Biocompatibility of pristine graphene for neuronal interface.

OBJECT Graphene possesses unique electrical, physical, and chemical properties that may offer significant potential as a bioscaffold for neuronal regeneration after spinal cord injury. The purpose of this investigation was to establish the in vitro biocompatibility of pristine graphene for interface with primary rat cortical neurons. METHODS Graphene films were prepared by chemical vapor deposition on a copper foil catalytic substrate and subsequent apposition on bare Permanox plastic polymer dishes. Rat neuronal cell culture was grown on graphene-coated surfaces, and cell growth and attachment were compared with those on uncoated and poly-d-lysine (PDL)-coated controls; the latter surface is highly favorable for neuronal attachment and growth. Live/dead cell analysis was conducted with flow cytometry using ethidium homodimer-1 and calcein AM dyes. Lactate dehydrogenase (LDH) levels-indicative of cytotoxicity-were measured as markers of cell death. Phase contrast microscopy of active cell culture was conducted to assess neuronal attachment and morphology. RESULTS Statistically significant differences in the percentage of live or dead neurons were noted between graphene and PDL surfaces, as well as between the PDL-coated and bare surfaces, but there was little difference in cell viability between graphene-coated and bare surfaces. There were significantly lower LDH levels in the graphene-coated samples compared with the uncoated ones, indicating that graphene was not more cytotoxic than the bare control surface. According to phase contrast microscopy, neurons attached to the graphene-coated surface and were able to elaborate long, neuritic processes suggestive of normal neuronal metabolism and morphology. CONCLUSIONS Further use of graphene as a bioscaffold will require surface modification that enhances hydrophilicity to increase cellular attachment and growth. Graphene is a nanomaterial that is biocompatible with neurons and may have significant biomedical applications.

[1]  Mi-Hee Kim,et al.  Behaviors of NIH-3T3 fibroblasts on graphene/carbon nanotubes: proliferation, focal adhesion, and gene transfection studies. , 2010, ACS nano.

[2]  Omid Akhavan,et al.  Toxicity of graphene and graphene oxide nanowalls against bacteria. , 2010, ACS nano.

[3]  A. Reina,et al.  Controlled Formation of Sharp Zigzag and Armchair Edges in Graphitic Nanoribbons , 2009, Science.

[4]  G. Wallace,et al.  Mechanically Strong, Electrically Conductive, and Biocompatible Graphene Paper , 2008 .

[5]  A. Reina,et al.  Large area, few-layer graphene films on arbitrary substrates by chemical vapor deposition. , 2009, Nano letters.

[6]  Andre K. Geim,et al.  The rise of graphene. , 2007, Nature materials.

[7]  Filip Braet,et al.  Carbon nanomaterials in biosensors: should you use nanotubes or graphene? , 2010, Angewandte Chemie.

[8]  SUPARNA DUTTASINHA,et al.  Graphene: Status and Prospects , 2009, Science.

[9]  Yang Xu,et al.  Cytotoxicity effects of graphene and single-wall carbon nanotubes in neural phaeochromocytoma-derived PC12 cells. , 2010, ACS nano.

[10]  C. Korzeniewski,et al.  An enzyme-release assay for natural cytotoxicity. , 1983, Journal of immunological methods.

[11]  F. Guinea,et al.  Biased bilayer graphene: semiconductor with a gap tunable by the electric field effect. , 2006, Physical review letters.

[12]  Xiangmin Miao,et al.  A novel fluorescent biosensor for sequence-specific recognition of double-stranded DNA with the platform of graphene oxide. , 2011, The Analyst.

[13]  Kwang S. Kim,et al.  Large-scale pattern growth of graphene films for stretchable transparent electrodes , 2009, Nature.

[14]  N. Gall’,et al.  Two Dimensional Graphite Films on Metals and Their Intercalation , 1997 .

[15]  S. Stankovich,et al.  Graphene-silica composite thin films as transparent conductors. , 2007, Nano letters.

[16]  Zheng Yan,et al.  Growth of graphene from solid carbon sources , 2010, Nature.

[17]  P. Kim,et al.  Energy band-gap engineering of graphene nanoribbons. , 2007, Physical review letters.

[18]  M. Chhowalla,et al.  A review of chemical vapour deposition of graphene on copper , 2011 .

[19]  D. Basko Calculation of the Raman G peak intensity in monolayer graphene: role of Ward identities , 2009, 0910.0727.

[20]  K. Horn,et al.  Overcoming Macrophage-Mediated Axonal Dieback Following CNS Injury , 2009, The Journal of Neuroscience.

