Education

1991-1995: University of Tennessee, Memphis, Ph.D. in Neurobiology

1980-1986: Moscow Institute of Physics and Technology, M.Sci. in Physics (with distinction)

1973-1980: Specialized High School #60, Moscow, High school diploma (gold medal)

Appointments

2022-present: Moscow State University, Moscow, Russia, Full Professor

2022-present: I.M. Sechenov Institute of Evolutionary Physiology and Biochemistry, St Petersburg, Russia, Chief Research Scientist

2020-2022: Skolkovo Institute of Science and Technology, Moscow, Russia, Full Professor

2018-present: National Research University Higher School of Economics, Moscow, Russia, Chief Research Scientist

2002-2018: Duke University Center for Neuroengineering, Durham, NC, USA, Senior Research Scientist

1997-2002: National Institute of Mental Health, Bethesda, MD, USA, Research Fellow

1995-1997: International School for Advanced Studies, Trieste, Italy, Research Fellow

1995: University of Tennessee, Memphis, TN, USA, Postdoctoral Fellow

1991-1995: University of Tennessee, Memphis, TN, USA, Graduate Teaching Assistant

1986-1991: Institute for Information Transmission Problems, Moscow, Russia, Junior Research Scientist

Teaching

2022: Neurophysiology and Neurotechnologies, Moscow State University, Moscow, Russia

Introduction to Neurotechnologies, Far Eastern Federal University, Vladivostok, Russia

Neurophysiology and Neurotechnologies, Skolkovo Institute of Science and Technology, Moscow, Russia

Introduction to Neurotechnologies, Skolkovo Institute of Science and Technology, Moscow, Russia

A short course on brain-computer interfaces, Far Eastern Federal University, Vladivostok, Russia

2021: Brain-machine interface, Higher School of Economics, Moscow, Russia

Psychophysiology, Higher School of Economics, Moscow, Russia

2020: Psychophysiology, Higher School of Economics, Moscow, Russia

Introduction to brain-computer interfaces, Far Eastern Federal University, Vladivostok, Russia

2014: Lecture course on BMI technologies, School of Psychology, Higher School of Economics, Moscow, Russia

2002-2018: Supervision of graduate students, lectures for undergraduates and high-school students, Duke University, Durham, NC, USA

1995-1997: Lecturers for graduate students, International School for Advanced Studies, Trieste

1991-1995: Teaching assistant in anatomy and histology classes, University of Tennessee, Memphis, TN, USA

1986-1991: Instructor for high school students, Moscow Institute of Physics and Technology, Moscow, Russia

Society Membership

2015: American Romanian Academy of Arts and Sciences, Full Member

2005: Cognitive Neuroscience

1991: Society Society for Neuroscience

Board Membership

Advisory Board, Master of Science in Neuroengineering, TUM Department of Electrical and Computer Engineering

Invited Talks

2022:

• Brain-computer interfaces for rehabilitation. Cognitive Neuroscience-2022. December 9. Ekaterinburg

• Neural interfaces: how to connect to the brain? November 30. International Linguistic School, Vladivostok

• Neural interfaces for rehabilitation. International Workshop on Artificial Intelligence and Applications. November 29. Institute for Artificial Intelligence, MSU, Moscow

• Productivity at the time of changes. Edcrunch. November 23. Almaty

• By the power of thought: how neural implants will change our lives. A scientist talks. November 16, Ekaterinburg

• Neuroplasticity: how to keep the brain young. IZOTOP.LAB. November 19, Moscow

• Brain-computer interfaces for rehabilitation. Sechenov International Biomedical Summit 2022, November 8, Moscow

• Neural interfaces: from basic science to rehabilitation. October 17. Sirius, Sochi

• Neural interfaces for rehabilitation. Active and Passive Methods of Brain Research. October 27. HSE University, Moscow

• Brain-computer interfaces for rehabilitation. October 13. PPGEE, Federal University of Para

• Neural interfaces: achievements and perspectives. September 3. AFK Sistema retreat, Gornoaltaysk

• Neural interfaces that restore health. All-Russia festival NAUKA 0+. October 9. Moscow State University, Moscow.

• Would brain-computer-interfaces help us understand consciousness? Geek picnic. July 30, Moscow

• Neural technologies for leaders. iVolga. July 23, Samara region.

• Neural interfaces serving people. June 19. Yeltsyn center, Ekaterinburg

• Poststroke rehabilitation by means of the brain-computer interface enabling a visuomotor transformation. Neurorehabilitation 2022. June 6, Moscow

• Neural interfaces in science and medicine. April 6. Special seminar, "Time, chaos and mathematical problems". Moscow State University, Moscow

• Interfacing to the brain. Brain 2022. March 22. Synergy.online, Moscow

2021:

• A Brain-computer interface based on visuomotor transformations: a possible use in neurorehabilitation An all-Russia conference with international participation, "Integrative physiology" December 8-10, I.P. Pavlov Physiology Institute, St Petersburg, Russia

• Brain-computer interfaces for rehabilitation. Neurotechnologies and Metaverse Conference, November 30, Mixed reality conference, Moscow

• Neural interfaces for neuromodulation and neuroenhancement. Neuroenhancement and neuromodulation. November 24, 2021. Skoltech, Moscow, Russia

• Brain-computer interfaces for brain studies. Young scientist school, "Neurotechnologies and bioelectronic medicine." V. Zelman Center for Neurobology and Brain rehabilitation, Moscow

• Brain-computer interfaces: yesterday, today, tomorrow. The 6th Ural industrial biennale. October 26, Ekaterinburg

• Brain-computer interfaces for basic science and rehabilitation. Нейроинтерфейсы для фундаментальной науки и реабилитации. Science Festival NAUKA 0+ at Zaryaye. October 10, Moscow

• Neural-interface control in different modes: monkey business and neuroplasticity. Neuro Baltic forum: Neuroscience, artificial intelligence and complex systems. September 13-15, 2021. Immanuel Kant Baltic Federal University, Kaliningrad, Russia

• Rotational dynamics versus sequence-like responses. Volga Neuroscience Meeting 2021. August 24-27, 2021. Nizhniy Novgorov, Russia

• Brain-computer interfaces: past, present and future. Federal Neurosurgery Center in Tyumen. August 22, Tyumen

