Magnetic techniques for the detection and determination of xenobiotics and cells in water

Safarik, Ivo; Horska, Katerina; Pospiskova, Kristyna; Safarikova, Mirka

doi:10.1007/s00216-012-6056-x

Magnetic techniques for the detection and determination of xenobiotics and cells in water

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Published: 12 May 2012

Volume 404, pages 1257–1273, (2012)
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Analytical and Bioanalytical Chemistry Aims and scope Submit manuscript

Ivo Safarik^1,2,
Katerina Horska¹,
Kristyna Pospiskova³ &
…
Mirka Safarikova¹

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Abstract

Magnetic techniques based on the application of magnetic nanoparticles and microparticles and films have been successfully used for the determination and detection of different types of xenobiotics (e.g. herbicides, insecticides, fungicides, aromatic and polyaromatic hydrocarbons, pentachlorophenol and heavy metal ions) as well as viruses, microbial pathogens and protozoan parasites in water samples. Preconcentration of xenobiotics from large volumes of samples can be performed using magnetic solid-phase extraction, stir-bar sorptive extraction and related procedures. This review provides basic information about these techniques. Published examples of successful applications document the importance of these simple and efficient procedures employing magnetic materials.

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References

Plaza G, Ulfig K, Tien AJ (2000) Pol J Environ Stud 9(4):231–236
CAS Google Scholar
Herzog DP (1997) Technical bulletin. Strategic Diagnostics, Newark
Google Scholar
Hennion M-C (1998) Analusis Mag 26(6):M149–M155
Article CAS Google Scholar
Marquette CA, Blum LJ (2006) Biosens Bioelectron 21:1424–1433
Article CAS Google Scholar
Dankwardt A (2000) In: Meyers RA (ed) Encyclopedia of analytical chemistry. Chichester, Wiley
Google Scholar
Safarik I, Safarikova M (2002) Monatsh Chem 133:737–759
Article CAS Google Scholar
Safarikova M, Safarik I (2001) Magn Electr Sep 10:223–252
Article CAS Google Scholar
Safarik I, Safarikova M (2009) Chem Pap 63:497–505
Article CAS Google Scholar
Safarik I, Safarikova M (2012) In: Thanh NTK (ed) Magnetic nanoparticles: from fabrication to biomedical and clinical applications. CRC, Boca Raton, pp 215–242
Chapter Google Scholar
Safarik I, Safarikova M (1999) J Chromatogr B 722:33–53
Article CAS Google Scholar
Safarik I, Safarikova M (2011) Veterinarstvi 61(4):199–202
Google Scholar
Gunther A, Bilitewski U (1995) Anal Chim Acta 300:117–125
Article Google Scholar
Safarikova M, Safarik I (1999) J Magn Magn Mater 194:108–112
Article CAS Google Scholar
David F, Tienpont B, Sandra P (2003) LC GC Eur (July):2–7
Aguilar-Arteaga K, Rodriguez JA, Barrado E (2010) Anal Chim Acta 674(2):157–165
Article CAS Google Scholar
Barrado E, Vega M, Pardo R, Grande P, Del Valle JL (1996) Water Res 30:2309–2314
Article CAS Google Scholar
Barrado E, Prieto F, Ribas J, Lopez FA (1999) Water Air Soil Pollut 115:385–394
Article CAS Google Scholar
Díaz-González M, González-García MB, Costa-García A (2005) Electroanalysis 17:1901–1918
Article CAS Google Scholar
Centi S, Rozum B, Laschi S, Palchetti I, Mascini M (2006) Chem Anal 51:963–975
CAS Google Scholar
Lin Y-Y, Liu G, Wai CM, Lin Y (2008) Anal Chim Acta 612(1):23–28
Article CAS Google Scholar
Liu GD, Riechers SL, Timchalk C, Lin YH (2005) Electrochem Commun 7:1463–1470
Article CAS Google Scholar
Gruessner B, Shambaugh NC, Watzin MC (1995) Environ Sci Technol 29:251–254
Article CAS Google Scholar
Reidt U, Geisberger B, Heller C, Friedberger A (2011) J Labor Automat 16(2):157–164
