Your search keyword '"L. Ballerini"' showing total 27 results

1. Interfacing Neurons with Nanostructured Electrodes Modulates Synaptic Circuit Features.

Author

Domínguez-Bajo A, Rodilla BL, Calaresu I, Arché-Núñez A, González-Mayorga A, Scaini D, Pérez L, Camarero J, Miranda R, López-Dolado E, González MT, Ballerini L, and Serrano MC

Subjects

Animals, Calcium Signaling, Cells, Cultured, Cerebral Cortex cytology, Equipment Design, Female, Hippocampus cytology, Microelectrodes, Rats, Rats, Wistar, Electric Stimulation instrumentation, Nanotechnology instrumentation, Nanowires chemistry, Neurons cytology, Neurons physiology, Synapses physiology

Abstract

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., (© 2020 The Authors. Published by Wiley-VCH GmbH.)

Published

2020

2. Thin graphene oxide nanoflakes modulate glutamatergic synapses in the amygdala cultured circuits: Exploiting synaptic approaches to anxiety disorders.

Author

Secomandi N, Franceschi Biagioni A, Kostarelos K, Cellot G, and Ballerini L

Subjects

Amygdala drug effects, Amygdala physiology, Animals, Anxiety Disorders physiopathology, Glutamic Acid metabolism, Graphite chemistry, Humans, Nanostructures chemistry, Neurons physiology, Patch-Clamp Techniques, Rats, Synapses physiology, Synaptic Transmission drug effects, Anxiety Disorders therapy, Graphite pharmacology, Neurons drug effects, Synapses drug effects

Abstract

Anxiety disorders (ADs) are nervous system maladies involving changes in the amygdala synaptic circuitry, such as an upregulation of excitatory neurotransmission at glutamatergic synapses. In the field of nanotechnology, thin graphene oxide flakes with nanoscale lateral size (s-GO) have shown outstanding promise for the manipulation of excitatory neuronal transmission with high temporal and spatial precision, thus they were considered as ideal candidates for modulating amygdalar glutamatergic transmission. Here, we validated an in vitro model of amygdala circuitry as a screening tool to target synapses, towards development of future ADs treatments. After one week in vitro, dissociated amygdalar neurons reconnected forming functional networks, whose development recapitulated that of the tissue of origin. When acutely applied to these cultures, s-GO flakes induced a selective modification of excitatory activity. This type of interaction between s-GO and amygdalar neurons may form the basis for the exploitation of alternative approaches in the treatment of ADs., (Copyright © 2020 The Author(s). Published by Elsevier Inc. All rights reserved.)

Published

2020

3. Foetal neural progenitors contribute to postnatal circuits formation ex vivo: an electrophysiological investigation.

Author

Manzati M, Sorbo T, Giugliano M, and Ballerini L

Subjects

Action Potentials physiology, Animals, Cells, Cultured, Coculture Techniques, Hippocampus physiology, Neurogenesis, Neurons cytology, Patch-Clamp Techniques, Rats, Rats, Wistar, Single-Cell Analysis, Electrophysiological Phenomena physiology, Hippocampus cytology, Nerve Net physiology, Neurons physiology

Abstract

Neuronal progenitor cells (NPC) play an essential role in homeostasis of the central nervous system (CNS). Considering their ability to differentiate into specific lineages, their manipulation and control could have a major therapeutic impact for those CNS injuries or degenerative diseases characterized by neuronal cell loss. In this work, we established an in vitro co-culture and tested the ability of foetal NPC (fNPC) to integrate among post-mitotic hippocampal neurons and contribute to the electrical activity of the resulting networks. We performed extracellular electrophysiological recordings of the activity of neuronal networks and compared the properties of spontaneous spiking in hippocampal control cultures (HCC), fNPC, and mixed circuitries ex vivo. We further employed patch-clamp intracellular recordings to examine single-cell excitability. We report of the capability of fNPC to mature when combined to hippocampal neurons, shaping the profile of network activity, a result suggestive of newly formed connectivity ex vivo.

Published

2020

4. Hybrid Interfaces Made of Nanotubes and Backbone-Altered Dipeptides Tune Neuronal Network Architecture.

Author

Dinesh B, Medelin M, Scaini D, Lareno Faccini F, Quici F, Ballerini L, and Bianco A

Subjects

Animals, Biocompatible Materials, Hippocampus, Rats, Nanotubes, Carbon, Nerve Net, Neurons, Tissue Engineering instrumentation, Tissue Engineering methods

Abstract

Peptides constituted of backbone homologated α-amino acids combined with carbon materials offer interesting possibilities in the modulation of cellular functions. In this work, we have prepared diphenylalanine β- and γ-peptides and conjugated them to carbon nanotubes (CNTs). These hybrids were able to self-assemble into fibrillar dendritic structures enabling the growth of primary hippocampal cells and the modulation of their neuronal functions. In particular, following the deposition of the different nanomaterials on glass substrates, we have evaluated their effects on circuit function and geometry. The geometrical restrictions due to CNT nucleated nodes allowed growth of neuronal networks with control over network geometry, and exploring its functional impact. In diverse applications from basic neuroscience, the presence of CNT nodes may be exploited in brain interfaces able to convey highly localized electrical stimuli.

