Applied Neuroscience & Neuroengineering Literature

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  2020 (7)
BrainKilter: A Real-Time EEG Analysis Platform for Neurofeedback Design and Training. Pei, G.; Guo, G.; Chen, D.; Yang, R.; Shi, Z.; Wang, S.; Zhang, J.; Wu, J.; and Yan, T. IEEE Access, 8: 57661–57673. 2020. ZSCC: 0000002 Conference Name: IEEE Access
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Consensus on the reporting and experimental design of clinical and cognitive-behavioural neurofeedback studies (CRED-nf checklist). Ros, T.; Enriquez-Geppert, S.; Zotev, V.; Young, K. D; Wood, G.; Whitfield-Gabrieli, S.; Wan, F.; Vuilleumier, P.; Vialatte, F.; Van De Ville, D.; Todder, D.; Surmeli, T.; Sulzer, J. S; Strehl, U.; Sterman, M. B.; Steiner, N. J; Sorger, B.; Soekadar, S. R; Sitaram, R.; Sherlin, L. H; Schönenberg, M.; Scharnowski, F.; Schabus, M.; Rubia, K.; Rosa, A.; Reiner, M.; Pineda, J. A; Paret, C.; Ossadtchi, A.; Nicholson, A. A; Nan, W.; Minguez, J.; Micoulaud-Franchi, J.; Mehler, D. M A; Lührs, M.; Lubar, J.; Lotte, F.; Linden, D. E J; Lewis-Peacock, J. A; Lebedev, M. A; Lanius, R. A; Kübler, A.; Kranczioch, C.; Koush, Y.; Konicar, L.; Kohl, S. H; Kober, S. E; Klados, M. A; Jeunet, C.; Janssen, T W P; Huster, R. J; Hoedlmoser, K.; Hirshberg, L. M; Heunis, S.; Hendler, T.; Hampson, M.; Guggisberg, A. G; Guggenberger, R.; Gruzelier, J. H; Göbel, R. W; Gninenko, N.; Gharabaghi, A.; Frewen, P.; Fovet, T.; Fernández, T.; Escolano, C.; Ehlis, A.; Drechsler, R.; Christopher deCharms , R; Debener, S.; De Ridder, D.; Davelaar, E. J; Congedo, M.; Cavazza, M.; Breteler, M. H M; Brandeis, D.; Bodurka, J.; Birbaumer, N.; Bazanova, O. M; Barth, B.; Bamidis, P. D; Auer, T.; Arns, M.; and Thibault, R. T Brain, 143(6): 1674–1685. June 2020. ZSCC: NoCitationData[s0]
Consensus on the reporting and experimental design of clinical and cognitive-behavioural neurofeedback studies (CRED-nf checklist) [link]Paper   doi   bibtex   abstract  
Real-time fMRI feedback impacts brain activation, results in auditory hallucinations reduction: Part 1: Superior temporal gyrus -Preliminary evidence. Okano, K.; Bauer, C. C. C.; Ghosh, S. S.; Lee, Y. J.; Melero, H.; de Los Angeles, C.; Nestor, P. G.; Del Re, E. C.; Northoff, G.; Whitfield-Gabrieli, S.; and Niznikiewicz, M. A. Psychiatry Research, 286: 112862. February 2020. ZSCC: NoCitationData[s0]
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CLoSES: A platform for closed-loop intracranial stimulation in humans. Zelmann, R.; Paulk, A. C.; Basu, I.; Sarma, A.; Yousefi, A.; Crocker, B.; Eskandar, E.; Williams, Z.; Cosgrove, G. R.; Weisholtz, D. S.; Dougherty, D. D.; Truccolo, W.; Widge, A. S.; and Cash, S. S. NeuroImage, 223: 117314. December 2020. ZSCC: NoCitationData[s0]
CLoSES: A platform for closed-loop intracranial stimulation in humans [link]Paper   doi   bibtex   abstract  
Investigation of the effects of transcranial direct current stimulation and neurofeedback by continuous performance test. Guleken, Z.; Eskikurt, G.; and Karamürsel, S. Neuroscience Letters, 716: 134648. January 2020. ZSCC: 0000000
Investigation of the effects of transcranial direct current stimulation and neurofeedback by continuous performance test [link]Paper   doi   bibtex   abstract  
SimBSI: An open-source Simulink library for developing closed-loop brain signal interfaces in animals and humans. Ojeda, A.; Buscher, N.; Balasubramani, P.; Maric, V.; Ramanathan, D.; and Mishra, J. Biomedical Physics & Engineering Express, 6(3): 035023. April 2020. ZSCC: 0000001
SimBSI: An open-source Simulink library for developing closed-loop brain signal interfaces in animals and humans [link]Paper   doi   bibtex  
Respiratory regulation & interactions with neuro-cognitive circuitry. Maric, V.; Ramanathan, D.; and Mishra, J. Neuroscience & Biobehavioral Reviews, 112: 95–106. May 2020. ZSCC: 0000001