• Brain-computer interfaces for rehabilitation. Neural interfaces in medicine. July 2. Federal Center for Brain and Neurotechnologies, Moscow

• How to connect to the brain. Large business conference. July 26, Moscow

• The future of brain-computer interfaces. Intraoperative neuromonitoring for neurosurgeons: practical aspects and clinical applications. June 14, 2021, Moscow, Russia

• Is the brain a computer? A pill against everything: connecting the brain to the computer. June 3. St Petersburg economic forum, St Petersburg

• Neurotechnologies that change the human and humanity. Codefest. May 30, Novosibirsk

• A popular lecture on neurophysiology. Inter-regional forum of network research projects. June 12, Novosibirsk

• Brain-computer interfaces as the way to restore and augment the brain functions. "A smart rote at Penza State University." May 18. Penza State University

• Post-COVID rehabilitation of olfaction using a brain-computer interface. The 13th international congress, "Neurorehabilitation". June 17, Moscow

• From vision to movement: rotational dynamics and practical tasks of neurorehabilitation. Pint of Science

• Brain-computer interfaces and mind reading. Seminar, "Thought, language and consciosness." May 15. Philosophy Faculty, MSU, Moscow

• The brain speaks and shows. Arhe Center. April 22, Moscow

• Brain-computer interfaces: science and technology structure. Enoteca IQ. April 9, Dolgoprudny

• Post-Stroke Rehabilitation Using a BCI Robotic System That Provides Eye-Hand Transformation. BCI and assistive devices, Tech Day Online. April 27, 2021. Berlin, Germany

• Repairing the brain with brain-machine interfaces. Grand Rounds, Keck Medicine of USC. February 12, 2021. Los Angeles, California, USA

2020:

• NeuraLink. Debriefing. Archipelago 20.35

• Controlling arm movements: still on the way toward understanding. Conference in memory of A.A. Frolov, Institute of Higher Nervous Activity and Neurophysiology, Moscow

• Cyborgization. Information centers for atomic energy

• What rotates and why? BCI: Science and practice, Samara

• Neuroprosthetics: science fiction becomes a reality. Neuroschool 2020, Far Eastern Federal University

• Neuronal dynamics: pitfalls and clarifications. Dynamics of Complex Networks and their Application in Intellectual Robotics, Innopolis University, Innopolis, Russia

• Neuroprosthetics: science fiction becomes a reality. The 24th international scientific conference of young scientists, "Psychology of the 21st century"

• Bidirectional neural interfaces based on intracranial implants. Brain-machine interfaces (BMI) to machine-brain interfaces (MBI): the next frontier. EMBC Conference Workshop

• Intracranial neurophysiology: where Chinese and Russian minds could collaborate. China-Russia workshop on Neuroscience

• Brain-computer interface: how it works with an exoskeleton. Exoatlet webinar

• Brain and machine: two-way communication. BCI & Neurotechnology Summer School 2020

• Brain-computer interfaces. Planet Masters International Conference

• Psychophysiological problem. Neurophysiology as an inquiry into how the brain works

• Basics of brain-computer interfaces / Artificial sensations /Futuristic interfaces. Far Eastern Federal University

• Neural interfaces: present and future. Science Bar Hopping

• Neurophysiology basis of brain-machine interfaces. BCI 101 Online Global Series

• Primate neurophysiology: from single neurons to neuronal ensembles and brain-machine Interfaces. Skoltech, Moscow, Russia

• An introduction to brain-computer interfaces. Higher School of Economics, Moscow, Russia

• From brain-computer to brain-to-brain and brain-to-cloud interfaces. Neuroscience Seminar Series, Helsinki Institute of Life Science, Helsinki, Finland

2019:

• Brain-computer interfaces: a tool to investigate consciousness? Studies of consciousness: theory and practice. Moscow Instititute of Physics and Technology, Dolgoprudniy, Russia

• Bidirectional neurointerface: two years on. Annual visiting strategic session of the Institute of Cognitive Neurosciences, Voronovo, Moscow, Russia

• Decoding locomotion in rats and monkeys. Exorehab spotlights 2019, Moscow, Russia

• Brain-computer interfaces for functional restoration, neurorehabilitation, fundamental science, and for fun. 10th RASA-America Conference, Chapel Hill, NC, USA

• Conversation with the brain through a neural interface. Planetarium, Ekaterinburg, Russia

• Augmentation of brain functions and neurorehabilitation with brain-computer interfaces. UNC, Chapel Hill

• Brain-computer interfaces: Implementation of Bernstein's ideas. Psychiatric Health of the Human and Society, Moscow State University, Moscow, Russia

• Augmentation of brain functions and neurorehabilitation with brain-computer interfaces. Skoltech CNBR Seminar, Moscow, Russia

• Augmentation of brain function with brain-computer interfaces. Urban Future Festival, Kirov, Russia

• Brain-machine interfaces: accomplishments and challenges. Neuralink, San Francisco, California, USA

• Brain-computer interfaces for augmentation of brain function and neurorehabilitation. Far Eastern Federal University, Vladivostok, Russia

• Decoding of neural information with brain-computer interfaces. Did not Agree, Ekaterinburg, Russia

• Brain-computer interfaces and our conscious "I". Pint of Science 2019, Moscow, Russia

• Intracranial brain-computer interfaces. Science of the Future, Sochi, Russia

• Brain-computer interfaces: a pathway to altered consciousness? Brain Seminar, Institute for Perspective Brain Studies, Moscow, Russia

• Invasive brain-computer interfaces: from monkey to human. Mechanisms of brain control: modern neurotechnologies, Institute of Higher Nervous Activity and Neurophysiology of RAS, Moscow, Russia

• Brain-computer interfaces: decoding of locomotion. Skolkovo Robotics, Moscow, Russia

• Restoration of brain function with brain-machine interfaces. Science Week, Saint Petersburg, Russia

• Neural interfaces and other methods for augmenting brain functions. Theology and modern studies of consciousness. Saint Petersburg Theological Academy, Saint Petersburg, Russia.