Published

2020

5. Chemically Cross-Linked Carbon Nanotube Films Engineered to Control Neuronal Signaling.

Author

Barrejón M, Rauti R, Ballerini L, and Prato M

Subjects

Cell Differentiation drug effects, Electric Conductivity, Humans, Nanocomposites chemistry, Neurons pathology, Signal Transduction drug effects, Nanotubes, Carbon chemistry, Neurons drug effects, Tissue Engineering

Abstract

In recent years, the use of free-standing carbon nanotube (CNT) films for neural tissue engineering has attracted tremendous attention. CNT films show large surface area and high electrical conductivity that combined with flexibility and biocompatibility may promote neuron growth and differentiation while stimulating neural activity. In addition, adhesion, survival, and growth of neurons can be modulated through chemical modification of CNTs. Axonal and synaptic signaling can also be positively tuned by these materials. Here we describe the ability of free-standing CNT films to influence neuronal activity. We demonstrate that the degree of cross-linking between the CNTs has a strong impact on the electrical conductivity of the substrate, which, in turn, regulates neural circuit outputs.

Published

2019

6. Graphene Oxide Flakes Tune Excitatory Neurotransmission in Vivo by Targeting Hippocampal Synapses.

Author

Rauti R, Medelin M, Newman L, Vranic S, Reina G, Bianco A, Prato M, Kostarelos K, and Ballerini L

Subjects

Animals, Animals, Newborn, Excitatory Amino Acid Agents chemical synthesis, Excitatory Amino Acid Agents chemistry, Excitatory Amino Acid Agents pharmacology, Glutamic Acid metabolism, Graphite chemical synthesis, Graphite chemistry, Hippocampus drug effects, Hippocampus metabolism, Humans, Nanostructures therapeutic use, Neurodegenerative Diseases physiopathology, Neurons metabolism, Primary Cell Culture, Quantum Dots chemistry, Rats, Rats, Wistar, Synapses drug effects, Synapses metabolism, Synaptic Transmission drug effects, Graphite pharmacology, Nanostructures chemistry, Neurodegenerative Diseases drug therapy, Neurons drug effects

Abstract

Synapses compute and transmit information to connect neural circuits and are at the basis of brain operations. Alterations in their function contribute to a vast range of neuropsychiatric and neurodegenerative disorders and synapse-based therapeutic intervention, such as selective inhibition of synaptic transmission, may significantly help against serious pathologies. Graphene is a two-dimensional nanomaterial largely exploited in multiple domains of science and technology, including biomedical applications. In hippocampal neurons in culture, small graphene oxide nanosheets (s-GO) selectively depress glutamatergic activity without altering cell viability. Glutamate is the main excitatory neurotransmitter in the central nervous system and growing evidence suggests its involvement in neuropsychiatric disorders. Here we demonstrate that s-GO directly targets the release of presynaptic vesicle. We propose that s-GO flakes reduce the availability of transmitter, via promoting its fast release and subsequent depletion, leading to a decline ofglutamatergic neurotransmission. We injected s-GO in the hippocampus in vivo, and 48 h after surgery ex vivo patch-clamp recordings from brain slices show a significant reduction in glutamatergic synaptic activity in respect to saline injections.

Published

2019

7. Sculpting neurotransmission during synaptic development by 2D nanostructured interfaces.

Author

Pampaloni NP, Scaini D, Perissinotto F, Bosi S, Prato M, and Ballerini L

Subjects

Animals, Animals, Newborn, Cells, Cultured, Hippocampus cytology, Neural Networks, Computer, Neurons cytology, Rats, Hippocampus physiology, Nanostructures chemistry, Nanotubes, Carbon chemistry, Neurons physiology, Synapses physiology, Synaptic Transmission, Tissue Scaffolds

Abstract

Carbon nanotube-based biomaterials critically contribute to the design of many prosthetic devices, with a particular impact in the development of bioelectronics components for novel neural interfaces. These nanomaterials combine excellent physical and chemical properties with peculiar nanostructured topography, thought to be crucial to their integration with neural tissue as long-term implants. The junction between carbon nanotubes and neural tissue can be particularly worthy of scientific attention and has been reported to significantly impact synapse construction in cultured neuronal networks. In this framework, the interaction of 2D carbon nanotube platforms with biological membranes is of paramount importance. Here we study carbon nanotube ability to interfere with lipid membrane structure and dynamics in cultured hippocampal neurons. While excluding that carbon nanotubes alter the homeostasis of neuronal membrane lipids, in particular cholesterol, we document in aged cultures an unprecedented functional integration between carbon nanotubes and the physiological maturation of the synaptic circuits., (Copyright © 2017 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2018

8. Single-layer graphene modulates neuronal communication and augments membrane ion currents.

Author

Pampaloni NP, Lottner M, Giugliano M, Matruglio A, D'Amico F, Prato M, Garrido JA, Ballerini L, and Scaini D

Subjects

Action Potentials, Animals, Biocompatible Materials chemistry, Cells, Cultured, Graphite chemistry, Nerve Net cytology, Neurons cytology, Potassium metabolism, Rats, Biocompatible Materials pharmacology, Cell Communication, Graphite pharmacology, Nanostructures chemistry, Nerve Net physiology, Neurons physiology