Respiratory regulation & interactions with neuro-cognitive circuitry [link]Paper   doi   bibtex  
  2019 (5)
The Interface Is the (Art)Work: EEG-Feedback, Circuited Selves and the Rise of Real-Time Brainmedia (1964–1977). Lysen, F. In Nijholt, A., editor(s), Brain Art: Brain-Computer Interfaces for Artistic Expression, pages 33–63. Springer International Publishing, Cham, 2019. ZSCC: NoCitationData[s0]
The Interface Is the (Art)Work: EEG-Feedback, Circuited Selves and the Rise of Real-Time Brainmedia (1964–1977) [link]Paper   doi   bibtex   abstract  
19 Channel Z-Score and LORETA Neurofeedback: Does the Evidence Support the Hype?. Coben, R.; Hammond, D. C.; and Arns, M. Applied Psychophysiology and Biofeedback, 44(1): 1–8. March 2019. ZSCC: 0000010
19 Channel Z-Score and LORETA Neurofeedback: Does the Evidence Support the Hype? [link]Paper   doi   bibtex   abstract  
Functional control of electrophysiological network architecture using direct neurostimulation in humans. Khambhati, A. N.; Kahn, A. E.; Costantini, J.; Ezzyat, Y.; Solomon, E. A.; Gross, R. E.; Jobst, B. C.; Sheth, S. A.; Zaghloul, K. A.; Worrell, G.; Seger, S.; Lega, B. C.; Weiss, S.; Sperling, M. R.; Gorniak, R.; Das, S. R.; Stein, J. M.; Rizzuto, D. S.; Kahana, M. J.; Lucas, T. H.; Davis, K. A.; Tracy, J. I.; and Bassett, D. S. Network Neuroscience, 3(3): 848–877. January 2019. ZSCC: NoCitationData[s0] Publisher: MIT Press
Functional control of electrophysiological network architecture using direct neurostimulation in humans [link]Paper   doi   bibtex   abstract  
Targeting Cognition and Networks Through Neural Oscillations: Next-Generation Clinical Brain Stimulation. Widge, A. S.; and Miller, E. K. JAMA Psychiatry, 76(7): 671. July 2019. ZSCC: 0000006
Targeting Cognition and Networks Through Neural Oscillations: Next-Generation Clinical Brain Stimulation [link]Paper   doi   bibtex  
Significant improvement in treatment resistant auditory verbal hallucinations after 5 days of double-blind, randomized, sham controlled, fronto-temporal, transcranial direct current stimulation (tDCS): A replication/extension study. Kantrowitz, J. T.; Sehatpour, P.; Avissar, M.; Horga, G.; Gwak, A.; Hoptman, M. J.; Beggel, O.; Girgis, R. R.; Vail, B.; Silipo, G.; Carlson, M.; and Javitt, D. C. Brain Stimulation, 12(4): 981–991. July 2019. ZSCC: NoCitationData[s0]
Significant improvement in treatment resistant auditory verbal hallucinations after 5 days of double-blind, randomized, sham controlled, fronto-temporal, transcranial direct current stimulation (tDCS): A replication/extension study [link]Paper   doi   bibtex   abstract  
  2017 (3)
Closed-loop brain training: the science of neurofeedback. Sitaram, R.; Ros, T.; Stoeckel, L.; Haller, S.; Scharnowski, F.; Lewis-Peacock, J.; Weiskopf, N.; Blefari, M. L.; Rana, M.; Oblak, E.; Birbaumer, N.; and Sulzer, J. Nature Reviews Neuroscience, 18(2): 86–100. February 2017. ZSCC: 0000400
Closed-loop brain training: the science of neurofeedback [link]Paper   doi   bibtex   abstract  
Transcranial Direct Current Stimulation in Patients with Prolonged Disorders of Consciousness: Combined Behavioral and Event-Related Potential Evidence. Zhang, Y.; Song, W.; Du, J.; Huo, S.; Shan, G.; and Li, R. Frontiers in Neurology, 8. 2017. ZSCC: 0000017 Publisher: Frontiers
Transcranial Direct Current Stimulation in Patients with Prolonged Disorders of Consciousness: Combined Behavioral and Event-Related Potential Evidence [link]Paper   doi   bibtex   abstract  
Mechanisms and Effects of Transcranial Direct Current Stimulation. Giordano, J.; Bikson, M.; Kappenman, E. S.; Clark, V. P.; Coslett, H. B.; Hamblin, M. R.; Hamilton, R.; Jankord, R.; Kozumbo, W. J.; McKinley, R. A.; Nitsche, M. A.; Reilly, J. P.; Richardson, J.; Wurzman, R.; and Calabrese, E. Dose-Response, 15(1): 1559325816685467. March 2017. ZSCC: NoCitationData[s0] Publisher: SAGE Publications Inc