Article CAS Google Scholar
Environmental Protection Agency (2005) US EPA method 1622. Cryptosporidium in water by filtration/IMS/FA. http://www.epa.gov/microbes/1622de05pdf
Environmental Protection Agency (2005) US EPA method 1623. Cryptosporidium and Giardia in water by filtration/IMS/FA. http://www.epa.gov/microbes/1623de05pdf
Thompson DE, Rajal VB, De Batz S, Wuertz S (2006) J Water Health 4:67–75
CAS Google Scholar
Van Dyk JS, Pletschke B (2011) Chemosphere 82(3):291–307
Article CAS Google Scholar
Llopis X, Pumera M, Alegret S, Merkoci A (2009) Lab Chip 9(2):213–218
Article CAS Google Scholar
Du D, Wang J, Wang L, Lu D, Smith JN, Timchalk C, Lin Y (2011) Anal Chem 83:3770–3777
Article CAS Google Scholar
Liu ZM, Liu YL, Yang HF, Yang Y, Shen GL, Yu RQ (2005) Anal Chim Acta 533(1):3–9
Article CAS Google Scholar
Wang SF, Tan YM, Zhao DM, Liu GD (2008) Biosens Bioelectron 23(12):1781–1787
Article CAS Google Scholar
Alkasir RSJ, Ganesana M, Won YH, Stanciu L, Andreescu S (2010) Biosens Bioelectron 26(1):43–49
Article CAS Google Scholar
Sima VH, Patris S, Aydogmus Z, Sarakbi A, Sandulescu R, Kauffmann J-M (2011) Talanta 83(3):980–987
Article CAS Google Scholar
Safarik I, Ptackova L, Koneracka M, Safarikova M, Timko M, Kopcansky P (2002) Biotechnol Lett 24(5):355–358
Article CAS Google Scholar
Chang Q, Deng KJ, Zhu LH, Jiang GD, Yu C, Tang HQ (2009) Microchimica Acta 165(3–4):299–305
CAS Google Scholar
Tan XC, Zhang JL, Tan SW, Zhao DD, Huang ZW, Mi Y, Huang ZY (2009) Sensors 9(8):6185–6199
Article CAS Google Scholar
Fritz JS, Dumont PJ, Schmidt LW (1995) J Chromatogr A 691(1–2):133–140
CAS Google Scholar
Berrueta LA, Gallo B, Vicente F (1995) Chromatographia 40(7–8):474–483
Article CAS Google Scholar
Shi Z-G, Lee HK (2010) Anal Chem 82(4):1540–1545
Article CAS Google Scholar
Richter P, Leiva C, Choque C, Giordano A, Sepulveda B (2009) J Chromatogr A 1216(49):8598–8602
Article CAS Google Scholar
Safarikova M, Kibrikova I, Ptackova L, Hubka T, Komarek K, Safarik I (2005) J Magn Magn Mater 293(1):377–381
Article CAS Google Scholar
Safarik I, Safarikova M (2002) Water Res 36(1):196–200
Article CAS Google Scholar
Komarek K, Safarikova M, Hubka T, Safarik I, Kandelova M, Kujalova H (2009) Chromatographia 69(1):133–137
Article CAS Google Scholar
Safarikova M, Lunackova P, Komarek K, Hubka T, Safarik I (2007) J Magn Magn Mater 311(1):405–408
Article CAS Google Scholar
Safarik I, Safarikova M, Vrchotova N (1995) Coll Czech Chem Commun 60(1):34–42
Article CAS Google Scholar
Luo Y-B, Shi Z-G, Gao Q, Feng Y-Q (2011) J Chromatogr A 1218(10):1353–1358
Article CAS Google Scholar
Huang C, Hu B (2008) Spectrochim Acta B 63(3):437–444
Article CAS Google Scholar
Shishehbore MR, Afkhami A, Bagheri H (2011) Chem Central J 5:41
Article CAS Google Scholar
Zhang N, Peng HY, Wang S, Hu B (2011) Microchim Acta 175(1–2):121–128
Google Scholar
Ibarra IS, Rodriguez JA, Miranda JM, Vega M, Barrado E (2011) J Chromatogr A 1218(16):2196–2202
Article CAS Google Scholar
Gao QA, Luo D, Ding J, Feng YQ (2010) J Chromatogr A 1217(35):5602–5609
Article CAS Google Scholar
Ding J, Gao Q, Li X-S, Huang W, Shi Z-G, Feng Y-Q (2011) J Sep Sci 34(18):2498–2504
Article CAS Google Scholar
Bonet-Domingo E, Grau-Gonzalez S, Martin-Biosca Y, Medina-Hernandez MJ, Sagrado S (2007) Anal Bioanal Chem 387(7):2537–2545
Article CAS Google Scholar
Richter P, Cańas A, Muńoz C, Leiva C, Ahumada I (2011) Anal Chim Acta 695(1–2):73–76
Article CAS Google Scholar
De Schepper W, Dries J, Geuens L, Blust R (2010) Ecotox Environ Safe 73(5):702–709
Article CAS Google Scholar
Gascon J, Durand G, Barcelo D (1995) Environ Sci Technol 29(6):1551–1556