[21]  Yuehe Lin,et al.  Graphene and graphene oxide: biofunctionalization and applications in biotechnology , 2011, Trends in Biotechnology.

[22]  P. Nelson,et al.  Oscillating field stimulation for complete spinal cord injury in humans: a phase 1 trial. , 2005, Journal of neurosurgery. Spine.

[23]  A. Geim,et al.  Two-dimensional gas of massless Dirac fermions in graphene , 2005, Nature.

[24]  C. N. Lau,et al.  Superior thermal conductivity of single-layer graphene. , 2008, Nano letters.

[25]  J. Tour,et al.  Mechanically Assisted Exfoliation and Functionalization of Thermally Converted Graphene Sheets , 2009 .

[26]  Peter Wick,et al.  Effects of carbon nanotubes on primary neurons and glial cells. , 2009, Neurotoxicology.

[27]  A Gupta,et al.  Raman scattering from high-frequency phonons in supported n-graphene layer films. , 2006, Nano letters.

[28]  B F Sisken,et al.  Prospects on clinical applications of electrical stimulation for nerve regeneration , 1993, Journal of cellular biochemistry.

[29]  A. Reina,et al.  Growth of large-area single- and Bi-layer graphene by controlled carbon precipitation on polycrystalline Ni surfaces , 2009, 0906.2236.

[30]  J. Kong,et al.  Graphene substrates promote adherence of human osteoblasts and mesenchymal stromal cells , 2010 .

[31]  J. Tour,et al.  Soluble graphene through edge-selective functionalization , 2010 .

[32]  Andre K. Geim,et al.  Electric Field Effect in Atomically Thin Carbon Films , 2004, Science.

[33]  Peng Chen,et al.  Interfacing live cells with nanocarbon substrates. , 2010, Langmuir : the ACS journal of surfaces and colloids.

[34]  Zhuang Liu,et al.  PEGylated nanographene oxide for delivery of water-insoluble cancer drugs. , 2008, Journal of the American Chemical Society.

[35]  Jiali Zhang,et al.  Biocompatibility of Graphene Oxide , 2010, Nanoscale research letters.

[36]  Agnes B Kane,et al.  Biopersistence and potential adverse health impacts of fibrous nanomaterials: what have we learned from asbestos? , 2009, Wiley interdisciplinary reviews. Nanomedicine and nanobiotechnology.

[37]  Deepthy Menon,et al.  Differential nano-bio interactions and toxicity effects of pristine versus functionalized graphene. , 2011, Nanoscale.

[38]  Laura Ballerini,et al.  Interactions Between Cultured Neurons and Carbon Nanotubes: A Nanoneuroscience Vignette. , 2009, Journal of nanoneuroscience.

[39]  Yanli Chang,et al.  In vitro toxicity evaluation of graphene oxide on A549 cells. , 2011, Toxicology letters.

[40]  R. Kaner,et al.  Honeycomb carbon: a review of graphene. , 2010, Chemical reviews.

[41]  Yi Zhang,et al.  Synthesis, Transfer, and Devices of Single- and Few-Layer Graphene by Chemical Vapor Deposition , 2009, IEEE Transactions on Nanotechnology.

[42]  S. Banerjee,et al.  Large-Area Synthesis of High-Quality and Uniform Graphene Films on Copper Foils , 2009, Science.

[43]  S. Stankovich,et al.  Graphene-based composite materials , 2006, Nature.

[44]  Chunhai Fan,et al.  Graphene-based antibacterial paper. , 2010, ACS nano.

[45]  M. Suh,et al.  The control of neural cell-to-cell interactions through non-contact electrical field stimulation using graphene electrodes. , 2011, Biomaterials.

[46]  Jingyun Wang,et al.  Cytotoxicity of single-walled carbon nanotubes on PC12 cells. , 2011, Toxicology in vitro : an international journal published in association with BIBRA.

[47]  J. Tour,et al.  Layer-by-Layer Removal of Graphene for Device Patterning , 2011, Science.

[48]  Christy L Haynes,et al.  Cytotoxicity of graphene oxide and graphene in human erythrocytes and skin fibroblasts. , 2011, ACS applied materials & interfaces.

[49]  C. McCaig,et al.  The direction of neurite growth in a weak DC electric field depends on the substratum: contributions of adhesivity and net surface charge. , 1998, Developmental biology.

[50]  L. Yao,et al.  Small applied electric fields guide migration of hippocampal neurons , 2008, Journal of cellular physiology.