Gene-Embedded Nanostructural Biotic-Abiotic Optoelectrode Arrays Applied for Synchronous Brain Optogenetics and Neural Signal Recording.
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Yu-Chun Lo | Ta-Chung Liu | Min-Yu Chiang | Y. Chen | Y. Lo | San-Yuan Chen | Ssu-Ju Li | San-Yuan Chen | Wei-Chen Huang | You-Yin Chen | Hsu-Yan Chen | Wei‐Chen Huang | M. Chiang | Hui-Shang Chi | Yi-Chao Lee | Ssu-Ju Li | Yi-Chao Lee | Ta‐Chung Liu | Hui-Shang Chi | Hsu-Yan Chen
[1] Vinayak Sant,et al. Graphene-based nanomaterials for drug delivery and tissue engineering. , 2014, Journal of controlled release : official journal of the Controlled Release Society.
[2] S. Cogan. Neural stimulation and recording electrodes. , 2008, Annual review of biomedical engineering.
[3] Karl Deisseroth,et al. Optogenetics in Neural Systems , 2011, Neuron.
[4] J. Zak,et al. Conjugated polymers as robust carriers for controlled delivery of anti-inflammatory drugs , 2014, Journal of Materials Science.
[5] K. Meletis,et al. Genetic manipulation of adult mouse neurogenic niches by in vivo electroporation , 2008, Nature Methods.
[6] Jianping Zhou,et al. A chitosan-graft-PEI-candesartan conjugate for targeted co-delivery of drug and gene in anti-angiogenesis cancer therapy. , 2014, Biomaterials.
[7] Wen-Hung Chao,et al. Automatic spike sorting for extracellular electrophysiological recording using unsupervised single linkage clustering based on grey relational analysis , 2011, Journal of neural engineering.
[8] Anoop C. Patil,et al. Neural interfaces engineered via micro- and nanostructured coatings , 2017 .
[9] Carmen Alvarez-Lorenzo,et al. Crosslinked ionic polysaccharides for stimuli-sensitive drug delivery. , 2013, Advanced drug delivery reviews.
[10] H. Steinbusch,et al. In vivo electroporation of the central nervous system: A non-viral approach for targeted gene delivery , 2010, Progress in Neurobiology.
[11] N. Mei,et al. Assessment of the toxic potential of graphene family nanomaterials , 2014, Journal of food and drug analysis.
[12] L. Fadiga,et al. Multilayer poly(3,4-ethylenedioxythiophene)-dexamethasone and poly(3,4-ethylenedioxythiophene)-polystyrene sulfonate-carbon nanotubes coatings on glassy carbon microelectrode arrays for controlled drug release. , 2017, Biointerphases.
[13] Jakub Jończyk,et al. Therapeutic strategies for Alzheimer’s disease in clinical trials , 2016, Pharmacological reports : PR.
[14] Xiaoming Yang,et al. Well-dispersed chitosan/graphene oxide nanocomposites. , 2010, ACS applied materials & interfaces.
[15] C. Goetz,et al. Initial management of Parkinson’s disease , 2014, BMJ : British Medical Journal.
[16] Martin Fussenegger,et al. Method for generation of homogeneous multicellular tumor spheroids applicable to a wide variety of cell types. , 2003, Biotechnology and bioengineering.
[18] Ziyun Jiang,et al. Three-Dimensional Stiff Graphene Scaffold on Neural Stem Cells Behavior. , 2016, ACS applied materials & interfaces.
[19] Y. Glinka,et al. Electroporation-enhanced nonviral gene transfer for the prevention or treatment of immunological, endocrine and neoplastic diseases. , 2006, Current gene therapy.
[20] J. E. Collazos-Castro,et al. Biofunctionalized PEDOT-coated microfibers for the treatment of spinal cord injury. , 2016, Biomaterials.
[21] Michael R Hamblin,et al. Physical energy for drug delivery; poration, concentration and activation. , 2014, Advanced drug delivery reviews.
[22] Matthew M. Crane,et al. Real-time multimodal optical control of neurons and muscles in freely-behaving Caenorhabditis elegans , 2011, Nature Methods.
[23] Tadaharu Tsumoto,et al. RNAi-induced gene silencing by local electroporation in targeting brain region. , 2005, Journal of neurophysiology.
[24] S. Šatkauskas,et al. Effect of electroporation medium conductivity on exogenous molecule transfer to cells in vitro , 2019, Scientific Reports.
[25] San-Yuan Chen,et al. Synergistic hierarchical silicone-modified polysaccharide hybrid as a soft scaffold to control cell adhesion and proliferation. , 2014, Acta biomaterialia.
[26] L. Mir,et al. Use of conductive gels for electric field homogenization increases the antitumor efficacy of electroporation therapies , 2008, Physics in medicine and biology.
[27] M. Bahmani,et al. Oxidative stress and Parkinson's disease: New hopes in treatment with herbal antioxidants. , 2015, Current pharmaceutical design.
[28] Nasim Annabi,et al. Electroconductive Gelatin Methacryloyl-PEDOT:PSS Composite Hydrogels: Design, Synthesis, and Properties. , 2018, ACS biomaterials science & engineering.
[29] M. Abidian,et al. A Review of Organic and Inorganic Biomaterials for Neural Interfaces , 2014, Advanced materials.