2018:

• Correction of impaired brain functions. University Clinic, Tyumen, Russia

• Brain augmentation and artificial intelligence. The brain: technological solutions for its development and augmentation on Neuronet market, Saint Petersburg, Russia

• Brain-computer interfaces for neurorehabilitation. The Turner Scientific Research Institute for Children's Orthopedics, Pushkin, Russia

• Invasive brain-computer interfaces: from monkey to human. Rehabilitation based on neural technologies, Russian National Research Medical University, Moscow, Russia

• Repairing the brain with brain-machine interfaces. 1st International Conference on Neuroscience, Neuroinformatics, Neurotechnology and Neuro-Psycho-Pharmacology, Bucharest, Romania

• Decoding with brain-machine intefaces. Invasive interfaces with sensory feedback. Cortical Codes: Control & Perception, HSE, Moscow, Russia.

• Telepathy and telekinesis: with brain-computer interfaces this is scientific. Popular lectures at Neurotlon, Samara, Russia

• Decoding but what? Brain-computer interface: science and practice. Samara, Russia

• Brain-machine interfaces. Neuroinformatics, Moscow, Russia

• Functional restoration and rehabilitation with brain-machine interfaces. From Lab to Clinic: Pathways to Translational Brain Machine Interfaces for Rehabilitation, University of Reading, Reading, UK

• Neural decoding: accounting for overt behaviors, plasticity and information transfer rate. Volga Neuroscience Meeting

• Brain-machine interfaces that multitask. Brain-based and Artificial Intelligence: Socio-ethical Conversations in Computing and Neurotechnology, Chicago, IL

• Interface between the brain and computer. Master’s Programme 'Cognitive Sciences and Technologies: From Neuron to Cognition', HSE, Moscow

• Neuroimaging with multielectrode implants. HSE, Moscow

• Horizons of neuroreality. Telling Stories Fest, Moscow, Russia

• Representation of multiple behavioral variables by frontal-cortex neurons. Transcending Biology: Reverse Engineering the Brain, Carboncopies

• Brain-machine interfaces for restoration of movements and sensations. Institute for Cognitive Systems, Technical University of Munich

• Brain-machine interfaces for restoration of movements and sensations. Korea Institute of science and technology

• Towards a versatile brain-machine interface: neural decoding of multiple behavioral variables and delivering sensory feedback. The 6th International Winter Conference on Brain-Computer Interfaces, High 1 Resort, South Korea

2017:

• Invasive BCI for communication, control and perception. Активные и пассивные методы исследования мозга, HSE, Moscow

• Нейронное кодирование множественных функций: значение для нейропротезирования и нейрореабилитации. Нейрокомпьютерный интерфейс: Наука и практика. Самара 2017, Samara

• Neural prostheses for movements and sensations. 8th International IEEE EMBS Neural Engineering Conference, Shanghai

• Brain-machine interfaces. Osher Lifelong Learning Institute

• Augmentation of brain function with neural prostheses. Skolkovo Institute of Science and Technology

2016:

• Neurocomputer interfaces. BWire SPb, St Petersburg, Russia

• Adding touch sensations to artificial hands. 11th Bernstein Sparks Workshop: Naturalistic integration of information from external stimulation into the ongoing neuronal activities of the brain, Delmenhorst, Germany

• Augmentation of brain function with brain-machine interfaces and other methods. Neurocomputer Interface: Theory and Practice. Samara - 2016, Samara, Russia

• Modern trends in brain-machine interfaces. Volga Neuroscience Meeting, Russia

2015:

• Brain-machine interfaces. Science-art-2015, Moscow, Russia

• Interfacing with the brain: monologue, dialogue, forum

• Moscow Science Week 2015, Moscow, Russia. Roundtable: the mysteries and capacities of the human brain, Open Innovations 2015, Moscow, Russia

• Brain-machine interfaces for motor control and artificial perception. BCI: Science and Practice, Samara, Russia

• Brain-machine interfaces for movements, sensations and more. Theoretical and Neurobiological Bases of Higher Cognitive Functions, Moscow, Russia

• Fundamental science + science fiction = brain-machine interface. 2045 Initiative, Moscow, Russia

• Brain-machine interfaces for motor control and sensory feedback. UNAM Frontiers in Genomics Seminars, Cuernavaca, Mexico

• Brain-machine interfaces for movements and sensations. Graduate School of Brain Science, Doshisha University, Kyoto, Japan

• Brain-machine interfaces for movements, sensations and more. B-DEBATE: A Dialogue with the Cerebral Cortex: Cortical Function and Interfacing, Barcelona, Spain

• Brain-machine interfaces for motor control and sensory feedback. Interaction with the robot using a brain-machine interface. Skolkovo Robotics 2014, Moscow, Russia

2014:

• Encoding principles of the brain / Representation of multiple behavioral variables by single neurons and neuronal ensembles / Oscillatory neurons and brain oscillations / Brain-machine interfaces / Artificial sensory feedback. School of Psychology, Higher School of Economics, Moscow, Russia

• Motor control and five senses for an artificial body. 2045 Initiative, Moscow, Russia

• Brain-machine interfaces. BioN-HSE School, Moscow Russia

• Brain-machine interfaces for movement and sensation. Open Innovations 2014, Moscow, Russia

• Brain-machine interfaces. Simposia Internacional de Ingenieria Biomedica 2014, Guadalajara, Mexico

• Brain-machine interfaces. Startup Village 2014, Moscow, Russia

• Brain-machine interface or scientific approach to telekinesis, extrasensory perception and telepathy. School of Psychology, Higher School of Economics, Moscow, Russia

2013:

• Brain machine interfaces for movement and sensation. 22nd Academic and Medical Congress, Botucatu, Brazil

• Brain machine interfaces for movement and sensation. Anatomical and Functional Modularity of the Cerebral Cortex, Louisville, Kentucky

• Roundtable on Life-extension of the Brain in a Full-body Prosthesis. Global Future 2045, New York

• Neural Interfaces: From Locomotion to Handwriting. Fondazione Santa Lucia, Rome Italy

• Brain machine interfaces for movement and sensation. Postural and Motor Perspectives in Portland, Portland, Oregon

2012:

• State of Research on Cortically Controlled Bipedal Locomotion. Walk Again Project Symposium, Duke University

2011:

• Brain-Machine Interfaces: From Locomotion to Sensorized Hand Movements.. Young European Scientist Meeting, Porto, Portugal

• Brain-Machine Interfaces: From Locomotion to Active Tactile Exploration. Horizons in Molecular Biology, Gоеttingen, Germany

• Brain-Machine Interfaces: From Locomotion to Fine Hand Movements. IGS 2011, Cancun, Mexico

2009:

• Brain-machine interfaces based on neuronal ensemble recordings. BBCI Wokshop 2009, Advances in Neurotechnology, Berlin, Germany

• Neuronal ensembles in control of brain-machine interfaces. JST/ICORP Symposium: Create a robot, and know a human being. Tokyo, Japan

2008:

• Encoding principles in the brain: rate versus temporal encoding. Feedback and feedforward loops in somatosensory system.

