In recent years, the outbreaks of foodborne diseases caused by pathogenic bacteria have made considerable economic losses and shown a threat to public health. The key to prevent and control these diseases is fast screening of pathogenic bacteria, which is usually performed with three procedures: sample collection, bacteria separation and bacteria detection. For sample collection, the national standard methods are often employed. For bacteria detection, currently available methods such as Polymerase Chain Reaction and Enzyme Linked Immuno-Sorbent Assay are often used. For bacteria separation, traditional methods such as filtration and centrifugation are not capable to specifically separate the target bacteria. However, food samples are very complicated and require efficient pretreatment for bacteria separation and concentration to achieve accurate and reliable results. The conventional immune magnetic separation method can be used to specifically separate the bacteria, but it still cannot meet the requirements for food sample pretreatment due to very low concentration of target bacteria in food. Therefore, this study developed an automatic and efficient immuno-separator of foodborne bacteria based on magnetophoresis and magnetic mixing, and E. coli O157:H7 was used as research model. A magnetic mixer was applied to facilitate the immunoreaction between the immune magnetic nanoparticles and the target bacteria cells, and a magnetophoretic separation tubing was utilized for magnetophoretic separation of the magnetic bacteria. Under the optimal mixing time of 20 min and the optimal flow rate of 50 µL/min, the separation efficiency of E. coli O157:H7 could be more than 90%, showing that the developed immuno-separator is promising to be applied for efficient separation of foodborne bacteria and can be easily extended for separation of other biological targets by using their specific antibodies.
Keywords: foodborne bacteria, immuno-separator, bacteria separation, magnetophoresis, magnetic mixing, magnetic nanoparticles
DOI: 10.25165/j.ijabe.20191205.3434

Citation: Wang Y H, Cai G Z, Wang M H, Lin J H. Development of automatic and efficient immuno-separator of foodborne pathogenic bacteria using magnetophoresis and magnetic mixing. Int J Agric & Biol Eng, 2019; 12(5): 167–172.

foodborne bacteria, immuno-separator, bacteria separation, magnetophoresis, magnetic mixing, magnetic nanoparticles

WHO. WHO estimates of the global burden of foodborne diseases: foodborne disease burden epidemiology reference group 2007-2015: World Health Organization, 2015; 72p.

Mclinden T, Sargeant J M, Thomas M K, Papadopoulos A, Fazil A. Component costs of foodborne illness: a scoping review. BMC Public Health, 2014; 14(1): 509.

Botes M, De Kwaadsteniet M, Cloete T E. Application of quantitative PCR for the detection of microorganisms in water. Anal Bioanal Chem, 2013; 405(1): 91–108.

Tachibana H, Saito M, Shibuya S, Tsuji K, Miyagawa N, Yamanaka K, et al. On-chip quantitative detection of pathogen genes by autonomous microfluidic PCR platform. Biosens Bioelectron, 2015; 74: 725–730.

Shih C-M, Chang C-L, Hsu M-Y, Lin J-Y, Kuan C-M, Wang H-K, et al. Paper-based ELISA to rapidly detect Escherichia coli. Talanta, 2015; 145: 2–5.

Postollec F, Falentin H, Pavan S, Combrisson J, Sohier D. Recent advances in quantitative PCR (qPCR) applications in food microbiology. Food Microbiol. 2011; 28(5): 848–861.

Pappert G, Rieger M, Niessner R, Seidel M. Immunomagnetic nanoparticle-based sandwich chemiluminescence-ELISA for the enrichment and quantification of E. coli. Microchim Acta, 2010; 168(1-2): 1–8.

Ma H, Hsiao B S, Chu B. Functionalized electrospun nanofibrous microfiltration membranes for removal of bacteria and viruses. J Membrane Sci, 2014; 452: 446–452.

Kroll S, Treccani L, Rezwan K, Grathwohl G. Development and characterisation of functionalised ceramic microtubes for bacteria filtration. J Membrane Sci, 2010; 365(1): 447–55.

Cho I-H, Bhandari P, Patel P, Irudayaraj J. Membrane filter-assisted surface enhanced Raman spectroscopy for the rapid detection of E. coli O157: H7 in ground beef. Biosens Bioelectron, 2015; 64: 171–176.