Article CAS Google Scholar
Gascon J, Salau JS, Oubina A, Barcelo D (1998) Analyst 123(5):941–945
Article CAS Google Scholar
Gascon J, Oubina A, Ferrer I, Onnerfjord P, Marko-Varga G, Hammock BD, Marco MP, Barcelo D (1996) Anal Chim Acta 330(1):41–51
Article CAS Google Scholar
Byer JD, Struger J, Sverko E, Klawunn P, Todd A (2011) Chemosphere 82(8):1155–1160
Article CAS Google Scholar
Graziano N, McGuire MJ, Roberson A, Adams C, Jiang H, Blute N (2006) Environ Sci Technol 40(4):1163–1171
Article CAS Google Scholar
McGregor EB, Solomon KR, Hanson ML (2008) Chemosphere 73(3):249–260
Article CAS Google Scholar
Castillo M, Oubina A, Barcelo D (1998) Environ Sci Technol 32(14):2180–2184
Article CAS Google Scholar
Herbrandson C, Bradbury SP, Swackhamer DL (2003) Aquat Toxicol 63(4):343–355
Article CAS Google Scholar
Herbrandson C, Bradbury SP, Swackhamer DL (2003) Aquat Toxicol 63(4):333–342
Article CAS Google Scholar
Wandan EN, Zabik MJ, Elleingand EF (2011) Sci Res Essays 6(8):1771–1779
CAS Google Scholar
Walker AE, Holman RE, Leidy RB (2000) J Am Water Resour Assoc 36(1):67–74
Article CAS Google Scholar
Farré M, Kuster M, Brix R, Rubio F, López de Alda M-J, Barceló D (2007) J Chromatogr A 1160(1–2):166–175
Google Scholar
Byer JD, Struger J, Klawunn P, Todd A, Sverko E (2008) Environ Sci Technol 42(16):6052–6057
Article CAS Google Scholar
Gaynor JD, Cancilla DA, Webster GRB, Sarna LP, Graham KN, Ng HYF, Tan CS, Drury CF, Welacky T (1996) J Agric Food Chem 44(9):2736–2741
Article Google Scholar
Schraer SM, Shaw DR, Boyette M, Coupe RH, Thurman EM (2000) J Agric Food Chem 48(12):5881–5886
Article CAS Google Scholar
Barcelo D, Oubina A, Salau JS, Perez S (1998) Anal Chim Acta 376(1):49–53
Article CAS Google Scholar
Fillmann G, Bicego MC, Zamboni A, Fileman TW, Depledge MH, Readman JW (2007) J Braz Chem Soc 18(4):774–781
Article CAS Google Scholar
Shelver WL, Parrotta CD, Slawecki R, Li QX, Ikonomou MG, Barcelo D, Lacorte S, Rubio FM (2008) Chemosphere 73(1):S18–S23
Article CAS Google Scholar
Xu T, Cho IK, Wang DL, Rubio FM, Shelver WL, Gasc AME, Li J, Li QX (2009) Environ Pollut 157(2):417–422
Article CAS Google Scholar
Barsh R, Bell J, Halliday H, Clifford M, Mottet G (2008) Preliminary Survey of pyrethroid pesticides and surfactants in San Juan County surface waters. KWIAHT (Center for the Historical Ecology of the Salish Sea). Lopez
Young DL, Mihaliak CA, West SD, Hanselman KA, Collins RA, Phillips AM, Robb CK (2000) J Agric Food Chem 48(11):5146–5153
Article CAS Google Scholar
Shelver WL, Shappell NW, Franek M, Rubio FR (2008) J Agric Food Chem 56(15):6609–6615
Article CAS Google Scholar
Raturi S, Carroll MJ, Hill RL (2003) J Environ Qual 32(1):215–223
CAS Google Scholar
Kantiani L, Farré M, Asperger D, Rubio F, González S, López de Alda MJ, Petrovic M, Shelver WL, Barceló D (2008) J Hydrol 361(1–2):1–9
Article CAS Google Scholar
Ricart M, Guasch H, Alberch M, Barcelo D, Bonnineau C, Geiszinger A, Farre M, Ferrer J, Ricciardi F, Romani AM, Morin S, Proia L, Sala L, Sureda D, Sabater S (2010) Aquat Toxicol 100(4):346–353
Article CAS Google Scholar
Haramoto E, Kitajima M, Katayama H, Ohgaki S (2010) Water Res 44(6):1747–1752
Article CAS Google Scholar
Hwang YC, Leong OM, Chen W, Yates MV (2007) Appl Environ Microbiol 73(7):2338–2340
Article CAS Google Scholar
Monceyron C, Grinde B (1994) J Virol Methods 46(2):157–166
Article CAS Google Scholar
Jothikumar N, Cliver DO, Mariam TW (1998) Appl Environ Microbiol 64(2):504–508
CAS Google Scholar
Cannon JL, Vinje J (2008) Appl Environ Microbiol 74(21):6818–6819
Article CAS Google Scholar
