Carbon Nanotubes, Directly Grown on Supporting Surfaces, Improve Neuronal Activity in Hippocampal Neuronal Networks

Rago, Ilaria; Rauti, Rossana; Bevilacqua, Manuela; Calaresu, Ivo; Pozzato, Alessandro; Cibinel, Matteo; Dalmiglio, Matteo; Tavagnacco, Claudio; Goldoni, Andrea; Scaini, Denis

doi:10.1002/adbi.201800286

Cited by 26 publications

(40 citation statements)

References 84 publications

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“…CNTs carpets have been since long characterized as platforms enriched with nano‐scaled topology able to support neural cultures development, and their effects on cultured hippocampal primary cells are well described (Cellot et al, 2009, 2011; Lovat et al, 2005). Anyway, being the result of a novel fabrication process, our first concern was to understand if the new tCNTs carpets were biocompatible and able to sustain the development of healthy and functional neural networks, potentiating the emerging synaptic activity in respect to Control cultures, as reported for opaque CNTs interfaces (Cellot et al, 2011; Lovat et al, 2005; Mazzatenta et al, 2007; Rago et al, 2019). To this aim, we compared cultured dissociated primary neurons from rat hippocampus interfaced to tCNTs‐decorated substrates with glass supported Controls.…”

Section: Resultsmentioning

confidence: 99%

Transparent carbon nanotubes promote the outgrowth of enthorino‐dentate projections in lesioned organ slice cultures

Pampaloni

Rago

Calaresu

et al. 2019

Developmental Neurobiology

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The increasing engineering of carbon‐based nanomaterials as components of neuroregenerative interfaces is motivated by their dimensional compatibility with subcellular compartments of excitable cells, such as axons and synapses. In neuroscience applications, carbon nanotubes (CNTs) have been used to improve electronic device performance by exploiting their physical properties. Besides, when manufactured to interface neuronal networks formation in vitro, CNT carpets have shown their unique ability to potentiate synaptic networks formation and function. Due to the low optical transparency of CNTs films, further developments of these materials in neural prosthesis fabrication or in implementing interfacing devices to be paired with in vivo imaging or in vitro optogenetic approaches are currently limited. In the present work, we exploit a new method to fabricate CNTs by growing them on a fused silica surface, which results in a transparent CNT‐based substrate (tCNTs). We show that tCNTs favor dissociated primary neurons network formation and function, an effect comparable to the one observed for their dark counterparts. We further adopt tCNTs to support the growth of intact or lesioned entorhinal–hippocampal complex organotypic cultures (EHCs). Through immunocytochemistry and electrophysiological field potential recordings, we show here that tCNTs platforms are suitable substrates for the growth of EHCs and we unmask their ability to significantly increase the signal synchronization and fiber sprouting between the cortex and the hippocampus with respect to Controls. tCNTs transparency and ability to enhance recovery of lesioned brain cultures, make them optimal candidates to implement implantable devices in regenerative medicine and tissue engineering.

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Section: Resultsmentioning

confidence: 99%

Transparent carbon nanotubes promote the outgrowth of enthorino‐dentate projections in lesioned organ slice cultures

Pampaloni

Rago

Calaresu

et al. 2019

Developmental Neurobiology

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“…Besides, 3D platforms, when compared to 2D ones, were shown to impact neuronal differentiation,9,43,44 cell and axonal growth,45,46 circuit functional organization and synaptic network synchronization 2. Further engineering of 3D scaffolds into CNS regenerative interfaces may be pursued by the use of nanomaterials, such as carbon‐based ones, to improve the device's electrical conductivity and to favor the development of excitable tissue 7,22,47–49. Here, we exploit elastomeric 3D platforms to investigate the impact on network dynamics of posing at the interface few‐layer graphene, known to affect cell signaling when supporting 2D cultures 8.…”

Section: Discussionmentioning

confidence: 99%

“…Decorating the elastomeric structure with nanomaterials exploits the scaffold properties at the interface, for example, guiding growth and adhesion of axons to the device or implementing the 3D construct of active components, such as electrically conductive pathways 4. Also, apart MWCNTs,2,5–7 many other carbon‐based nanomaterials as, for example, graphene,8 may be used. This will provide artificial biomimetic cues able to affect synapse formation or neuronal information processing through the physical interactions of the nanomaterial with the biological environment.…”

