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1. Carbon Nanotube Yarn Microelectrodes Promote High Temporal Measurements of Serotonin Using Fast Scan Cyclic Voltammetry

   https://doi.org/10.3390/s20041173  

   Mendoza, Alexander; Asrat, Thomas; Liu, Favian; Wonnenberg, Pauline; Zestos, Alexander G. (February 2020, Sensors)

   Carbon fiber-microelectrodes (CFMEs) have been the standard for neurotransmitter detection for over forty years. However, in recent years, there have been many advances of utilizing alternative nanomaterials for neurotransmitter detection with fast scan cyclic voltammetry (FSCV). Recently, carbon nanotube (CNT) yarns have been developed as the working electrode materials for neurotransmitter sensing capabilities with fast scan cyclic voltammetry. Carbon nanotubes are ideal for neurotransmitter detection because they have higher aspect ratios enabling monoamine adsorption and lower limits of detection, faster electron transfer kinetics, and a resistance to surface fouling. Several methods to modify CFMEs with CNTs have resulted in increases in sensitivity, but have also increased noise and led to irreproducible results. In this study, we utilize commercially available CNT-yarns to make microelectrodes as enhanced neurotransmitter sensors for neurotransmitters such as serotonin. CNT-yarn microelectrodes have significantly higher sensitivities (peak oxidative currents of the cyclic voltammograms) than CFMEs and faster electron transfer kinetics as measured by peak separation (ΔEP) values. Moreover, both serotonin and dopamine are adsorption controlled to the surface of the electrode as measured by scan rate and concentration experiments. CNT yarn microelectrodes also resisted surface fouling of serotonin onto the surface of the electrode over thirty minutes and had a wave application frequency independent response to sensitivity at the surface of the electrode. 

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2. Ultrafast Detection of Arsenic Using Carbon-Fiber Microelectrodes and Fast-Scan Cyclic Voltammetry

   https://doi.org/10.3390/mi15060733  

   Manring, Noel; Strini, Miriam; Koifman, Gene; Xavier, Jonathan; Smeltz, Jessica L; Pathirathna, Pavithra (May 2024, Micromachines)

   Arsenic contamination poses a significant public health risk worldwide, with chronic exposure leading to various health issues. Detecting and monitoring arsenic exposure accurately remains challenging, necessitating the development of sensitive detection methods. In this study, we introduce a novel approach using fast-scan cyclic voltammetry (FSCV) coupled with carbon-fiber microelectrodes (CFMs) for the electrochemical detection of As3+. Through an in-depth pH study using tris buffer, we optimized the electrochemical parameters for both acidic and basic media. Our sensor demonstrated high selectivity, distinguishing the As3+ signal from those of As5+ and other potential interferents under ambient conditions. We achieved a limit of detection (LOD) of 0.5 μM (37.46 ppb) and a sensitivity of 2.292 nA/μM for bare CFMs. Microscopic data confirmed the sensor’s stability at lower, physiologically relevant concentrations. Additionally, using our previously reported double-bore CFMs, we simultaneously detected As3+-Cu2+ and As3+-Cd2+ in tris buffer, enhancing the LOD of As3+ to 0.2 μM (14.98 ppb). To our knowledge, this is the first study to use CFMs for the rapid and selective detection of As3+ via FSCV. Our sensor’s ability to distinguish As3+ from As5+ in a physiologically relevant pH environment showcases its potential for future in vivo studies. 

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3. High resolution voltammetric and field-effect transistor readout of carbon fiber microelectrode biosensors

   https://doi.org/10.1039/D2SD00023G  

   Cho, Whirang; Rafi, Harmain; Cho, Seulki; Balijepalli, Arvind; Zestos, Alexander G. (May 2022, Sensors & Diagnostics)

   Rapid and sensitive pH measurements with increased spatiotemporal resolution are imperative to probe neurochemical signals and illuminate brain function. We interfaced carbon fiber microelectrode (CFME) sensors with both fast scan cyclic voltammetry (FSCV) and field-effect transistor (FET) transducers for dynamic pH measurements. The electrochemical oxidation and reduction of functional groups on the surface of CFMEs affect their response over a physiologically relevant pH range. When measured with FET transducers, the sensitivity of the measurements over the measured pH range was found to be (101 ± 18) mV, which exceeded the Nernstian value of 59 mV by approximately 70%. Finally, we validated the functionality of CFMEs as pH sensors with FSCV ex vivo in rat brain coronal slices with exogenously applied solutions of varying pH values indicating that potential in vivo study is feasible. 

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4. Design of 256-ch neurochemical MEA probe

   https://doi.org/10.1109/BioCAS54905.2022.9948577  

   White, Kevin A.; Kim, Brian N. (October 2022, 2022 IEEE Biomedical Circuits and Systems Conference (BioCAS))

   Dopamine constitutes a significant portion of the catecholamine content in the brain and plays a distinct role in neuromodulation including directing motor control, motivation, reward, and cognitive function. For future neuroprobe technology, not only is simultaneous high-density neurochemical recording vital, temporal resolution plays a key part in the roles of the spatiotemporal distributions of catecholamines in the brain. In this work, we present a new probe design that contains a 256 microelectrode array with an integrated 256 transimpedance amplifier array capable of both amperometry and fast-scan cyclic voltammetry. Each amplifier in the array is capable of both modes of electrochemical detection with three gain settings for the voltammetry mode and occupies an area of 60 μm × 60 μm. The new probe enables a high-resolution spatiotemporal mapping of neurochemicals in the brain. 

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5. Caged Zn ²⁺ Photolysis in Zebrafish Whole Brains Reveals Subsecond Modulation of Dopamine Uptake

   https://doi.org/10.1021/acschemneuro.3c00668  

   Hettiarachchi, Piyanka; Niyangoda, Sayuri; Shigemoto, Austin; Solowiej, Isabel J; Burdette, Shawn C; Johnson, Michael A (February 2024, ACS Chemical Neuroscience)

   Free, ionic zinc (Zn2+) modulates neurotransmitter dynamics in the brain. However, the sub-s effects of transient concentration changes of Zn2+ on neurotransmitter release and uptake are not well understood. To address this lack of knowledge, we have combined the photolysis of the novel caged Zn2+ compound [Zn(DPAdeCageOMe)]+ with fast scan cyclic voltammetry (FSCV) at carbon fiber microelectrodes in live, whole brain preparations from zebrafish (Danio rerio). After treating the brain with [Zn(DPAdeCageOMe)]+, Zn2+ was released by application of light that was gated through a computer-controlled shutter synchronized with the FSCV measurements and delivered through a 1 mm fiber optic cable. We systematically optimized the photocage concentration and light application parameters, including the total duration and light-to-electrical stimulation delay time. While sub-s Zn2+ application with this method inhibited DA reuptake, assessed by the first-order rate constant (k) and half-life (t1/2), it had no effect on the electrically stimulated DA overflow ([DA]STIM). Increasing the photocage concentration and light duration progressively inhibited uptake, with maximal effects occurring at 100 μM and 800 ms, respectively. Furthermore, uptake was inhibited 200 ms after Zn2+ photorelease, but no measurable effect occurred after 800 ms. We expect that application of this method to the zebrafish whole brain and other preparations will help expand the current knowledge of how Zn2+ affects neurotransmitter release/uptake in select neurological disease states. 

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