Abstract

The use of graphene-based materials to engineer sophisticated biosensing interfaces that can adapt to the central nervous system requires a detailed understanding of how such materials behave in a biological context. Graphene's peculiar properties can cause various cellular changes, but the underlying mechanisms remain unclear. Here, we show that single-layer graphene increases neuronal firing by altering membrane-associated functions in cultured cells. Graphene tunes the distribution of extracellular ions at the interface with neurons, a key regulator of neuronal excitability. The resulting biophysical changes in the membrane include stronger potassium ion currents, with a shift in the fraction of neuronal firing phenotypes from adapting to tonically firing. By using experimental and theoretical approaches, we hypothesize that the graphene-ion interactions that are maximized when single-layer graphene is deposited on electrically insulating substrates are crucial to these effects.

Published

2018

9. Nanomaterials at the neural interface.

Author

Scaini D and Ballerini L

Subjects

Animals, Humans, Membrane Potentials physiology, Nanostructures, Nanotechnology, Neurons physiology, Tissue Scaffolds

Abstract

Interfacing the nervous system with devices able to efficiently record or modulate the electrical activity of neuronal cells represents the underlying foundation of future theranostic applications in neurology and of current openings in neuroscience research. These devices, usually sensing cell activity via microelectrodes, should be characterized by safe working conditions in the biological milieu together with a well-controlled operation-life. The stable device/neuronal electrical coupling at the interface requires tight interactions between the electrode surface and the cell membrane. This neuro-electrode hybrid represents the hyphen between the soft nature of neural tissue, generating electrical signals via ion motions, and the rigid realm of microelectronics and medical devices, dealing with electrons in motion. Efficient integration of these entities is essential for monitoring, analyzing and controlling neuronal signaling but poses significant technological challenges. Improving the cell/electrode interaction and thus the interface performance requires novel engineering of (nano)materials: tuning at the nanoscale electrode's properties may lead to engineer interfacing probes that better camouflaged with their biological target. In this brief review, we highlight the most recent concepts in nanotechnologies and nanomaterials that might help reducing the mismatch between tissue and electrode, focusing on the device's mechanical properties and its biological integration with the tissue., (Copyright © 2017 Elsevier Ltd. All rights reserved.)

Published

2018

10. Exploiting natural polysaccharides to enhance in vitro bio-constructs of primary neurons and progenitor cells.

Author

Medelin M, Porrelli D, Aurand ER, Scaini D, Travan A, Borgogna MA, Cok M, Donati I, Marsich E, Scopa C, Scardigli R, Paoletti S, and Ballerini L

Subjects

Animals, Biocompatible Materials, Cell Culture Techniques, Cell Differentiation, Cells, Cultured, Chitosan chemistry, Female, Glass, Hippocampus cytology, Hydrogels, Microscopy, Atomic Force, Microscopy, Confocal, Motor Neurons cytology, Motor Neurons metabolism, Nerve Growth Factors, Nerve Regeneration, Neurogenesis, Patch-Clamp Techniques, Phenotype, Polymers chemistry, Porosity, Rats, Static Electricity, Tissue Scaffolds chemistry, Neurons cytology, Neurons drug effects, Polysaccharides chemistry, Stem Cells cytology, Tissue Engineering methods

Abstract

Current strategies in Central Nervous System (CNS) repair focus on the engineering of artificial scaffolds for guiding and promoting neuronal tissue regrowth. Ideally, one should combine such synthetic structures with stem cell therapies, encapsulating progenitor cells and instructing their differentiation and growth. We used developments in the design, synthesis, and characterization of polysaccharide-based bioactive polymeric materials for testing the ideal composite supporting neuronal network growth, synapse formation and stem cell differentiation into neurons and motor neurons. Moreover, we investigated the feasibility of combining these approaches with engineered mesenchymal stem cells able to release neurotrophic factors. We show here that composite bio-constructs made of Chitlac, a Chitosan derivative, favor hippocampal neuronal growth, synapse formation and the differentiation of progenitors into the proper neuronal lineage, that can be improved by local and continuous delivery of neurotrophins., Statement of Significance: In our work, we characterized polysaccharide-based bioactive platforms as biocompatible materials for nerve tissue engineering. We show that Chitlac-thick substrates are able to promote neuronal growth, differentiation, maturation and formation of active synapses. These observations support this new material as a promising candidate for the development of complex bio-constructs promoting central nervous system regeneration. Our novel findings sustain the exploitation of polysaccharide-based scaffolds able to favour neuronal network reconstruction. Our study shows that Chitlac-thick may be an ideal candidate for the design of biomaterial scaffolds enriched with stem cell therapies as an innovative approach for central nervous system repair., (Copyright © 2018 Acta Materialia Inc. Published by Elsevier Ltd. All rights reserved.)

