Bibliographies thématiques / BRAIN COMMUNICATION / Articles de revues

Articles de revues sur le sujet « BRAIN COMMUNICATION »

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Auteur : Grafiati
Publié le 11 mars 2023

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1

KIM, JeongTak. « Communication Philosophy in Taoism : Beyond “Brain-to-Brain” Communication ». Asian Communication Research 14, no 2 (31 décembre 2017) : 122–32. http://dx.doi.org/10.20879/acr.2017.14.2.122.

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Stower, Hannah. « Gut–brain communication ». Nature Medicine 25, no 12 (décembre 2019) : 1799. http://dx.doi.org/10.1038/s41591-019-0685-y.

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Sakaguchi, Yutaka, Takeshi Aihara, Peter Ford Dominey et Ichiro Tsuda. « Communication and Brain ». Neural Networks 62 (février 2015) : 1–2. http://dx.doi.org/10.1016/j.neunet.2014.12.005.

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Quan, Ning, et William A. Banks. « Brain-immune communication pathways ». Brain, Behavior, and Immunity 21, no 6 (août 2007) : 727–35. http://dx.doi.org/10.1016/j.bbi.2007.05.005.

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Bara, Bruno G., et Maurizio Tirassa. « Neuropragmatics : Brain and Communication ». Brain and Language 71, no 1 (janvier 2000) : 10–14. http://dx.doi.org/10.1006/brln.1999.2198.

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Powley, Terry L. « Brain-gut communication : vagovagal reflexes interconnect the two “brains” ». American Journal of Physiology-Gastrointestinal and Liver Physiology 321, no 5 (1 novembre 2021) : G576—G587. http://dx.doi.org/10.1152/ajpgi.00214.2021.

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The gastrointestinal tract has its own “brain,” the enteric nervous system or ENS, that executes routine housekeeping functions of digestion. The dorsal vagal complex in the central nervous system (CNS) brainstem, however, organizes vagovagal reflexes and establishes interconnections between the entire neuroaxis of the CNS and the gut. Thus, the dorsal vagal complex links the “CNS brain” to the “ENS brain.” This brain-gut connectome provides reflex adjustments that optimize digestion and assimilation of nutrients and fluid. Vagovagal circuitry also generates the plasticity and adaptability needed to maintain homeostasis to coordinate among organs and to react to environmental situations. Arguably, this dynamic flexibility provided by the vagal circuitry may, in some circumstances, lead to or complicate maladaptive disorders.
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De Massari, Daniele, Carolin A. Ruf, Adrian Furdea, Tamara Matuz, Linda van der Heiden, Sebastian Halder, Stefano Silvoni et Niels Birbaumer. « Brain communication in the locked-in state ». Brain 136, no 6 (26 avril 2013) : 1989–2000. http://dx.doi.org/10.1093/brain/awt102.

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Winek, Katarzyna, Daniel Cuervo Zanatta et Marietta Zille. « Brain–body communication in stroke ». Neuroforum 28, no 1 (20 décembre 2021) : 31–39. http://dx.doi.org/10.1515/nf-2021-0030.

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Abstract Stroke is a leading cause of death and disability worldwide with limited therapeutic options available for selected groups of patients. The susceptibility to stroke depends also on systemic parameters, and some stroke risk factors are modifiable, such as atrial fibrillation (AF) or hypertension. When considering new treatment strategies, it is important to remember that the consequences of stroke are not limited to the central nervous system (CNS) injury, but reach beyond the boundaries of the brain. We provide here a brief overview of the mechanisms of how the brain communicates with the body, focusing on the heart, immune system, and gut microbiota (GM).
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Kübler, Andrea, Nicola Neumann, Barbara Wilhelm, Thilo Hinterberger et Niels Birbaumer. « Predictability of Brain-Computer Communication ». Journal of Psychophysiology 18, no 2/3 (janvier 2004) : 121–29. http://dx.doi.org/10.1027/0269-8803.18.23.121.

