Nanomaterials for Neural Interfaces

Kotov, Nicholas A.; Winter, Jessica O.; Clements, Isaac P.; Jan, Edward; Timko, Brian P.; Campidelli, Stéphane; Pathak, Smita; Mazzatenta, Andrea; Lieber, Charles M.; Prato, Maurizio; Bellamkonda, Ravi V.; Silva, Gabriel A.; Kam, Nadine Wong Shi; Patolsky, Fernando; Ballerini, Laura

doi:10.1002/adma.200801984

Cited by 462 publications

(457 citation statements)

References 517 publications

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“…There is a growing interest in engineering neuronal networks in vitro [1,2]. Such artificial neuronal networks have been employed as models for studying the functions of neuronal network [3][4][5] for engineering artificial intelligence [6,7] and for neuro-interfacing [8].…”

Section: Introductionmentioning

confidence: 99%

Surface Coating as a Key Parameter in Engineering Neuronal Network Structures In Vitro

et al. 2012

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By quantitatively comparing a variety of macromolecular surface coating agents, we discovered that surface coating strongly modulates the adhesion and morphogenesis of primary hippocampal neurons and serves as a switch of somata clustering and neurite fasciculation in vitro. The kinetics of neuronal adhesion on poly-lysine-coated surfaces is much faster than that on laminin and Matrigel-coated surfaces, and the distribution of adhesion is more homogenous on poly-lysine. Matrigel and laminin, on the other hand, facilitate neuritogenesis more than poly-lysine does. Eventually, on Matrigel-coated surfaces of self-assembled monolayers, neurons tend to undergo somata clustering and neurite fasciculation. By replacing coating proteins with cerebral astrocytes, and patterning neurons on astrocytes through self-assembled monolayers, microfluidics and micro-contact printing, we found that astrocyte promotes soma adhesion and astrocyte processes guide neurites. There, astrocytes could be a versatile substrate in engineering neuronal networks in vitro. Besides, quantitative measurements of cellular responses on various coatings would be valuable information for the neurobiology community in the choice of the most appropriate coating strategy.

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Section: Introductionmentioning

confidence: 99%

Surface Coating as a Key Parameter in Engineering Neuronal Network Structures In Vitro

et al. 2012

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“…All these features make them excellent devices for neural implants, helping structurally and functionally for regeneration of damaged axons (Kotov et al, 2009;Sun, Sun, Li, & Peng, 2013).…”

Section: Introductionmentioning

confidence: 99%

“…Nanometric supports have also been implemented to promote growth and development of neurons and non-neural cells (Mattson, Haddon, & Rao, 2000). The large class of nanomaterials currently available contains many families of nanostructures (Kotov et al, 2009).…”

Section: Introductionmentioning

confidence: 99%

Sciatic nerve repair using poly(ε‐caprolactone) tubular prosthesis associated with nanoparticles of carbon and graphene

et al. 2017

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“…Carbon nanotube cylindrical morphology is reminiscent of that of distal neuronal dendrites [68], small cellular processes crucially involved in the ability of neurons to express complex computational skills. This similarity, together with carbon nanotube topographic features, physical properties, as conductivity, and surface-tovolume ratio [69], sets the stage for carbon nanotube exploitation in devices able to interface neuronal physiology. The use of nanomaterials in the design of tissue scaffolds in the CNS is primarily due to their abilities to favour neuronal adhesion, to re-create an ECM-like microenvironment and to interact with neuronal membranes at the nanoscale.…”

Section: Carbon Nanotubesmentioning

confidence: 99%

Potential Drug Targets for Neuroregeneration and Repair

Kumar

Rawat

Kurmi

et al. 2017

JAPLR

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Unlike the peripheral nervous system (PNS) the adult mammalian central nervous system (CNS) does not spontaneously regenerate after injury. Numerous axon-inhibitory molecules are present in the injured CNS and various strategies for overcoming these obstacles and enhancing CNS regeneration had been experimentally developed. Adult neuroregeneration is a complex process, beyond the common knowledge of neurogenesis that also comprises endogenous neuroprotection leading to neuroplasticity and neurorestoration, a therapeutical approach of implantation of viable cells. Regeneration in the CNS implies that new neuron generate either through proliferation of endogenous stem/ progenitor cells or by administration of exogenous stem/precursor cells with potential to substitute for lost tissue, or can be maintained by targeting the axon inhibitory molecule in the CNS. Here, the main focus of review emphasis on the axon inhibitory molecules, which prevents neuroregeneration and repair.

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Nanomaterials for Neural Interfaces

Cited by 462 publications

References 517 publications

Surface Coating as a Key Parameter in Engineering Neuronal Network Structures In Vitro

Surface Coating as a Key Parameter in Engineering Neuronal Network Structures In Vitro

Sciatic nerve repair using poly(ε‐caprolactone) tubular prosthesis associated with nanoparticles of carbon and graphene

Potential Drug Targets for Neuroregeneration and Repair

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