Same Action, Different Meaning: Neural Substrates of Action Semantic Meaning<\/strong><\/a> – Aberbach-Goodman, S., Buaron, B., Mudrik, L. & Mukamel, R., Cerebral Cortex, 2022<\/p>\n Real-time processes in the development of action planning<\/strong><\/a> – Ossmy, O., Kaplan, B.E., Han, D., Xu, M., Bianco, C., Mukamel, R. & Adolph, K.E., Current Biology, 2022<\/p>\n Children do not distinguish efficient from inefficient actions during observation<\/strong><\/a> – Ossmy, O., Han, D., Kaplan, B.E., Xu, M., Bianco, C., Mukamel, R. & Adolph, K.E., Scientifc Reports 2021<\/p>\n Action-locked neural responses in auditory cortex to self-generated sounds<\/a><\/strong> – Reznik, D., Guttman, N., Buaron, B., Zion-Golumbic, E. & Mukamel, R., Cerebral Cortex 2021<\/p>\n Single-cell activity in human STG during perception of phonemes is <\/strong>organized according to manner of articulation<\/strong><\/a> – Lakertz, Y., Ossmy, O., Friedmann, N., Mukamel, R. & Fried, I., NeuroImage 2020<\/p>\n Motor learning in hemi-Parkinson using VR-manipulated sensory feedback<\/strong><\/a> – Ossmy O., Mansano L., Frenkel-Toledo S., Kagan E., Koren S., Gilron R., Reznik D., Soroker S. & Mukamel R., Disability and Rehabilitation 2020<\/p>\n Voluntary actions modulate perception and neural representation of action-consequences in a hand-dependent manner<\/strong><\/a>– Buaron B., Reznik D., Gilron R., Mukamel R., Cerebral Cortex 2020<\/p>\n Better-than-chance classification for signal detection<\/strong><\/a>– Rosenblatt, J. D., Benjamini, Y., Gilron, R., Mukamel, R., & Goeman, J. J., Biostatistics, 2019<\/p>\n Motor output, neural states and auditory perception<\/strong><\/a>– Reznik, D. & Mukamel, R., Neuroscience & Biobehavioral Reviews, 2019<\/p>\n A novel tool for time-locking study plans to results<\/strong><\/a>– Mazor, M., Mazor, N. & Mukamel, R., European Journal of Neuroscience, 2018<\/p>\n Predicted sensory consequences of voluntary actions modulate amplitude of preceding readiness potentials<\/strong><\/a>– Reznik, D., Simon, S. & Mukamel, R., Neuropsychologia, 2018<\/p>\n Suppression of EEG Mu Rhythm During Action Observation Corresponds with Subsequent Changes in Behavior<\/strong><\/a>– Aridan, N., Ossmy, O., Buaron, B., Reznik, D. & Mukamel, R., Brain Research, 2018<\/p>\n Perception as a Route for Motor Skill Learning: Perspectives from Neuroscience<\/strong><\/a>– Ossmy, O. & Mukamel, R., Neuroscience, 2018<\/p>\n Behavioral and Neural Effects of Congruency of Visual Feedback During Short-Term Motor Learning<\/strong><\/a>– Ossmy, O. & Mukamel, R., NeuroImage, 2018<\/p>\n Using Virtual Reality to Transfer Motor Skill Knowledge from One Hand to Another<\/strong><\/a>– Ossmy, O. & Mukamel, R., J. Vis. Exp.,<\/em> 2017<\/p>\n Sensitivity to perception level differentiates two subnetworks within the mirror neuron system<\/strong><\/a>– Simon, S. & Mukamel, R., SCAN 2017<\/p>\n What’s in a pattern? Examining the type of signal multivariate analysis uncovers at the group level<\/strong><\/a>– Gilron, R., Rosenblatt, J., Koyejo, O., Poldrack, R.A. & Mukamel, R., NeuroImage 2017<\/p>\n Short Term Motor-Skill Acquisition Improves with Size of Self-Controlled Virtual Hands<\/strong><\/a>– Ossmy, O. & Mukamel, R., Plos One 2017<\/p>\n Neural Network Underlying Intermanual Skill Transfer in Humans<\/strong><\/a>– Ossmy, O. & Mukamel, R., Cell Reports 2016<\/p>\n Activity in primary motor cortex during action observation covaries with subsequent behavioral changes in execution<\/strong><\/a>– Aridan, N. & Mukamel, R., Brain and Behavior 2016<\/p>\n Activity in superior parietal cortex during training by observation predicts asymmetric learning levels across hands<\/strong><\/a>– Ossmy, O. & Mukamel, R., Scientific Reports 2016<\/p>\n Power modulation of electroencephalogram mu and beta frequency depends on perceived level of observed actions<\/strong><\/a>– Simon S. & Mukamel, R., Brain and Behavior 2016<\/p>\n Decoding speech perception from single cell activity in humans<\/strong><\/a>– Ossmy, O., Fried, I. & Mukamel, R., NeuroImage 2015<\/p>\n Preconscious