Mechanisms and Effects of Transcranial Direct Current Stimulation [link]Paper   doi   bibtex   abstract  
  2016 (6)
A psychoengineering paradigm for the neurocognitive mechanisms of biofeedback and neurofeedback. Gaume, A.; Vialatte, A.; Mora-Sánchez, A.; Ramdani, C.; and Vialatte, F. Neuroscience & Biobehavioral Reviews, 68: 891–910. September 2016. ZSCC: NoCitationData[s0]
A psychoengineering paradigm for the neurocognitive mechanisms of biofeedback and neurofeedback [link]Paper   doi   bibtex  
Case studies in neural data analysis: a guide for the practicing neuroscientist. Kramer, M. A.; and Eden, U. T. of Computational neuroscience seriesThe MIT Press, Cambridge, Massachusetts, 2016. ZSCC: NoCitationData[s0]
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Case studies in neural data analysis: a guide for the practicing neuroscientist. Kramer, M. A.; and Eden, U. T. of Computational neuroscience seriesThe MIT Press, Cambridge, Massachusetts, 2016. ZSCC: NoCitationData[s0]
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Effects of Fronto-Temporal Transcranial Direct Current Stimulation on Auditory Verbal Hallucinations and Resting-State Functional Connectivity of the Left Temporo-Parietal Junction in Patients With Schizophrenia. Mondino, M.; Jardri, R.; Suaud-Chagny, M.; Saoud, M.; Poulet, E.; and Brunelin, J. Schizophrenia Bulletin, 42(2): 318–326. March 2016. ZSCC: NoCitationData[s0] Publisher: Oxford Academic
Effects of Fronto-Temporal Transcranial Direct Current Stimulation on Auditory Verbal Hallucinations and Resting-State Functional Connectivity of the Left Temporo-Parietal Junction in Patients With Schizophrenia [link]Paper   doi   bibtex   abstract  
Neuroplastic Mechanisms Underlying Perceptual and Cognitive Enhancement. de Villers-Sidani, E.; Mishra, J.; Zhou, X.; and Voss, P. Neural Plasticity, 2016: 1–2. 2016. ZSCC: 0000000
Neuroplastic Mechanisms Underlying Perceptual and Cognitive Enhancement [link]Paper   doi   bibtex  
Review of analytical instruments for EEG analysis. Agapov, S. N.; Bulanov, V. A.; Zakharov, A. V.; and Sergeeva, M. S. arXiv:1605.01381 [q-bio]. March 2016. ZSCC: 0000001 arXiv: 1605.01381
Review of analytical instruments for EEG analysis [link]Paper   bibtex   abstract  
  2015 (2)
Efficacy of Transcranial Magnetic Stimulation (TMS) in the Treatment of Schizophrenia: A Review of the Literature to Date. Cole, J. C.; Green Bernacki, C.; Helmer, A.; Pinninti, N.; and O’reardon, J. P. Innovations in Clinical Neuroscience, 12(7-8): 12–19. 2015. ZSCC: NoCitationData[s0]
Efficacy of Transcranial Magnetic Stimulation (TMS) in the Treatment of Schizophrenia: A Review of the Literature to Date [link]Paper   bibtex   abstract  
Enhancing cognition using transcranial electrical stimulation. Santarnecchi, E.; Brem, A.; Levenbaum, E.; Thompson, T.; Kadosh, R. C.; and Pascual-Leone, A. Current Opinion in Behavioral Sciences, 4: 171–178. August 2015. ZSCC: 0000101
Enhancing cognition using transcranial electrical stimulation [link]Paper   doi   bibtex  
  2014 (4)
Neuroenhancement: Enhancing brain and mind in health and in disease. Clark, V. P.; and Parasuraman, R. NeuroImage, 85: 889–894. January 2014. ZSCC: 0000102
Neuroenhancement: Enhancing brain and mind in health and in disease [link]Paper   doi   bibtex   abstract  
The effects of theta transcranial alternating current stimulation (tACS) on fluid intelligence. Pahor, A.; and Jaušovec, N. International Journal of Psychophysiology, 93(3): 322–331. September 2014. ZSCC: 0000063
The effects of theta transcranial alternating current stimulation (tACS) on fluid intelligence [link]Paper   doi   bibtex   abstract  
Is neuroenhancement by noninvasive brain stimulation a net zero-sum proposition?. Brem, A.; Fried, P. J.; Horvath, J. C.; Robertson, E. M.; and Pascual-Leone, A. NeuroImage, 85: 1058–1068. January 2014.