• Representation of multiple spatial variables in the brain / Cortical oscillations and their role in information encoding / Decoding neuronal signals in brain-machine interfaces /Cortical microstimulation as the way to deliver information to the brain. First CAPES and ELS-IINN/UFRN Summer School, Natal, Brazil

• Brain-machine interaces: past, present and future. Ethics of human techno-enhancement: future of brain-machine interface, Kyoto, Japan

2007:

• Decoding and encoding with cortical multiple electrode implants. Organtechno 2007, Tokyo, Japan

• Decoding and encoding with cortical multielectrode implants. RIKEN, Wako City, Japan

• Decoding and encoding with multielectrode implants. Neurizons. Max Planck Institute for Experimental Medicine, Goettingen, Germany

• Decoding multiple behavioral variables from neuronal ensemble activity. Advanced Telecommunications Research Institute International, Kyoto, Japan

2006:

• Encoding of attended versus remembered locations by prefrontal cortex neurons. Cognitive Neuroscience Meeting, San Francisco, California

• Obtaining accurate read-out of multiple behavioral variables from large neuronal ensembles. Barrow Neurological Institute, Phoenix, Arizona

2004:

• Frontal cortex mechanisms of spatial motor behavior. IBRO Summer School: Sensory and Integrative Neuroscience, Moscow, Russia

2003:

• Monkey attend, monkey do. Dissociation of spatial attention from other variables in task-related activity of frontal cortex neurons. Department of Neurobiology and Anatomy, Wake Forest University

2002:

• Processing of spatial information in frontal cortex. Department of Neurobiology, Duke University

2000:

• Dissociation of spatial, mnemonic, attentional, and intentional signals related to reaching movements and eye movements in frontal cortex. Neural Control of Movement Meeting, Naples, Florida

• Processing of spatial information in frontal cortex. Department of Psychology, Vanderbilt University

1998:

• Oscillations in the activity of individual premotor cortex neurons. Department of Psychology, Vanderbilt University

• Premotor cortex: detection of oscillations in single-unit activity. Human Motor Control Section, National Institute of Neurological Disorders and Stroke

1995:

• Computing the meaning of neural activity. Second Borsellino College of Neurophysics. The Abdus Salam International Centre for Theoretical Physics

• Rhythmic activity of SI neurons. Cognitive Neuroscience Sector, International School for Advanced Studies, Trieste, Italy

Editor

• BioMed Research International

• Brain-Computer Interfaces

• Computational Intelligence and Neuroscience

• Frontiers in Neuroscience

• Frontiers in Systems Neuroscience

• Frontiers in Human Neuroscience

• Journal of Neural Engineering

• Neuropsychologia

• PLOS ONE

• Technologies

• Vestnik RGMU

• Science and Innovations in Medicine

Reviewer

• Brain Research

• Brain Topography

• Cerebral Cortex

• Engineering and Physical Sciences Research Council, UK

• European Journal of Neuroscience

• European Research Council Starting Grants 2017

• Experimental Brain Research

• Frontiers in Neuroscience

• IEEE Healthcom 2014

• IEEE World Haptics Conference

• IEEE Transactions on Biomedical Engineering

• IEEE Transactions on Cybernetics

• IEEE Transactions on Systems, Man and Cybernetics

• Industrial Robot

• International Journal of Psychophysiology

• Journal of Cognitive Neuroscience

• Journal of Neural Engineering

• Journal of Neuroscience

• Journal of Neurophysiology

• Journal of Neuroscience Methods

• Journal of Zhejiang University

• Nature Communications

• Netherlands Organisation for Scientific Research

• Neural Computation

• Neural Networks

• Neuroscience

• Neuroscience Bulletin

• Neuroscience Letters

• NSF Board on Robust Intelligence

• PLOS Computational Biology

• Proceedings of the National Academy of Sciences of the United States of America

• Scientific Reports

• SwissTransMed

• Synapse

• The Annual BCI Reward Award 2014, Juror

• The Annual BCI Reward Award 2016, Chair

• The 5th Joint Eurohaptics Conference and IEEE Haptics Symposium

• Trends in Cognitive Sciences

• The Neuroscientist

Honors and Awards

2021: RSF Grant

2020: TUM Visiting Professorship

2018: Megagrant from the government of Russian Federation

2017: Frontiers Spotlight Award

2016: Frontiers Travel Award

Scientific Reports Top 100 Badge

2015: Frontiers Travel Award

2012: Duke University Science Education Grant Award

1993: Travel Award, University of Tennessee, Memphis

1988: 2nd Prize, Annual Research Competition, Institute for Information Transmission Problems, Moscow

1986: Diploma with Distinction, Moscow Institute of Physics and Technology

1980: Graduation with Gold Medal, Specialized High School #60, Moscow

Hobbies

2017: Umstead Trail Marathon

2016: Umstead Trail Marathon

Publications

Books

1. Guger C, Allison B, Lebedev M (Editors) Brain-Computer Interface Research: A State-of-the-Art Summary 6 (SpringerBriefs in Electrical and Computer Engineering)

2. Lebedev MA, Erlichman J, Teulings H-L (Editors) Bioelectrical Technologies for Normal Motor Functions and Movement Disorders

3. Mirabella G, Lebedev MA, Priori A, Duque J, Ossadtchi A, Rossi S, David O (Editors) Neural Electroceuticals: Interfacing with the Nervous System with Electrical Stimulation

4. Allison BZ, Lebedev MA, Song D, Panetsos F, Berger TW, Opris I, Dunne S (Editors) Futuristic Neural Prostheses

5. Ferris DP, Lebedev MA, Ivanenko YP, Lee K, Sakurai Y, Beloozerova IN (Editors) Neural Prostheses for Locomotion

6. Noga BR, Lebedev MA, Opris I, Mitchell GS (Editors) Neuromodulatory Control of Brainstem Function in Health and Disease