Published

2018

11. Graphene Improves the Biocompatibility of Polyacrylamide Hydrogels: 3D Polymeric Scaffolds for Neuronal Growth.

Author

Martín C, Merino S, González-Domínguez JM, Rauti R, Ballerini L, Prato M, and Vázquez E

Subjects

Acrylic Resins chemistry, Animals, Cells, Cultured, Hydrogels adverse effects, Neurons drug effects, Neurons physiology, Rats, Synaptic Transmission drug effects, Tissue Scaffolds adverse effects, Graphite chemistry, Hydrogels chemistry, Neurons cytology, Tissue Scaffolds chemistry

Abstract

In tissue engineering strategies, the design of scaffolds based on nanostructures is a subject undergoing intense research: nanomaterials may affect the scaffolds properties, including their ability to interact with cells favouring cell growth and improving tissue performance. Hydrogels are synthetic materials widely used to obtain realistic tissue constructs, as they resemble living tissues. Here, different hydrogels with varying content of graphene, are synthesised by in situ radical polymerization of acrylamide in aqueous graphene dispersions. Hydrogels are characterised focusing on the contribution of the nanomaterial to the polymer network. Our results suggest that graphene is not a mere embedded nanomaterial within the hydrogels, rather it represents an intrinsic component of these networks, with a specific role in the emergence of these structures. Moreover, a hybrid hydrogel with a graphene concentration of only 0.2 mg mL -1 is used to support the growth of cultured brain cells and the development of synaptic activity, in view of exploiting these novel materials to engineer the neural interface of brain devices of the future. The main conclusion of this work is that graphene plays an important role in improving the biocompatibility of polyacrylamide hydrogels, allowing neuronal adhesion.

Published

2017

12. Tumor Necrosis Factor-α Impairs Kisspeptin Signaling in Human Gonadotropin-Releasing Hormone Primary Neurons.

Author

Sarchielli E, Comeglio P, Squecco R, Ballerini L, Mello T, Guarnieri G, Idrizaj E, Mazzanti B, Vignozzi L, Gallina P, Maggi M, Vannelli GB, and Morelli A

Subjects

Cells, Cultured, Female, Fetus cytology, Fetus drug effects, Humans, Kisspeptins genetics, Male, Neurons cytology, Neurons drug effects, Receptors, G-Protein-Coupled genetics, Receptors, Kisspeptin-1, Signal Transduction drug effects, Fetus metabolism, Gene Expression Regulation drug effects, Gonadotropin-Releasing Hormone metabolism, Kisspeptins metabolism, Neurons metabolism, Receptors, G-Protein-Coupled metabolism, Tumor Necrosis Factor-alpha pharmacology

Abstract

Context: Inflammatory pathways may impair central regulatory networks involving gonadotropin-releasing hormone (GnRH) neuron activity. Studies in humans are limited by the lack of human GnRH neuron cell lines., Objective: To establish an in vitro model of human GnRH neurons and analyze the effects of proinflammatory cytokines., Design: The primary human fetal hypothalamic cells (hfHypo) were isolated from 12-week-old fetuses. Responsiveness to kisspeptin, the main GnRH neurons' physiological regulator, was evaluated for biological characterization. Tumor necrosis factor alpha (TNF-α) was used as a proinflammatory stimulus. Main Outcome Measures: Expression of specific GnRH neuron markers by quantitative reverse transcription-polymerase chain reaction, flow cytometry, and immunocytochemistry analyses; and GnRH-releasing ability and electrophysiological changes in response to kisspeptin., Results: The primary hfHypo showed a high percentage of GnRH-positive cells (80%), expressing a functional kisspeptin receptor (KISS1R) and able to release GnRH in response to kisspeptin. TNF-α exposure determined a specific inflammatory intracellular signaling and reduced GnRH secretion, KISS1R expression, and kisspeptin-induced depolarizing effect. Moreover, hfHypo possessed a primary cilium, whose assembly was inhibited by TNF-α., Conclusion: The hfHypo cells represent a novel tool for investigations on human GnRH neuron biology. TNF-α directly affects GnRH neuron function by interfering with KISS1R expression and ciliogenesis, thereby impairing kisspeptin signaling., (Copyright © 2017 by the Endocrine Society)

Published

2017

13. Graphene Oxide Nanosheets Reshape Synaptic Function in Cultured Brain Networks.

Author

Rauti R, Lozano N, León V, Scaini D, Musto M, Rago I, Ulloa Severino FP, Fabbro A, Casalis L, Vázquez E, Kostarelos K, Prato M, and Ballerini L

Subjects

Animals, Calcium metabolism, Cell Culture Techniques, Down-Regulation, Fluorescent Antibody Technique, Optical Imaging, Particle Size, Rats, Surface Properties, Synapses physiology, Brain physiology, Graphite chemistry, Nanostructures chemistry, Nerve Net physiology, Neurons physiology, Oxides chemistry

Abstract

Graphene offers promising advantages for biomedical applications. However, adoption of graphene technology in biomedicine also poses important challenges in terms of understanding cell responses, cellular uptake, or the intracellular fate of soluble graphene derivatives. In the biological microenvironment, graphene nanosheets might interact with exposed cellular and subcellular structures, resulting in unexpected regulation of sophisticated biological signaling. More broadly, biomedical devices based on the design of these 2D planar nanostructures for interventions in the central nervous system require an accurate understanding of their interactions with the neuronal milieu. Here, we describe the ability of graphene oxide nanosheets to down-regulate neuronal signaling without affecting cell viability.

