Polyethylenimine Carbon Nanotube Fiber Electrodes for Enhanced Detection of Neurotransmitters

Zestos, Alexander G.; Jacobs, Christopher B.; Trikantzopoulos, Elefterios; Ross, Ashley E.; Venton, B. Jill

doi:10.1021/ac5003273

Cited by 85 publications

(104 citation statements)

References 36 publications

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“…Our group has used polyethylenimine (PEI)-CNT fiber electrodes for enhanced detection of neurotransmitters. [68] Wet spinning CNTs into fibers was performed using PEI as a coagulating polymer. Compared with poly(vinyl alcohol) (PVA) CNT fiber-electrodes[69], the PEI-CNT fiber electrodes had lower overpotentials and better detection limits for dopamine, likely because they were more conductive.…”

Section: 0 Neurotransmitters/neurochemicalsmentioning

confidence: 99%

“…[68] Figure 3 shows that the current did not decrease for repeated injections of 1 µM serotonin at PEI-CNT fiber microelectrodes, in contrast to carbon-fiber microelectrodes, which had a 50% decrease after 25 injections. The resistance to serotonin fouling at CNT based electrodes is often attributed to the higher density of edge plane sites, but the addition of oxygen groups, while maintaining a high sp 2 conjugation, may also help reduce fouling.…”

Section: 0 Neurotransmitters/neurochemicalsmentioning

confidence: 99%

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Recent trends in carbon nanomaterial-based electrochemical sensors for biomolecules: A review

Yang

Denno

Pyakurel

et al. 2015

Analytica Chimica Acta

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473

263

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Carbon nanomaterials are advantageous for electrochemical sensors because they increase the electroactive surface area, enhance electron transfer, and promote adsorption of molecules. Carbon nanotubes (CNTs) have been incorporated into electrochemical sensors for biomolecules and strategies have included the traditional dip coating and drop casting methods, direct growth of CNTs on electrodes and the use of CNT fibers and yarns made exclusively of CNTs. Recent research has also focused on utilizing many new types of carbon nanomaterials beyond CNTs. Forms of graphene are now increasingly popular for sensors including reduced graphene oxide, carbon nanohorns, graphene nanofoams, graphene nanorods, and graphene nanoflowers. In this review, we compare different carbon nanomaterial strategies for creating electrochemical sensors for biomolecules. Analytes covered include neurotransmitters and neurochemicals, such as dopamine, ascorbic acid, and serotonin; hydrogen peroxide; proteins, such as biomarkers; and DNA. The review also addresses enzyme-based electrodes that are used to detect non-electroactive species such as glucose, alcohols, and proteins. Finally, we analyze some of the future directions for the field, pointing out gaps in fundamental understanding of electron transfer to carbon nanomaterials and the need for more practical implementation of sensors.

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Section: 0 Neurotransmitters/neurochemicalsmentioning

confidence: 99%

Section: 0 Neurotransmitters/neurochemicalsmentioning

confidence: 99%

Recent trends in carbon nanomaterial-based electrochemical sensors for biomolecules: A review

Yang

Denno

Pyakurel

et al. 2015

Analytica Chimica Acta

Self Cite

473

263

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“…89 In particular, fabricating CNT fibers directly into electrodes in a manner similar to CFMEs dramatically simplifies the electrode fabrication process and improves the reproducibility. 90 The first electrochemical application of a CNT fiber sensor was reported in 2003 91 and CNT fiber microelectrodes have been developed for dopamine detection using DPV 92 , chronoamperometry 89 , and FSCV. 93,94 Two distinct routes have been developed for manufacturing CNT fibers: wet-spinning a suspension of CNTs into a bath or direct spinning a fiber from a CNT forest.…”

Section: Carbon Nanotube-fiber Microelectrodesmentioning

confidence: 99%

“…Our group has successfully applied PEI/CNT fiber microelectrodes for in vivo monitoring of dopamine and serotonin in brain slice. 90 Thin, uniform fibers were fabricated by wet spinning CNTs into fibers using PEI as a coagulating polymer. In comparison to PVA/CNT fibers, PEI/CNT fibers have better LODs of dopamine (4.7 ± 0.2 nM) and lower overpotential.…”

Section: Carbon Nanotube-fiber Microelectrodesmentioning

confidence: 99%

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Development of Electrochemical Microsensors for in vivo Neurotransmitter Detection

Yang

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Everything that happens in our body and all the interactions we have with the outside world are controlled by our brain. Studies of neurotransmitters are critical for a better understanding of how our brain works. Fast-scan cyclic voltammetry (FSCV) is the most popular electrochemical technique for the in vivo detection of electroactive neurotransmitters and neurochemicals with high temporal resolution. To further improve the detection selectivity, sensitivity, and spatial resolution, carbon nanomaterial based microelectrodes are applied to enhance FSCV for the neurotransmitters detection. In this thesis, I introduce and discuss synthesis and fabrication of several novel carbon nanomaterials, the effect of different surface modifications, and their applications for in vivo neurotransmitter detection.Chapter 1 covers the recent advances in carbon nanomaterial based electrochemical sensors for direct neurotransmitter detection. First, strategies are compared to incorporate carbon nanomaterials into electrochemical sensors for neurotransmitter detection. Second, several new applications are highlighted as well as studies to address the remaining challenges for implementation. Chapters 2-5 describe new carbon nanomaterials and surface treatments for enhanced neurotransmitter detection. The direct growth of CNTs on metal wires is introduced in Chapter 2. Chapter 3 and Chapter 4 introduce three surface modification methods, laser treatment, O2 plasma etching, and anti-static gun treatment, to improve sensitivity, selectivity, and bio-fouling properties on CNT yarn microelectrodes. In Chapter 5, three different types of CNT fiber materials, CNT yarn, PEI/CNT fiber, and CA/CNT fiber, are introduced and compared for the detection of neurotransmitters. Surface physical properties and the electrochemical performance to neurotransmitters are characterized in these studies and correlated using Langmuir adsorption isotherm and diffusion profiles. Moreover, in vivo measurements are performed for dopamine at CNT-Nb microelectrodes and laser treated CNT yarn microelectrodes in Chapter 2 and Chapter 3. The effect of bio-fouling on CNT yarn is discussed in Chapter 4. Yang| iiChapter 6 and Chapter 7 introduce two novel electrode fabrication methods based on 3D printing: a 3D printed mold assisted microelectrode fabrication method and a novel 3D printed electrode design for fiber-like materials. The 3D printing technology with low-cost, high efficiency, and customizable design provides a new path to apply our studies on novel fiber-like carbon nanomaterials and surface modifications to broader applications.Overall, this thesis explores the synthesis and fabrication of several novel carbon nanomaterials, the effect of different surface modifications, and their applications for in vivo neurotransmitters detection. Moreover, the electrode surface properties are also characterized and then correlated to their electrochemical performance. The systematic comparison of different carbon nanomaterials and different surface modificati...

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Carbon Nanomaterials for Neuroanalytical Chemistry

Yang

Venton

2017

Nanocarbons for Electroanalysis

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Polyethylenimine Carbon Nanotube Fiber Electrodes for Enhanced Detection of Neurotransmitters

Cited by 85 publications

References 36 publications

Recent trends in carbon nanomaterial-based electrochemical sensors for biomolecules: A review

Recent trends in carbon nanomaterial-based electrochemical sensors for biomolecules: A review

Development of Electrochemical Microsensors for in vivo Neurotransmitter Detection

Carbon Nanomaterials for Neuroanalytical Chemistry

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