7. Deca D, Koene RA, Opris I, Lebedev MA, Mikula S (Editors) Towards Whole Brain Emulation: System Identification Using Neuroprosthetics for Neuromodulation

8. Ballerini L, Ionescu SC, Lebedev MA, Opris I, Boy F, Lewinski P (Editors) Application of Neural Technology to Neuro-Management and Neuro-Marketing

9. Opris I, Lebedev MA, Vidu R, Pulgar VM, Enachescu M, Casanova MF (Editors) Nanotechnologies in Neuroscience and Neuroengineering

10. Lebedev MA (Editor) Brain-Machine Interface Technology

11. Lebedev MA, Barbara JG, Antoniades CA, Lorusso L, Judas M, Opris I (Editors) Paradigm Shifts in Neuroscience

12. Ionta S, Lebedev MA (Editors) Health, Pathology, and Rehabilitation of the Sensory-Motor Loop

13. Opris I, Lebedev MA, Vidu R, Pulgar VM, Enachescu M, Casanova MF (Editors) Neural Nanotechnology: Revolutionary Approach for Neuroscientists

14. Lebedev MA, Opris I, CasanoLebedev M, Pimashkin A, Ossadtchi A (2018). Navigation patterns and scent marking: underаppreciated contributors to hippocampal and entorhinal spatial representations? Front Behavioral Neurosci 12: 98.va MF (Editors) Augmentation of Brain Function: Facts, Fiction and Controversy

Articles

1. Senko, D., Gorovaya, A., Stekolshchikova, E., Anikanov, N., Fedianin, A., Baltin, M., ... & Tkachev, A. (2022). Time-Dependent Effect of Sciatic Nerve Injury on Rat Plasma Lipidome. International Journal of Molecular Sciences, 23(24), 15544.

2. Syrov, N., Yakovlev, L., Nikolaeva, V., Kaplan, A., & Lebedev, M. (2022). Mental Strategies in a P300-BCI: Visuomotor Transformation Is an Option. Diagnostics, 12(11), 2607.

3. Bugakova, A., Nikolaeva, V., Gorin, A., Muraveva, A., Kuzmina, E., & Lebedev, M. (2022, September). EEG during Motor Imagery under Different Postural Conditions–Case Study. In 2022 6th Scientific School Dynamics of Complex Networks and their Applications (DCNA) (pp. 55-57). IEEE.

4. Kuzmina, E., Kriukov, D., & Lebedev, M. (2022, September). Further Observations on the Rotational Structure in Neural Data. In 2022 6th Scientific School Dynamics of Complex Networks and their Applications (DCNA) (pp. 168-171). IEEE.

5. Gorin, A., Bugakova, A., Kirasirova, L., & Lebedev, M. (2022, September). EEG responses evoked by transcutaneous spinal cord stimulation: a pilot study. In 2022 Fourth International Conference Neurotechnologies and Neurointerfaces (CNN) (pp. 32-34). IEEE.

6. Syrov, N., Polukeev, S., Nikolaeva, V., Smirnova, S., Moiseev, G., Kaplan, A., & Lebedev, M. (2022, September). Adapting a P300-BCI for Visuomotor Transformation: Counting Target Stimuli Versus Imagining Movements Toward Them. In 2022 Fourth International Conference Neurotechnologies and Neurointerfaces (CNN) (pp. 194-197). IEEE.

7. Gorovaya, A., Lebedev, M., Lavrov, I., Baltina, T., Baltin, M., & Fedyanin, A. (2022, September). Sciatic nerve clamp: a rat model of neuropathic pain with low inter-subject variability. In 2022 Fourth International Conference Neurotechnologies and Neurointerfaces (CNN) (pp. 35-37). IEEE.

8. Soghoyan, G., Sintsov, M., Biktimirov, A., Chekh, I., & Lebedev, M. (2022, September). Peripheral nerve stimulation for tactile feedback and phantom limb pain suppression. In 2022 Fourth International Conference Neurotechnologies and Neurointerfaces (CNN) (pp. 162-164). IEEE.

9. Ninenko, I., Kleeva, D., Bukreev, N., Gritsenko, G., & Lebedev, M. (2022, September). Brain-computer interface for olfaction: detecting olfactory related EEG components. In 2022 Fourth International Conference Neurotechnologies and Neurointerfaces (CNN) (pp. 108-110). IEEE.

10. Ninenko, I., Kleeva, D., Bukreev, N., Gritsenko, G., & Lebedev, M. (2022, September). Brain-computer interface for olfaction: detecting olfactory related EEG components. In 2022 Fourth International Conference Neurotechnologies and Neurointerfaces (CNN) (pp. 108-110). IEEE.

11. Makarova, A., Volkova, K., Lebedev, M., & Ossadtchi, A. (2022, September). ECoG Based Classification of Hand Movement Direction in The Stylus Center-Out Paradigm. In 2022 Fourth International Conference Neurotechnologies and Neurointerfaces (CNN) (pp. 86-89). IEEE.

12. Piliugin, N., Soghoyan, G., Matvienko, Y., Sintsov, M., Chekh, I., Biktimirov, A., & Lebedev, M. (2022, September). Evoking sensation in the phantom hand of amputees using invasive stimulation of peripheral nerves. In 2022 Fourth International Conference Neurotechnologies and Neurointerfaces (CNN) (pp. 113-116). IEEE.

13. Kleeva, D., Lebedev, M., Biktimirov, A., Matvienko, Y., Sintsov, M., Piliugin, N., & Soghoyan, G. (2022, September). EEG markers of pain suppression as a result of electrical stimulation: case report. In 2022 Fourth International Conference Neurotechnologies and Neurointerfaces (CNN) (pp. 75-77). IEEE.

14. Onuchin, A., Chernizova, A., Lebedev, M., & Polovnikov, K. (2022). Communities in C. elegans connectome through the prism of non-backtracking walks. arXiv preprint arXiv:2207.11282.

15. Swan, M., Dos Santos, R. P., Lebedev, M., & Witte, F. (2022). Quantum Computing for the Brain.

16. Morozova, M., Bikbavova, A., Bulanov, V., & Lebedev, M. (2022). EEG Changes during Odor Perception and Discrimination. bioRxiv.

