A baseline drift detrending technique for fast scan cyclic voltammetry

DeWaele, Mark; Oh, Yoonbae; Park, Cheonho; Kang, Yu Min; Shin, Hojin; Blaha, Charles D.; Bennet, Kevin E.; Kim, In Young; Lee, Kendall H.; Jang, Dong Pyo

doi:10.1039/c7an01465a

Cited by 25 publications

(35 citation statements)

References 17 publications

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“…DOPAC and AA are known for low or non-adsorptive species at CFMs resulting in low sensitivity and fast equilibrium states in multiple pulses (Atcherley et al, 2013). Transient local pH changes in the brain is an accompanying phenomenon with neuronal activity and it has been a major contributor to capacitive background drift in voltammetry (DeWaele et al, 2017). The features of M-CSWV allow the removal of capacitive charging currents which includes the background drift caused by pH changes.…”

Section: Resultsmentioning

confidence: 99%

Tracking tonic dopamine levels in vivo using multiple cyclic square wave voltammetry

Heien

Park

et al. 2018

Biosensors and Bioelectronics

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119

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For over two decades, fast-scan cyclic voltammetry (FSCV) has served as a reliable analytical method for monitoring dopamine release in near real-time in vivo. However, contemporary FSCV techniques have been limited to measure only rapid (on the order of seconds, i.e. phasic) changes in dopamine release evoked by either electrical stimulation or elicited by presentation of behaviorally salient stimuli, and not slower changes in the tonic extracellular levels of dopamine (i.e. basal concentrations). This is because FSCV is inherently a differential method that requires subtraction of prestimulation tonic levels of dopamine to measure phasic changes relative to a zeroed baseline. Here, we describe the development and application of a novel voltammetric technique, multiple cyclic square wave voltammetry (M-CSWV), for analytical quantification of tonic dopamine concentrations in vivo with relatively high temporal resolution (10 s). M-CSWV enriches the electrochemical information by generating two dimensional voltammograms which enable high sensitivity (limit of detection, 0.17 nM) and selectivity against ascorbic acid, and 3,4-dihydroxyphenylacetic acid (DOPAC), including changes in pH. Using M-CSWV, a tonic dopamine concentration of 120 ± 18 nM (n = 7 rats, ± SEM) was determined in the striatum of urethane anethetized rats. Pharmacological treatments to elevate dopamine by selectively inhibiting dopamine reuptake and to reduce DOPAC by inhibition of monoamine oxidase supported the selective detection of dopamine in vivo. Overall, M-CSWV offers a novel voltammetric technique to quantify levels and monitor changes in tonic dopamine concentrations in the brain to further our understanding of the role of dopamine in normal behavior and neuropsychiatric disorders.

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Section: Resultsmentioning

confidence: 99%

Tracking tonic dopamine levels in vivo using multiple cyclic square wave voltammetry

Heien

Park

et al. 2018

Biosensors and Bioelectronics

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119

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“…Previously, we have demonstrated detection of exogenously administered MT in anesthetized mouse brain using square wave voltammetry (SWV) (Castagnola et al, 2020). Fast scan cyclic voltammetry (FSCV) is an electroanalytical technique with higher temporal resolution (usually 100 ms) (Robinson et al, 2003;Swamy and Venton, 2007;Wood and Hashemi, 2013;Oh et al, 2016;Ou et al, 2019;Puthongkham and Venton, 2020) and, when used in combination with carbon fiber electrodes (CFEs), can achieve detection of sub-second fluctuations in neurotransmitter concentrations in real-time in the brain (Keithley et al, 2011;Wood and Hashemi, 2013;Nguyen and Venton, 2014;Mark DeWaele et al, 2017;Castagnola et al, 2018;Puthongkham and Venton, 2020). However, being primarily a background subtraction technique, FSCV measurements are limited to short time intervals (<90 s) due to the instability of the background currents, i.e., background drifting (Oh et al, 2016;Oh et al, 2016;Mark DeWaele et al, 2017;Meunier et al, 2019).…”

Section: Introductionmentioning

confidence: 99%

“…Fast scan cyclic voltammetry (FSCV) is an electroanalytical technique with higher temporal resolution (usually 100 ms) (Robinson et al, 2003;Swamy and Venton, 2007;Wood and Hashemi, 2013;Oh et al, 2016;Ou et al, 2019;Puthongkham and Venton, 2020) and, when used in combination with carbon fiber electrodes (CFEs), can achieve detection of sub-second fluctuations in neurotransmitter concentrations in real-time in the brain (Keithley et al, 2011;Wood and Hashemi, 2013;Nguyen and Venton, 2014;Mark DeWaele et al, 2017;Castagnola et al, 2018;Puthongkham and Venton, 2020). However, being primarily a background subtraction technique, FSCV measurements are limited to short time intervals (<90 s) due to the instability of the background currents, i.e., background drifting (Oh et al, 2016;Oh et al, 2016;Mark DeWaele et al, 2017;Meunier et al, 2019). This background drift can be attributed to a number of factors, comprising the changes occurring at the carbon surface itself-i.e., chemical reaction of electrode material, non-specific absorption of proteins, deposition of byproducts of electrochemical reactions (Harreither et al, 2016;Hensley et al, 2018;Puthongkham and Venton, 2020)-and changes in the surrounding chemical and biological neuroenvironment-i.e., pH and local blood flow fluctuations (Mark DeWaele et al, 2017;Roberts and Sombers, 2018;Meunier et al, 2019).…”