Is neuroenhancement by noninvasive brain stimulation a net zero-sum proposition? [link]Paper   doi   bibtex   abstract  
Five methodological challenges in cognitive electrophysiology. Cohen, M. X; and Gulbinaite, R. NeuroImage, 85: 702–710. January 2014. ZSCC: 0000036
Five methodological challenges in cognitive electrophysiology [link]Paper   doi   bibtex   abstract  
  2011 (1)
Electrode Positioning and Montage in Transcranial Direct Current Stimulation. DaSilva, A. F.; Volz, M. S.; Bikson, M.; and Fregni, F. Journal of Visualized Experiments, (51): 2744. May 2011. ZSCC: 0000287
Electrode Positioning and Montage in Transcranial Direct Current Stimulation [link]Paper   doi   bibtex   abstract  
  2009 (1)
A theory of alpha/theta neurofeedback, creative performance enhancement, long distance functional connectivity and psychological integration. Gruzelier, J. Cognitive Processing, 10(S1): 101–109. February 2009. ZSCC: 0000257
A theory of alpha/theta neurofeedback, creative performance enhancement, long distance functional connectivity and psychological integration [link]Paper   doi   bibtex  
  2006 (1)
Rhythms of the Brain. Buzsáki, G. Oxford University Press, October 2006. ZSCC: 0000060
Rhythms of the Brain [link]Paper   doi   bibtex  
  2005 (1)
Getting started with neurofeedback. Demos, J. N. W.W. Norton, New York, 1st ed edition, 2005. ZSCC: 0000479
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  2004 (1)
Simulated Apoptosis/Neurogenesis Regulates Learning and Memory Capabilities of Adaptive Neural Networks. Chambers, R. A.; Potenza, M. N.; Hoffman, R. E.; and Miranker, W. Neuropsychopharmacology, 29(4): 747–758. April 2004. ZSCC: 0000170 Number: 4 Publisher: Nature Publishing Group
Simulated Apoptosis/Neurogenesis Regulates Learning and Memory Capabilities of Adaptive Neural Networks [link]Paper   doi   bibtex   abstract  
  undefined (10)
ADVERSE REACTIONS AND POTENTIAL IATROGENIC EFFECTS IN NEUROFEEDBACK TRAINING: Journal of Neurotherapy: Vol 4, No 4.
ADVERSE REACTIONS AND POTENTIAL IATROGENIC EFFECTS IN NEUROFEEDBACK TRAINING: Journal of Neurotherapy: Vol 4, No 4 [link]Paper   bibtex  
The BRAIN Initiative and Neuroethics: Enabling and Enhancing Neuroscience Advances for Society: AJOB Neuroscience: Vol 11, No 3.
The BRAIN Initiative and Neuroethics: Enabling and Enhancing Neuroscience Advances for Society: AJOB Neuroscience: Vol 11, No 3 [link]Paper   bibtex  
Professional Neurofeedback Training & Education.
Professional Neurofeedback Training & Education [link]Paper   bibtex  
Quantitative EEG and normative databases.
Quantitative EEG and normative databases [link]Paper   bibtex   abstract  
P300-mediated modulations in self–other processing under psychedelic psilocybin are related to connectedness and changed meaning: A window into the self–other overlap. Smigielski, L.; Kometer, M.; Scheidegger, M.; Stress, C.; Preller, K. H.; Koenig, T.; and Vollenweider, F. X. Human Brain Mapping, n/a(n/a). . ZSCC: NoCitationData[s0] _eprint: https://onlinelibrary.wiley.com/doi/pdf/10.1002/hbm.25174
P300-mediated modulations in self–other processing under psychedelic psilocybin are related to connectedness and changed meaning: A window into the self–other overlap [link]Paper   doi   bibtex   abstract  
tDCS Montage Guide.
tDCS Montage Guide [link]Paper   bibtex   abstract  
Brodmann-Cortical-Areas.jpg (601×657).
Brodmann-Cortical-Areas.jpg (601×657) [jpg]Paper   bibtex  
10-20-System-Electrode-Distances.jpg (592×618).
10-20-System-Electrode-Distances.jpg (592×618) [jpg]Paper   bibtex  
BrainBay.
BrainBay [link]Paper   bibtex  
Analyzing neural time series data: Theory and practice. Cohen, M. X ,11. . ZSCC: 0000961
bibtex  
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