Myrmel M, Rimstad E, Wasteson Y (2000) Int J Food Microbiol 62(1–2):17–26
Article CAS Google Scholar
Yang W, Gu AZ, Zeng S-Y, Li D, He M, Shi H-C (2011) J Microbiol Methods 84(3):447–453
Article CAS Google Scholar
Grinde B, Jonassen TO, Ushijima H (1995) J Virol Methods 55(3):327–338
Article CAS Google Scholar
Chakraborty R, Hazen TC, Joyner DC, Küsel K, Singer ME, Sitte J, Torok T (2011) J Microbiol Methods 86(2):204–209
Article Google Scholar
Lee JY, Deininger RA (2004) Luminescence 19(1):31–36
Article CAS Google Scholar
Dudak FC, Boyaci IH (2008) J Rapid Methods Autom Microbiol 16(2):122–131
Article CAS Google Scholar
Bushon RN, Likirdopulos CA, Brady AMG (2009) Water Res 43(19):4940–4946
Article CAS Google Scholar
Garcia-Aljaro C, Bonjoch X, Blanch AR (2005) J Appl Microbiol 98(3):589–597
Article CAS Google Scholar
Muller EE, Grabow WOK, Ehlers MM (2003) Water SA 29(4):427–432
CAS Google Scholar
Shelton DR, Karns JS (2001) Appl Environ Microbiol 67(7):2908–2915
Article CAS Google Scholar
Schets FM, During M, Italiaander R, Heijnen L, Rutjes SA, van der Zwaluw WK, de Roda Husman AM (2005) Water Res 39(18):4485–4493
Article CAS Google Scholar
Enroth H, Engstrand L (1995) J Clin Microbiol 33(8):2162–2165
CAS Google Scholar
Yanez MA, Carrasco-Serrano C, Barbera VM, Catalan V (2005) Appl Environ Microbiol 71(7):3433–3441
Article CAS Google Scholar
Allegra S, Girardot F, Grattard F, Berthelot P, Helbig JH, Pozzetto B, Riffard S (2011) J Appl Microbiol 110(4):952–961
CAS Google Scholar
Goosen C (2001) Development of PCR-based detection assays for Legionella pneumophila in water. MSc dissertation, University of Pretoria
Whan L, Ball HJ, Grant IR, Rowe MT (2005) Appl Environ Microbiol 71(11):7107–7112
Article CAS Google Scholar
Whan L, Ball HJ, Grant IR, Rowe MT (2005) Lett Appl Microbiol 40(4):269–273
Article CAS Google Scholar
Stinear T, Davies JK, Jenkin GA, Hayman JA, Oppedisano F, Johnson PDR (2000) Environ Microbiol 66(8):3206–3213
Article CAS Google Scholar
Roberts B, Hirst R (1997) J Clin Microbiol 35(10):2709–2711
CAS Google Scholar
Ochiai Y, Takada C, Hosaka M (2005) Appl Environ Microbiol 71(2):898–903
Article CAS Google Scholar
Kuczynska E, Boyer DG, Shelton DR (2003) J Microbiol Methods 53(1):17–26
Article Google Scholar
Kuhn RC, Rock CM, Oshima KH (2002) Appl Environ Microbiol 68(4):2066–2070
Article CAS Google Scholar
Jiang JL, Alderisio KA, Singh A, Xiao LH (2005) Appl Environ Microbiol 71(3):1135–1141
Article CAS Google Scholar
Yang WL, Chen P, Villegas EN, Landy RB, Kanetsky C, Cama V, Dearen T, Schultz CL, Orndorff KG, Prelewicz GJ, Brown MH, Young KR, Xiao LH (2008) Appl Environ Microbiol 74(21):6495–6504
Article CAS Google Scholar
McCuin RM, Clancy JL (2006) J Water Health 4(4):437–452
Google Scholar
McCuin RM, Bukhari Z, Sobrinho J, Clancy JL (2001) J Microbiol Methods 45(2):69–76
Article CAS Google Scholar
Kim KJ, Jung HH, Lee K (2006) Biotechnol Bioprocess Eng 11(4):368–371
Article CAS Google Scholar
Zuckerman U, Tzipori S (2006) J Appl Microbiol 100(6):1220–1227
Article CAS Google Scholar
Ramadan Q, Christophe L, Teo W, Li SJ, Hua FH (2010) Anal Chim Acta 673(1):101–108
Article CAS Google Scholar
Zhang T, Xie X, Hu H, Song Y, Wu Q, Zong Z (2008) Front Environ Sci Eng China 2(3):380–384
Article Google Scholar
Khouja LB, Cama V, Xiao LH (2010) Parasitol Res 107(1):109–116
Article Google Scholar
Moulin L, Richard F, Stefania S, Goulet M, Gosselin S, Goncalves A, Rocher V, Paffoni C, Dumetre A (2010) Water Res 44:5222–5231
Article CAS Google Scholar
Castro-Hermida JA, Garcia-Presedo I, Almeida A, Gonzalez-Warleta M, Da Costa JMC, Mezo M (2008) Water Res 42(13):3528–3538
Article CAS Google Scholar