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Abstract Since 1996 we have been teaching more than 18 severely or totally paralyzed patients to successfully control the movements of a cursor on a computer screen by means of systematic changes in the amplitudes of their slow cortical potentials (SCPs; Birbaumer, Ghanayim, Hinterberger, Iversen, Kotchoubey et al., 1999 ). Patients learned regulation of their SCP amplitudes by means of a brain-computer interface (BCI) and on-line feedback about the time course of SCP amplitude shifts, represented by cursor movements on a computer screen. When patients were able to successfully regulate their SCP amplitude, they were trained to use this ability to communicate with friends and caregivers by means of a Language Support Program ( Perelmouter, Kotchoubey, Kübler, Taub, & Birbaumer, 1999 ). Having a reliable predictor of progress in training would be particularly helpful because training patients at their homes requires substantial effort and a positive outcome is desirable given limited personal and financial resources. In this study we present data from healthy participants (n = 10) and a sample of patients (n = 10), diagnosed with amyotrophic lateral sclerosis, who participated in six BCI training sessions; six patients continued training for another six sessions. All participants except one achieved stable significant cursor control. The number of sessions needed to achieve significant cursor control (initial training phase) correlated moderately with the number of sessions needed to achieve a correct response rate of 70% (advanced training phase). Individual differences in performance remained stable within the six training sessions. After six sessions both groups had achieved significant cursor control, but patients' performance was poorer than that of healthy participants. The patients, however, were trained once a week only, and for some patients longer breaks in training occurred. We conclude that learning during the initial training phase indicates the duration of training that will be necessary to achieve 70% correct responses. A higher frequency of training sessions per week seems necessary to achieve faster progress.
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Sagara, K. « Special Section on Brain Communication ». IEICE Transactions on Communications E91-B, no 7 (1 juillet 2008) : 2101. http://dx.doi.org/10.1093/ietcom/e91-b.7.2101.

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11

Souček, Branko, et Albert D. Carlson. « Brain windows in firefly communication ». Journal of Theoretical Biology 119, no 1 (mars 1986) : 47–65. http://dx.doi.org/10.1016/s0022-5193(86)80050-9.

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Agnati, L. F., K. Fuxe et F. Mora. « Intercellular communication in the brain ». Brain Research Reviews 55, no 1 (août 2007) : 1–2. http://dx.doi.org/10.1016/j.brainresrev.2007.07.004.

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Fujiki, Nobuya, et Yasushi Naito. « Auditory Communication and Brain Function ». Japan Journal of Logopedics and Phoniatrics 48, no 3 (2007) : 277–83. http://dx.doi.org/10.5112/jjlp.48.277.

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14

Monje, Michelle. « Synaptic Communication in Brain Cancer ». Cancer Research 80, no 14 (7 mai 2020) : 2979–82. http://dx.doi.org/10.1158/0008-5472.can-20-0646.

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Brown, Jason W. « Language, Communication and the Brain ». Journal of Nervous and Mental Disease 176, no 9 (septembre 1988) : 576–77. http://dx.doi.org/10.1097/00005053-198809000-00014.

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Janić, Milan, Marko Ćirović, Nikolaos Dimitriadis, Neda Jovanović Dimitriadis et Panayiota Alevizou. « Neuroscience and CSR : Using EEG for Assessing the Effectiveness of Branded Videos Related to Environmental Issues ». Sustainability 14, no 3 (25 janvier 2022) : 1347. http://dx.doi.org/10.3390/su14031347.