17. Ninenko, I., Kleeva, D. F., Bukreev, N., & Lebedev, M. A. (2022). EEG correlates of olfactory processing during an instructed-delay task. bioRxiv.

18. Yakovlev, L., Syrov, N., Miroshnikov, A., Lebedev, M., & Kaplan, A. (2022). Event-Related Desynchronization induced by Tactile Imagery: an EEG Study. bioRxiv.

19. Pais-Vieira, M., Ramakrishnan, A., Rocon, E., Lebedev, M., & da Cruz-e-Silva, O. A. (2022). Digital health and neuroscience: Recent history, current trends, and future developments. Frontiers in Integrative Neuroscience, 16.

20. Volodina, M., Smetanin, N., Lebedev, M., & Ossadtchi, A. (2021). Cortical and autonomic responses during staged Taoist meditation: Two distinct meditation strategies. PloS one, 16(12), e0260626.

21. Rakhmatulin, I., Parfenov, A., Traylor, Z., Nam, C. S., & Lebedev, M. (2021). Low-cost brain computer interface for everyday use. Experimental Brain Research, 239(12), 3573-3583.

22. Daly, I., Matran-Fernandez, A., Valeriani, D., Lebedev, M., & Kübler, A. (Eds.). (2021). Datasets for Brain-Computer Interface Applications. Frontiers Media SA.

23. Wen, S., Yin, A., Tseng, P. H., Itti, L., Lebedev, M. A., & Nicolelis, M. (2021). Capturing spike train temporal pattern with wavelet average coefficient for brain machine interface. Scientific reports, 11(1), 1-10.

24. Ninenko, I., Gritsenko, G., Bukreev, N., Ossadtchi, A., & Lebedev, M. (2021, September). Brain-computer interface for olfaction: machine learning decoding odors from EEG. In 2021 Third International Conference Neurotechnologies and Neurointerfaces (CNN) (pp. 74-75). IEEE.

25. Volodina, M., Smetanin, N., Rusinova, A., Lebedev, M., & Ossadtchi, A. (2021, September). Different central and autonomic nervous system coupling in the experienced meditators and novices during the Taoist meditation. In 2021 Third International Conference Neurotechnologies and Neurointerfaces (CNN) (pp. 118-120). IEEE.

26. Paltarzhitskaya, A., Kleeva, D., Osadchaya, M., Lebedev, M., Myachykov, A., & Ossadtchi, A. (2021, September). Exploring time interval estimation for familiar and unfamiliar musical pieces. In 2021 Third International Conference Neurotechnologies and Neurointerfaces (CNN) (pp. 76-78). IEEE.

27. Makarova, A., Volkova, K., Lebedev, M., & Ossadtchi, A. (2021, September). Exploration of Cortical Dynamics in the Center-Out with Stylus Paradigm. In 2021 Third International Conference Neurotechnologies and Neurointerfaces (CNN) (pp. 64-66). IEEE.

28. Opris, I., Lebedev, M. A., & Casanova, M. F. (Eds.). (2021). Modern Approaches to Augmentation of Brain Function. Springer International Publishing.

29. Yadav, A. P., Li, S., Krucoff, M. O., Lebedev, M. A., Abd-El-Barr, M. M., & Nicolelis, M. A. (2021). Generating artificial sensations with spinal cord stimulation in primates and rodents. Brain Stimulation, 14(4), 825-836.

30. Bulanov, V., Zakharov, A., Sergio, L., & Lebedev, M. (2021). Visuomotor Transformation with a P300 Brain-Computer Interface Combined with Robotics and Virtual Reality: A Device for Post-Stroke Rehabilitation. Available at SSRN 3811232.

31. Petrosyan, A., Sinkin, M., Lebedev, M., & Ossadtchi, A. (2021). Decoding and interpreting cortical signals with a compact convolutional neural network. Journal of Neural Engineering, 18(2), 026019.

32. Gerasimov, A., Lebedev, G., Lebedev, M., & Semenycheva, I. (2021). COVID-19 dynamics: a heterogeneous model. Frontiers in Public Health, 8, 558368.

33. Wen, S., Yin, A., Tseng, P. H., Itti, L., Lebedev, M., & Nicolelis, M. (2021). Wavelet average coefficient: a new statistical feature for capturing the temporal pattern of spike trains, with application in Brain Machine Interface.

34. Sinkin, M. V., Evdokimov, A. I., Sklifosovsky, N. V., Ossadtchi, A. E., Lebedev, M. A., Volkova, K. V., ... & Bulgakova, V. O. (2021). High-Resolution Intraoperative Speech Mapping Using Electrocorticographic Signals.

35. Ivanenko, Y., Ferris, D. P., Lee, K., Sakurai, Y., Beloozerova, I. N., & Lebedev, M. (2021). Neural Prostheses for Locomotion. Frontiers in Neuroscience, 15.

36. Lebedev, M. A., Shaderkin, I. A., Ryabkov, I. V., & Lebedev, G. S. (2021). Augmentation Through Interconnection: Brain-Nets and Telemedicine. In Modern Approaches to Augmentation of Brain Function (pp. 343-355). Springer, Cham.

37. Angelica, A., Opris, I., Lebedev, M. A., & Boehm, F. J. (2021). Cognitive Augmentation Via a Brain/Cloud Interface. In Modern Approaches to Augmentation of Brain Function (pp. 357-386). Springer, Cham.

38. Opris, I., Noga, B. R., Lebedev, M. A., & Casanova, M. F. (2021). Modern Approaches to Augmenting the Brain Functions. Modern Approaches to Augmentation of Brain Function, 57-89.

39. Opris, I., Preza, N., Lebedev, M. A., Noga, B. R., Chang, S. J., Casanova, M. F., ... & Popescu, A. I. (2021). Augmentation of Brain Functions by Nanotechnology. In Modern Approaches to Augmentation of Brain Function (pp. 233-259). Springer, Cham.

40. Soghoyan, G., Smetanin, N., Lebedev, M., & Ossadtchi, A. (2021). Performance Analysis of a Source-Space Low-Density EEG-Based Motor Imagery BCI. In International Conference on Cognitive Sciences (pp. 687-691). Springer, Cham.