Sorel N, Guillot E, Thellier M, Accoceberry I, Datry A, Mesnard-Rouiller L, Miegeville M (2003) J Appl Microbiol 94(2):273–279
Article CAS Google Scholar
Hsu BM, Huang CP, Lai YC, Tai HS, Chung YC (2001) Parasitol Res 87(6):472–474
Article CAS Google Scholar
Mahbubani MH, Schaefer FW, Jones DD, Bej AK (1998) Curr Microbiol 36(2):107–113
Article CAS Google Scholar
Garcia A, Yanko W, Batzer G, Widmer G (2002) Water. Environ Res 6:541–544
Google Scholar
Bifulco JM, Schaefer FW III (1993) Appl Environ Microbiol 59(3):772–776
CAS Google Scholar
Dumetre A, Darde ML (2007) Parasitol Res 101(4):989–996
Article Google Scholar
Kindervater R, Kunnecke W, Schmid RD (1990) Anal Chim Acta 234(1):113–117
Article CAS Google Scholar
Min H, Qu YH, Li XH, Xie ZH, Wei YY, Jin LT (2007) Acta Chim Sin 65(20):2303–2308
CAS Google Scholar
Istarnboulie G, Andreescu S, Marty JL, Noguer T (2007) Biosens Bioelectron 23(4):506–512
Article CAS Google Scholar
Tan XC, Zhang JL, Tan SW, Zhao DD, Huang ZW, Mi Y, Huang ZY (2009) Electroanalysis 21(13):1514–1520
Article CAS Google Scholar
Komarek K, Hubka T, Safarikova M, Elcnerova M, Safarik I, Kujalova H (2008) Sci Pap Univ Pardubice Ser A 14:21–32
CAS Google Scholar
Ding J, Gao QA, Luo D, Shi ZG, Feng YQ (2010) J Chromatogr A 1217(47):7351–7358
Article CAS Google Scholar
Sun L, Chen L, Sun X, Du X, Yue Y, He D, Xu H, Zeng Q, Wang H, Ding L (2009) Chemosphere 77(10):1306–1312
Article CAS Google Scholar
Román IP, Chisvert A, Canals A (2011) J Chromatogr A 1218(18):2467–2475
Article CAS Google Scholar
Bai L, Mei B, Guo QZ, Shi ZG, Feng YQ (2010) J Chromatogr A 1217(47):7331–7336
Article CAS Google Scholar
Zhang SX, Niu HY, Cai YQ, Shi YL (2010) Anal Chim Acta 665(2):167–175
Article CAS Google Scholar
Guan Y, Jiang C, Hu CF, Jia L (2010) Talanta 83(2):337–343
Article CAS Google Scholar
Pardasani D, Kanaujia PK, Purohit AK, Shrivastava AR, Dubey DK (2011) Talanta 86:248–255
Article CAS Google Scholar
Mehdinia A, Roohi F, Jabbari A (2011) J Chromatogr A 1218(28):4269–4274
Article CAS Google Scholar
Mashhadizadeh MH, Karami Z (2011) J Hazard Mater 190(1–3):1023–1029
Article CAS Google Scholar
Parham H, Rahbar N (2009) Talanta 80(2):664–669
Article CAS Google Scholar
Standler A, Schatzl A, Klampfl CW, Buchberger W (2004) Microchim Acta 148(3–4):151–156
CAS Google Scholar
Brossa L, Marce RM, Borrull F, Pocurull E (2005) Chromatographia 61(1–2):61–65
Article CAS Google Scholar
Giordano A, Fernandez-Franzon M, Ruiz MJ, Font G, Pico Y (2009) Anal Bioanal Chem 393(6–7):1733–1743
Article CAS Google Scholar
Serodio P, Nogueira JMF (2005) Anal Bioanal Chem 382(4):1141–1151
Article CAS Google Scholar
Tan BLL, Hawker DW, Muller JF, Tremblay LA, Chapman HF (2008) Water Res 42(1–2):404–412
Article CAS Google Scholar
Silva ARM, Portugal FCM, Nogueira JMF (2008) J Chromatogr A 1209(1–2):10–16
CAS Google Scholar
Serodio P, Cabral MS, Nogueira JMF (2007) J Chromatogr A 1141(2):259–270
Article CAS Google Scholar
Rodil R, Moeder M (2008) J Chromatogr A 1178(1–2):9–16
CAS Google Scholar
Quintana JB, Rodil R, Muniategui-Lorenzo S, Lopez-Mahia P, Prada-Rodriguez D (2007) J Chromatogr A 1174(1–2):27–39
CAS Google Scholar
Popp P, Bauer C, Wennrich L (2001) Anal Chim Acta 436(1):1–9
Article CAS Google Scholar
Chen LG, Wang T, Tong J (2011) Trends Anal Chem 30(7):1095–1108
Article CAS Google Scholar
Luo YB, Ma Q, Feng YQ (2010) J Chromatogr A 1217(22):3583–3589
Article CAS Google Scholar
Alcudia-Leon MC, Lucena R, Cardenas S, Valcarcel M (2009) Anal Chem 81:8957–8961
Article CAS Google Scholar
Luo YB, Cheng JS, Ma Q, Feng YQ, Li JH (2011) Anal Methods 3:92–98
Article CAS Google Scholar