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The majority of studies evaluating the effectiveness of branded CSR campaigns are concentrated and base their conclusions on data collection through self-reporting questionnaires. Although such studies provide insights for evaluating the effectiveness of CSR communication methods, analysing the message that is communicated, the communication channel used and the explicit brain responses of those for whom the message is intended, they lack the ability to fully encapsulate the problem of communicating environmental messages by not taking into consideration what the recipients’ implicit brain reactions are presenting. Therefore, this study aims to investigate the effectiveness of CSR video communications relating to environmental issues through the lens of the recipients’ implicit self, by employing neuroscience-based assessments. For the examination of implicit brain perception, an electroencephalogram (EEG) was used, and the collected data was analysed through three indicators identified as the most influential indicators on human behaviour. These three indicators are emotional valence, the level of brain engagement and cognitive load. The study is conducted on individuals from the millennial generation in Thessaloniki, Greece, whose implicit brain responses to seven branded commercial videos are recorded. The seven videos were a part of CSR campaigns addressing environmental issues. Simultaneously, the self-reporting results from the participants were gathered for a comparison between the explicit and implicit brain responses. One of the key findings of the study is that the explicit and implicit brain responses differ to the extent that the CSR video communications’ brain friendliness has to be taken into account in the future, to ensure success. The results of the study provide an insight for the future creation process, conceptualisation, design and content of the effective CSR communication, in regard to environmental issues.
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Tuor, Paula, et Jenkins Zhao. « Pathogenesis of Brain : Autism Spectrum Disorders ». Neuroscience and Neurological Surgery 2, no 2 (20 avril 2018) : 01–02. http://dx.doi.org/10.31579/2578-8868/029.

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Autism spectrum disorders (ASDs) affect as many as 1 in 45 children and are characterized by deficits in sociability and communication, as well as stereotypic movements. Many children also show severe anxiety.
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Vasile, Aurelia Ana. « Formal, Non-formal, and Informal Approaches in Prosocial Crisis Communication while Dealing with Refugees from Conflict Areas ». BRAIN. Broad Research in Artificial Intelligence and Neuroscience 14, no 1 (9 mars 2023) : 157–74. http://dx.doi.org/10.18662/brain/14.1/412.

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The way formal organisations (governmental), non-formal (non-governmental) organisations, and informal citizen communication deal with social crisis pro-socially, that is, to the benefit of others, accounts for some characteristics that are worth fathoming in order to create the framework for the development of better communication strategies and better and faster prosocial reaction within socially challenging crisis contexts. Crisis communication has been tackled in public relations mostly with regard to governmental and nongovernmental organisations, whilst citizen informal communication has not been a matter of PR scientific focus so far, and neither has a comparison between these ways to communicate been approached for that matter. As speed is key in communication, and mostly within a refugee crisis, a double fold quantitative and qualitative analysis of the communication content and strategies used by key social actors in a hub-country of refugee reception like Romania in the emergency context created by Russia’s invasion of Ukraine may provide useful scientific information to generate consequent strategic improvements. This content analysis methodological approach on communication in the social media and on websites of such various outlets (the Facebook pages and groups of the Romanian Red Cross, UNICEF, Romanian Government, the “Uniţi pentru Ucraina” group, the Romanian government, UNICEF and Red Cross websites) from 24th February 2022, the beginning of the conflict in Ukraine, to the moment, allows intriguing conclusions about the effectiveness, timeliness, and constancy in communicating support in times of social crisis within a prosocial approach in Romania to receiving refugees from the conflict areas in Ukraine.
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19

Chin, F. C. J., M. L. Ooi et M. W. Yip. « The Effects of Colored Brain Communication and Brain Processing Interpretation on the Academic Performance of Students : A Literature Review ». International Journal of Information and Education Technology 6, no 12 (2016) : 945–48. http://dx.doi.org/10.7763/ijiet.2016.v6.822.

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20

Dahal, Prawesh, Naureen Ghani, Adeen Flinker, Patricia Dugan, Daniel Friedman, Werner Doyle, Orrin Devinsky, Dion Khodagholy et Jennifer N. Gelinas. « Interictal epileptiform discharges shape large-scale intercortical communication ». Brain 142, no 11 (9 septembre 2019) : 3502–13. http://dx.doi.org/10.1093/brain/awz269.