41. Sinkin, M. V., Volkova, K. V., Kondratova, M. S., Voskoboynikov, A. M., Lebedev, M. A., Ivanova, M. D., & Ossadtchi, A. E. (2021). Passive Intraoperative Language Mapping Using Electrocorticographic Signals. In International Conference on Cognitive Sciences (pp. 533-540). Springer, Cham.

42. Lebedev M, Ninenko I, Ossadtchi A (2020) Rotational dynamics versus sequence-like responses. https://www.biorxiv.org/content/10.1101/2020.09.16.300046v5

43. Kirasirova L, Bulanov V, Ossadtchi A, Kolsanov A, Pyatin V, Lebedev M (2020) A P300 brain-computer interface with a reduced visual field. https://www.biorxiv.org/content/10.1101/2020.09.07.285379v2

44. Belinskaia A, Smetanin N, Lebedev M, Ossadtchi A (2020) Short-delay neurofeedback facilitates training of the parietal alpha rhythm. https://www.biorxiv.org/content/10.1101/2020.07.27.222786v2

45. Kirasirova L, Bulanov V, Ossadtchi A, Kolsanov A, Pyatin V, Lebedev M (2020) A P300 brain-computer interface with a reduced visual field. https://www.biorxiv.org/content/10.1101/2020.09.07.285379v1

46. Smetanin N, Belinskaya A, Lebedev MA, Ossadtchi A (2020) Digital filters for low-latency quantification of brain rhythms in real-time. J Neural Eng, in press.

47. Petrosuan A, Lebedev M, Ossadtchi A (2020) Decoding neural signals with a compact and interpretable convolutional neural network. https://www.biorxiv.org/content/10.1101/2020.06.02.129114v1

48. Kuznetsova A, Lebedev M, Ossadtchi A (2020) Local propagation dynamics of MEG interictal spikes: source reconstruction with traveling-wave priors. https://www.biorxiv.org/content/10.1101/2020.05.17.101121v1

49. Yadav AP, Li S, Krucoff MO, Lebedev MA, Abd-El-Barr MM, Nicolelis MA (2020) Generating artificial sensations with spinal cord stimulation in primates and rodents. https://www.biorxiv.org/content/10.1101/2020.05.09.085647v1

50. Gerasimov A, Lebedev G, Lebedev M, Semenycheva I (2020) COVID-19 dynamics: a heterogeneous model. https://www.medrxiv.org/content/10.1101/2020.05.04.20090688v1

51. Gerasimov A, Lebedev G, Lebedev M, Semenycheva I (2020) Reaching collective immunity for COVID-19: an estimate with a heterogeneous model based on the data for Italy. https://www.medrxiv.org/content/10.1101/2020.05.24.20112045v1

52. Maksimenko V, Frolov N, Kuc A, Hramov A, Pisarchik A, Lebedev M (2020) Neuronal adaptation in the course of the prolonged task improves visual stimuli processing. https://www.biorxiv.org/content/10.1101/2020.04.07.029959v1

53. Opris I, Ionescu SC, Lebedev M, Boy F, Lewinski P, Ballerini L (2020) Editorial: Application of neural technology to neuro-management and neuro-marketing. Frontiers in Neuroscience 14: 53.

54. Noga BR, Opris I, Lebedev M, Mitchell GS (2020) Editorial: Neuromodulatory control of brainstem function in health and disease. Frontiers in Neuroscience 14: 86.

55. Opris I, Lebedev M, Pulgar VM, Enachescu M, Vidu R, Casanova MF (2020) Editorial: Nanotechnologies in neuroscience and neuroengineering. Frontiers in Neuroscience 14: 33.

56. Lebedev MA, Ossadtchi A, Mill NA, Urpí NA, Cervera MR, Nicolelis MAL (2019) Analysis of neuronal ensemble activity reveals the pitfalls and shortcomings of rotation dynamics. Scientific Reports 9: 1-14.

57. O'Doherty JE, Shokur S, Medina LE, Lebedev MA, Nicolelis MAL (2019) Creating a neuroprosthesis for active tactile exploration of textures. PNAS 116: 21821-21827.

58. Tseng PH, Urpi NA, Lebedev M, Nicolelis M. (2019) Decoding movements from cortical ensemble activity using a long short-term memory recurrent network. Neural Comput 31: 1085-1113.

59. Martins NRB, Angelica A, Chakravarthy K, Svidinenko Y, Boehm FJ, Opris I, Lebedev MA, Swan M, Garan SA, Rosenfeld JV, Hogg T, Freitas RA Jr. (2019) Human brain/cloud interface. Front Neurosci 13:112.

60. Ros T, Enriquez-Geppert S, Zotev V, Young KD, Wood G, Whitfield-Gabrieli S, Wan F, Vuilleumier P, Vialatte F, Van De Ville D, Todder D, Surmeli T, Sulzer JS, Strehl U, Sterman MB, Steiner NJ, Sorger B, Soekadar SR, Sitaram R, Sherlin LH, Schönenberg M, Scharnowski F, Schabus M, Rubia K, Rosa A, Reiner M, Pineda JA, Paret C, Ossadtchi A, Nicholson AA, Nan W, Minguez J, Micoulaud-Franchi JA, Mehler DMA, Lührs M, Lubar J, Lotte F, Linden DEJ, Lewis-Peacock JA, Lebedev MA, Lanius RA, Kübler A, Kranczioch C, Koush Y, Konicar L, Kohl SH, Kober SE, Klados MA, Jeunet C, Janssen TWP, Huster RJ, Hoedlmoser K, Hirshberg LM, Heunis S, Hendler T, Hampson M, Guggisberg AG, Guggenberger R, Gruzelier JH, Göbel RW, Gninenko N, Gharabaghi A, Frewen P, Fovet T, Fernández T, Escolano G, Ehlis AC, Drechsler R, deCharms RC, Debener S, De Ridder D, Davelaar EJ, Congedo M, Cavazza M, Breteler MHM, Brandeis D, Bodurka J, Birbaumer N, Bazanova OM, Barth B, Bamidis PD, Auer T, Arns M, Thibault RT (2019) Consensus on the reporting and experimental design of clinical and cognitive-behavioural neurofeedback studies (CRED-nf checklist). Brain, in press