[30] Shengshui Hu,et al. Nanocomposites of graphene and graphene oxides: Synthesis, molecular functionalization and application in electrochemical sensors and biosensors. A review , 2016, Microchimica Acta.
[31] Zhijun Zhang,et al. Functional graphene oxide as a nanocarrier for controlled loading and targeted delivery of mixed anticancer drugs. , 2010, Small.
[32] Michael Bruns,et al. An interpenetrating, microstructurable and covalently attached conducting polymer hydrogel for neural interfaces. , 2017, Acta biomaterialia.
[33] Y. Chen,et al. Conductive nanogel-interfaced neural microelectrode arrays with electrically controlled in-situ delivery of manganese ions enabling high-resolution MEMRI for synchronous neural tracing with deep brain stimulation. , 2017, Biomaterials.
[34] K. Deisseroth,et al. Millisecond-timescale, genetically targeted optical control of neural activity , 2005, Nature Neuroscience.
[35] Lief E. Fenno,et al. The development and application of optogenetics. , 2011, Annual review of neuroscience.
[36] Katsuhiko Ariga,et al. Two-Dimensional (2D) Nanomaterials towards Electrochemical Nanoarchitectonics in Energy-Related Applications , 2017 .
[37] Aaron D. Gilmour,et al. Interpenetrating Conducting Hydrogel Materials for Neural Interfacing Electrodes , 2017, Advanced healthcare materials.
[38] G. Bi,et al. Electrically Controlled Neurochemical Release from Dual‐Layer Conducting Polymer Films for Precise Modulation of Neural Network Activity in Rat Barrel Cortex , 2018, Advanced functional materials.
[39] S. Pun,et al. Neuron‐specific delivery of nucleic acids mediated by Tet1‐modified poly(ethylenimine) , 2007, The journal of gene medicine.
[40] P. Starr,et al. Combining cell transplants or gene therapy with deep brain stimulation for Parkinson's disease , 2015, Movement disorders : official journal of the Movement Disorder Society.
[41] He Shen,et al. Biomedical Applications of Graphene , 2012, Theranostics.
[42] Wei Lu,et al. Ultrafine Sulfur Nanoparticles in Conducting Polymer Shell as Cathode Materials for High Performance Lithium/Sulfur Batteries , 2013, Scientific Reports.
[43] In vivo electroporation to physiologically identified deep brain regions in postnatal mammals , 2014, Brain Structure and Function.
[44] L. Humphreys,et al. Enduring high-efficiency in vivo transfection of neurons with non-viral magnetoparticles in the rat visual cortex for optogenetic applications. , 2015, Nanomedicine : nanotechnology, biology, and medicine.
[45] Thomas Scheibel,et al. Electroconductive Biohybrid Hydrogel for Enhanced Maturation and Beating Properties of Engineered Cardiac Tissues , 2018, Advanced Functional Materials.
[46] E. Hirsch,et al. Understanding Dopaminergic Cell Death Pathways in Parkinson Disease , 2016, Neuron.
[47] A. C. Jayasuriya,et al. The effect of graphene substrate on osteoblast cell adhesion and proliferation. , 2013, Journal of biomedical materials research. Part A.
[48] Jeffrey J. Tabor,et al. Light-Activated Nuclear Translocation of Adeno-Associated Virus Nanoparticles Using Phytochrome B for Enhanced, Tunable, and Spatially Programmable Gene Delivery. , 2016, ACS nano.
[49] M. Rols,et al. Ionic-strength modulation of electrically induced permeabilization and associated fusion of mammalian cells. , 1989, European journal of biochemistry.
[50] J. Jin,et al. Subsurface mechanical properties of polyurethane/organoclay nanocomposite thin films studied by nanoindentation , 2010 .
[51] Li-Wei Kuo,et al. Multifunctional 3D Patternable Drug‐Embedded Nanocarrier‐Based Interfaces to Enhance Signal Recording and Reduce Neuron Degeneration in Neural Implantation , 2015, Advanced materials.
[52] Xinyan Tracy Cui,et al. Electrochemically controlled release of dexamethasone from conducting polymer polypyrrole coated electrode. , 2006, Journal of controlled release : official journal of the Controlled Release Society.
[53] G. Shi,et al. Graphene oxide/conducting polymer composite hydrogels , 2011 .
[54] Wei Fan,et al. Dye-Sensitized Core/Active Shell Upconversion Nanoparticles for Optogenetics and Bioimaging Applications. , 2016, ACS nano.
[55] Sabine Szunerits,et al. Graphene-based biosensors , 2018, Interface Focus.
[56] K. Ono,et al. Rapid and efficient gene delivery into the adult mouse brain via focal electroporation , 2016, Scientific Reports.
[57] San-Yuan Chen,et al. An amphiphilic silicone-modified polysaccharide molecular hybrid with in situ forming of hierarchical superporous architecture upon swelling , 2012 .
[58] M. Abidian,et al. Conducting‐Polymer Nanotubes for Controlled Drug Release , 2006, Advanced materials.
[59] Y. Chen,et al. Neurotensin‐Conjugated Reduced Graphene Oxide with Multi‐Stage Near‐Infrared‐Triggered Synergic Targeted Neuron Gene Transfection In Vitro and In Vivo for Neurodegenerative Disease Therapy , 2016, Advanced healthcare materials.