1985, 57 (12), 2223–2228.
Galeano DT, Guiberteau CA and Salinas F. Rapid determination of sulfathiazole,
oxytetracycline and tetracycline in honey by high-performance liquid
chromatography. Analytical Letters, 1990, 23 (4), 607-616.
174
Galera MM, García MDG and Valverde RS. Determination of nine pyrethroid
insecticides by high-performance liquid chromatography with post-column
photoderivatization and detection based on acetonitrile
chemiluminescence. Journal of Chromatography A, 2006, 1113 (1-2),
191-197.
Gajda A, Posyniak A, Zmudzki J and Tomczyk G. Determination of doxycycline
in chicken fat by liquid chromatography with UV detection and liquid
chromatography-tandem mass spectrometry. Journal of Chromatography
B, 2013, 928 (1 June), 113–120.
Ganter M, Dudziak D and Delbeck F. Treatment of swine with chronic pneumonia
with chlortetracycline-medicated feed. Deutsche Tierarztliche
Wochenschrift, 1995, 102 (1), 44-49.
Gao K, Henning SM, Niu Y, Youssefian AA, Seeram NP, Xu A and Heber D.
The citrus flavonoid naringenin stimulates DNA repair in prostate cancer
cells. The Journal of Nutritional Biochemistry , 2006, 17 (2), 89-95.
Gaudin V, De Courville A, Hedou C, Rault A, Diomandé SE, Creff-Froger C and
Verdon E. Evaluation and validation of two microbiological tests for
screening antibiotic residues in honey according to the European guideline
for the validation of screening methods. Food Additives & Contaminants.
Part A, Chemistry, Analysis, Control, Exposure & Risk Assessment, 2013,
30 (2), 234-243.
Gentili A, Perret D, Marchese S, Sergi M, Ormi C and Curini R. Accelerated
solvent extraction and confirmatory analysis of sulfonamide residues in
raw meat and infant foods by liquid chromatography electro spray tandem
mass spectrometry. Journal of Agricultural and Food Chemistry, 2004, 52
(15), 4614–4624.
Georg Z, Michael P, Erika MS and Eike S. Metabolites of oxytetracycline,
tetracycline, and chlortetracycline and their distribution in egg white, egg
yolk, and hen plasma. Journal of Agriculture and Food Chemistry, 2000,
48 (12), 6392–6396.
George W, Paul DD and Leonard G. HPLC method for the simultaneous analysis
of sulfadimethoxine and ormetoprim in tissues and blood of cattle,
chickens, and catfish. Journal of Agriculture and Food Chemistry, 1987,
35 (6), 905–909.
175
Geoffrey CW, Sarah A and Cooper G. Hyperuricemia new guidelines and
treatments, Journal of Pharmacy Practice, 2009, 22 (1), 104-115.
Gheldof N, Wang X and Engeseth N. Identification and quantification of
antioxidant components of honeys from various floral sources. Journal of
Agricultural and Food Chemistry, 2002, 50 (21), 5870–5877.
Ghidini S, Zanardi E, Varisco G and Chizzolini R. Residues of beta-lactam
antibiotics in bovine milk: confirmatory analysis by liquid chromatography
tandem mass spectrometry after microbial assay screening. Food
Additives and Contaminants, 2003, 20(6), 528-534.
Gil GMD, Belmonte GA, Valverde RS and Martínez GM. Determination of
(fluoro)quinolones in environmental water using online preconcentration
with column switching linked to large sample volumes and fluorescence
detection. Journal of Separation Science, 2012, 35 (7), 823-831.
Gilden RC, Huffling K and Sattler B. Pesticides and health risks. Journal of
Obstetric, Gynecologic and Neonatal Nursing, 2010, 39(1), 103-110.
Gina L and Barnes A. Paddy soils now and then, world. Archaeology, 1990, 22
(1), 1-17.
Glen AG, Andrew AP and Lorne AB. Clinical and pathological evaluation of
sulbactam/ampicillin for treatment of experimental bovine pneumonic
pasteurellosis. The Canadian Veterinary Journal, 1988, 29(2), 142–148.
Goda K, Tsia K and Jalali B. Serial time-encoded amplified imaging for real-time
observation of fast dynamic phenomena. Nature, 2009, 458 (7242), 1145–
1149.
Gorinstein S, Caspi A, Libman I, Lerner HT, Huang D, Leontowicz H,
Leontowicz M, Tashma Z, Katrich E, Feng S and Trakhtenberg S. Red
grapefruit positively influences serum triglyceride level in patients
suffering from coronary atherosclerosis: studies in vitro and in humans.
Journal of Agricultural and Food Chemistry, 2006 , 854 (5), 1887-1892.
Guomin S, Whitney RL, Donald WS, Shirley JG, Daniel PYC and Bruce DH.
Enzyme-linked immunosorbent assay for the pyrethroid permethrin.
Journal of Agriculture and Food Chemistry, 2000, 48 (9), 4032 - 4040.
Griffin MO, Fricovsky E, Ceballos G and Villarreal F. Tetracyclines: a pleitropic
family of compounds with promising therapeutic properties. Review of the
176
literature. American Journal of Physiology - Cell Physiology, 2010, 299
(3), C539-548.
Gruda N. Impact of environmental factors on product quality of greenhouse
vegetables for fresh consumption. Critical Reviews in Plant Sciences,
2005, 24 (3), 227–247.
Guangming H, Jin O, Willy RGB, Yiping Y and Chuanjiang T. High-performance
liquid chromatographic assay of dichlorvos, isocarbophos and methyl
parathion from plant leaves using chemiluminescence detection. Analytica
Chimica Acta, 2002, Volume 474 (1–2), 21–29.
Guixiang Y, Baoyin L, Zhenling Z, Zhangliu C and Xianhui H. Multiresidue
determination of eleven quinolones in milk by liquid chromatography with
fluorescence detection. Journal of AOAC International, 2005, 88 (6),
1688-1692.
Gunes ME, Gunes N and Cibik R. Oxytetracycline and sulphonamide residues
analysis of honey samples from southern marmara region in turkey.
Bulgarian Journal of Agricultural Science, 2009, 15 (2), 163-167.
Guo L, Chen Y, Zhang L, Yang W and He P. Development and validation of a
liquid chromatographic/ tandem mass spectrometric method for
determination of chlortetracycline, oxytetracycline, tetracycline, and
doxycycline in animal feeds. Journal of AOAC International, 2012,
95(4), 1010-1015.
Guzel M, Karakurum MC, Durgut R and Mamak N. Clinical efficacy of
diclofenac sodium and flunixin meglumine as adjuncts to antibacterial
treatment of respiratory disease of calves. Australian Veterinary Journal,
2010, 88(6), 236-239.
Hahn-Obercyger M, Stark AH and Madar Z. Grapefruit and oroblanco enhance
hepatic detoxification enzymes in rats, possible role in protection against
chemical carcinogenesis. Journal of Agricultural and Food Chemistry,
2005, 53 (5), 1828-1832.
Hai YZ, Dong HC, Yi Z and Hong TH. Analysis of tetracyclines (TCs) residues in
honey with HPLC – UV. Advanced Materials Research, 2010, 159, 89-94.
Hakuta T, Shinzawa H and Ozaki Y. Practical method for the detection of
tetracyclines in honey by HPLC and derivative UV-Vis spectra. Analytical
Science, 2009, 25 (9), 1149-1153.
177
Hanwen S, Lixin W, Xiaolan Q and Xusheng G. Simultaneous determination of
malachite green, enrofloxacin and ciprofloxacin in fish farming water and
fish feed by liquid chromatography with solid-phase extraction.
Environmental Monitoring and Assessment, 2011, 179 (1-4), 421-429.
Hao YS and Hai LJ. Screening, determination and confirmation of
chloramphenicol in seafood, meat and honey using ELISA, HPLC–UVD,
GC–ECD, GC–MS–EI–SIM and GCMS–NCI–SIM methods. Analytica
Chimica Acta, 2005, 535 (1–2), 33–41.
Hatano K. Simultaneous determination of quinolones in foods by LC/MS/MS.
Journal of the Food Hygienic Society of Japan, 2004, 45(5), 239-244.
Hermo MP, Nemutlu E, Kir S, Barrón D and Barbosa J. Improved determination
of quinolones in milk at their MRL levels using LC-UV, LC-FD, LC-MS
and LC-MS/MS and validation in line with regulation 2002/657/EC.
Analytica Chimica Acta, 2008, 613(1), 98-107.
Hernández-Jover T, Izquierdo P, Veciana-Nogués MT, Mariné-Font A and
Vidal-Carou MC. Ion-pair high-performance liquid chromatographic
determination of biogenic amines in meat and meat products. Journal of
Agricultural and Food Chemistry, 1996, 44 (9), 2710-2715.
Herrera HAV, Hernández BJ, Borges MTM and Rodríguez DMÁ. Dispersive
liquid-liquid microextraction combined with nonaqueous capillary
electrophoresis for the determination of fluoroquinolone antibiotics in
waters. Electrophoresis, 2010, 31 (20), 3457-3465.
Hernandez M. Determination of ciprofloxacin, enrofloxacin and flumequine in pig
plasma samples by capillary isotachophoresis-capillary zone
electrophoresis. Journal of Chromatography B, 2002, 772(1), 163-172.
Helio AMJ, Tereza AK, Alexandre YW and Daniel TL. A rapid method to
determine antibiotic residues in milk using liquid chromatography coupled
to electrospray tandem mass spectrometry. Journal of the Brazilian
Chemical Society, 2007, 18 (2), 431-436.
Hellio C, Pons AM, Beaupoil C, Bourgougnon N and Le Gal Y. Antibacterial,
antifungal and cytotoxic activities of extract from fish epidermis and
epidermal mucus. International Journal of Antimicrobial Agents, 2002, 20
(3), 214-219.
178
Hilliard JJ, Krause HM, Bernstein JI, Fernandez JA, Nguyen V, Ohemeng KA and
Barrett JF. A comparison of active site binding of 4-quinolones and novel
flavone gyrase inhibitors to DNA gyrase. Advances in Experimental
Medicine and Biology, 1995, 390 (1), 59-69.
Holt RM, Newman MJ, Pullen FS, Richards DS and Swanson AG. High-
performance liquid chromatography NMR spectrometry/mass
spectrometry, further advances in hyphenated technology. Journal of mass
spectrometry, 1997, 32 (1), 64–70.
Hong D and Shah M. Development and validation of HPLC stability indicating
assay in drugs and the pharmaceutical sciences. Marcel Dekker, 2000, 18
(1), 329–384.
Honikel KO and Hambloch H. Fast fluorimetric assay of chlortetracycline in meat
and bone. Zeitschrift für Lebensmittel-Untersuchung und–Forschung,
1976, 161 (4), 337-346.
Hong YL, Hossler PA, Calhoun DH and Meshnick SR. Inhibition of recombinant
Pneumocystis carinii dihydropteroate synthetase by sulfa drugs.
Antimicrobial Agents and Chemotherapy, 1995, 39 (8), 1756-1763.
Horie M, Saito K, Hoshino Y, Nose N, Mochizuki E and Nakazawa H.
Simultaneous determination of nalidixic acid, oxolinic acid and piromidic
acid in fish by high-performance liquid chromatography with fluorescence
and UV detection. Journal of Chromatography A, 1987, 402, 301-308.
Hoofa NV, De Wasch K, Okerman L, Reybroeck L, Poelmans S, Noppe H and De
Brabander H. Validation of a liquid chromatography–tandem mass
spectrometric method for the quantification of eight quinolones in bovine
muscle, milk and aquacultured products. Analytica Chimica Acta, 2005,
529 (1-2), 265–272.
Hooper DC and, Wolfson JS. Quinolone Antimicrobial Agents, 2nd ed, 1993,
59-75
Hormazabal V and Yndestad M. Rapid assay for monitoring residues of
enrofloxacin in milk and meat tissues by HPLC. Journal of Liquid
Chromatography, 1994, 17(17), 3775-3782.