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Acknowledgment

This research was supported by the Grant Agency of the Czech Republic (project no. P503/11/2263).

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Department of Nanobiotechnology, Institute of Nanobiology and Structural Biology of GCRC, Na Sadkach 7, 370 05, Ceske Budejovice, Czech Republic
Ivo Safarik, Katerina Horska & Mirka Safarikova
Regional Centre of Advanced Technologies and Materials, Palacky University, Slechtitelu 11, 783 71, Olomouc, Czech Republic
Ivo Safarik
Department of Biochemistry, Faculty of Science, Palacky University, Slechtitelu 11, 783 71, Olomouc, Czech Republic
Kristyna Pospiskova

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Ivo Safarik
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Safarik, I., Horska, K., Pospiskova, K. et al. Magnetic techniques for the detection and determination of xenobiotics and cells in water. Anal Bioanal Chem 404, 1257–1273 (2012). https://doi.org/10.1007/s00216-012-6056-x

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Received: 15 February 2012
Revised: 15 April 2012
Accepted: 16 April 2012
Published: 12 May 2012
Issue Date: September 2012
DOI: https://doi.org/10.1007/s00216-012-6056-x

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Magnetic techniques for the detection and determination of xenobiotics and cells in water

Abstract

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Magnetic techniques for the detection and determination of xenobiotics and cells in water

Abstract

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Application of Magnetic Nanoparticles for Removal of Pesticides from Environmental Samples Prior to Instrumental Analysis

Magnetic adsorbents based on iron oxide nanoparticles for the extraction and preconcentration of organic compounds

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