Abstract
During conventional microdialysis, dialysate samples are periodically analysed offline by lab bench instruments. This approach is inadequate for some applications, especially those that require high temporal resolution and rapid data collection.
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References
Alaejos MS, Montelongo FJG (2004) Application of amperometric biosensors to the determination of vitamins and α-amino acids. Chem Rev 104:3239–3265
Ballerstadt R, Schultz JS (1996) Sensor methods for use with microdialysis and ultrafiltration. Adv Drug Deliv Rev 21:225–238
Blazkiewicz P, Blazkiewicz K, Verhaege A, Anissimov YG, Roberts MS, Zvyagin AV (2006) Dialysis-assited fiber optic spectroscopy for in situ biomedical sensing. J Biomed Opt 11
Böhm S, Olthuis W, Bergveld P (2000) Micromachined double lumen microdialysis probe connector with incorporated sensor for on-line sampling. Sens Actuators B Chem 63:201–208
Feuerstein D, Parker KH, Boutelle MG (2009) Practical methods for noise removal: applications to spikes, non-stationary quasi-periodic noise and baseline drift. Anal Chem 81:4987–4994
Gramsbergen JB, Cumming P (2007) Serotonin mediates rapid changes of striatal glucose and lactate metabolism after systemic 3, 4-methylenedioxymethamphetamine (MDMA, “Ecstasy”) administration in awake rats. Neurochem Int 51:8–15
Jakubowska M (2011) Signal Processing in Electrochemistry. Electroanalysis 23:553–572
Jones DA, Parkin MC, Langemann H, Landolt H, Hopwood SE, Strong AJ, Boutelle MG (2002) On-line monitoring in neurointensive care: enzyme-based electrochemical assay for simultaneous, continuous monitoring of glucose and lactate from critical care patients. J Electroanal Chem 538:243–252
Malecha K, Pijanowska DG, Golonka LJ, Kurek P (2011) Low temperature co-fired ceramic (LTCC)-based biosensor for continuous glucose monitoring. Sens Actuators B Chem 155:923–929
Obrenovitch TP, Zilkha E (2001) Microdialysis coupled to online enzymatic assays. Methods 23:63–71
Parkin MC, Hopwood SE, Strong AJ, Boutelle MG (2003) Resolving dynamic changes in brain metabolism using biosensors and on-line microdialysis. Trends Anal Chem 22:487–497
Pasic A, Koehler H, Schaupp L, Pieber TR, Klimant I (2006) Fiber-optic flow-through sensor for online monitoring of glucose. Anal Bioanal Chem 386:1293–1302
Pasic A, Koehler H, Klimant I, Schaupp L (2007) Miniaturized fiber-optic hybrid sensor for continuous glucose monitoring in subcutaneous tissue. Sens Actuators B Chem 122:60–68
Petrou PS, Moser I, Jobst G (2002) BioMEMS device with integrated microdialysis probe and biosensor array. Biosens Bioelectron 17:859–865
Petrou PS, Moser I, Jobst G (2003) Microdevice with integrated dialysis probe and biosensor array for continuous multi-analyte monitoring. Biosens Bioelectron 18:613–619
Ricci F, Caprio F, Poscia A, Valgimigli F, Messeri D, Lepori E, Dall’Oglio G, Palleschi G, Moscone D (2007) Toward continuous glucose monitoring with planar modified biosensors and microdialysis. Study of temperature, oxygen dependence and in vivo experiment. Biosens Bioelectron 22:2032–2039
Rogers M, Leong C, Niu X, de Mello A, Parker KH, Boutelle MG (2011) Optimisation of a microfluidic analysis chamber for the placement of microelectrodes. Phys Chem Chem Phys 13:5298–5303
Seo JH, Leow PL, Cho SH, Lim HW, Kim JY, Patel BA, Park JG, O’Hare D (2009) Development of inlaid electrodes for whole column electrochemical detection in HPLC. Lab Chip Miniaturisation Chem Biol 9:2238–2244
Tseng YT, Yang CS, Tseng FG (2009) A perfusion-based micro opto-fluidic system (PMOFS) for continuously in situ immune sensing. Lab Chip Miniaturisation Chem Biol 9:2673–2682
Wang M, Roman GT, Perry ML, Kennedy RT (2009) Microfluidic chip for high efficiency electrophoretic analysis of segmented flow from a microdialysis probe and in vivo chemical monitoring. Anal Chem 81:9072–9078
Yao T, Okano G (2008) Simultaneous determination of L-glutamate, acetylcholine and dopamine in rat brain by a flow-injection biosensor system with microdialysis sampling. Anal Sci 24:1469–1473
Zahn JD, Trebotich D, Liepmann D (2005) Microdialysis micro needles for continuous medical monitoring. Biomed Microdevices 7:59–69
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Córcoles, E.P., Boutelle, M.G. (2013). Microdialysis Coupled with Biosensors. In: Biosensors and Invasive Monitoring in Clinical Applications. SpringerBriefs in Applied Sciences and Technology. Springer, Heidelberg. https://doi.org/10.1007/978-3-319-00360-3_9
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DOI: https://doi.org/10.1007/978-3-319-00360-3_9
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