Horváth CS, Preiss BA and Lipsky SR. Fast liquid chromatography. investigation
of operating parameters and the separation of nucleotides on pellicular ion
exchangers. Analytical Chemistry, 1967, 39 (12), 1422–1428.
179
Huang HN, Chen TB, Chen RM and Rao PF. Detection of residual antibiotics in
honey by capillary high performance liquid chromatography. Se Pu
(Chinese Journal of Chromatography), 1999, 17 (6), 588-589.
Hussein K, Marcinák S, Máté D, Koárová I, Sokol J and Zdolec N. Use of
Premi®test for the detection of sulphonamide residues in chicken. Acta
Veterinaria (Beograd), 2005, 55 (5-6), 493-500.
Hussain Z and Samia S. Determination of pesticides in fruits and vegetables using
acetonitrile extraction and GC/MS Technique. Journal of Scientific
Research, 2010, 40 (2), 19-29.
Hundt HKL and Barlow EC. Thin-layer chromatographic method for the
quantitative analysis of nalidixic acid in human plasma. Journal of
Chromatography B: Biomedical Sciences and Applications, 1981, 223 (1),
165–172.
Hyun T, Barrett-Connor E and Milne D. Zinc intakes and plasma concentrations
in men with osteoporosis, the rancho bernardo study. The American
Journal of Clinical Nutrition, 2004, 80 (3), 715-721.
Hyun HC, Jung BL, Yun HC and Kwang GL. Analysis of sulfonamide and
quinolone antibiotic residues in Korean milk using microbial assays and
high performance liquid chromatography. Food Chemistry, 2009, 113 (1),
297–301.
Ibarra IS, Rodriguez JA, Miranda JM, Vega M and Barrado E. Magnetic solid
phase extraction based on phenyl silica adsorbent for the determination of
tetracyclines in milk samples by capillary electrophoresis. Journal of
Chromatography A, 2011, 1218 (16), 2196-2202.
Ibrahim MS, Shehatta IS and Sultan MR. Cathodic adsorptive stripping
voltammetric determination of nalidixic acid in pharmaceuticals, human
urine and serum. Talanta, 2002, 56 (3), 471-479.
Iffat ATK, Zahida P, Riazuddin and Mubarik A. Multi-residue determination of
organophosphorus pesticides and synthetic pyrethroids in wheat,
International Journal of Agriculture & Biology, 2007, 9 (6), 905-908.
Ikai Y, Oka K, Kawamura N, Yamada M, Harada K, Suzuki M and Nakazawa H.
Improvement of chemical analysis of antibiotics. Simple and rapid
determination of residual pyridonecarboxylic acid antibacterials in fish
180
using a prepacked amino cartridge. Journal of Chromatography, 1989,
477 (2), 397-406.
Imdad UMZ, Khaliqur R, Arshad H and Shafqatullah. Detection and
quantification of antibiotics residues in honey samples by chromatographic
techniques, Middle-East Journal of Scientific Research, 2013, 14 (5),
683-687.
Ionela DP, Elena CS, Simona M and Rodica C. Method validation for
simultaneous determination of 12 sulfonamides in honey using biochip
array technology, Farmacia, 2012, 60 (1), 143-154.
Iqbal MF, Maqbool U, Asi MR and Aslam S. Determination of pesticide residues
in brinjal fruit at supervised trial. Journal of Animal and Plant Sciences,
2007, 17 (1), 21-23.
Ishii R, Horie M, Murayama M and Maitani T. Analysis of tetracyclines in honey
and royal jelly by LC/MS/MS. Shokuhin Eiseigaku Zasshi, 2006, 47 (6).
277-283.
James DT and Carol MA. The law of unintended consequences and antibiotics.
Open Journal of Immunology, 2012, 2 (2), 59-64.
Jandera P. Gradient elution in normal-phase high-performance liquid
chromatographic systems. Journal of Chromatography A, 2002 , 965(1-
2), 239-261.
Janghel EK, Rai JK, Rai MK and Gupta VK. A new sensitive spectrophotometric
determination of cypermethrin insecticide in environmental and biological
samples. Journal of Brazilian Chemical Society, 2007, 18 (3), 590-594.
Jain RK. Fenvalerate (α-cyano-m-phenoxy-benzyl α-isopropyl-p-chlorophenyl
acetate) residues in and on okra fruits. Science of the Total Environment,
1996, 187 (3), 253–255.
Jeffery GH, Bassett J, Mendham J and Benney RC. The text book of quantitative
chemical analysis, 5th edition, 1989, 1-906.
Jin QJ, Hai TZ, Zhi XA, Xiao JZ, Jun JC, Hua GH and Zi LW. Development of an
Indirect competitive enzyme-linked immunosorbent assay for detection of
enrofloxacin residue in chicken. Advanced Materials Research, 2011, 345
(297), 297-303.
Jin JZ, Li GZ, Jin EZ, Guan WC, Bo T, Xiang YL and Li Z. Determination of
cypermethrin residues in gingkgo biloba leaves by high performance liquid
181
chromatography. Bulletin of the Chemical Society of Ethiopia, 2009, 23
(1), 97-100.
Jing FH, Hui JZ and Yu QF. Chloramphenicol extraction from honey, milk, and
eggs using polymer monolith microextraction followed by liquid
chromatography−mass spectrometry determination. Journal of
Agriculture and Food Chemistry, 2006, 54 (25), 9279–9286.
Jing T, Gao XD, Wang P, Wang Y, Lin YF, Hu XZ, Hao QL, Zhou YK and
Mei SR. Determination of trace tetracycline antibiotics in foodstuffs by
liquid chromatography-tandem mass spectrometry coupled with selective
molecular-imprinted solid-phase extraction. Analytical and Bioanalytical
Chemistry, 2009, 393 (8), 2009-2018.
Ji-Lai G, Fu-Chun G, Ying K, Ge-Ming Z, Guo-Li S and Ru-Qin Y. Capacitive
chemical sensor for fenvalerate assay based on electropolymerized
molecularly imprinted polymer as the sensitive layer. Analytical and
Bioanalytical Chemistry, 2004, 379 (2), 302-307.
Joe S, Pfenning A, Sherri T, Gene N, Rebecca L, Cathy B and Mark M.
Determination of chloramphenicol residues in shrimp and crab tissues by
electrospray triple quadrupole LC/MS/MS. Laboratory Information
Bulletin LIB No. 4306, 2003, 19 (6).
Joshua SW, Juan FGR, Jason DH, Nicholas AC, Zheng O and Graham CR.
Screening of agrochemicals in foodstuffs using low-temperature plasma
(LTP) ambient ionization mass spectrometry. Analyst, 2010, 135 (5), 971-
979.
Juan J, Daohong Z, Wen Z, Xiupin W, Ye K, Qi Z and Peiwu L. Preparation,
identification, and preliminary application of monoclonal antibody against
pyrethroid insecticide fenvalerate. Analytical Letters, 2010, 43 (17), 2773-
2789.
Jukes and Thomas H. Some historical notes on chlortetracycline. Reviews of
Infectious Diseases, 1985, 7 (5), 702-707.
Julie S, Andrew ML, Caroline MT, Alasdair PM, John MR and Anne AD.
Determination by HPLC of chlortetracycline in pig faeces. Journal of
Antimicrobial Chemotherapy, 2003, 52 (1), 135–137.
Junxia C, Fei X, Haiyang J, Yali H, Qinxiong R, Pengju G and Shuangyang D. A
novel quantum dot-based fluoroimmunoassay method for detection of
182
enrofloxacin residue in chicken muscle tissue. Food Chemistry, 2009, 113
(4), 1197–1201.
Jurewicz J and Hanke W. Prenatal and childhood exposure to pesticides and
neurobehavioral development, review of epidemiological studies.
International Journal of Occupational and Environmental Health, 2008,
21 (2), 121–132.
Kanda M, Kusano T, Osanai T, Ushiyama K, Takeba K, Sakamoto M, Hayashi H,
Igusa K, Ibe A and Nagayama T. Rapid determination of residues of 4
tetracyclines in meat by a microbiological screening, HPLC and
LC/MS/MS. Shokuhin Eiseigaku Zasshi, 2008, 49(1), 37-44.
Kaniou S, Pitarakis K, Barlagianni I and Poulios I. Photocatalytic oxidation of
sulfamethazine. Chemosphere, 2005, 60 (3), 372–380.
Katia DW, Lieve O, Siska C, Hubert DB, Jan VH and Patrick DB. Detection of
residues of tetracycline antibiotics in pork and chicken meat: correlation
between results of screening and confirmatory tests. Analyst, 1998, 123
(12), 2737–2741.
Katz SE and Fassbender CA. Microbiological assay with increased sensitivity for
chlortetracycline in eggs. Journal of Agricultural and Food Chemistry,
1970, 18(6), 1165-1167.
Katzung BG. Basic and clinical pharmacology 10th edition. New York, NY
McGraw Hill Medical, 2007, 733-741.
Kaufmann A, Pacciarelli B, Prijic A, Ryser B and Roth S. Travaux de chimie
alimentaire et d’hygiène, 1999, 90 , 167-176.
Kazemipour M, Noroozian E, Saber Tehrani M and Mahmoudian M. A new
second-derivative spectrophotometric method for the determination of
permethrin in shampoo. Journal of Pharmaceutical and Biomedical
Analysis, 2002, 30 (4), 1379-1384.
Kazakevich YV and LoBrutto R. HPLC for pharmaceutical scientists wiley,
2007, 1st ed., 75-141.
Khaskheli M, Malik RS, Arain MA, Soomro AH and Arain HH. Detection of ß -
Lactam antibiotic residues in market milk. Pakistan Journal of Nutrition,
2008, 7 (5): 682-685.
183
Kirkup BC Jr. Bacteriocins as oral and gastrointestinal antibiotics, theoretical
considerations, applied research, and practical applications. Current
Medicinal Chemistry, 2006, 13 (27), 3335-3350.
Kitts DD, Zheng M, Burns-Flett E and McErlane KM. Comparison of
sulfadimethoxine residue analyses in salmon muscle using HPLC and
Charm II Test. Journal of Food Protection, 1995, 58 (6), 678-682.
Knorr HV. Physical methods in qualitative and quantitative chemical analysis,
Ohio Journal of Science, 1952, 52 (3), 113-114.
Koárová I, Máté D, Hussein K, Raschmanová K, Marcinák S and Jevinová P.
High-performance liquid chromatographic determination of sulfadimidine
residues in eggs. Acta Veterinaria (Beograd), 2004, 54 (5-6, 427-435.
Korimová L, Máté D, Turek P and Sokol J. Determination of tetracycline in
bones, mechanically separated bones and meat using HPLC and
microbiological plating methods, Veterinarni Medicina (Praha),1997, 42
(5), 129-131.
Kou J and Bloomquist JR. Neurotoxicity in murine striatal dopaminergic
pathways following long-term application of low doses of permethrin and
MPTP. Toxicology Letters, 2007, 171 (3), 154–161.
Krause. Analytical method validation for biopharmaceuticals, a practical guide.
Guide to validation. BioPharmInternational Supplements, 2005, 26–34.
Kris-Etherton PM, William S and Harris LJA. Fish consumption, fish oil
omega-3 fatty acids and cardiovascular disease. Circulation, 2002,
106 (21), 2747–2757.
Kirbiš JM and Flajs VC. Introduction of the HPLC method for the determination
of quinolone residues in various muscle tissues. Biomedical
Chromatography, 2005, 19 (4), 259–265.
Krcmár P and Růzicková V. High-voltage electrophoretic identification of
residual antibiotics in milk. Veterinarni Medicina (Praha), 1996, 41(3),
93-95.
Kumar KS, Swaroop BL, Suvardhan K, Rekha D, Jayaraj B and Chiranjeevi P.