Published

2016

14. Graphene-Based Interfaces Do Not Alter Target Nerve Cells.

Author

Fabbro A, Scaini D, León V, Vázquez E, Cellot G, Privitera G, Lombardi L, Torrisi F, Tomarchio F, Bonaccorso F, Bosi S, Ferrari AC, Ballerini L, and Prato M

Subjects

Animals, Animals, Newborn, Cell Adhesion drug effects, Cell Survival drug effects, Electrodes, Hippocampus, Microscopy, Atomic Force, Neurons physiology, Neurons ultrastructure, Patch-Clamp Techniques, Primary Cell Culture, Rats, Synapses physiology, Synapses ultrastructure, Synaptic Transmission drug effects, Biocompatible Materials pharmacology, Graphite pharmacology, Nanotubes, Carbon chemistry, Neurons drug effects, Synapses drug effects

Abstract

Neural-interfaces rely on the ability of electrodes to transduce stimuli into electrical patterns delivered to the brain. In addition to sensitivity to the stimuli, stability in the operating conditions and efficient charge transfer to neurons, the electrodes should not alter the physiological properties of the target tissue. Graphene is emerging as a promising material for neuro-interfacing applications, given its outstanding physico-chemical properties. Here, we use graphene-based substrates (GBSs) to interface neuronal growth. We test our GBSs on brain cell cultures by measuring functional and synaptic integrity of the emerging neuronal networks. We show that GBSs are permissive interfaces, even when uncoated by cell adhesion layers, retaining unaltered neuronal signaling properties, thus being suitable for carbon-based neural prosthetic devices.

Published

2016

15. From 2D to 3D: novel nanostructured scaffolds to investigate signalling in reconstructed neuronal networks.

Author

Bosi S, Rauti R, Laishram J, Turco A, Lonardoni D, Nieus T, Prato M, Scaini D, and Ballerini L

Subjects

Animals, Calcium Signaling, Cell Culture Techniques, Cells, Cultured, Dimethylpolysiloxanes chemistry, Microscopy, Confocal, Models, Theoretical, Nanotubes, Carbon chemistry, Neurons metabolism, Porosity, Rats, Tissue Scaffolds, Nanostructures chemistry, Neurons cytology

Abstract

To recreate in vitro 3D neuronal circuits will ultimately increase the relevance of results from cultured to whole-brain networks and will promote enabling technologies for neuro-engineering applications. Here we fabricate novel elastomeric scaffolds able to instruct 3D growth of living primary neurons. Such systems allow investigating the emerging activity, in terms of calcium signals, of small clusters of neurons as a function of the interplay between the 2D or 3D architectures and network dynamics. We report the ability of 3D geometry to improve functional organization and synchronization in small neuronal assemblies. We propose a mathematical modelling of network dynamics that supports such a result. Entrapping carbon nanotubes in the scaffolds remarkably boosted synaptic activity, thus allowing for the first time to exploit nanomaterial/cell interfacing in 3D growth support. Our 3D system represents a simple and reliable construct, able to improve the complexity of current tissue culture models.

Published

2015

16. Adhesion to carbon nanotube conductive scaffolds forces action-potential appearance in immature rat spinal neurons.

Author

Fabbro A, Sucapane A, Toma FM, Calura E, Rizzetto L, Carrieri C, Roncaglia P, Martinelli V, Scaini D, Masten L, Turco A, Gustincich S, Prato M, and Ballerini L

Subjects

Animals, Cell Adhesion, Cell Culture Techniques, Cell Differentiation, Gene Expression Profiling, Gene Expression Regulation, Molecular Sequence Annotation, Rats, Spinal Cord cytology, Action Potentials, Nanotubes, Carbon chemistry, Nanotubes, Carbon ultrastructure, Neurons cytology, Neurons physiology, Tissue Scaffolds chemistry

Abstract

In the last decade, carbon nanotube growth substrates have been used to investigate neurons and neuronal networks formation in vitro when guided by artificial nano-scaled cues. Besides, nanotube-based interfaces are being developed, such as prosthesis for monitoring brain activity. We recently described how carbon nanotube substrates alter the electrophysiological and synaptic responses of hippocampal neurons in culture. This observation highlighted the exceptional ability of this material in interfering with nerve tissue growth. Here we test the hypothesis that carbon nanotube scaffolds promote the development of immature neurons isolated from the neonatal rat spinal cord, and maintained in vitro. To address this issue we performed electrophysiological studies associated to gene expression analysis. Our results indicate that spinal neurons plated on electro-conductive carbon nanotubes show a facilitated development. Spinal neurons anticipate the expression of functional markers of maturation, such as the generation of voltage dependent currents or action potentials. These changes are accompanied by a selective modulation of gene expression, involving neuronal and non-neuronal components. Our microarray experiments suggest that carbon nanotube platforms trigger reparative activities involving microglia, in the absence of reactive gliosis. Hence, future tissue scaffolds blended with conductive nanotubes may be exploited to promote cell differentiation and reparative pathways in neural regeneration strategies.