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Focal epilepsy is associated with large-scale brain dysfunction. Dahal et al. reveal that interictal epileptiform discharges modulate normal brain rhythms in regions beyond the epileptic network, potentially impairing processes that rely heavily upon intercortical communication, such as cognition and memory.
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21

Graham, Daniel, Andrea Avena-Koenigsberger et Bratislav Mišić. « Editorial : Network Communication in the Brain ». Network Neuroscience 4, no 4 (janvier 2020) : 976–79. http://dx.doi.org/10.1162/netn_e_00167.

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Communication models describe the flow of signals among nodes of a network. In neural systems, communication models are increasingly applied to investigate network dynamics across the whole brain, with the ultimate aim to understand how signal flow gives rise to brain function. Communication models range from diffusion-like processes to those related to infectious disease transmission and those inspired by engineered communication systems like the internet. This Focus Feature brings together novel investigations of a diverse range of mechanisms and strategies that could shape communication in mammal whole-brain networks.
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22

TANEMURA, Jun, et Akio TSUBAHARA. « Communication Disorders following Traumatic Brain Injury ». Japanese Journal of Rehabilitation Medicine 43, no 2 (2006) : 110–19. http://dx.doi.org/10.2490/jjrm1963.43.110.

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Avena-Koenigsberger, Andrea, Bratislav Misic et Olaf Sporns. « Communication dynamics in complex brain networks ». Nature Reviews Neuroscience 19, no 1 (14 décembre 2017) : 17–33. http://dx.doi.org/10.1038/nrn.2017.149.

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24

Xiaomei Pei, J. Hill et G. Schalk. « Silent Communication : Toward Using Brain Signals ». IEEE Pulse 3, no 1 (janvier 2012) : 43–46. http://dx.doi.org/10.1109/mpul.2011.2175637.

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25

Ylvisaker, Mark. « Communication Outcome Following Traumatic Brain Injury ». Seminars in Speech and Language 13, no 04 (novembre 1992) : 239–51. http://dx.doi.org/10.1055/s-2008-1064200.

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Herzog, Jean. « Communication Disorders Following Traumatic Brain Injury ». Journal of Head Trauma Rehabilitation 16, no 6 (décembre 2001) : 612–13. http://dx.doi.org/10.1097/00001199-200112000-00010.

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Berthoud, Hans-Rudolf, Andrew C. Shin et Huiyuan Zheng. « Obesity surgery and gut–brain communication ». Physiology & ; Behavior 105, no 1 (novembre 2011) : 106–19. http://dx.doi.org/10.1016/j.physbeh.2011.01.023.

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Newman, John D. « Vocal communication and the triune brain ». Physiology & ; Behavior 79, no 3 (août 2003) : 495–502. http://dx.doi.org/10.1016/s0031-9384(03)00155-0.

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29

Morley, John E. « Bidirectional Communication Between Brain and Muscle ». Journal of nutrition, health & ; aging 22, no 10 (26 novembre 2018) : 1144–45. http://dx.doi.org/10.1007/s12603-018-1141-2.

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Sauma, Sami, et Patrizia Casaccia. « Gut-brain communication in demyelinating disorders ». Current Opinion in Neurobiology 62 (juin 2020) : 92–101. http://dx.doi.org/10.1016/j.conb.2020.01.005.

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Ebrahimi, T., J. M. Vesin et G. Garcia. « Brain-computer interface in multimedia communication ». IEEE Signal Processing Magazine 20, no 1 (janvier 2003) : 14–24. http://dx.doi.org/10.1109/msp.2003.1166626.

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32

Wolpaw, Jonathan R., et Dennis J. McFarland. « Multichannel EEG-based brain-computer communication ». Electroencephalography and Clinical Neurophysiology 90, no 6 (juin 1994) : 444–49. http://dx.doi.org/10.1016/0013-4694(94)90135-x.

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Brumberg, Jonathan S., Alfonso Nieto-Castanon, Philip R. Kennedy et Frank H. Guenther. « Brain–computer interfaces for speech communication ». Speech Communication 52, no 4 (avril 2010) : 367–79. http://dx.doi.org/10.1016/j.specom.2010.01.001.