Facile and sensitive spectrophotometric determination of synthetic
pyrithroids in their formulations, water and grain samples. Environmental
Monitoring and Assessment, 2006, 122 (1-3), 1-8.
184
Kunihiro K and Furusawa N. Application of shielded column liquid
chromatography for determination of sulfamonomethoxine,
sulfadimethoxine, and their N4-acetyl metabolites in milk. Journal of
Chromatography A, 2004, 1028 (1), 175-177.
Kunihiro K and Furusawa N. Simultaneous determination of
sulfamonomethoxine, sulfadimethoxine, and their hydroxy/N(4)-acetyl
metabolites with gradient liquid chromatography in chicken plasma,
tissues, and eggs. Talanta, 2005, 67 (1), 54-58.
Kurittu J, Lönnberg S, Virta M and Karp M. Qualitative detection of tetracycline
residues in milk with a luminescence-based microbial method: the effect of
milk composition and assay performance in relation to an immunoassay
and a microbial inhibition assay. Journal of Food Protection, 2000, 63 (7),
953-957.
Laloux J, Romnee JM, Marin C and Vanwijnsberghe D. Determination of
sulfonamides in milk using fluorescamine derivatization and HPLC
separation. Milchwissenschaft, 1996, 51 (9), 517-520.
Lara FJ, García CAM, Alés-Barrero F, Bosque-Sendra JM and García-Ayuso LE.
Multiresidue method for the determination of quinolone antibiotics in
bovine raw milk by capillary electrophoresis-tandem mass spectrometry.
Analytical Chemistry, 2006, 78 (22), 7665-7673.
Leistner.L. Principles and applications of hurdle technology. New Methods of
Food Preservation, 1995, 1st ed., 1-21.
Lialikov I and Fiziko-Khimicheskie S. Melody Analiza, 4th ed. Moscow, 1964.
Liboux ALE, Cachia JPS, Kirkesseli JY, Gautier C, Guimart G, Montay PA,
Peeters E, Groen J, Jonkman H and Wemer J. A comparison of the
pharmacokinetics and tolerability of riluzole after repeat dose
administration in healthy elderly and young volunteers. Clinical
Pharmacology, 1999, 39 (5), 480-486.
Li T, Molteni A, Latkovich P, Castellani W and Baybutt RC. Vitamin A
depletion induced by cigarette smoke is associated with the development
of emphysema in rats. Journal of Nutrition, 2003 , 133 (8), 2629-2634.
Li J, Chen L, Wang X, Jin H, Ding L, Zhang K and Zhang H. Determination of
tetracyclines residues in honey by on-line solid-phase extraction high-
performance liquid chromatography. Talanta, 2008, 75 (5), 1245-1252.
185
Li TL, Chung WYJ and Shih YC. Determination and confirmation of
chloramphenicol residues in swine muscle and liver. Journal of Food
Science, 2002, 67 (1), 21–28.
Li W, Yan Z, Xiang G, Zhenjuan D and Shuo W. Determination of
chloramphenicol residues in milk by enzyme-linked immunosorbent assay:
Improvement by biotin−streptavidin-amplified system, Journal of
Agriculture and Food Chemistry, 2010, 58 (6), 3265–3270.
Li YL, Hao XL, Jia BQ, Xu CL, Chen W, Shen CY and Ding T. Rapid
determination of 19 quinolone residues in spiked fish and pig muscle by
high-performance liquid chromatography (HPLC) tandem mass
spectrometry. Food Additives & Contaminants: Part A, 2009, 26 (3), 306-
313.
Li YL, Hao XL, Ji BQ, Xu CL, Chen W, Shen CY and Ding T. Rapid
determination of 19 quinolone residues in spiked fish and pig muscle by
high-performance liquid chromatography (HPLC) tandem mass
spectrometry. Food Additives & Contaminants. Part A, Chemistry,
Analysis, Control, Exposure and Risk Assessment, 2009, 26 (3), 306-313.
Li H and Kijak PJ. Development of a quantitative multiclass/multiresidue method
for 21 veterinary drugs in shrimp. Journal of AOAC International, 2011,
94 (2), 394-406.
Lian W and Li YQ. Simultaneous determination of ten antibiotic residues in milk
by UPLC. Chromatographia, 2009, 70 (1-2), 253-258.
Liapis KS, Aplada SP and Kyriakidis NV. Rapid multi-residue method for the
determination of azinphos methyl, bromopropylate, chlorpyrifos,
dimethoate, parathion methyl and phosalone in apricots and peaches by
using negative chemical ionization ion trap technology. Journal of
Chromatography A, 2003, 996 (1-2), 181-187.
Lieve O, Siska C, Siegrid DB, Jan VH, Patrick DB and Hubert DB. Inhibition
tests for detection and presumptive identification of tetracyclines, beta-
lactam antibiotics and quinolones in poultry meat. Food Additives and
Contaminants, 2001, 18 (5), 385-393.
Linage B, Gonzalo C, Carriedo JA, Asensio JA, Blanco MA, De La Fuente LF
and San PF. Performance of Blue-Yellow screening test for antimicrobial
186
detection in ovine milk. Journal of Dairy Science, 2007, 90 (12), 5374–
5379.
Lindsay S, Kealey D, Hung LB, Parcher, JF, Shores JC and Ward EH.
Theoretical and experimental foundation for surface-coverage
programming in gas-solid chromatography with an adsorbable carrier gas.
Journal of the American Chemical Society, 1987, 110 (11), 1090-1096.
Lipeng Y, Bo L, Kaidan Y, Guandong Y, Li H and Yehua N. Biotin-streptavidin-
enhanced enzyme-linked immunosorbent assay for the determination of
parathion-methyl in vegetables. Analytical Letters, 2013, 46 (7), 1084-
1096.
Liu CE, Lin H, Cao LM, Lu P and Liu F. Establishment of ELISA for
enrofloxacin and comparative studies with HPLC. Chinese Journal of
Animal Health Inspection, 2009, 26 (9), 44-46.
Liu Y, Yang H, Yang S, Hu Q, Cheng H, Liu H and Qiu Y. High-performance
liquid chromatography using pressurized liquid extraction for the
determination of seven tetracyclines in egg, fish and shrimp. Journal of
Chromatography. B, Analytical Technologies in Biomedical Life Sciences,
2013, 917-918 (15 Febrauary), 11-17.
Liu Y, Zhang C, Men L, Liu Z and Wang S. Determination of tetracycline
antibiotics residues in chicken muscle by liquid chromatography-tandem
mass spectrometry. Se Pu (Chinese Journal of Chromatography), 2006,
24 (2), 171-173.
Lolo M, Pedreira S, Fente C, Vázquez BI, Franco CM and Cepeda A. Study of
enrofloxacin depletion in the eggs of laying hens using diphasic dialysis
extraction/purification and determinative HPLC-MS Analysis. Journal of
Agriculture and Food Chemistry, 2005, 53 (8), 2849–2852.
Long AR, Short CR and Barker SA. Method for the isolation and liquid
chromatographic determination of eight sulfonamides in milk. Journal of
Chromatography, 1990, 502 (1), 87-94.
Long AR, Hsieh LC, Malbrough MS, Short CR and Barker SA. Matrix solid
phase dispersion isolation and liquid chromatographic determination of
sulfadimethoxine in catfish (Ictalurus punctatus) muscle tissue. Journal of
The Association of Official Analytical Chemists, 1990, 73 (6), 868-871.
187
Long AR, Hsieh LC, Malbrough MS, Short CR and Barker SA. Matrix solid-
phase dispersion (MSPD) isolation and liquid chromatographic
determination of oxytetracycline, tetracycline, and chlortetracycline in
milk. Journal- Association of Official Analytical Chemists, 1990, 73 (3),
379-384.
Long AR, Hsieh LC, Malbrough MS, Short CR and Barker SA. Matrix solid
phase dispersion isolation and liquid, chromatographic determination of
oxytetracycline in catfish (Ictalurus punctatus) muscle tissue. Journal-
Association of Official Analytical Chemists, 1990, 73 (6), 864-867.
López-López T, Gil-Garcia MD, Mart´ınez-Vidal JL and Mart´ınez-Galera M.
Determination of pyrethroids in vegetables by HPLC using continuous on-
line post-elution photoirradiation with fluorescence detection. Analytica
Chimica Acta, 2001, 447 (1-2), 101–111.
Lovelock ES and Lipsky R. Electron Affinity spectroscopy a new method for the
identification of functional groups in chemical compounds separated by
gas chromatography. Journal of the American Chemical Society,
1960, 82 (2), 431–433.
Lucas H, Pedro H and José V. Voltammetric determination of methyl parathion,
ortho, meta and para nitrophenol with a carbon paste electrode modified
with C18. Fresenius' Journal of Analytical Chemistry, 1993, 345 (11),
712-715.
Luis ES, Donald SG and Donald WG. Sorption and bound residue formation of
linuron, methylparathion, and metolachlor by carrot tissues: Kinetics by
on-line HPLC microextraction, Journal of Agriculture and Food
Chemistry, 1997, 45 (9), 3634–3641.
Lure and Iu Iu. Spravochnik po analiticheskoi khimii, 4th ed. Moscow, 1971.
Lu Y, Yu K, Qu HB and Cheng YY. Development of an HPLC-UV-ELSD
method for quantification of multiple components of a chinese medicine
made from radix salvia miltiorrhiza and panax notoginseng.
Chromatographia, 2007, 65 (1-2), 19-24.
Luo W, Ang CY and Thompson HC Jr. Rapid method for the determination of
ampicillin residues in animal muscle tissues by high-performance liquid
chromatography with fluorescence detection. Journal of Chromatography
B, Biomedical Sciences and Applications, 1997, 694(2), 401-407.
188
Mahgoub IS, Abdalla AE, Hassan EA and Hassan YAE. Simultaneous
determination of cypermethrin and fenvalerate residues in tomato by gas
chromatography and their applications to kinetic studies after field
treatment. Biomedical Chromatography, 2012, 26 (5), 589-593.
Małgorzata G, Andrzej P and Anna G. Simultaneous determinaton of
fluoroquinolones in feed by liquid chromatography with fluorescence
detection. Bulletin of the Veterinary Institute in Pulawy, 2013, 56 (3), 343–
347.
Ma Lure and Iu Iu. Spravochnik po analiticheskoi khimii, 4th ed. Moscow, 1971.
Mamdouh RR, Safaa MR, Fatma IK and Hoda MM. Electrochemical
determination of ciprofloxacin hydrochloride in pharmaceutical
formulation, aquatic environment and in fish tissues. International Journal
of Biological & Pharmaceutical Research, 2013, 4 (6), 390-396.
Manuel LA, Ana MGC, Laura GG and Carmen CB. Laser induced fluorescence
coupled to capillary electrophoresis for the determination of
fluoroquinolones in foods of animal origin using molecularly imprinted
polymers. Journal of Chromatography A, 2010, 1217 (15), 2237–2242.
Marazuela MD and Moreno BMC. Multiresidue determination of
fluoroquinolones in milk by column liquid chromatography with
fluorescence and ultraviolet absorbance detection. Journal of
Chromatography A, 2004, 1034 (1-2), 25-32.
Marie M, Michael OK and Malcolm RS. Multi-residue analysis of penicillin
residues in porcine tissue using matrix solid phase dispersion. Analyst,
1998, 123 (12), 2779–2783.
Marilyn JS, Susan EB, Ixchel RH and Dan JD. Simultaneous determination of
fluoroquinolones and tetracyclines in chicken muscle using HPLC with
fluorescence detection. Journal of Chromatography B, 2007, 846 (1–2), 8–
13.
Marilyn JS, Ixchel RH and Dan JD. Evaluation of serum as a potential matrix for
multiresidue determination of fluoroquinolone antibiotics in chicken using
liquid chromatography-fluorescence-mass spectrometry(n). Journal of
AOAC International, 2007, 90 (6), 1716-1723.