Published

2013

17. Carbon nanotubes: artificial nanomaterials to engineer single neurons and neuronal networks.

Author

Fabbro A, Bosi S, Ballerini L, and Prato M

Subjects

Animals, Cells, Cultured, Humans, Neuronal Plasticity physiology, Patch-Clamp Techniques, Synapses physiology, Tissue Engineering, Nanostructures, Nanotubes, Carbon, Neural Networks, Computer, Neurons physiology

Abstract

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.

Published

2012

18. Carbon nanotube scaffolds tune synaptic strength in cultured neural circuits: novel frontiers in nanomaterial-tissue interactions.

Author

Cellot G, Toma FM, Varley ZK, Laishram J, Villari A, Quintana M, Cipollone S, Prato M, and Ballerini L

Subjects

Animals, Cell Membrane physiology, Cells, Cultured, Cerebral Cortex chemistry, Cerebral Cortex physiology, Electrophysiological Phenomena, Excitatory Postsynaptic Potentials physiology, Female, Fluorescent Antibody Technique, Hippocampus cytology, Male, Microscopy, Confocal, Microscopy, Electron, Transmission, Nanostructures, Nerve Net cytology, Neuronal Plasticity physiology, Patch-Clamp Techniques, Rats, Thermogravimetry, gamma-Aminobutyric Acid physiology, Nanotubes, Carbon, Nerve Net physiology, Neurons physiology, Synapses physiology, Tissue Scaffolds

Abstract

A long-term goal of tissue engineering is to exploit the ability of supporting materials to govern cell-specific behaviors. Instructive scaffolds code such information by modulating (via their physical and chemical features) the interface between cells and materials at the nanoscale. In modern neuroscience, therapeutic regenerative strategies (i.e., brain repair after damage) aim to guide and enhance the intrinsic capacity of the brain to reorganize by promoting plasticity mechanisms in a controlled fashion. Direct and specific interactions between synthetic materials and biological cell membranes may play a central role in this process. Here, we investigate the role of the material's properties alone, in carbon nanotube scaffolds, in constructing the functional building blocks of neural circuits: the synapses. Using electrophysiological recordings and rat cultured neural networks, we describe the ability of a nanoscaled material to promote the formation of synaptic contacts and to modulate their plasticity.

Published

2011

19. Interfacing neurons with carbon nanotubes: (re)engineering neuronal signaling.

Author

Fabbro A, Cellot G, Prato M, and Ballerini L

Subjects

Animals, Biocompatible Materials chemistry, Biocompatible Materials metabolism, Membrane Potentials physiology, Neurons cytology, Tissue Scaffolds, Nanotubes, Carbon chemistry, Neurons physiology, Signal Transduction physiology

Abstract

Carbon nanotubes (CNTs) are cylindrically shaped nanostructures made by sheets of graphene rolled up to form hollow tubes. Owing to their unique range of thermal, electronic, and structural properties, CNTs have been rapidly developing as a technology platform for biological and medical applications, including those designed to develop novel neuro-implantable devices. Depending on their structure, CNTs combine an incredible strength with an extreme flexibility. Further, these materials exhibit physical and chemical properties which allow them to efficiently conduit electrical current in electrochemical interfaces. CNTs can be organized in scaffolds made up of small fibers or tubes with diameters similar to those of neural processes such as axons and dendrites. Recently, CNT scaffolds have been found to promote growth, differentiation, and survival of neurons and to modify their electrophysiological properties. These features make CNTs an attractive material for the design of nano-bio hybrid systems able to govern cell-specific behaviors in cultured neuronal networks. The leading scope of this short review is to highlight how nanotube scaffolds can impact on neuronal signaling ability. In particular, we will focus on the direct and specific interactions between this synthetic nanomaterial and biological cell membranes, and on the ability of CNTs to improve interfaces developed to record or to stimulate neuronal activity. CNTs hold the potential for the development of innovative nanomaterial-based neurological implants. Therefore, it is particularly relevant to improve our knowledge on the impact on neuronal performance of interfacing nerve cells with CNTs., (Copyright © 2011 Elsevier B.V. All rights reserved.)

Published

2011

20. Neurons are able to internalize soluble carbon nanotubes: new opportunities or old risks?

Author

Cellot G, Ballerini L, Prato M, and Bianco A

Subjects

Cell Line, Cell Line, Tumor, Cells, Cultured, Humans, Nanotubes, Carbon, Neurons metabolism

Published

2010

21. Insights into medio-lateral signalling in the developing mouse hindbrain: properties of midline drivers of network activity.

Author

Ballerini L

Subjects

Animals, Cells, Cultured, Electric Conductivity, Mice, Rhombencephalon cytology, Action Potentials physiology, Calcium Signaling physiology, Cell Membrane physiology, Neurons physiology, Rhombencephalon embryology, Rhombencephalon physiology

Published

2009

22. The patterns of spontaneous Ca2+ signals generated by ventral spinal neurons in vitro show time-dependent refinement.