Christner M, Rohde H, Wolters M, Sobottka I, Wegscheider K, Aepfelbacher M. Rapid identification of bacteria from positive blood culture bottles by use of matrix-assisted laser desorption-ionization time of flight mass spectrometry fingerprinting. J Clin Microbiol, 2010; 48(5): 1584–1591.

Hu Y H, Wang C C, Bai B, Li M T, Wang R H, Li Y B. Detection of Staphylococcus Aureus using quantum dots as fluorescence labels. Int J Agric & Biol Eng, 2014; 7(1): 77–83.

Chen P, Li Y, Cui T, Ruan R. Nanoparticles based sensors for rapid detection of foodborne pathogens. Int J Agric & Biol Eng, 2013; 6(1): 28–35.

Lee W, Kwon D, Chung B, Jung G-Y, Au A, Folch A, et al. Ultrarapid detection of pathogenic bacteria using a 3D immunomagnetic flow assay. Anal Chem, 2014; 86(13): 6683–6688.

Ditsch A, Lindenmann S, Laibinis P, Wang D, Hatton T. High-gradient magnetic separation of magnetic nanoclusters. Ind Eng Chem Res, 2005; 44(17): 6824–6836.

Gómez-Pastora J, Xue X, Karampelas I H, Bringas E, Furlani E-P, Ortiz, I. Analysis of separators for magnetic beads recovery: From large systems to multifunctional microdevices. Sep Purif Technol, 2017; 172: 16–31.

Wang Y, Li Y, Wang R, Wang M, Lin J. Three-dimensional printed magnetophoretic system for the continuous flow separation of avian influenza H5N1 viruses. J Sep Sci, 2017; 40: 1540–1547.

Chen Q, Wang D, Cai G, Xiong Y, Li Y, Wang M, et al. Fast and sensitive detection of foodborne pathogen using electrochemical impedance analysis, urease catalysis and microfluidics. Biosens Bioelectron, 2016; 86: 770–776.

Liu R H, Stremler M A, Sharp K V, Olsen M G, Santiago J G, Adrian R J, et al. Passive mixing in a three-dimensional serpentine microchannel. J Microelectromech S, 2000; 9(2): 190–197.

Lin J, Li M, Li Y, Chen Q. A high gradient and strength bioseparator with nano-sized immunomagnetic particles for specific separation and efficient concentration of E. coli O157: H7. J Magn Magn Mater, 2015; 378: 206–213.

Xiong Q, Cui X, Saini JK, Liu D, Shan S, Jin Y, et al. Development of an immunomagnetic separation method for efficient enrichment of Escherichia coli O157: H7. Food Control, 2014; 37: 41–5.

Wang Y, Chen Q, Gan C, Yan B, Han Y, Lin J. A Review on Magnetophoretic Immunoseparation. J Nanosci Nanotechno, 2016; 16(3): 2152–2163.

Suwa M, Watarai H. Magnetoanalysis of micro/nanoparticles: A review. Anal Chim Acta, 2011; 690(2): 137–147.

Huang H, Ruan C, Lin J, Li M, Cooney L M, Oliver WF, et al. Magnetic nanoparticle based magnetophoresis for efficient separation of E. coli O157: H7. Trans ASABE, 2011; 54(3): 1015–1024.

Lee J-J, Jeong K J, Hashimoto M, Kwon A H, Rwei A, Shankarappa S A, et al. Synthetic ligand-coated magnetic nanoparticles for microfluidic bacterial separation from blood. Nano Lett, 2013; 14(1): 1–5.

Baek C, Kim H Y, Na D, Min J. A microfluidic system for the separation and detection of E. coli O157: H7 in soil sample using ternary interactions between humic acid, bacteria, and a hydrophilic surface. Sensor Actuat B: Chem, 2015; 208: 238–244.

Zhang B H, Wang R H, Wang Y X, Li Y B. LabVIEW-based impedance biosensing system for detection of avian influenza virus. Int J Agric & Biol Eng, 2016; 9(4): 116–122.

Chang W H, Wang C H, Lin C L, Wu J-J, Lee M S, Lee G-B. Rapid detection and typing of live bacteria from human joint fluid samples by utilizing an integrated microfluidic system. Biosens Bioelectron, 2015; 66: 148–54.