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Aroniadis, Olga C., Douglas A. Drossman et Magnus Simrén. « A Perspective on Brain–Gut Communication ». Psychosomatic Medicine 79, no 8 (octobre 2017) : 847–56. http://dx.doi.org/10.1097/psy.0000000000000431.

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Johnson, Pamela R., et Claudia Rawlins Daumer. « Intuitive Development : Communication in the Nineties ». Public Personnel Management 22, no 2 (juin 1993) : 257–68. http://dx.doi.org/10.1177/009102609302200206.

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Communication is an intuitive as well as cognitive process. In order to develop the brain skill of intuition, it is sometimes necessary to shut down cognitive (left-brain analyses and pay special attention to intuitive (right-brain) ways of knowing. The brain hemispheres work differently and yet in conjunction. This article suggests techniques for developing intuitive brain skills. Mandalas, “other” hand writing, and positive affirmations can be used to improve intuitive skills.
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Birbaumer, N. « Brain–machine interfaces (BMI) for brain communication and chronic stroke ». Annals of Physical and Rehabilitation Medicine 56 (octobre 2013) : e373. http://dx.doi.org/10.1016/j.rehab.2013.07.961.

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BLONDER, L. X., D. BOWERS et K. M. HEILMAN. « THE ROLE OF THE RIGHT HEMISPHERE IN EMOTIONAL COMMUNICATION ». Brain 114, no 3 (1 juin 1991) : 1115–27. http://dx.doi.org/10.1093/brain/114.3.1115.

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BLONDER, LEE XENAKIS, DAWN BOWERS et KENNETH M. HELLMAN. « THE ROLE OF THE RIGHT HEMISPHERE IN EMOTIONAL COMMUNICATION ». Brain 115, no 2 (1992) : 645. http://dx.doi.org/10.1093/brain/115.2.645.

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Wang, Zhuo, Niting Wang, Zehua Li, Fangyan Xiao et Jiapei Dai. « Human high intelligence is involved in spectral redshift of biophotonic activities in the brain ». Proceedings of the National Academy of Sciences 113, no 31 (18 juillet 2016) : 8753–58. http://dx.doi.org/10.1073/pnas.1604855113.

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Human beings hold higher intelligence than other animals on Earth; however, it is still unclear which brain properties might explain the underlying mechanisms. The brain is a major energy-consuming organ compared with other organs. Neural signal communications and information processing in neural circuits play an important role in the realization of various neural functions, whereas improvement in cognitive function is driven by the need for more effective communication that requires less energy. Combining the ultraweak biophoton imaging system (UBIS) with the biophoton spectral analysis device (BSAD), we found that glutamate-induced biophotonic activities and transmission in the brain, which has recently been demonstrated as a novel neural signal communication mechanism, present a spectral redshift from animals (in order of bullfrog, mouse, chicken, pig, and monkey) to humans, even up to a near-infrared wavelength (∼865 nm) in the human brain. This brain property may be a key biophysical basis for explaining high intelligence in humans because biophoton spectral redshift could be a more economical and effective measure of biophotonic signal communications and information processing in the human brain.
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Ramírez-Moreno, Mauricio A., Jesús G. Cruz-Garza, Akanksha Acharya, Girija Chatufale, Woody Witt, Dan Gelok, Guillermo Reza et José L. Contreras-Vidal. « Brain-to-brain communication during musical improvisation : a performance case study ». F1000Research 11 (1 septembre 2022) : 989. http://dx.doi.org/10.12688/f1000research.123515.1.