189
Marilyn JS. Multiresidue analysis of fluoroquinolone antibiotics in chicken tissue
using automated microdialysis–liquid chromatography, Journal of
Chromatographic Science, 2001, 39 (5), 350-356.
Marques MV. Sulfonamides quantification in milk by high performace liquid
chromatography via azoderivatives. Pesquisa Agropecuária Brasileira,
2008, 43 (12), 1817-1820.
Martos I, Ferreres F and Tomás-Barberán F. Identification of flavonoid markers
for the botanical origin of Eucalyptus honey. Journal of Agricultural and
Food Chemistry, 2000, 48 (5), 1498–502.
Martinez-Cabrillo JL. Responses of populations of the tobacco budworm
(Lepidopterea: Noctuidae) from northwest Mexico to pyrethroids. Journal
of Economic Entomology, 1991, 84 (2), 363–366.
Martinez RC, Gonzalo ER, Moran MJA and Mendez JH. Sensitive method for the
determination of organophosphorus pesticides in fruits and surface waters
by high-performance liquid chromatography with ultraviolet detection.
Journal of Chromatography A, 1992, 607 (1), 37–45.
Martinez EE and Shimoda W. Liquid chromatographic determination of
tetracycline residues in animal feeds. Journal- Association of Official
Analytical Chemists, 1988, 71 (3), 477-480.
Martínez DB, Vázquez PP, Galera MM and García MDG. Determination of
pyrethroid insecticides in vegetables with liquid chromatography using
detection by electrospray mass spectrometry. Chromatographia, 2006, 63
(9-10), 487-491.
Mazumdar K, Dutta NK, Dastidar SG, Motohashi N and Shirataki Y. Diclofenac
in the management of E. coli urinary tract infections. In Vivo, 2006, 20 (5),
613–619.
McCann D, Barrett A, Cooper A, Crumpler D, Dalen L, Grimshaw K, Kitchin
E, Lok K, Porteous L, Prince E, Sonuga-Barke E, Warner JO and
Stevenson J. Food additives and hyperactive behaviour in 3-year-old and
8/9-year-old children in the community: a randomised, double-blinded
placebo-controlled trial. Lancet, 2007, 370 (9598), 1560-1567.
Mehran MA, Hossein B, Masoud A, Ashraf-o-sadat N and Mahboob N.
Simultaneous Determination of tetracyclines residues in bovine milk
190
samples by solid phase extraction and HPLC-FL method. Advanced
Pharmaceutical Bulletin, 2011, 1 (1), 34-39.
Mehran MA, Mohammad RR, Afshin J, Maryam BA, Solmaz M and Maryam Z.
Levels of tetracycline residues in cattle meat, liver, and kidney from a
slaughterhouse in Tabriz, Iran, Turkish Journal of Veterinary and Animal
Sciences, 2009, 33 (4), 345-349.
Mei LW, Sheng CC, Jin CL and Sheng CK. Determination of nalidixic acid by
fluorometry with sodium borohydride and hydrogen peroxide. Journal of
AOAC International, 2002, 85 (3), 572-575.
Mei B, Rong L, Tingting C, Shouhui D, Hualin Z, Shuming Y and Jing Q.
Simultaneous determination of tetracycline antibiotics in beehives by
liquid chromatography–triple quadrupole mass spectrometry. Advances in
Applied Science Research, 2012, 3 (1), 462-468.
Mendham J. Vogels textbook of quantitative chemical analysis, John Wiley &
Sons Inc, Volume-6, 1989, 117-191.
Meredith WE, Weiser HH and Winter AR. Chlortetracycline and oxytetracycline
residues in poultry tissues and eggs. Applied Microbiology, 1965, 13 (1),
86–88.
Michael A, Becker H, Ralph S, Robert LW, Patricia AM, Denise E, William AP,
Janet S and Nancy JR. Febuxostat compared with allopurinol in patients
with hyperuricemia and gout. New England Journal of Medicine, 2005,
353 (16), 2450-2456.
Min JK, Hye SL, Duck HC and Yong TL. Synthesis of haptens of
organophosphorus pesticides and development of enzyme-linked
immunosorbent assays for parathion-methyl. Analytica Chimica Acta,
2003, 493 (1), 47–62.
Mishra GP and Mulani JD. Doxycycline, An old drug with a new role In
idiopathic pulmonary fibrosis. International Journal of Pharma and Bio
Sciences, 2010, 1 (2), 1-6.
Mi-Ra J, Kim PH, Lee HJ and Lee TS. A new analytical method for
fluoroquinolones in fisheries products by high performance liquid
chromatography. Korean Journal of Fisheries and Aquatic Sciences, 2006,
39 (2), 59-65.
191
Mikaela N, Xun F, Zheng Y, Ping Z, James RS, Dan C, Shirley JG and Bruce DH.
Immunochemical screening of pesticides (simazine and cypermethrin) in
orange oil. Journal of Agriculture and Food Chemistry, 2009, 57 (13),
5673–5679.
Moema D, Nindi MM and Dube S. Development of a dispersive liquid-liquid
microextraction method for the determination of fluoroquinolones in
chicken liver by high performance liquid chromatography. Analytica
Chimica Acta, 2012, 730 (12 June), 80-86.
Moghbel A and Makhmalzadeh B. The spectrofluorimetry method for
determination of nalidixic acid in human plasma, Jundishapur Journal of
Natural Pharmaceutical Products, 2006, 1 (1), 41-47.
Mohammed S, Hortense ET, Ulrich G, Tony B and Maxime P. Electrochemical
stripping analysis of methyl-parathion (MPT) using carbon fiber
microelectrodes (CFME) modified with combinations of poly-NiTSPc and
Nafion® films. Sensors and Actuators B: Chemical, 2007, 124 (2), 368–
375.
Mohammad AR, Dzolkhifli O, Mohammad ZI, Morshed MM and Rashid KNHB.
Supercritical fluid extraction and quantification of chlorpyrifos
insecticides in fresh vegetables by gas chromatography with electron
capture detection (GC-ECD). Agriculture and Biology Journal of North
America, 2010, 1(4), 548-555.
Mohammed ES, Mohammed SO and Riham AR. A high-performance liquid
chromatographic method for the determination of cypermethrin in
vegetables and its application to kinetic studies after greenhouse treatment.
Food Chemistry, 1997, 59 (2), 283–290.
Mohammad AR, Dzolkhifli O, Zaidul ISM, Morshed MM and Rashid KNHB.
Supercritical carbondioxide extraction of cypermethrin in different fresh
vegetables using anhydrous sodium sulfate for sample preparation and
extraction. African Journal of Biotechnology, 2010, 9 (15), 2290-2297.
Molnár and Horváth D. Reverse-phase chromatography of polar biological
substances: separation of catechol compounds by high-performance liquid
chromatography. Clinical Chemistry, 1976, 22 (9), 1497–1502.
192
Mónica CVM, Felix GRR and Susanne R. Multiresidue determination of
tetracyclines, sulphonamides and chloramphenicol in bovine milk using
HPLC-DAD. Food Chemistry, 2009, 117 (3), 545–552.
Montero A, Althaus RL, Berruga AM and Molina MP. Detection of antimicrobial
agents by a specific microbiological method (Eclipse100®) for ewe milk.
Small Ruminant Research, 2005, 57 (2), 229-237.
Morris KR, Griesser UJ, Eckhardt CJ and Stowell JG. Theoretical approaches to
physical transformations of active pharmaceutical ingredients during
manufacturing processes. Advanced Drug Delivery Reviews, 2001, 48 (1),
91-114.
Mulders EJ and Vande LD. Determination of residues of tetracycline antibiotics in
animal tissues by high-performance liquid chromatography. Journal of
Pharmaceutical and Biomedical Analysis, 1989, 7 (12), 1829-1835.
Mullen W, Marks S and Crozier A. Evaluation of phenolic compounds in
commercial fruit juices and fruit drinks. Journal of Agriculture and Food
Chemistry, 2007, 55 (8), 3148-3157.
Muriuki FK, Ogara WO, Njeruh FM and Mitema ES. Tetracycline residue levels
in cattle meat from Nairobi salughter house in Kenya. Journal of
Veterinary Science, 2001, 2 (2), 97-101.
Muhammad UF, Ping S and Yi Y. Applications of a novel sample preparation
method for the determination of sulfonamides in edible meat by CZE.
Chromatographia, 2009, 69 (9-10), 1107-1111.
Muhammad F, Akhtar M, Rahman ZU, Farooq HU, Khaliq T and Anwar MI.
Multi-residue determination of pesticides in the meat of cattle in
Faisalabad-Pakistan, Egypt. Academic Journal of biological Science, 2010,
2 (2), 19-28.
Munns RK, Turnipseed SB, Pfenning AP, Roybal JE, Holland DC, Long AR and
Plakas SM. Liquid chromatographic determination of flumequine,
nalidixic acid, oxolinic acid, and piromidic acid residues in catfish
(Ictalurus punctatus). Journal of AOAC International, 1998, 81 (4), 825-
838.
Munns RK, Holland DC, Roybal JE, Storey JM, Long AR, Stehly GR and
Plakas SM. Gas chromatographic determination of chloramphenicol
193
residues in shrimp: interlaboratory study. Journal of AOAC International,
1994, 77 (3), 596-601.
Meng Y, Wei S, Yan Z, Junping W, Yijin Y, Shuguang Z, Irina YG and Shuo W.
A gel-based visual immunoassay for non-instrumental detection of
chloramphenicol in food samples. Analytical Chimica Acta, 2012, 751 (2
November), 128-134.
Myllyniemi AL, Sipilä H, Nuotio ,Niemi A and Honkanen-Buzalski T. An
indirect conductimetric screening method for the detection of antibiotic
residues in bovine kidneys. The Analyst, 2002, 127 (9), 1247-1251.
Nagaraja P and Bhaskara BL. A Novel method for the assessment of methyl
parathion by using coupling agents in environmental and commercial
samples. Chemistry & Biodiversity, 2007, 4 (1), 89–97.
Naidoo V and Swan GE. Diclofenac toxicity in gyps vulture is associated with
decreased uric acid excretion and not renal portal vasoconstriction.
Comparative Biochemistry and Physiology Part C: Toxicology, 2008,
149 (3), 269–274.
Narin T and Supaporn S. Determination of tetracycline antibiotic residues in
honey samples collected from northern places of Thailand by HPLC.
KMITL Science Journal, 2008, 8 (2), 18-25.
Nakazawa H, Ino S, Kato K, Watanabe T, Ito Y and Oka H. Simultaneous
determination of residual tetracyclines in foods by high-performance liquid
chromatography with atmospheric pressure chemical ionization tandem
mass spectrometry. Journal of Chromatography. B, Biomedical Sciences
and Applications, 1999, 732 (1), 55-64.
Neetu T, Anupama A and Kanchan U. Kinetic-spectrophotometric determination
of methyl parathion in water and vegetable samples. Spectrochimica Acta
Part A: Molecular and Biomolecular Spectroscopy, 2013, 101 (1), 54–58.
Nelson JM, Chiller TM, Powers JH and Angulo FJ. Fluoroquinolone-resistant
campylobacter species and the withdrawal of fluoroquinolones from use in
poultry, a public health success story. Clinical Infectious Diseases, 2007,
44 (7), 977–980.
Neufeld DSG, Savoeun H, Phoeurk C, Glick A and Hernandez C. Prevalence and
persistence of organophosphate and carbamate pesticides in Cambodian
194
market vegetables. Asian Journal of Water, Environment and Pollution,
2010, 7 (4), 89-98.
Niu CQ and Zhu SQ. LC-MS analysis of related substances in ampicillin and
amoxicillin. Yao Xue Xue Bao, 2001, 36 (10), 758-761.