prediction of a driver’s decision using intracranial recordings<\/strong><\/a>– Perez, O., Mukamel, R., Tankus, A., Rosenblatt, J.D., Yeshurun, Y. & Fried, I., Journal of Cognitive Neuroscience 2015<\/p>\n Perceived loudness of self-generated sounds is differentially modified by expected sound intensity<\/strong><\/a>– Reznik, D., Henkin, Y., Levy, O. & Mukamel, R., Plos One 2015<\/p>\n Enhanced auditory evoked activity to self-generated sounds is mediated by primary and supplementary motor cortices<\/strong><\/a>– Reznik, D., Ossmy, O. & Mukamel, R., Journal of Neuroscience 2015<\/p>\n \u201cNeural correlates of intentions\u201d in \u201cHuman Agency: Functions and Mechanisms\u201d<\/strong><\/a>– Gilron R., Simon S. & Mukamel R. Editors Eitam B. & Haggard P., Oxford University Press, 2015<\/p>\n Differentiating intended sensory outcome from underlying motor actions in the human brain<\/strong><\/a>– Krasovsky, A., Gilron, R., Yeshurun, Y. & Mukamel, R., Journal of Neuroscience 2014<\/p>\n Decoding letter position in word reading<\/strong><\/a>– Ossmy, O., Ben-Shachar, M. & Mukamel, R., Cortex 2014<\/p>\n Lateralized enhancement of auditory cortex activity and increased sensitivity to self-generated sounds<\/strong><\/a>– Reznik, D., Henkin, Y., Schadel, N. & Mukamel, R., Nature Communications 2014<\/p>\n Memory enhancement and deep-brain stimulation of the entorhinal area<\/strong><\/a>– Suthana, N., Haneef, Z., Stern, J., Mukamel, R., Behnke, E., Knowlton, B. & Fried, I., New England Journal of Medicine 2012<\/p>\n Human intracranial recordings and cognitive neuroscience<\/strong><\/a>– Mukamel, R. & Fried, I., Annual Review of Psychology 2011<\/p>\n Invariance of firing rate and field potential dynamics to stimulus modulation rate in human auditory cortex<\/strong><\/a>– Mukamel, R., Nir, Y., Harel, M., Arieli, A., Malach, R. & Fried, I., Human Brain Mapping 2011<\/p>\n Internally generated preactivation of single neurons in human medial frontal cortex predicts volition<\/strong><\/a>– Fried, I., Mukamel, R. & Kreiman, G., Neuron 2011<\/p>\n Single-neuron responses in humans during execution and observation of actions<\/strong><\/a>– Mukamel, R., Ekstrom, A.D., Kaplan, J., Iacoboni, M. & Fried, I., Current Biology 2010<\/p>\n A neural substrate in the human hippocampus for linking successive events<\/strong><\/a>– Paz, R., Gelbard-Sagiv, H., Mukamel, R., Harel, M., Malach, R. & Fried, I., PNAS 2010<\/p>\n Internally generated reactivation of single neurons in human hippocampus during free recall<\/strong><\/a>– Gelbard-Sagiv, H., Mukamel, R., Harel, M., Malach, R. & Fried, I., Science 2008<\/p>\n Interhemispheric correlations of slow spontaneous neuronal fluctuations revealed in human sensory cortex<\/strong><\/a>– Nir, Y., Mukamel, R., Dinstein, I., Privman, E., Harel, M., Fisch, L., Gelbard-Sagiv, H., Kipervasser, S., Andelman, F., Neufeld, M.Y., Kramer, U., Arieli, A., Fried, I. & Malach, R., Nature Neuroscience 2008<\/p>\n Human single-neuron responses at the threshold of conscious recognition<\/strong><\/a>– Quiroga, R.Q., Mukamel, R., Isham, E.A., Malach, R. & Fried, I., PNAS 2008<\/p>\n Ultra-fine frequency tuning revealed in single neurons of human auditory cortex<\/strong><\/a>– Bitterman, Y., Mukamel, R., Malach, R., Fried, I. & Nelken, I., Nature 2008<\/p>\n Coupling between neuronal firing rate, gamma LFP, and BOLD fMRI is related to interneuronal correlations<\/strong><\/a>– Nir, Y., Fisch, L., Mukamel, R., Gelbard-Sagiv, H., Arieli, A., Fried, I. & Malach, R., Current Biology 2007<\/p>\n Enhanced category tuning revealed by intracranial electroencephalograms in high-order human visual areas<\/strong><\/a>– Privman, E., Nir, Y., Kramer, U., Kipervasser, S., Andelman, F., Neufeld, M.Y., Mukamel, R., Yeshurun, Y., Fried, I. & Malach, R., Journal of Neuroscience 2007<\/p>\n Coupling between neuronal firing, field potentials, and FMRI in human auditory cortex<\/strong><\/a>– Mukamel, R., Gelbard, H., Arieli, A., Hasson, U., Fried, I. & Malach, R., Science 2005<\/p>\n2021<\/h2>\n
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