Section: Introductionmentioning

confidence: 99%

Tuning Neuronal Circuit Formation in 3D Polymeric Scaffolds by Introducing Graphene at the Bio/Material Interface

et al. 2020

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2D cultures are useful platforms allowing studies of the fundamental mechanisms governing neuron and synapse functions. Yet, such models are limited when exploring changes in network dynamics due to 3D‐space topologies. 3D platforms fill this gap and favor investigating topologies closer to the real brain organization. Graphene, an atom‐thick layer of carbon, possesses remarkable properties and since its discovery is considered a highly promising material in neuroscience developments. Here, elastomeric 3D platforms endowed with graphene cues are exploited to modulate neuronal circuits when interfaced to graphene in 3D topology. Ex vivo neuronal networks are successfully reconstructed within 3D scaffolds, with and without graphene, characterized by comparable size and morphology. By confocal microscopy and live imaging, the 3D architecture of synaptic networks is documented to sustain a high rate of bursting in 3D scaffolds, an activity further increased by graphene interfacing. Changes are reported in the excitation/inhibition ratio, potentially following 3D‐graphene interfacing. A hypothesis is thus proposed, where the combination of synapse formation under 3D architecture and graphene interfaces affects the maturation of GABAergic inhibition. This will tune the balance between hyperpolarizing and depolarizing responses, potentially contributing to network synchronization in the absence of changes in GABAergic phenotype expression.

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“…After 10 min of recording of sustained spontaneous synaptic activity (Figure 6c), a cocktail of synaptic receptor antagonists, containing APV (25 × 10 −6 m), BIC (10 × 10 −6 m), and CNQX (10 × 10 −6 m), was applied to functionally disconnect neurons from the network activity. [48,49] This condition allowed testing the efficacy of electrical stimuli delivered via the Au substrates in directly depolarizing the monitored neurons, eventually inducing a burst of action potentials. Figure 6d shows such recordings where five biphasic low-voltage steps, repeated three times (Figure 6b, lower left sketch), were delivered either via Au-Flat or Au-NWs electrodes.…”

Section: Nanostructured Electrodes Enable Electrical Stimulation Of Bmentioning

confidence: 99%

Interfacing Neurons with Nanostructured Electrodes Modulates Synaptic Circuit Features

et al. 2020

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Understanding neural physiopathology requires advances in nanotechnology‐based interfaces, engineered to monitor the functional state of mammalian nervous cells. Such interfaces typically contain nanometer‐size features for stimulation and recording as in cell‐non‐invasive extracellular microelectrode arrays. In such devices, it turns crucial to understand specific interactions of neural cells with physicochemical features of electrodes, which could be designed to optimize performance. Herein, versatile flexible nanostructured electrodes covered by arrays of metallic nanowires are fabricated and used to investigate the role of chemical composition and nanotopography on rat brain cells in vitro. By using Au and Ni as exemplary materials, nanostructure and chemical composition are demonstrated to play major roles in the interaction of neural cells with electrodes. Nanostructured devices are interfaced to rat embryonic cortical cells and postnatal hippocampal neurons forming synaptic circuits. It is shown that Au‐based electrodes behave similarly to controls. Contrarily, Ni‐based nanostructured electrodes increase cell survival, boost neuronal differentiation, and reduce glial cells with respect to flat counterparts. Nonetheless, Au‐based electrodes perform superiorly compared to Ni‐based ones. Under electrical stimulation, Au‐based nanostructured substrates evoke intracellular calcium dynamics compatible with neural networks activation. These studies highlight the opportunity for these electrodes to excite a silent neural network by direct neuronal membranes depolarization.

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Carbon Nanotubes, Directly Grown on Supporting Surfaces, Improve Neuronal Activity in Hippocampal Neuronal Networks

Cited by 26 publications

References 84 publications

Transparent carbon nanotubes promote the outgrowth of enthorino‐dentate projections in lesioned organ slice cultures

Transparent carbon nanotubes promote the outgrowth of enthorino‐dentate projections in lesioned organ slice cultures

Tuning Neuronal Circuit Formation in 3D Polymeric Scaffolds by Introducing Graphene at the Bio/Material Interface

Interfacing Neurons with Nanostructured Electrodes Modulates Synaptic Circuit Features

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