Nief RA and Suhaib NL. High performance liquid chromatographic method for
the determination of diclofenac sodium in pharmaceutical preparations and
in environmental samples. Iraqi National Journal of Chemistry, 2011, 44
(2), 467-473.
Naidong W, Hua S, Roets E and Hoogmartens J. Assay and purity control of
tetracycline, chlortetracycline and oxytetracycline in animal feeds and
premixes by TLC densitometry with fluorescence detection. Journal of
Pharmaceutical and Biomedical Analysis, 2003, 33 (1), 85-93.
Nouws JFM, Vree TB, R Aerts and Grondel J. Pharmacokinetics and residues of
sulfadimidine and its N4-Acetyl and Hydroxy metabolites in food-
producing animals. ACS Symposium Series, 1986, 320 (15), 168–182.
Nouws JF, Loeffen G, Schouten J, Van Egmond H, Keukens H and Stegeman H.
Testing of raw milk for tetracycline residues. Journal of Dairy Science,
1998, 81 (9), 2341-2345.
Oka H, Matsumoto H, Uno K, Harada K, Kadowaki S and Suzuki M.
Improvement of chemical analysis of antibiotics. VIII. Application of
prepacked C18 cartridge for the analysis of tetracycline residues in animal
liver. Journal of Chromatography, 1985, 325 (1), 265-274.
Oka H, Ikai Y, Ito Y, Hayakawa J, Harada K, Suzuki M, Odani H and Maeda K.
Improvement of chemical analysis of antibiotics. XXIII. Identification of
residual tetracyclines in bovine tissues by electrospray high-performance
liquid chromatography-tandem mass spectrometry. Journal of
Chromatography. B, Biomedical Sciences and Applications, 1997, 693 (2),
337-344.
Oka H, Ikai Y, Hayakawa J, Masuda K, Harada K and Suzuki M. Improvement of
chemical analysis of antibiotics. Part XIX: Determination of tetracycline
antibiotics in milk by liquid chromatography and thin-layer
chromatography/fast atom bombardment mass spectrometry. Journal of
AOAC International, 1994 , 77 (4), 891-895.
195
Omori M and Nakano E. Jellyfish fisheries in southeast Asia. Hydrobiologia,
2001, 451 (1-3), 19–26
Ong YW, Xavier R and Marimuthu K. Screening of antibacterial activity of
mucus extract of snakehead fish, channa striatus (Bloch). European
Review for Medical and Pharmacological Sciences, 2010, 14 (8), 675-681.
Pagliuca G, Gazzotti T, Serra G and Sabatini AG. A scientific note on the
determination of oxytetracycline residues in honey by high-performance
liquid chromatography with UV detection. Apidologie, 2002, 3 (6), 583 –
584.
Pan Y, Xu Q, Kang X and Zhang J. Determination of chloramphenicol residues in
milk by reversed-phase high performance liquid chromatography with
fluorescence detection. Se Pu (Chinese Journal of Chromatography),
2005, 23 (6), 577-580.
Pang GF, Fan CL, Liu YM, Cao YZ, Zhang JJ, Li XM, Li ZY, Wu YP and
Guo TT. Determination of residues of 446 pesticides in fruits and
vegetables by three-cartridge solid-phase extraction-gas chromatography-
mass spectrometry and liquid chromatography-tandem mass spectrometry.
Journal of AOAC International, 1987, 89 (3), 740-771.
Pang GF, Fan CL, Chao YZ and Zhao TS. Packed-column gas chromatographic
method for the simultaneous determination of 10 pyrethroid insecticide
residues in fruits, vegetables, and grains. Journal of AOAC International,
1994a, 77 (3), 738-747.
Pang GF, Fan CL, Chao YZ and Zhao TS. Rapid method for the determination of
multiple pyrethroid residues in fruits and vegetables by capillary column
gas chromatography. Journal of Chromatography A, 1994b, 667 (1-2),
348-353.
Pang GF, Chao YZ, Liu XS and Fan CL. Multiresidue liquid chromatographic
method for simultaneous determination of pyrethroid insecticides in fruits
and vegetables. Journal of AOAC International , 1995, 78 (6), 1474-1480.
Pang GF, Chao YZ, Fan CL, Zhang JJ, Li XM and Zhao TS. Modification of
AOAC multiresidue method for determination of synthetic pyrethroid
residues in fruits, vegetables, and grains. Part I: Acetonitrile extraction
system and optimization of florisil cleanup and gas chromatography.
Journal of AOAC International, 1995, 78 (6), 1481-1488.
196
Paranthaman R, Sudha A and Kumaravel S. Determination of pesticide residues in
banana by using high performance liquid chromatography and gas
chromatography-mass spectrometry. American Journal of Biochemistry
and Biotechnology, 2012, 8 (1), 1-6.
Pavlína N, Ivana B, Michaela D, Bohumíra J and Lenka V. Occurrence of
tetracycline, chlortetracyclin, and oxytetracycline residues in raw cow’s
milk. Czech Journal of Food Sciences, 2009, 27 (5), 379–385.
Pavlína N, Ivana B, Jana V and Lenka V. Fluoroquinolone residues in raw cow’s
milk. Czech Journal of Food Sciences, 2011, 29 (6), 641–646.
Pehrsson PR, Haytowitz DB, Holden JM, Perry CR and Beckler DG. USDA's
national food and nutrient analysis program, food sampling. Journal of
Food Composition and Analysis, 2000, 13 (4), 379–389.
Pena A, Pina J, Silva LJ, Meisel L and Lino CM. Fluoroquinolone antibiotics
determination in piggeries environmental waters. Journal of
Environmental Monitoring, 2010, 12 (3), 642-646.
Pena A, Pelantova N, Lino CM, Silveira MIN and Solich P. Validation of an
analytical methodology for determination of oxytetracycline and
tetracycline residues in honey by HPLC with fluorescence detection.
Journal of Agriculture and Food Chemistry, 2005, 53 (10), 3784-3788.
Pérez RP, Martínez LC, Sanz A and Bravo E. Separation and simultaneous
determination of quinolone antibiotics by capillary zone electrophoresis.
Chromatographia, 1999, 49 (7-8), 419-423.
Peters J. The dromedary, ancestry history of domestication and medical treatment
in early historic times. Tierarztl Prax Ausg G Grosstiere Nutztiere,
1997, 25 (6), 559–565.
Philippe AG, Delphine R, Pascal M, Eric G, Adrienne P and Richard HS.
Quantitative determination of chloramphenicol in milk powders by isotope
dilution liquid chromatography coupled to tandem mass spectrometry.
Journal of Chromatography A, 2004, 1054 (1-2), 365-371.
Pimentel D, Acquay H, Biltonen M, Rice P and Silva M. Environmental and
economic costs of pesticide use. BioScience, 1992, 42 (10), 750-760
Ping F, Wei QS, Cheng ZH and Yuan FL. Total Internal Reflected Resonance
Light Scattering determination of chlortetracycline in body fluid with the
197
complex cation of chlortetracycline−europium−trioctyl phosphine oxide at
the water/tetrachloromethane interface. Analytical Chemistry, 2001, 73
(17), 4307–4312.
Piñero MY, Garrido-Delgado R, Bauza R, Arce L and Valcárcel M. Easy sample
treatment for the determination of enrofloxacin and ciprofloxacin residues
in raw bovine milk by capillary electrophoresis. Electrophoresis, 2012, 33
(19-20), 2978-2986.
Prasanna KS and Surendra KR. Modified popoff’s reaction for indirect
spectrophotometric determination of cypermethrin. Journal of Applicable
Chemistry, 2012, 1 (4), 490-499.
Rade I, Nina K and Borut Š. Optimized method for determination of amoxicillin,
ampicillin, sulfamethoxazole, and sulfacetamide in animal feed by micellar
electrokinetic capillary chromatography and comparison with high-
performance liquid chromatography. Croatica chemica acta, 2009, 82 (3),
685–694.
Ralph K, Franz JH and Frank R. Simple and rapid determination of enrofloxacin
and ciprofloxacin in edible tissues by turbulent flow
chromatography/tandem mass spectrometry (TFC–MS/MS). Analytica
Chimica Acta, 2009, 637 (1-2), 208–213.
Ramesh A and Balasubramanian M. Rapid preconcentration method for the
determination of pyrethroid insecticides in vegetable oils and butter fat and
simultaneous determination by gas chromatography–electron capture
detection and gas chromatography–mass spectrometry. Analyst, 1998, 123
(9), 1799–1802.
Ramos M, Aranda PMA, Rodriguez I, Diaz R and Blanca J. Determination of
chloramphenicol residues in shrimps by liquid chromatography–mass
spectrometry. Journal of Chromatography B, 2003, 791 (1–2), 31–38.
Ran W, Ruicheng W, Ming C and Tian W. A new, simple and rapid HPLC
method for determination of chlortetracycline in pig solid manure. Italian
Journal of Animal Science, 2010, 9 (2), e 37.
Rauh V, Arunajadai S, Horton M, Perera F, Hoepner L, Barr DB and
Whyatt R. 7-year neurodevelopmental scores and prenatal exposure to
chlorpyrifos, a common agricultural pesticide. Environ Health Perspect,
2011, 119 (8), 1196–1201.
198
Ravikumar CH, Srinivas P and Seshaiah K. Determination of pyrethroid pesticide
residues in rice by gas chromatography tandem mass spectrometry.
Journal of Chemical and Pharmaceutical Research, 2013, 5 (4), 175-180.
Richard EM, Thomas MP, Theresa AB and John JJ. A simple HPLC method for
the determination of chlorpyrifos in black oil sunflower seeds. Journal of
Liquid Chromatography & Related Technologies, 2006, 29 (3), 339–348.
Robert SS, David D, Lindseymcrobbie, Julio Q, David L, Janine S, David C,
Carlamcphee, Steven S and Robert M. Validation of the Charm
3SL3 _Lactam test for screening raw milk in compliance with the U.S.
pasteurized milk ordinance. Journal of AOAC International, 2011, 94 (1),
348-357.
Rocha SSR, Luiz DJ, de NG and Reyes FGR. A high-throughput method for
determining chloramphenicol residues in poultry, egg, shrimp, fish, swine
and bovine using LC-ESI-MS/MS. Journal of Separation Science, 2009,
32 (23-24), 23-24, 4012–4019.
Rodrigo BH, Fabiano B and Tarso BLK. Use of capillary electrophoresis with
laser-induced fluorescence detection to screen and liquid chromatography–
tandem mass spectrometry to confirm sulfonamide residues: Validation
according to European Union 2002/657/EC. Journal of Chromatography
A, 2009, 1216 (46), 8254–8261.
Rodríguez DRC, Fernandez RJM, Aguilar CMP and Gómez HA. Determination
of fluoroquinolones in milk samples by postcolumn derivatization liquid
chromatography with luminescence detection. Journal of Agriculture and
Food Chemistry, 2006, 54 (26), 9670-9676.
Rodziewicz L and Zawadzka I. Rapid determination of chloramphenicol residues
in milk powder by liquid chromatography-elektrospray ionization tandem
mass spectrometry. Talanta, 2008, 75 (3), 846-850.
Rohan D, Siddharth T and Padmaja N. Pesticide residue analysis of fruits and
vegetables. Journal of Environmental Chemistry and Ecotoxicology,
2012, 4 (2), 19-28.
Romváry A and Simon F. Sulfonamide residues in eggs, Acta veterinaria
Hungarica, 1992, 40 (1-2), 99-106.
Rønning HT, Einarsen K and Asp TN. Determination of chloramphenicol residues
in meat, seafood, egg, honey, milk, plasma and urine with liquid
199
chromatography-tandem mass spectrometry, and the validation of the
method based on 2002/657/EC. Journal of Chromatography A, 2006, 1118
(2), 226-233.
Rosa MGR, Raquel RO, Beatriz CG and Jesús SG. Determination of 23 pesticide
residues in leafy vegetables using gas chromatography–ion trap mass
spectrometry and analyte protectants. Journal of Chromatography A, 2008,
1196–1197 (4 July), 100–109.
Rosemary A and Cole. Isothiocyanates, nitriles and thiocyanates as products of
autolysis of glucosinolates in Cruciferae. Phytochemutry, 1976, 15,
759-762.
Roseane BB and Roberto GJ. Determination of Beta-Lactam residues in milk by
high performance liquid chromatography. Brazilian Archives of Biology
and Technology, 2006, 49 (special issue), 41-46.
Roudaut B and Garnier M. Sulphonamide residues in eggs following drug
administration via the drinking water. Food Additives and Contaminants,
2002, 19(4), 373-378.
Rouhollah D, Mansoreh S, Hadi E, Gholamabbas M, Davar KR and Davod HS.
Detrmination of organophosphorus pesticides (diazinon and chlorpyrifos)
in water resources in Barzok, Kashan. Zahedan Journal of Research in
Medical Sciences, 2012, 14 (10), 66-72.
Roya K, Mir-Jamal H, Shahram S and Behrooz J. Detection of oxytetracycline
residue in infant formula by high-performance liquid chromatography
(HPLC), Iranian Journal of Pharmaceutical Research, 2011, 10 (2),
221-224.
Sabo JA and Abdel-Rahman SM. Voriconazole a new triazole antifungal. The
Annals of Pharmacotherapy, 2000, 34 (9), 1032-1043.
Sajjad AB, Niaz AA, Muhammad A and Muhammad RA. Determination of the
organophosphorus pesticide in vegetables by high-performance liquid
chromatography. American-Eurasian Journal of Agriculture and
Environmental Science, 2009, 6 (5), 513-519.
Salas Rojas A. 1997. Organic produce prospers at Retail. Produce Business,
November 1997.
Samanidou VF, Nikolaidou KI and Papadoyannis IN. Development and validation
of an HPLC confirmatory method for the determination of seven
200
tetracycline antibiotics residues in milk according to the European Union
Decision 2002. Journal of Separation Science, 2007, 30 (15), 2430–2439.
San MB, Cornejo J, Iragüen D, Hidalgo H and Anadón A. Depletion study of
enrofloxacin and its metabolite ciprofloxacin in edible tissues and feathers
of white leghorn hens by liquid chromatography coupled with tandem
mass spectrometry. Journal of Food Protection, 2007, 70 (8), 1952-1957.
Santiago VR, Sánchez PI, Franceschelli F, Martínez G M and Gil GMD.
Determination of photoirradiated tetracyclines in water by high-
performance liquid chromatography with chemiluminescence detection
based reaction of rhodamine B with cerium (IV). Journal of
Chromatography A, 2007, 1167 (1), 85-94.
Sara B, Vittorio C, Roberta C, Antonio DC, Manuela N and Manuel S. Simple
and rapid liquid chromatography−tandem mass spectrometry confirmatory
assay for determining amoxicillin and ampicillin in bovine tissues and
milk. Journal of Agricultural and Food Chemistry, 2004, 52 (11), 3286–
3291.
Sara B, Roberta C, Antonio DC, Manuela N and Maria LP. Rapid confirmatory
assay for determining 12 sulfonamide antimicrobials in milk and eggs by
matrix solid-phase dispersion and Liquid Chromatography−Mass
Spectrometry, Journal of Agricultural and Food Chemistry, 2003, 51 (15),
4225–4232.
Sandra I, Wim R, Jan V, Dirk C, Sigrid O, Katia DW, Walter S and Hubert DB.
Screening and confirmation of chloramphenicol in shrimp tissue using
ELISA in combination with GC–MS2 and LC–MS2. Analytica Chimica
Acta, 2003, 483 (1-2), 153–163.
Sannino A, Bandini M and Bolzoni L. Determination of pyrethroid pesticide
residues in processed fruits and vegetables by gas chromatography with
electron capture and mass spectrometric detection. Journal of AOAC
International, 2003, 86 (1), 101-108.
Schermelleh L, Carlton, PM, Haase S, Shao L, Winoto L, Kner P, Burke B
and Cardoso MC. Subdiffraction multicolor imaging of the nuclear
periphery with 3D structured illumination microscopy. Science, 2008, 320
(5881), 1332-1335.
201
Schurgers LJ and Vermeer C. Determination of phylloquinone and
menaquinones in food. Effect of food matrix on circulating vitamin K
concentrations. Haemostasis, 2000, 30 (6), 298–307.
Schumacher HR, Becker MA, Lloyd E, MacDonald PA and Lademacher C.
Febuxostat in the treatment of gout 5-yr findings of the focus efficacy and
safety study. Rheumatology, 2009, 48 (2), 188-194.
Shinger MI, Elbashir AA, Ahmed Hel-O and Aboul-Enein HY. Simultaneous
determination of cypermethrin and fenvalerate residues in tomato by gas
chromatography and their applications to kinetic studies after field
treatment. Biomedical Chromatography, 2012, 26 (5), 589-593.
Shishovska1 MA and Stefova MT. Fast and universal HPLC method for
determination of permethrin in formulations using 1.8-µm particle-packed
column and performance comparison with other column types, Journal of
Chromatography Sciences, 2012, 50 (1), 43-50.
Shishovska MA, Trajkovska VP and Stefova MT. A simple HPLC method for
determination of permethrin residues in wine. Journal of Environmental
Science and Health Part B Pesticides Food Contaminants and
Agricultural Wastes, 2010, 45 (7), 694-701.
Schneider MJ. Rapid fluorescence screening assay for enrofloxacin and
tetracyclines in chicken muscle. Journal of Agricultural and Food
Chemistry, 2004, 52(26), 7809-7813.
Sebastian VDL, Steve W and Markus S. Single-molecule photoswitching and
localization. Australian Journal of Chemistry, 2011, 64 (5), 503-511.
Semjén G, Magyar T and Laczay P. Therapeutic efficacy of doxycycline against
experimental Pasteurella multocida infection in broiler chickens. Acta
Veterineria Hungarica, 1998, 46 (1), 85-93.
Serôdio P and Nogueira JMF. Development of a stir-bar-sorptive extraction–liquid
desorption–large-volume injection capillary gas chromatographic–mass
spectrometric method for pyrethroid pesticides in water samples.
Analytical and Bioanalytical Chemistry, 2005, 382 (4), 1141-1151.
Seyed EM and Somashekar RK. Synthetic pyrethroides multiresidue in grapes
from southern India. Kathmandu University Journal of Science,
Engineering and Technology, 2010, 6 (2), 104-110.
202
Shanker A, Sood C, Kumar V and Ravindranath SD. A modified extraction and
clean-up procedure for the detection and determination of parathion-
methyl and chlorpyrifos residues in tea. Pest Management Science, 2001,
57 (5), 458–462.
Shakila RJ, Saravanakumar R, Vyla SAP and Jeyasekaran G. An improved
microbial assay for the detection of chloramphenicol residues in shrimp
tissues. Innovative Food Science & Emerging Technologies, 2007, 8 (4),
515–518.
Shailendra SC, Swati N, Nimisha S, Gunjan B and Anjana S. Monitoring of
pesticides residues in farmgate vegetables of Uttarakhand, India.
Wudpecker Journal of Agricultural Research, 2012, 1 (7), 250 – 256.
Sheheli I, Nazneen A, Mohammad SH, Nilufar N, Mohammad M and Mohammad
IRM. Analysis of some pesticide residues in cauliflower by high
performance liquid chromatography. American Journal of Environmental
Sciences, 2009, 5 (3), 325-329, 2009.
Sheehan DJ, Hitchcock CA and Sibley CM. Current and emerging azole
antifungal agents. Clinical Microbiology Reviews, 1999, 12 (1), 40-79.
Shinde LP, Kolhatkar DG, Baig MMV and Subhash C. study of cypermethrin
residue in okra leaves and fruits assessed by GC, International Journal of
Research in Pharmacy and Chemistry, 2012, 2 (2), 273-276.
Sierra D, Contreras A, Sánchez A, Luengo C, Corrales JC, Morales CT, De la Fe
C, Guirao I and Gonzalo C. Detection limits of non-β-lactam antibiotics in
goat's milk by microbiological residues screening tests. Journal of Dairy
Science, 2009, 92 (9), 4200–4206.
Sijun Z, Haiyang J, Xuelian L, Tiejun M, Cun L and Jianzhong S. Simultaneous
determination of trace levels of 10 quinolones in swine, chicken, and
shrimp muscle tissues using HPLC with programmable fluorescence
detection. Journal of Agriculture and Food Chemistry, 2007, 55 (10),
3829–3834.
Sijun Z, Xuelian L, Younkyoung R, Cun L, Haiyang J, Jiancheng L, Zhina Q,
Suxia Z, Fangyang H, Yuping W, Caiwei F, Zengren Z and Jianzhong S.
Developing and optimizing an immunoaffinity cleanup technique for
determination of quinolones from chicken muscle. Journal of Agriculture
and Food Chemistry, 2009, 57 (2), 365-371.
203
Silver and Mary W. Protecting ourselves from shellfish poisoning. American
Scientist, 2006, 94 (4), 316–325.
Siska C and Carlos VP. Sensitive spectrofluorimetric determination of tetracycline
residues in bovine milk. Analyst, 1994, 119 (12), 2713-2716.
Skoog DA, West DM and Holler FJ. Fundamentals of analytical chemistry, New
York: Saunders College publishing, 5th ed., 1988.
Slama TG, Amin A, Brunton SA, File TM, Milkovich G, Rodvold KA, Sahm DF,
Varon J and Weiland D. Council for appropriate and rational antibiotic
therapy (CARAT), a clinician's guide to the appropriate and accurate use
of antibiotics: the council for appropriate and rational antibiotic therapy
(CARAT) criteria. American Journal of Medicine, 2005, 118 (Suppl, 7A),
1S-6S.
Smedley MD and Weber JD. Liquid chromatographic determination of multiple
sulfonamide residues in bovine milk. Journal-Association of Official
Analytical Chemists, 1990, 73 (6), 875-879.
Smythies JR, Benington F and Morin RD. On the molecular mechanism of action
of the tetracyclines. Experientia, 1972, 28 (10), 1253-1254.
Sokol J and Matisova E. Determination of tetracycline antibiotics in animal tissues
of food-producing animals by high-performance liquid chromatography
using solid-phase extraction. Journal of Chromatography A, 1994, 669
(1-2), 75-80.
Solomon D, Avorn J, Stürmer T, Glynn R, Mogun H and Schneeweiss S.
Cardiovascular outcomes in new users of coxibs and nonsteroidal
antiinflammatory drugs, high-risk subgroups and time course of
risk. Arthritis & Rheumatism, 2006, 54 (5), 1378–1389.
Soto-Chinchilla JJ, García-Campaña AM and Gámiz-Gracia L. Analytical
methods for multiresidue determination of sulfonamides and trimethoprim
in meat and ground water samples by CE-MS and CE-MS/MS.
Electrophoresis, 2007, 28 (22), 4164-4172.
Soto-Chinchilla JJ, García-Campaña AM, Gámiz-Gracia L and Cruces-Blanco C.
Application of capillary zone electrophoresis with large-volume sample
stacking to the sensitive determination of sulfonamides in meat and ground
water. Electrophoresis, 2006, 27 (20), 4060–4068.
Specialist laboratory services, 1998
204
Sray A. QA with EPA. American Vegetable Grower, 1998, 22-25.
Srivastava AK, Trivedi P, Srivastava MK, Lohani M and Srivastava LP.
Monitoring of pesticide residues in market basket samples of vegetable
from Lucknow City, India: QuEChERS method. Environmental
Monitoring and Assessment, 2011, 176 (1-4), 465-472.
Stanley DW and Aguil Pontificia JN. Universidad Católica de Chile, Santiago,
Chile, Microstructural principles of food processing and engineering.