61. Ros T, Enriquez-Geppert S, Zotev V, Young K, Wood G, Whitfield-Gabrieli S, Wan F, Vialatte F, Van De Ville D, Todder D, Surmeli T, Sulzer J, Strehl U, Sterman B, Steiner N, Sorger B, Soekadar S, Sitaram R, Sherlin L, Schönenberg M, Scharnowski F, Schabus M, Rubia K, Rosa A, Reiners M, Pineda J, Paret C, Nicholson A, Nan W,, Minguez J, Micoulaud-Franchi J, Mehler DMA, Lubar J, Lotte F, Linden DEJ, Lewis-Peacock J, Lebedev M, Lanius R, Kübler A, Kranczioch C, Koush Y, Konicar L, Kober SE, Klados M, Jeunet C, Janssen T, Huster RJ, Hoedlmoser K, Hirshberg L, Hendler T, Hampson M, Guggisberg A, Gruzelier J, Göbel R, Gninenko N, Gharabaghi A, Frewen P, Fovet T, Fernandez T, Escolano C, Ehlis A, Drechsler R, deCharms RC, De Ridder D, Davelaar E, Congedo M, Cavazza M, Breteler R, Brandeis D, Bodurka J, Birbaumer N, Bazanova O, Bauer R, Barth B, Bamidis P, Auer T, Arns M, Thibault RT (2019) Consensus on the reporting and experimental design of clinical and cognitive-behavioural neurofeedback studies (CRED-nf checklist). https://psyarxiv.com/nyx84/

62. O’Doherty JE, Shokur S, Medina, LE, Lebedev MA, Nicolelis MA (2019) Creating a neuroprosthesis for active tactile exploration of textures. bioRxiv, p.594994.

63. Lebedev MA, Ossadtchi A, Mill NA, Urpí NA, Cervera MR, Nicolelis MA (2019) What, if anything, is the true neurophysiological significance of “rotational dynamics”? BioRxiv, p.597419.

64. Shokur S, Donati ARC, Campos DSF, Gitti C, Bao G, Fischer D, Almeida S, Braga VAS, Augusto P, Petty C, Alho EJL, Lebedev M, Song AW, Nicolelis MAL (2018) Training with brain-machine interfaces, visuo-tactile feedback and assisted locomotion improves sensorimotor, visceral, and psychological signs in chronic paraplegic patients. PLoS One 13: e0206464.

65. Lebedev MA, Opris I, Casanova MF. (2018) Editorial: Augmentation of brain function: facts, fiction and controversy. Front Syst Neurosci 12: 45.

66. Yin A, Tseng PH, Rajangam S, Lebedev MA, Nicolelis MAL (2018) Place cell-like activity in the primary sensorimotor and premotor cortex during monkey whole-body navigation. Scientific Reports 8: 9184.

67. Lebedev M, Pimashkin A, Ossadtchi A (2018). Navigation patterns and scent marking: underаppreciated contributors to hippocampal and entorhinal spatial representations? Front Behavioral Neurosci 12: 98.

68. Tseng PH, Rajangam S, Lehew G, Lebedev MA, Nicolelis MA (2018) Interbrain cortical synchronization encodes multiple aspects of social interactions in monkey pairs. Scientific reports 8: 4699.

69. Lebedev MA, Ossadtchi A (2018) Commentary: Spatial olfactory learning contributes to place field formation in the hippocampus. Front Systems Neurosci 12: 8.

70. Lebedev M, Ossadtchi A (2018) Commentary: Injecting instructions into premotor cortex. Front Cell Neurosci, 12: 65.

71. Lebedev M (2017) Commentary: Emergence of a stable cortical map for neuroprosthetic control. Front Neurosci 11: 642.

72. Lebedev, M (2017). Commentary: Cortical activity in the null space: permitting preparation without movement. Front Neurosci 11: 502.

73. Krucoff MO, Zhuang K, Macleod DB, Yin A, Byun YW, Manson RJ, Turner DA, Oliveira L, Lebedev MA (2017) A novel paraplegia model in awake behaving macaques. J Neurophysiol jn.00327.2017

74. Ossadtchi A, Shamaeva T, Okorokova E, Moiseeva V, Lebedev MA (2017) Neurofeedback learning modifies the incidence rate of alpha spindles, but not their duration and amplitude. Sci Rep 7: 3772.

75. Ramakrishnan A, Byun YW, Rand K, Pedersen CE, Lebedev MA, Nicolelis MAL (2017) Cortical neurons multiplex reward-related signals along with sensory and motor information. Proc Natl Acad Sci U S A 114: E4841-E4850.

76. Lebedev MA, Nicolelis MA (2017) Brain-machine interfaces: From basic science to neuroprostheses and neurorehabilitation. Physiol Rev 97: 767-837.

77. Mirabella G, Lebedev MА (2017) Interfacing to the brain's motor decisions. J Neurophysiol 117: 1305-1319.

78. Vouga T, Zhuang KZ, Olivier J, Lebedev MA, Nicolelis MA, Bouri M, Bleuler H (2017) EXiO-A brain-controlled lower limb exoskeleton for rhesus macaques. IEEE Trans Neural Syst Rehabil Eng 25: 131-141.

79. Rieznik A, Lebedev M, Sigman M (2017) Dazzled by the mystery of mentalism: The cognitive neuroscience of mental athletes. Front Hum Neurosci 11: 287.

80. Pais-Vieira M, Yadav AP, Moreira D, Guggenmos D, Santos A, Lebedev M, Nicolelis MA (2016) A closed loop brain-machine interface for epilepsy control using dorsal column electrical stimulation. Sci Rep 6.

81. Yin A, An J, Lehew G, Lebedev MA, Nicolelis MA (2016) An automatic experimental apparatus to study arm reaching in New World monkeys. J Neurosci Methods 264:57-64.

82. Onose G, Cârdei V, Crăciunoiu ŞT, Avramescu V, Opriş I, Lebedev MA, Constantinescu MV (2016) Mechatronic wearable exoskeletons for bionic bipedal standing and walking: a new synthetic approach. Front Neurosci 10.

83. Rajangam S, Tseng PH, Yin A, Lehew G, Schwarz D, Lebedev MA, Nicolelis MA (2016) Wireless cortical brain-machine interface for whole-body navigation in primates. Sci Rep 6:22170.

84. Lebedev M (2016) Augmentation of sensorimotor functions with neural prostheses. Opera Medica et Physiologica 3-4.

85. Levitskaya O, