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      N 3-MEA Probes: Scooping Neuronal Networks

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          Abstract

          In the current work, we introduce a brand new line of versatile, flexible, and multifunctional MEA probes, the so-called Nano Neuro Net, or N 3-MEAs. Material choice, dimensions, and room for further upgrade, were carefully considered when designing such probes in order to cover the widest application range possible. Proof of the operation principle of these novel probes is shown in the manuscript via the recording of extracellular signals, such as action potentials and local field potentials from cardiac cells and retinal ganglion cells of the heart tissue and eye respectively. Reasonably large signal to noise ratio (SNR) combined with effortless operation of the devices, mechanical and chemical stability, multifunctionality provide, in our opinion, an unprecedented blend. We show successful recordings of (1) action potentials from heart tissue with a SNR up to 13.2; (2) spontaneous activity of retinal ganglion cells with a SNR up to 12.8; and (3) local field potentials with an ERG-like waveform, as well as spiking responses of the retina to light stimulation. The results reveal not only the multi-functionality of these N 3-MEAs, but high quality recordings of electrogenic tissues.

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          Dissolvable films of silk fibroin for ultrathin conformal bio-integrated electronics.

          Dae-Hyeong Kim, Jonathan Viventi, Jason J Amsden (2010)
          Electronics that are capable of intimate, non-invasive integration with the soft, curvilinear surfaces of biological tissues offer important opportunities for diagnosing and treating disease and for improving brain/machine interfaces. This article describes a material strategy for a type of bio-interfaced system that relies on ultrathin electronics supported by bioresorbable substrates of silk fibroin. Mounting such devices on tissue and then allowing the silk to dissolve and resorb initiates a spontaneous, conformal wrapping process driven by capillary forces at the biotic/abiotic interface. Specialized mesh designs and ultrathin forms for the electronics ensure minimal stresses on the tissue and highly conformal coverage, even for complex curvilinear surfaces, as confirmed by experimental and theoretical studies. In vivo, neural mapping experiments on feline animal models illustrate one mode of use for this class of technology. These concepts provide new capabilities for implantable and surgical devices.
          Article 0 comments Cited 520 times – based on 0 reviews     Review now
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            NeuroGrid: recording action potentials from the surface of the brain

            Dion Khodagholy, Jennifer N. Gelinas, Thomas Thesen (2014)
            Recording from neural networks at the resolution of action potentials is critical for understanding how information is processed in the brain. Here, we address this challenge by developing an organic material-based, ultra-conformable, biocompatible and scalable neural interface array (the ‘NeuroGrid’) that can record both LFP and action potentials from superficial cortical neurons without penetrating the brain surface. Spikes with features of interneurons and pyramidal cells were simultaneously acquired by multiple neighboring electrodes of the NeuroGrid, allowing for isolation of putative single neurons in rats. Spiking activity demonstrated consistent phase modulation by ongoing brain oscillations and was stable in recordings exceeding one week. We also recorded LFP-modulated spiking activity intra-operatively in patients undergoing epilepsy surgery. The NeuroGrid constitutes an effective method for large-scale, stable recording of neuronal spikes in concert with local population synaptic activity, enhancing comprehension of neural processes across spatiotemporal scales and potentially facilitating diagnosis and therapy for brain disorders.
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              2D and 3D cell cultures – a comparison of different types of cancer cell cultures

              Marta Kapałczyńska, Tomasz Kolenda, Weronika Przybyła (2016)
              Cell culture is a widely used in vitro tool for improving our understanding of cell biology, tissue morphology, and mechanisms of diseases, drug action, protein production and the development of tissue engineering. Most research regarding cancer biology is based on experiments using two-dimensional (2D) cell cultures in vitro. However, 2D cultures have many limitations, such as the disturbance of interactions between the cellular and extracellular environments, changes in cell morphology, polarity, and method of division. These disadvantages led to the creation of models which are more closely able to mimic conditions in vivo. One such method is three-dimensional culture (3D). Optimisation of the culture conditions may allow for a better understanding of cancer biology and facilitate the study of biomarkers and targeting therapies. In this review, we compare 2D and 3D cultures in vitro as well as different versions of 3D cultures.
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                Author and article information

                Contributors
                Journal
                Journal ID (nlm-ta): Front Neurosci
                Journal ID (iso-abbrev): Front Neurosci
                Journal ID (publisher-id): Front. Neurosci.
                Title: Frontiers in Neuroscience
                Publisher: Frontiers Media S.A.
                ISSN (Print): 1662-4548
                ISSN (Electronic): 1662-453X
                Publication date (Electronic): 10 April 2019
                Publication date Collection: 2019
                Volume: 13
                Electronic Location Identifier: 320
                Affiliations
                [1] 1Forschungszentrum Jülich, Institute of Bioelectronics (ICS-8) , Jülich, Germany
                [2] 2Department of Electrical and Computer Engineering, University of Texas at Austin , Austin, TX, United States
                Author notes

                Edited by: Udo Kraushaar, Natural and Medical Sciences Institute, Germany

                Reviewed by: Marc Heuschkel, University of Applied Sciences and Arts of Western Switzerland, Switzerland; Yilin Song, Institute of Electronics, Chinese Academy of Sciences, China

                *Correspondence: Dmitry Kireev kirdmitry@ 123456gmail.com

                This article was submitted to Neural Technology, a section of the journal Frontiers in Neuroscience

                Article
                DOI: 10.3389/fnins.2019.00320
                PMC ID: 6467947
                PubMed ID: 31024239
                SO-VID: 6c5559c5-9bb9-4e45-88e2-5cc9973336c0
                Copyright © Copyright © 2019 Kireev, Rincón Montes, Stevanovic, Srikantharajah and Offenhäusser.
                License:

                This is an open-access article distributed under the terms of the Creative Commons Attribution License (CC BY). The use, distribution or reproduction in other forums is permitted, provided the original author(s) and the copyright owner(s) are credited and that the original publication in this journal is cited, in accordance with accepted academic practice. No use, distribution or reproduction is permitted which does not comply with these terms.

                History
                Date received : 14 December 2018
                Date accepted : 20 March 2019
                Page count
                Figures: 6, Tables: 0, Equations: 0, References: 37, Pages: 10, Words: 7072
                Categories
                Subject: Neuroscience
                Subject: Original Research

                ScienceOpen disciplines: Neurosciences
                Keywords: microelectrode array,neuronal networks,neural probes,advanced neurotechologies,brain-computer interface
                Data availability:
                ScienceOpen disciplines: Neurosciences
                Keywords: microelectrode array, neuronal networks, neural probes, advanced neurotechologies, brain-computer interface

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