Author

Sibilla S, Fabbro A, Grandolfo M, D'Andrea P, Nistri A, and Ballerini L

Subjects

6-Cyano-7-nitroquinoxaline-2,3-dione metabolism, Animals, Calbindins, Cells, Cultured, Embryo, Mammalian anatomy & histology, Embryo, Mammalian physiology, Enzyme Inhibitors metabolism, Excitatory Amino Acid Antagonists metabolism, Mice, Neurons cytology, Patch-Clamp Techniques, Ryanodine metabolism, S100 Calcium Binding Protein G metabolism, Sodium Channel Blockers metabolism, Spinal Cord embryology, Tetrodotoxin metabolism, Thapsigargin metabolism, Time Factors, Action Potentials physiology, Calcium metabolism, Calcium Signaling physiology, Neurons metabolism, Spinal Cord cytology

Abstract

Embryonic spinal neurons maintained in organotypic slice culture are known to mimic certain maturation-dependent signalling changes. With such a model we investigated, in embryonic mouse spinal segments, the age-dependent spatio-temporal control of intracellular Ca(2+) signalling generated by neuronal populations in ventral circuits and its relation with electrical activity. We used Ca(2+) imaging to monitor areas located within the ventral spinal horn at 1 and 2 weeks of in vitro growth. Primitive patterns of spontaneous neuronal Ca(2+) transients (detected at 1 week) were typically synchronous. Remarkably, such transients originated from widespread propagating waves that became organized into large-scale rhythmic bursts. These activities were associated with the generation of synaptically mediated inward currents under whole-cell patch-clamp. Such patterns disappeared during longer culture of spinal segments: at 2 weeks in culture, only a subset of ventral neurons displayed spontaneous, asynchronous and repetitive Ca(2+) oscillations dissociated from background synaptic activity. We observed that the emergence of oscillations was a restricted phenomenon arising together with the transformation of ventral network electrophysiological bursting into asynchronous synaptic discharges. This change was accompanied by the appearance of discrete calbindin immunoreactivity against an unchanged background of calretinin-positive cells. It is attractive to assume that periodic oscillations of Ca(2+) confer a summative ability to these cells to shape the plasticity of local circuits through different changes (phasic or tonic) in intracellular Ca(2+).

Published

2009

23. Carbon nanotubes might improve neuronal performance by favouring electrical shortcuts.

Author

Cellot G, Cilia E, Cipollone S, Rancic V, Sucapane A, Giordani S, Gambazzi L, Markram H, Grandolfo M, Scaini D, Gelain F, Casalis L, Prato M, Giugliano M, and Ballerini L

Subjects

Action Potentials, Animals, Biocompatible Materials chemistry, Cell Adhesion, Cells, Cultured, Electric Capacitance, Electric Stimulation instrumentation, Electric Stimulation methods, Microscopy, Electron, Scanning, Nanotechnology methods, Patch-Clamp Techniques, Rats, Tissue Scaffolds chemistry, Nanotechnology instrumentation, Nanotubes, Carbon chemistry, Neural Conduction, Neurons physiology

Abstract

Carbon nanotubes have been applied in several areas of nerve tissue engineering to probe and augment cell behaviour, to label and track subcellular components, and to study the growth and organization of neural networks. Recent reports show that nanotubes can sustain and promote neuronal electrical activity in networks of cultured cells, but the ways in which they affect cellular function are still poorly understood. Here, we show, using single-cell electrophysiology techniques, electron microscopy analysis and theoretical modelling, that nanotubes improve the responsiveness of neurons by forming tight contacts with the cell membranes that might favour electrical shortcuts between the proximal and distal compartments of the neuron. We propose the 'electrotonic hypothesis' to explain the physical interactions between the cell and nanotube, and the mechanisms of how carbon nanotubes might affect the collective electrical activity of cultured neuronal networks. These considerations offer a perspective that would allow us to predict or engineer interactions between neurons and carbon nanotubes.

Published

2009

24. Interfacing neurons with carbon nanotubes: electrical signal transfer and synaptic stimulation in cultured brain circuits.

Author

Mazzatenta A, Giugliano M, Campidelli S, Gambazzi L, Businaro L, Markram H, Prato M, and Ballerini L

Subjects

Action Potentials physiology, Animals, Animals, Newborn, Cell Culture Techniques instrumentation, Cell Culture Techniques methods, Electric Stimulation instrumentation, Electric Stimulation methods, Hippocampus ultrastructure, Microscopy, Electron, Scanning, Models, Neurological, Nanotechnology instrumentation, Neural Pathways physiology, Neural Pathways ultrastructure, Neurons ultrastructure, Organ Culture Techniques, Patch-Clamp Techniques, Rats, Rats, Sprague-Dawley, Hippocampus physiology, Nanotechnology methods, Nanotubes, Carbon chemistry, Neurons physiology, Prostheses and Implants trends, Synaptic Transmission physiology

Abstract

The unique properties of single-wall carbon nanotubes (SWNTs) and the application of nanotechnology to the nervous system may have a tremendous impact in the future developments of microsystems for neural prosthetics as well as immediate benefits for basic research. Despite increasing interest in neuroscience nanotechnologies, little is known about the electrical interactions between nanomaterials and neurons. We developed an integrated SWNT-neuron system to test whether electrical stimulation delivered via SWNT can induce neuronal signaling. To that aim, hippocampal cells were grown on pure SWNT substrates and patch clamped. We compared neuronal responses to voltage steps delivered either via conductive SWNT substrates or via the patch pipette. Our experimental results, supported by mathematical models to describe the electrical interactions occurring in SWNT-neuron hybrid systems, clearly indicate that SWNTs can directly stimulate brain circuit activity.

