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Leva-Bueno J, Peyman SA, Millner PA. A review on impedimetric immunosensors for pathogen and biomarker detection. Med Microbiol Immunol 2020; 209:343-362.Leva-BuenoJPeymanSAMillnerPAA review on impedimetric immunosensors for pathogen and biomarker detectionMed Microbiol Immunol202020934336210.1007/s00430-020-00668-0Search in Google Scholar
Brosel-Oliu S, Abramova N, Uria N, Bratov A. Impedimetric transducers based on interdigitated electrode arrays for bacterial detection -a review. Anal Chim Acta. 2019; 1088:1-19.Brosel-OliuSAbramovaNUriaNBratovAImpedimetric transducers based on interdigitated electrode arrays for bacterial detection -a reviewAnal Chim Acta2019108811910.1016/j.aca.2019.09.026Search in Google Scholar
Zhang F, Jin T, Hu Q, He P. Distinguishing skin cancer cells and normal cells using electrical spectroscopy. J Electroanal Chem, 2018; 823:531-536.ZhangFJinTHuQHePDistinguishing skin cancer cells and normal cells using electrical spectroscopyJ Electroanal Chem201882353153610.1016/j.jelechem.2018.06.021Search in Google Scholar
Valero A, Braschler T, Renaud P. A unified approach to dielectric single cell analysis: Impedance and dielectrophoretic force spectroscopy. Lab Chip, 2010; 10:2216-2225.ValeroABraschlerTRenaudPA unified approach to dielectric single cell analysis: Impedance and dielectrophoretic force spectroscopyLab Chip2010102216222510.1039/c003982aSearch in Google Scholar
Cranfield C, Carne S, Martinac B, Cornell B. The assembly and use of tethered bilayer lipid membranes (tBLMs). Methods Mol Biol, 2015; 1232: 1232-1245.CranfieldCCarneSMartinacBCornellBThe assembly and use of tethered bilayer lipid membranes (tBLMs)Methods Mol Biol201512321232124510.1007/978-1-4939-1752-5_4Search in Google Scholar
Maccarini M, Gayet L, Alcaraz JP, Liguoria L, Stidder B, Cortès S, Watkins E, Lenormand JL, Martin DK. Function of recombinant OprF from Pseudomonas aeruginosa stably incorporated in supported lipid bilayers. Langmuir. 2017; 33:9988-9996.MaccariniMGayetLAlcarazJPLiguoriaLStidderBCortèsSWatkinsELenormandJLMartinDKFunction of recombinant OprF from Pseudomonas aeruginosa stably incorporated in supported lipid bilayersLangmuir2017339988999610.1021/acs.langmuir.7b01731Search in Google Scholar
Bürgel SC, Escobedo C, Haandbæk N, Hierlemann A. On-chip electroporation and impedance spectroscopy of single-cells. Sens Actuators B. 2015; 210:82-90.BürgelSCEscobedoCHaandbækNHierlemannAOn-chip electroporation and impedance spectroscopy of single-cellsSens Actuators B2015210829010.1016/j.snb.2014.12.016Search in Google Scholar
Benson K, Cramer S, Galla H-J. Impedance-based cell monitoring: barrier properties and beyond. Fluids Barriers CNS, 2013; 10:5.BensonKCramerSGallaH-JImpedance-based cell monitoring: barrier properties and beyondFluids Barriers CNS201310510.1186/2045-8118-10-5Search in Google Scholar
Czulkies BA, Mastroianni J, Lutz L, Lang S, Schwan C, Schmidt G, Lassmann S, Zeiser R, Aktories K, Papatheodorou O. Loss of LSR affects epithelial barrier integrity and tumor xenograft growth of CaCo-2 cells. Oncotarget. 2017; 8(23):37009-37022.CzulkiesBAMastroianniJLutzLLangSSchwanCSchmidtGLassmannSZeiserRAktoriesKPapatheodorouOLoss of LSR affects epithelial barrier integrity and tumor xenograft growth of CaCo-2 cellsOncotarget2017823370093702210.18632/oncotarget.10425Search in Google Scholar
Gawad S, Cheung K, Seger U, Bertsch A, Renaud P. Dielectric spectroscopy in a micromachined flow cytometer: theoretical and practical considerations. Lab Chip, 2014; 4:241-251.GawadSCheungKSegerUBertschARenaudPDielectric spectroscopy in a micromachined flow cytometer: theoretical and practical considerationsLab Chip2014424125110.1039/b313761aSearch in Google Scholar
Vykoukal J, Vykoukal DM, Sharma S, Bescker FF, Gascoyne PRC. Dielectrically addressable microspheres engineered using self-assembled monolayers. Langmuir, 2003; 29:2425-2433.VykoukalJVykoukalDMSharmaSBesckerFFGascoynePRCDielectrically addressable microspheres engineered using self-assembled monolayersLangmuir2003292425243310.1021/la0264318Search in Google Scholar
Wiedman G, Herman K, SearsonP, Wimley WC,Hristova K. The electrical response of bilayers to the bee venom toxin melittin: evidence for transient bilayer permeabilization. Biochim Biophys Acta. 2013; 1828:1357-1364.WiedmanGHermanKSearsonPWimleyWCHristovaKThe electrical response of bilayers to the bee venom toxin melittin: evidence for transient bilayer permeabilizationBiochim Biophys Acta201318281357136410.1016/j.bbamem.2013.01.021Search in Google Scholar
Andersson J, Fuller MA, Wood K, Holt SA, Köper I. A tethered bilayer lipid membrane that mimics microbial membranes. Phys Chem Chem Phys, 2018; 20:12958-12969.AnderssonJFullerMAWoodKHoltSAKöperIA tethered bilayer lipid membrane that mimics microbial membranesPhys Chem Chem Phys201820129581296910.1039/C8CP01346BSearch in Google Scholar
Zhao Y, Liu Q, Sun H, Chen D, Li Z, Fan B, George J, Xue C, Cui Z, Wang J, Chen J. Electrical property characterization of neural stem cells in differentiation. PLos ONE. 2016; 11:e0158044.ZhaoYLiuQSunHChenDLiZFanBGeorgeJXueCCuiZWangJChenJElectrical property characterization of neural stem cells in differentiationPLos ONE201611e015804410.1371/journal.pone.0158044Search in Google Scholar
Tang VW, Goodenough DA. Paracellular ion channel at the tight junction. Biophys J, 2003; 84:1660-1673.TangVWGoodenoughDAParacellular ion channel at the tight junctionBiophys J2003841660167310.1016/S0006-3495(03)74975-3Search in Google Scholar
Singh AB, Harris RC. Epidermal growth factor receptor activation differentially regulates claudin expression and enhances transepithelial resistance in Madin-Darby Canine Kidney Cells J Biol Chem, 2004; 279:3543-3552.SinghABHarrisRCEpidermal growth factor receptor activation differentially regulates claudin expression and enhances transepithelial resistance in Madin-Darby Canine Kidney CellsJ Biol Chem20042793543355210.1074/jbc.M308682200Search in Google Scholar