Food Engineering Series, 1999, 432.
Steven JL, André DK, Maurice H and Peter VB. Validation of a fast and easy
method for the determination of residues from 229 pesticides in fruits and
vegetables using gas and liquid chromatography and mass spectrometric
detection. Journal of AOAC International, 2005, 88 (2), 595-614.
Stoilova N and Petkova M. developing and validation of method for detection of
quinolone residues in poultry meat. Trakia Journal of Sciences, 2010, 8
(1), 64-69.
Stowe CM. The sulfonamides. In Jones LM (ed), Veterinary Pharmacology and
Therapeutics, Ames, Iowa, Iowa State University Press, chapter 33, 1965.
Straub RF and Voyksner RD. Determination of penicillin G, ampicillin,
amoxicillin, cloxacillin and cephapirin by high-performance liquid
chromatography-electrospray mass spectrometry. Journal of
chromatography, 1993, 647(1), 167-181.
Subramanian S, Ross NW and Mackinnon SL. Comparison of antimicrobial
activity in the epidermal mucus extracts of fish. Comparative Biochemistry
and Physiology, 2008, 150 (1), 85-92.
Subhash C, Anil NM and Shinde LP. Determination of cypermethrin and
chlorpyrifos in vegetables by GC-ECD. International Journal of
ChemTech Research, 2010, 2 (2), 908-911.
Subhash C, Anil NM and Shinde LP. Capillary gas chromatography-mass
spectrometry determination of pesticide residues in vegetables.
Middle-East Journal of Scientific Research, 2012, 11 (5), 589-594.
Suchada C, Orawon C and Shoji M. Electrochemical analysis of chloramphenicol
using boron-doped diamond electrode applied to a flow-injection system.
Analytical Science, 2008, 24 (4), 493-498.
205
Susan BC, Joseph MS and Sherri BT. Optimization and validation of multi-class,
multi-residue LC-MS/MS screening and confirmation method for drug
residues in milk. FDA/ORA/DFS Laboratory Information Bulletin 4443,
2003, Page 1-27.
Sun JW and Zhao XH. Analysis of sulfonamide residues in milk with rapid
HPLC method. Food Science, 2007, 28 (6), 256-259.
Sun X, He X, Zhang Y and Chen L. Determination of tetracyclines in food
samples by molecularly imprinted monolithic column coupling with high
performance liquid chromatography. Talanta, 2009, 79 (3), 926-934.
Sun X, Cao Y, Gong Z, Wang X, Zhang Y and Gao J. An amperometric
immunosensor based on multi-walled carbon nanotubes-thionine-chitosan
nanocomposite film for chlorpyrifos detection. Sensors (Basel), 2012a, 12
(12), 17247-17261.
Sun X, Qiao L and Wang X. A novel amperometric immunosensor based on
{MWCNTs-COOH-CHIT}2/GNPs for detection of chlorpyrifos. Sensors
& Transducers, 2012b, 146 (11), 96-106.
Suthasinee B, Wittaya N and Supalax S. Determination of six pyrethroid
insecticides in fruit juice samples using dispersive liquid–liquid
microextraction combined with high performance liquid chromatography.
Talanta, 2012, 88 (15 January), 209–215.
Supaporn S and Narin T. HPLC-Fluorescence detection method for quantitative
determination of tetracycline antibiotic residues in honey. Naresuan
University Journal, 2009, 6 (2), 147-155.
Tahir A, Imtiaz A and Seema T. Determination of pesticide residues in fruits of
nawabshah district, Sindh, Pakistan, Pakistan Journal of Botany, 2011, 43
(2), 1133-1139.
Tajika H, Malekinejad H, Rouhani SMR, Pajouhi MR, Mahmoudi R and
Haghnazari A. Chloramphenicol residues in chicken liver, kidney and
muscle: A comparison among the antibacterial residues monitoring
methods of Four Plate Test, ELISA and HPLC. Food and Chemical
Toxicology, 2010, 48 (8–9), 2464–2468.
Takeda N and Akiyama Y. Rapid determination of sulphonamides in milk using
liquid chromatographic separation and fluorescamine derivatization.
Journal of Chromatography, 1992, 607(1), 31-35.
206
Takeda N and Akiyama Y. Pre-column derivatization of sulfa drugs with
fluorescamine and high-performance liquid chromatographic
determination at their residual levels in meat and meat products. Journal of
Chromatography, 1991, 558(1), 175-180.
Takeda N, Gotoh M and Matsuoka T. Rapid screening method for quinolone
residues in livestock and fishery products using immobilised metal chelate
affinity chromatographic clean-up and liquid chromatography-
fluorescence detection. Food Additives Contaminants. Part A, Chemistry,
Analysis, Control, Exposure Risk Assessment, 2011, 28 (9), 1168-1174.
Tamrakar U, Gupta V and Pillai A. A spectrophotometric method for the
determination of fenvalerate and cypermethrin in presence of each other.
Journal of Analytical Chemistry, 2012, 67 (5), 437-440.
Tarbin JA, Clarke P and Shearer G. Screening of sulphonamides in egg using gas
chromatography-mass-selective detection and liquid chromatography-mass
spectrometry. Journal of Chromatography B, Biomedical Sciences and
Applications, 1999, 729(1-2), 127-138.
Thais MU and Francisco RAN. Development and validation of a method for the
analysis of tetracyclines in chicken-muscle by liquid chromatography-
electrospray-mass spectrometry in tandem (LC-ESI-MS/MS). Quimica
Nova, 2011, 34 (1), 43-48.
The text book of quantitative chemical analysis, 5th edition, 1999, 10-11.
Theresa AG, Bill G, Rod W, Charles G, Larry GR and Paul HS. Multiresidue
determination of sulfonamides in edible catfish, shrimp and salmon tissues
by high-performance liquid chromatography with postcolumn
derivatization and fluorescence detection. Journal of Chromatography B,
2006, 840 (2), 132–138.
Tian H. Determination of chloramphenicol, enrofloxacin and 29 pesticides
residues in bovine milk by liquid chromatography-tandem mass
spectrometry. Chemosphere, 2011, 83(3), 349-355.
Tidwell JH and Allan GL. Fish as food, aquaculture’s contribution ecological and
economic impacts and contributions of fish farming and capture fisheries.
World Aquaculture, 2002, 33 (3), 44–48.
Ting L, Zhi GS, Ming MZ and Yu QF. Multiresidue determination of
sulfonamides in chicken meat by polymer monolith microextraction and
207
capillary zone electrophoresis with field-amplified sample stacking.
Journal of Chromatography A, 2008, 1205 (1-2), 163–170.
Thomas CCY, Lun Y and Li-Jen L. Determination of sulfonamide residues in
milk by on-line microdialysis and HPLC. Journal of Liquid
Chromatography & Related Technologies, 2004, 27 (3), 501–510.
Tolika EP, Samanidou VF and Papadoyannis IN. Development and validation of
an HPLC method for the determination of ten sulfonamide residues in milk
according to 2002/657/EC. Journal of Separation Science, 2011, 34(14),
1627-1635.
Tomas C, Chris S, Veronika B, Lucie D, Kamila K, Jana P and Jana H.
Streamlining sample preparation and gas chromatography–tandem mass
spectrometry analysis of multiple pesticide residues in tea. Analytica
Chimica Acta, 2012, 743 (19 september), 51– 60.
Tomlin C (Ed.). The pesticide manual, 10th ed., BCPC/ Royal Society of
Chemistry, 1994, 771.
Tong C, Zhuo X, Liu W and Wu J. Synchronous fluorescence measurement of
enrofloxacin in the pharmaceutical formulation and its residue in milks
based on the yttrium (III)-perturbed luminescence. Talanta, 2010, 82(5),
1858-1863.
Tordzagla N, Adosraku KR and Okine NAN. Studies on residues of insecticide
used to spray pineapples grown at Samsam in the Amasaman District
(Ghana). International Journal of Environmental Sciences, 2013, 3 (5),
1577-1586.
Toral MI, Alejandra B, Claudia S and Pablo R. Simultaneous determination of
parathion and p-nitrophenol in vegetable tissues by derivative
spectrophotometry. Environmental Monitoring and Assessment, 2002, 76
(3), 263-274.
Torlak E, Gökmen M, Gürbüz Ü, Kıztanır B and Isık MK. Evaluation of rapid
test methods and HPLC for antibiotic residue analysis in raw milk
samples. Atatürk Üniversitesi Veteriner Bilimleri Dergisi, 2012, 7(2),
105-111.
208
Toth GP, Wang SR, McCarthy H, Tocco DR and Smith MK. Effects of three
male reproductive toxicants on rat cauda epididymal sperm motion.
Reproductive Toxicology, 1992, 6(6), 507-515.
Toussainta B, Bordin G, Janosib A and Rodrigueza AR. Validation of a liquid
chromatography–tandem mass spectrometry method for the simultaneous
quantification of 11 (fluoro)quinolone antibiotics in swine kidney. Journal
of Chromatography A, 2002, 976 (1–2), 195–206.
Toussainta B, Chedin M, Bordin G and Rodrigueza AR. Determination of
(fluoro)quinolone antibiotic residues in pig kidney using liquid
chromatography–tandem mass spectrometry: I. Laboratory-validated
method. Journal of Chromatography A, 2005, 1088 (1–2), 32–39.
Tsuyoshi T, Marina CB and Zahra FCB. Validation of a rapid and sensitive
routine method for determination of chloramphenicol in honey by LC-
MS/MS. Food additives & Contaminants. Part A, Chemistry,
Analysis, Control, Exposure & Risk Assessment, 2012, 29 (4), 596-601.
Turnipseed SB, Storey JM, Clark SB and Miller KE. Analysis of veterinary drugs
and metabolites in milk using quadrupole time-of-flight liquid
chromatography-mass spectrometry. Journal of Agriculture and Food
Chemistry, 2011, 59(14), 7569-7581.
Turnipseed SB, José ER, Allen PP and Philip JK. Use of ion-trap liquid
chromatography–mass spectrometry to screen and confirm drug residues in
aquacultured products. Analytica Chimica Acta, 2003, 483 (1-2), 373–386.
Tyczkowska KL, Voyksner RD, Anderson KL and Papich MG. Simultaneous
determination of enrofloxacin and its primary metabolite ciprofloxacin in
bovine milk and plasma by ion-pairing liquid chromatography. Journal of
Chromatography B, Biomedical Applications, 1994, 658(2), 341-348.
Tyagi T, Vernekar P, Iddya K and Indrani K. Determination of chloramphenicol
in shrimp by liquid chromatography-electrospray ionization tandem mass
spectrometry (LC-ESI-MS-MS). Food additives & Contaminants. Part A,
Chemistry, Analysis, Control, Exposure & Risk Assessment, 2008, 25 (4),
432-437.
Umesh KA, Phul PS and Kerry BW. Evaluation of a dry extract system involving
NIR spectroscopy (DESIR) for rapid assessment of pesticide
209
contamination of fruit surfaces. American Journal of Analytical Chemistry,
2012, 3 (8), 524-533.
Urmila T, Gupta VK and Pillai AK. A spectrophotometric method for the
determination of fenvalerate and cypermethrin in presence of each other.
Journal of Analytical Chemistry, 2012, 67 (5), 437-442.
Ute S and Anke M. Determination of flumequine, nalidixic acid and oxolinic acid
in shrimps by high-performance liquid chromatography with fluorescence
detection. European Food Research & Technology, 2007, 225 (5/6), 627-
634.
Van Poucke LS, Depourcq GC and Van Peteghem CH. A quantitative method for
the detection of sulfonamide residues in meat and milk samples with a
high-performance thin-layer chromatographic method. Journal of
Chromatographic Science, 1991, 29(10), 423-427.
