Carbon Nanotube Scaffolds Tune Synaptic Strength in Cultured Neural Circuits: Novel Frontiers in Nanomaterial–Tissue Interactions

Cellot, Giada; Toma, Francesca M.; Varley, Zeynep Kasap; Laishram, Jummi; Villari, Ambra; Quintana, Mildred; Cipollone, Sara; Prato, Maurizio; Ballerini, Laura

doi:10.1523/jneurosci.1332-11.2011

Cited by 146 publications

(278 citation statements)

References 63 publications

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“…In this study, we showed that culturing neurons on CNT scaffolds almost doubled the probability of finding monosynaptically connected neurons, when compared to controls, i.e., CNTs guide the build-up of more synapses than in control conditions. In the same work, we further demonstrated that the strong rise in the coupling probability was due to a massive increase in synaptic density: immunofluorescence colocalization experiments reported the morphological evidence of an increase in the number of GABAergic synaptic contacts in networks grown on CNTs layers compared to that of controls 27 ( Figure 3b). This strong boosting in neuronal network connectivity is proposed to be the major mechanism by which CNTs increase the frequency of spontaneous PSCs of cultured networks reported in the previous studies 27−29 and fosters CNTs as a powerful artificial growth support able to promote de novo formation of synapses.…”

Section: −30supporting

confidence: 58%

“…30,45 The summation of CNT nanotopography and physical and chemical properties provides neurons with a great deal of information, thus suggesting that neuronal contacts to CNT scaffolds might activate multiple and complex adhesion-mediated, intracellular signaling cascades. growth supports or on control glass 27 ( Figure 3a). Action potentials were evoked in the first (presynaptic) neuron by injecting a depolarizing current pulse, while the evoked unitary postsynaptic currents (PSCs, usually GABA A receptor-mediated in these experimental conditions) 27 were recorded in the second (postsynaptic) cell.…”

Section: −30mentioning

confidence: 99%

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Carbon Nanotubes: Artificial Nanomaterials to Engineer Single Neurons and Neuronal Networks

Fabbro

Bosi

Ballerini

et al. 2012

ACS Chem. Neurosci.

106

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In the past decade, nanotechnology applications to the nervous system have often involved the study and the use of novel nanomaterials to improve the diagnosis and therapy of neurological diseases. In the field of nanomedicine, carbon nanotubes are evaluated as promising materials for diverse therapeutic and diagnostic applications. Besides, carbon nanotubes are increasingly employed in basic neuroscience approaches, and they have been used in the design of neuronal interfaces or in that of scaffolds promoting neuronal growth in vitro. Ultimately, carbon nanotubes are thought to hold the potential for the development of innovative neurological implants. In this framework, it is particularly relevant to document the impact of interfacing such materials with nerve cells. Carbon nanotubes were shown, when modified with biologically active compounds or functionalized in order to alter their charge, to affect neurite outgrowth and branching. Notably, purified carbon nanotubes used as scaffolds can promote the formation of nanotube−neuron hybrid networks, able per se to affect neuron integrative abilities, network connectivity, and synaptic plasticity. We focus this review on our work over several years directed to investigate the ability of carbon nanotube platforms in providing a new tool for nongenetic manipulations of neuronal performance and network signaling. KEYWORDS: Carbon nanotubes, nanotechnology, cultured neuronal network, synapse, short-term plasticity, patch clamp recordingsThe discovery and manipulation of innovative nanomaterials, such as carbon nanotubes (CNTs), are becoming increasingly helpful in biomedical applications in general 1,2 and in neuroscience research approaches and developments in particular, thus providing new tools able to specifically interact with the nervous system and with neurons at the nanoscale. 3CNTs have been alternatively proposed as growth substrates promoting neuronal development, scaffolds for nerve tissue engineering, electrode coating, or neuronal interfaces for longterm implants.4−10 In their soluble form, CNTs are also promising nanovectors for drug delivery and molecular sensing applications. 11−13Since their discovery in 1991 by Ijima, 14 CNTs have shown outstanding mechanical, thermal, and conductive properties: these unique nanoobjects made of one or more rolled-up graphene sheets possess high surface area, high mechanical strength but ultralight weight, rich electronic properties, and excellent chemical and thermal stability. 15 These properties make CNTs very promising in different technological fields; in particular, CNTs were used as conductive composites, energy storage and energy conversion devices, sensors, field emission displays and radiation sources, hydrogen storage media and nanometer-sized semiconductor devices, probes, and interconnects (for a review, see ref 16). Their poor solubility and their apparently high toxicity have been faced in the past decade via functionalization of the CNT surface by means of many different approaches (Figure ...