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Understanding and predicting others' actions in ecological settings is an important research goal in social neuroscience. Here, we deployed a mobile brain-body imaging (MoBI) methodology to analyze inter-brain communication between professional musicians during a live jazz performance. Specifically, bispectral analysis was conducted to assess the synchronization of scalp electroencephalographic (EEG) signals from three expert musicians during a three-part 45 minute jazz performance, during which a new musician joined every five minutes. The bispectrum was estimated for all musician dyads, electrode combinations, and five frequency bands. The results showed higher bispectrum in the beta and gamma frequency bands (13-50 Hz) when more musicians performed together, and when they played a musical phrase synchronously. Positive bispectrum amplitude changes were found approximately three seconds prior to the identified synchronized performance events suggesting preparatory cortical activity predictive of concerted behavioral action. Moreover, a higher amount of synchronized EEG activity, across electrode regions, was observed as more musicians performed, with inter-brain synchronization between the temporal, parietal, and occipital regions the most frequent. Increased synchrony between the musicians' brain activity reflects shared multi-sensory processing and movement intention in a musical improvisation task.
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Grau, Carles, Romuald Ginhoux, Alejandro Riera, Thanh Lam Nguyen, Hubert Chauvat, Michel Berg, Julià L. Amengual, Alvaro Pascual-Leone et Giulio Ruffini. « Conscious Brain-to-Brain Communication in Humans Using Non-Invasive Technologies ». PLoS ONE 9, no 8 (19 août 2014) : e105225. http://dx.doi.org/10.1371/journal.pone.0105225.

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Hurley, Dan. « Report Describes First Instance of Direct, Noninvasive Brain-to-Brain Communication ». Neurology Today 14, no 21 (novembre 2014) : 33–37. http://dx.doi.org/10.1097/01.nt.0000457149.60646.22.

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Neumann, Nicola, Andrea Kübler, Jochen Kaiser, Thilo Hinterberger et Niels Birbaumer. « Conscious perception of brain states : mental strategies for brain–computer communication ». Neuropsychologia 41, no 8 (janvier 2003) : 1028–36. http://dx.doi.org/10.1016/s0028-3932(02)00298-1.

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44

Sutter, Erich E. « The brain response interface : communication through visually-induced electrical brain responses ». Journal of Microcomputer Applications 15, no 1 (janvier 1992) : 31–45. http://dx.doi.org/10.1016/0745-7138(92)90045-7.

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Grau, Carles, Romuald Ginhoux, Alejandro Riera, Thanh Lam Nguyen, Hubert Chauvat, Michel Berg, Julià L. Amengual, Alvaro Pascual-Leone et Giulio Ruffini. « Conscious Brain-to-Brain Communication in Humans Using Non-Invasive Technologies ». Brain Stimulation 8, no 2 (mars 2015) : 323. http://dx.doi.org/10.1016/j.brs.2015.01.047.

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Liu, Wei, Xinying Zhang, Zifeng Wu, Kai Huang, Chun Yang et Ling Yang. « Brain–heart communication in health and diseases ». Brain Research Bulletin 183 (juin 2022) : 27–37. http://dx.doi.org/10.1016/j.brainresbull.2022.02.012.

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47

Kitada, Ryo. « Cognitive Brain Mechanisms Underlying Haptic Social Communication ». Journal of the Robotics Society of Japan 30, no 5 (2012) : 466–68. http://dx.doi.org/10.7210/jrsj.30.466.

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Bosone, Camilla, Abraham Andreu et Diego Echevarria. « GAP junctional communication in brain secondary organizers ». Development, Growth & ; Differentiation 58, no 5 (juin 2016) : 446–55. http://dx.doi.org/10.1111/dgd.12297.

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Mingui Sun, M. Mickle, Wei Liang, Qiang Liu et R. J. Sclabassi. « Data communication between brain implants and computer ». IEEE Transactions on Neural Systems and Rehabilitation Engineering 11, no 2 (juin 2003) : 189–92. http://dx.doi.org/10.1109/tnsre.2003.814421.

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McEwen, Bruce S. « Epigenetic Interactions and the Brain-Body Communication ». Psychotherapy and Psychosomatics 86, no 1 (25 novembre 2016) : 1–4. http://dx.doi.org/10.1159/000449150.

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