Van Rhijn JA, Lasaroms JJ, Berendsen BJ and Brinkman UA. Liquid
chromatographic-tandem mass spectrometric determination of selected
sulphonamides in milk. Journal of Chromatography A, 2002, 960(1-2),
121-133.
Venugopal NVS, Sumalatha B, Srinivasa Rao B and Veeribabu G.
Spectrophotometric determination of organophosphate insecticide
(chlorpyrifos) based on diazotisation with anthranilic acid. The
Malaysian Journal of Analytical Sciences, 2012, 16 (2), 180 – 186.
Vázquez PP, Mughari AR and Galera MM. Solid-phase microextraction (SPME)
for the determination of pyrethroids in cucumber and watermelon using
liquid chromatography combined with post-column photochemically
induced fluorimetry derivatization and fluorescence detection. Analytica
Chimica Acta, 2008, 607 (1), 74–82.
Verdon E and Couedor P. Determination of ampicillin residues in milk by ion-pair
reversed phase high performance liquid chromatography after precolumn
derivatization. Journal of Pharmaceutical and Biomedical Analysis, 1996,
14(8-10), 1201-1207.
Verzegnassia L, Royera D, Mottiera P and Stadlera RH. Analysis of
chloramphenicol in honeys of different geographical origin by liquid
chromatography coupled to electrospray ionization tandem mass
spectrometry. Food Additives & Contaminants, 2003, 20 (4), 335-342.
210
Victoria FS, Eleni AC and Ioannis NP. Direct determination of five
fluoroquinolones in chicken whole blood and in veterinary drugs by
HPLC. Journal of Separation Science, 2005, 28 (4), 325-331.
Mendham J. Vogels textbook of quantitative chemical analysis, John Wiley &
Sons Inc, Volume-6, 1989, 117-191.
Walsh JR, Walker LV and Webber JJ. Determination of tetracyclines in bovine
and porcine muscle by high-performance liquid chromatography using
solid-phase extraction. Journal of Chromatography, 1992, 596 (2), 211-
216.
Wang S, Yang P and Cheng Y. Analysis of tetracycline residues in bovine milk by
CE-MS with field-amplified sample stacking. Electrophoresis, 2007, 28
(11), 4173–4179.
Wang Y, Zheng F and Chen F. Study on the analytical method of methyl-
parathion and phoxim in methyl-parathion, phoxim and cypermethrin
mixed formulation. Chinese Journal of Chromatography (Se Pu), 1999,
17(4), 360-362.
Wang Y, Zhang Q, Li P, Zhang W, Li Y and Ding X. Selective sample cleanup by
immunoaffinity chromatography for determination of fenvalerate in
vegetables. Journal of Chromatography. B, Analytical Technologies in
Biomedical and Life Sciences, 2011, 879 (30), 3531-3537.
Walker CC and Barker SA. Extraction and liquid chromatographic analysis of
sulfadimethoxine and 4-N-acetylsulfadimethoxine residues in channel
catfish (Ictalurus punctatus) muscle and plasma. Journal of AOAC
International, 1994, 77(6), 1460-1466.
Weihai X, Xiaobin Z, Xinting W, Liping D and Gan Z. Residues of
enrofloxacin, furazolidone and their metabolites in Nile tilapia
(Oreochromis niloticus). Aquaculture, 2006, 254 (1-4), 1–8.
Weijun K, Cheng J, Wei L, Xiaohe X, Yanling Z, Zulun L, Ping Z and
Xingfeng L. Development and validation of a UPLC-ELSD method for
fast simultaneous determination of five bile acid derivatives in calculus
bovis and its medicinal preparations. Food Chemistry, 2010, 120 (4),
1193-1200.
Weimin W, Yimin W, Minmin Z, Liuming Y, Xiaoping W, Xucong L and
Zenghong X. Pressurized capillary electrochromatography with indirect
211
amperometric detection for analysis of organophosphorus pesticide
residues. Analyst, 2010, 135 (29 June), 2150-2156.
Whyatt RM, Barr DB, Camann DE, Kinney PL, Barr JR, Andrews HF,
Hoepner LA and Garfinkel R. Contemporary-use pesticides in personal
air samples during pregnancy and blood samples at delivery among urban
minority mothers and newborns. Environmental Health Perspectives,
2002, 111 (5), 749–756.
Williamson R, Hakenbeck R and Tomasz A. In vivo interaction of beta-lactam
antibiotics with the penicillin-binding proteins of Streptococcus
pneumoniae. Antimicrobial Agents and Chemotherapy, 1980, 18(4), 629-
637.
Wim R, Sigrid O, Hubert DB and Els D. Validation of the tetrasensor honey test
kit for the screening of tetracyclines in honey. Journal of Agriculture and
Food Chemistry, 2007, 55 (21), 8359–8366.
Wish T, Senee K, Richard LD, Boonsom L, Sunantha W and Saisunee L.
Sequential injection spectrophotometric determination of tetracycline
antibiotics in pharmaceutical preparations and their residues in honey and
milk samples using yttrium (III) and cationic surfactant. Talanta, 2011, 84
(5), 1401– 1409.
Winger BE and Kemp CAJ. Characterization of pharmaceutical compounds and
related substances by using HPLC FTICR-MS and tandem mass
spectrometry. American Pharmaceutical Review, 2001, summer issue.
Wiseman A. The GMO handbook, Genetically modified animals, microbes, and
plants in biotechnology. Edited by Sarad R Parekh. Humana Press, New
Jersey, USA. Journal of Chemical Technology and Biotechnology, 2005,
80 (1), 113.
Wood and Rebecca. The whole foods encyclopedia. New York, NY: Prentice-hall
press, 1988.
Wright CG, Leidy RB and Dupree HE Jr. Cypermethrin in the ambient air and on
surfaces of rooms treated for cockroaches. Bulletin of Environmental
Contamination and Toxicology, 1993, 51(3), 356-360.
Xiang Y,Liu Y and Lee ML. Ultrahigh pressure liquid chromatography using
elevated temperature. Journal of chromatography A, 2006, 1104 (1–2),
198–202.
212
Xingyuan L. Electrochemical sensor for determination of parathion based on
electropolymerization poly(safranine) film electrode, International Journal
of Electrochemistry, 2011 (2011), Article ID 986494, 6 pages.
Xizhi S, Aibo W, Sulian Z, Rongxiu L and Dabing Z. Molecularly imprinted
polymer microspheres for solid-phase extraction of chloramphenicol
residues in foods. Journal of Chromatography B, 2007, 850 (1–2), 24–30.
Yang D, Jiang D, Wang Z and Fang C. Study on the determination of
chloramphenicol residues in muscles and viscera of the livestock and
poultry and in the shrimp. Wei Sheng Yan Jiu (Journal of Hygiene
Research), 2004, 33 (2), 198-201.
Yang SS and Yueh CY. Oxytetracycline production by immobilized streptomyces
rimosus. Journal of Microbiology, Immunology and Infection, 2001,
34(4), 235-242.
Yanhu W, Dejin Z, Shenguang G, Lei G, Jinghua Y and Mei Y. A novel
microfluidic origami photoelectrochemical sensor based on CdTe quantum
dots modified molecularly imprinted polymer and its highly selective
detection of S-fenvalerate. Electrochimica Acta, 2013, 107 (30
September), 147–154.
Yaowu HY, Hong SH, Haowen TH, Olaf NO, Wu LW, Zhao C, Yu J,
Wang C, Trinkaus E and Richards M. Stable isotope dietary analysis of
the tianyuan 1 early modern human. Proceedings of the National Academy
of Sciences, 2009, 106 (27), 10971-10974.
Yi Z, Biao H, Jue Z, Ke W and Jian J. Development of a homogeneous
immunoassay based on the AlphaLISA method for the detection of
chloramphenicol in milk, honey and eggs. Journal of Science and Food
Agriculture, 2012, 92 (9), 1944-1947.
Yin LW, Cun L, Yong JL and Jian ZS. Validation method for the determination of
sulfonamide residues in bovine milk by HPLC. Chromatographia, 2007a,
66 (3-4), 191-195.
Yin LW, Li Z, Yongjun L, Yanbin J, Xingguo L and Jianzhong S. Simultaneous
determination of nine sulfonamide residues in milk using solid phase
extraction and high performance liquid chromatography. Se Pu
(Chinese journal of chromatography), 2007b, 25 (5), 728-731.
213
Yongnian N, Dengb N and Serge K. A simple kinetic spectrophotometric
method for simultaneous determination of tetracyclines by use of
chemometrics. Analytical Methods, 2010, 2 (9), 1302-1309.
Yongnian N, Shuzhen L and Serge K. Simultaneous voltammetric analysis of
tetracycline antibiotics in foods. Food chemistry, 2011, 124 ( 3 ), 1157-
1163 .
Yorke JC and Froc P. Quantitation of nine quinolones in chicken tissues by high-
performance liquid chromatography with fluorescence detection. Journal
of Chromatography A, 2000, 882 (1-2), 63–77.
Yue Y, Zhang R, Fan W and Tang F. High-performance thin-layer
chromatographic analysis of selected organophosphorous pesticide
residues in tea. Journal of AOAC International, 2008, 91 (5), 1210-1217.
Zana S, Agim S, Zehra H and Elida M. Abuse of pharmaceutical drugs-antibiotics
in dairy cattle in kosovo and detection of their residues in milk. Journal of
Ecosystem and Ecography, 2012, 2(4), 1-6.
Zawiyaha S, Man YBC, Nazimah SAH, Chin CK, Tsukamotod I, Hamanyza AH
and Norhaizan I. Determination of organochlorine and pyrethroid
pesticides in fruit and vegetables using SAX/PSA clean-up column. Food
Chemistry, 2007, 102 (1), 98–103.
Zhang H, Chen S, Lu Y and Dai Z. Simultaneous determination of quinolones in
fish by liquid chromatography coupled with fluorescence detection:
Comparison of sub-2 µm particles and conventional C18 columns.
Journal of Separation Science, 2010, 33 (13), 1959–1967.
Zhang, ZY, Zhang CZ, Liu XJ and Hong XY. Dynamics of pesticide residues in
the autumn Chinese cabbage (Brassica chinensis L.) grown in open fields.
Pest Management Science, 2006, 62 (4), 350–355.
Zhao SJ, Jiang HY, Ding SY, Li XL, Wang GQ, Li C and Shen JZ. A reliable LC
method with fluorescence detection for quantification of (fluoro)quinolone
residues in chicken muscle. Chromatographia, 2007, 65 (9-10), 539-544.
Zhenbo W and Jun W. Detection of antibiotic residues in bovine milk by a
voltammetric electronic tongue system. Analytica Chimica Acta, 2011,694
(1-2), 46-56.
214
Zhao F, Zhang X and Gan Y. Determination of tetracyclines in ovine milk by
high-performance liquid chromatography with a coulometric electrode
array system. Journal of Chromatography A, 2004, 1055 (1-2), 109-114.
Zhihong C, Jianrong F, Ping Z, Jingfa H, Hong L, Jieping W and Jinlong D.
Origin and chronosequence of paddy soils in china, 19th world congress of
soil science, soil solutions for a changing world, 2010, pg : 39-42.
Zhou X, Xing D, Zhu D, Tang Y and Jia L. Development and application of a
capillary electrophoresis-electrochemiluminescent method for the analysis
of enrofloxacin and its metabolite ciprofloxacin in milk. Talanta, 2008,
75(5), 1300-1306.
Zou QH, Xie MX, Wang XF, Liu Y, Wang J, Song J, Gao H and Han J.
Determination of sulphonamides in animal tissues by high performance
liquid chromatography with pre-column derivatization of 9-
fluorenylmethyl chloroformate. Journal of Separation Science, 2007,
30(16), 2647-2655.
Zwiers LH. ABC transporters of the wheat pathogen mycosphaerella graminicola
function as protectants against biotic and xenobiotic toxic compounds.
Molecular genetics and genomics, 2003, 269 (4), 499-507.