Section: Introductionmentioning

confidence: 99%

“…However, being primarily a background subtraction technique, FSCV measurements are limited to short time intervals (<90 s) due to the instability of the background currents, i.e., background drifting (Oh et al, 2016;Oh et al, 2016;Mark DeWaele et al, 2017;Meunier et al, 2019). This background drift can be attributed to a number of factors, comprising the changes occurring at the carbon surface itself-i.e., chemical reaction of electrode material, non-specific absorption of proteins, deposition of byproducts of electrochemical reactions (Harreither et al, 2016;Hensley et al, 2018;Puthongkham and Venton, 2020)-and changes in the surrounding chemical and biological neuroenvironment-i.e., pH and local blood flow fluctuations (Mark DeWaele et al, 2017;Roberts and Sombers, 2018;Meunier et al, 2019). To predict the noise and extract the signal contribution from the drifting background, signal filtering (Mark DeWaele et al, 2017;Puthongkham and Venton, 2020), multivariate analyses (Hermans et al, 2008;Meunier et al, 2019), and waveform manipulations combined with mathematical techniques (Oh et al, 2016;Meunier et al, 2019) have been investigated, but they require training sets (Johnson et al, 2016;Puthongkham and Venton, 2020) and/or data preprocessing (Puthongkham and Venton, 2020).…”

Section: Introductionmentioning

confidence: 99%

“…This background drift can be attributed to a number of factors, comprising the changes occurring at the carbon surface itself-i.e., chemical reaction of electrode material, non-specific absorption of proteins, deposition of byproducts of electrochemical reactions (Harreither et al, 2016;Hensley et al, 2018;Puthongkham and Venton, 2020)-and changes in the surrounding chemical and biological neuroenvironment-i.e., pH and local blood flow fluctuations (Mark DeWaele et al, 2017;Roberts and Sombers, 2018;Meunier et al, 2019). To predict the noise and extract the signal contribution from the drifting background, signal filtering (Mark DeWaele et al, 2017;Puthongkham and Venton, 2020), multivariate analyses (Hermans et al, 2008;Meunier et al, 2019), and waveform manipulations combined with mathematical techniques (Oh et al, 2016;Meunier et al, 2019) have been investigated, but they require training sets (Johnson et al, 2016;Puthongkham and Venton, 2020) and/or data preprocessing (Puthongkham and Venton, 2020). On the other hand, different electrochemical procedures have been shown to restore the sensitivity of the carbon surface and preserve their current stability and sensitivity both in vitro and in vivo (Hafizi et al, 1990;Heien et al, 2003;Takmakov et al, 2010), suggesting a potential alternative to stabilize the FSCV current background.…”

Section: Introductionmentioning

confidence: 99%

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Real-Time Fast Scan Cyclic Voltammetry Detection and Quantification of Exogenously Administered Melatonin in Mice Brain

Castagnola

Robbins

Woeppel

et al. 2020

Front. Bioeng. Biotechnol.

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Melatonin (MT) has been recently considered an excellent candidate for the treatment of sleep disorders, neural injuries, and neurological diseases. To better investigate the actions of MT in various brain functions, real-time detection of MT concentrations in specific brain regions is much desired. Previously, we have demonstrated detection of exogenously administered MT in anesthetized mouse brain using square wave voltammetry (SWV). Here, for the first time, we show successful detection of exogenous MT in the brain using fast scan cyclic voltammetry (FSCV) on electrochemically pre-activated carbon fiber microelectrodes (CFEs). In vitro evaluation showed the highest sensitivity (28.1 nA/μM) and lowest detection limit (20.2 ± 4.8 nM) ever reported for MT detection at carbon surface. Additionally, an extensive CFE stability and fouling assessment demonstrated that a prolonged CFE pre-conditioning stabilizes the background, in vitro and in vivo, and provides consistent CFE sensitivity over time even in the presence of a high MT concentration. Finally, the stable in vivo background, with minimized CFE fouling, allows us to achieve a drift-free FSCV detection of exogenous administered MT in mouse brain over a period of 3 min, which is significantly longer than the duration limit (usually < 90 s) for traditional in vivo FSCV acquisition. The MT concentration and dynamics measured by FSCV are in good agreement with SWV, while microdialysis further validated the concentration range. These results demonstrated reliable MT detection using FSCV that has the potential to monitor MT in the brain over long periods of time.

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