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Section: −30supporting

confidence: 58%

Section: −30mentioning

confidence: 99%

Carbon Nanotubes: Artificial Nanomaterials to Engineer Single Neurons and Neuronal Networks

Fabbro

Bosi

Ballerini

et al. 2012

ACS Chem. Neurosci.

106

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“…XPS analysis confirmed an increase in oxygen species and decrease in carbon species, rendering the surfaces more hydrophilic. To add to it, such surfaces had exposed nanotubes which renders the surfaces even more rough and thus, shown to promote neural synapsis 43 . We believe that the roughness in combination with increased oxygen content after plasma treatment led to better facilitation of neural adhesion and synaptic support.…”

Section: Discussionmentioning

confidence: 99%

“…Previously, nanotube-based scaffolds have been shown to be able to lead to increased connectivity by promoting synaptogenesis via modulation of deposition of an extracellular matrix more permissive for synapse construction 50 . Carbon nanotube platforms have also been shown to support network connectivity and synaptic plasticity in mammalian cortical circuits 43 . Carbon nanotube-neuron hybrid networks have been shown to detect a boost in signal transmission with increase in frequency of synaptic events 51,52 .…”

Section: Discussionmentioning

confidence: 99%

Chitin and carbon nanotube composites as biocompatible scaffolds for neuron growth

et al. 2016

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“…Since a metal catalyst, such as, nickel can be utilized for the growth process of CNTs, nitric acid-containing oxidants are generally refined with CNTs for biological applications, which can regulate the chemical composition of CNT surfaces by making carboxylic acid groups at the terminal CNT end. CNTs are commonly utilized in biomedical applications ( Figure 8) because of their high aspect ratio, low density, and electrical and physical properties [106][107][108][109][110][111]. Zhang et al investigated the interaction between cells and modified multi-walled carbon nanotubes (MWCNTs) for biomedical applications [112].…”

Section: Carbonsmentioning

confidence: 99%

Incorporation of Conductive Materials into Hydrogels for Tissue Engineering Applications

Min¹,

Koh²

2018

Preprint

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In the field of tissue engineering, conductive hydrogels have been the most effective biomaterials to mimic the biological and electrical properties of tissues in the human body. The main advantages of conductive hydrogel include not only its physical properties, but also its adequate electrical properties, thus providing electrical signals to cells efficiently. However, when introducing a conductive material into a non-conductive hydrogel, a conflicting relationship between the electrical and mechanical properties may develop. This review examines the strengths and weaknesses of the generation of conductive hydrogels using various conductive materials and introduces the use of these conductive hydrogels in tissue engineering applications.

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Carbon Nanotube Scaffolds Tune Synaptic Strength in Cultured Neural Circuits: Novel Frontiers in Nanomaterial–Tissue Interactions

Cited by 146 publications

References 63 publications

Carbon Nanotubes: Artificial Nanomaterials to Engineer Single Neurons and Neuronal Networks

Carbon Nanotubes: Artificial Nanomaterials to Engineer Single Neurons and Neuronal Networks

Chitin and carbon nanotube composites as biocompatible scaffolds for neuron growth

Incorporation of Conductive Materials into Hydrogels for Tissue Engineering Applications

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