3D‐Printed Carbon Electrodes for Neurotransmitter Detection

Yang, Cheng; Cao, Qun; Puthongkham, Pumidech; Lee, Scott T.; Ganesana, Mallikarjunarao; Lavrik, Nickolay V.; Venton, B. Jill

doi:10.1002/anie.201809992

Cited by 100 publications

(80 citation statements)

References 40 publications

(59 reference statements)

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“…3D printing can process 3D porous carbon structures of 10 µm thick or thicker with very quick drying time . Some 3D‐printed electrodes have been used in Li‐O 2 batteries and are attracting tremendous interest, though the application of 3D‐printed electrodes in electrocatalysis is still in its infancy . 3D‐printed electrode use in electrocatalysis might be hampered, though, by the development of an appropriate ink and printing scheme for abundant active sites generation.…”

Section: Designing 3d Porous Carbons For Electrocatalysismentioning

confidence: 99%

“…[126][127][128][129] Some 3D-printed electrodes have been used in Li-O 2 batteries [116] and are attracting tremendous interest, though the application of 3D-printed electrodes in electrocatalysis is still in its infancy. [36,130] 3D-printed electrode use in electrocatalysis might be hampered, though, by the development of an appropriate ink and printing scheme for abundant active sites generation. Other major printing techniques, such as inkjet printing, screen printing, and transfer printing, have also been commonly used for depositing nanostructured carbons onto substrates of varying size, surface energy, and flexibility for energy applications.…”

Section: D Porous Carbon Macrostructuresmentioning

confidence: 99%

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3D Carbon Materials for Efficient Oxygen and Hydrogen Electrocatalysis

Sobrido

Jervis

Periasamy

et al. 2019

Advanced Energy Materials

108

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Sustainable energy production at an acceptable cost is key for its widespread application. At present, noble metals and metal oxides are the most widely used for electrocatalysis, but they suffer from low selectivity, poor durability, and scarcity. Because of this, metal‐free carbons have become the subject of great interest as promising alternative electrocatalysts for energy conversion and storage devices, and remarkable progress has been accomplished in the advance of metal‐free carbons as electrocatalysts for renewable energy technologies. Particularly interesting are 3D porous carbon architectures, which exhibit outstanding features for electrocatalysis applications, including broad range of active sites, interconnected porosity, high conductivity, and mechanical stability. This review summarizes the latest advances in 3D porous carbon structures for oxygen and hydrogen electrocatalysis. The structure–performance relationship of these materials is consequently rationalized and perspectives on creating more efficient 3D carbon electrocatalysts are suggested.

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Section: Designing 3d Porous Carbons For Electrocatalysismentioning

confidence: 99%

Section: D Porous Carbon Macrostructuresmentioning

confidence: 99%

3D Carbon Materials for Efficient Oxygen and Hydrogen Electrocatalysis

Sobrido

Jervis

Periasamy

et al. 2019

Advanced Energy Materials

108

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“… 8 In addition, carbon nanostructures are now made by nanolithography and 3D printing techniques. 9 , 10 Structures are made from photoresist and then pyrolyzed to form carbon, resulting in customized geometries such as arrays.…”

Section: Introductionmentioning

confidence: 99%

Review: new insights into optimizing chemical and 3D surface structures of carbon electrodes for neurotransmitter detection

2019

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“…Electrochemical methods of neurotransmitter detection have some advantages over more traditional microdialysis probes (Rogers et al 2017) because of their smaller footprint, response speed on the order of seconds and because their fabrication shares many steps with that of traditional electrode arrays (Ou et al 2019). Application of advanced fabrication strategies such as multi-fiber braiding and 3D printing open further possibilities for parallel detection from multiple sites and for engineering the mechanical properties of probes closer to that of soft brain tissues (Wang et al 2019;Yang et al 2018).…”

Section: Future Directions: Multimodal Neural Systems For Addiction Tmentioning

confidence: 99%

Biomarkers and neuromodulation techniques in substance use disorders

et al. 2020

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Addictive disorders are a severe health concern. Conventional therapies have just moderate success and the probability of relapse after treatment remains high. Brain stimulation techniques, such as transcranial Direct Current Stimulation (tDCS) and Deep Brain Stimulation (DBS), have been shown to be effective in reducing subjectively rated substance craving. However, there are few objective and measurable parameters that reflect neural mechanisms of addictive disorders and relapse. Key electrophysiological features that characterize substance related changes in neural processing are Event-Related Potentials (ERP). These high temporal resolution measurements of brain activity are able to identify neurocognitive correlates of addictive behaviours. Moreover, ERP have shown utility as biomarkers to predict treatment outcome and relapse probability. A future direction for the treatment of addiction might include neural interfaces able to detect addiction-related neurophysiological parameters and deploy neuromodulation adapted to the identified pathological features in a closed-loop fashion. Such systems may go beyond electrical recording and stimulation to employ sensing and neuromodulation in the pharmacological domain as well as advanced signal analysis and machine learning algorithms. In this review, we describe the state-of-the-art in the treatment of addictive disorders with electrical brain stimulation and its effect on addiction-related neurophysiological markers. We discuss advanced signal processing approaches and multi-modal neural interfaces as building blocks in future bioelectronics systems for treatment of addictive disorders.

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3D‐Printed Carbon Electrodes for Neurotransmitter Detection

Cited by 100 publications

References 40 publications

3D Carbon Materials for Efficient Oxygen and Hydrogen Electrocatalysis

3D Carbon Materials for Efficient Oxygen and Hydrogen Electrocatalysis

Review: new insights into optimizing chemical and 3D surface structures of carbon electrodes for neurotransmitter detection

Biomarkers and neuromodulation techniques in substance use disorders

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