Published

2007

25. Activity-independent intracellular Ca2+ oscillations are spontaneously generated by ventral spinal neurons during development in vitro.

Author

Fabbro A, Pastore B, Nistri A, and Ballerini L

Subjects

Animals, Calcium pharmacology, Calcium Channels metabolism, Gap Junctions metabolism, Glutamic Acid pharmacology, Immunohistochemistry, In Vitro Techniques, Mice, Mice, Inbred C57BL, Time Factors, gamma-Aminobutyric Acid metabolism, Calcium metabolism, Calcium Signaling, Ganglia, Spinal metabolism, Neurons metabolism, Spinal Cord metabolism

Abstract

Within the CNS, distinct neurons may rely on different processes to modulate cytosolic Ca2+ depending on the network developmental phase. In particular, in the immature spinal cord, synchronous electrical discharges are coupled with biochemical signals triggered by intracellular Ca2+ waves. Nevertheless, the presence of neuronal-specific Ca2+ elevations independent from synaptic activity within mammalian spinal networks has not yet been described. The present report is the first description of repetitive calcium events generated by discrete ventral spinal neurons maintained in organotypic culture during in vitro maturation stages crucial for network evolution. Ventral interneurons in one-third of slices displayed spontaneous intracellular calcium transients suppressed by calcium-free extracellular solution or by application of cobalt, and resistant to blockers of network activity like TTX, CNQX, APV, strychnine or bicuculline. Our data suggest a primary role for mitochondria in intracellular calcium oscillations, because CCCP, that selectively collapses the mitochondrial electrochemical gradient, eliminated the ability of these neurons to show activity-independent calcium oscillations. Likewise, CGP-37157, a blocker of mitochondrial Na+/Ca2+ exchanger, inhibited oscillations in the majority of neurons. We propose that spontaneous Ca2+ transients, dynamically regulated by mitochondria, occurred in a discrete cluster of interneurons possibly to guide the development of synaptic connections.

Published

2007

26. Carbon nanotube substrates boost neuronal electrical signaling.

Author

Lovat V, Pantarotto D, Lagostena L, Cacciari B, Grandolfo M, Righi M, Spalluto G, Prato M, and Ballerini L

Subjects

Animals, Astrocytes metabolism, Cell Adhesion, Cell Survival, Crystallization, Dendrites metabolism, Electronics, Glial Fibrillary Acidic Protein metabolism, Hippocampus metabolism, Humans, Immunohistochemistry, Models, Chemical, Signal Transduction, Time Factors, Electrochemistry methods, Nanotechnology methods, Nanotubes, Carbon chemistry, Neurons metabolism

Abstract

We demonstrate the possibility of using carbon nanotubes (CNTs) as potential devices able to improve neural signal transfer while supporting dendrite elongation and cell adhesion. The results strongly suggest that the growth of neuronal circuits on a CNT grid is accompanied by a significant increase in network activity. The increase in the efficacy of neural signal transmission may be related to the specific properties of CNT materials, such as the high electrical conductivity.

Published

2005

27. Electrophysiological interactions between 5-hydroxytryptamine and thyrotropin releasing hormone on rat hippocampal CA1 neurons.

Author

Ballerini L, Corradetti R, Nistri A, Pugliese AM, and Stocca G

Subjects

Animals, Electrophysiology, Hippocampus cytology, Hippocampus physiology, In Vitro Techniques, Male, Membrane Potentials drug effects, Neurons physiology, Patch-Clamp Techniques, Potassium Channels drug effects, Potassium Channels metabolism, Pyramidal Cells drug effects, Pyramidal Cells physiology, Rats, Rats, Wistar, Hippocampus drug effects, Neurons drug effects, Serotonin pharmacology, Thyrotropin-Releasing Hormone pharmacology

Abstract

Intracellular recording from CA1 neurons of the rat hippocampal slice preparation was used to examine the possibility of functional interactions between 5-hydroxytryptamine (5-HT) and thyrotropin releasing hormone (TRH), which act as cotransmitters in other areas of the central nervous system. 5-HT (30 microM) elicited complex effects consisting of biphasic changes in membrane potential and a strong depression of the afterhyperpolarization (AHP) following a spike burst. TRH (10 microM) did not alter membrane potential or input conductance but it produced a partial block of the AHP. Under single-electrode voltage clamp, 5-HT and TRH both reduced the amplitude of voltage-activated total K+ currents. When the two substances were co-applied, their actions were occluded. The voltage-activated K+ current remaining in Ca(2+)-free solution lost its sensitivity to 5-HT and TRH, suggesting that the K+ current modulated by TRH and 5-HT was Ca(2+)-dependent, although TRH itself did not depress high-threshold voltage-activated Ca2+ currents. When a relatively small concentration (5 microM) of 5-HT was co-applied with an equimolar amount of TRH, the degree of block of the spike AHP was the sum of the two individual effects of these drugs. It is suggested that in hippocampal pyramidal cells 5-HT and TRH influenced neuronal excitability by depressing a Ca(2+)-dependent K+ current, a phenomenon perhaps mediated through a common intracellular second messenger pathway.

Published

1994