Titlebook: Nanotechnology and Neuroscience: Nano-electronic, Photonic and Mechanical Neuronal Interfacing; Massimo De Vittorio,Luigi Martiradonna,Joh

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singcapabilities. Thesesensornodescanbenetworkedinanadhocmanner to perform distributed sensing and information processing. Such ad hoc s- sor networks provide greater fault tolerance and sensing accuracy and are typically less expensive compared to the alternative of using only a few large isolated

Detonate

,Carbon Nanotubes for Neuron–Electrode Interface with Improved Mechanical Performance,s to restore impaired neuronal activity. Recording and stimulating electrodes are accordingly one of the major building blocks of these systems, and extensive investigations were directed to build better performing electrodes. The electrochemical properties of the electrodes have clearly gained a lo

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Nanoscale Field-Effect Transistors for Minimally Invasive, High Spatial Resolution, and Three-Dimenpared to optical methods, the electrical recording of action potentials has high signal-to-noise ratio (SNR) and temporal resolution. But the need for electrodes limits its spatial resolution and also poses perturbation on the biological system under investigation. One way to overcome these problems

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Nanostructured Coatings for Improved Charge Delivery to Neurons, lead to efficacious activation of nearby neurons and examining the basic electrochemical mechanisms of charge transfer at an electrode/electrolyte interface. It then covers the advantages and current challenges of emerging micro-/nanostructured electrode materials for next-generation neural stimula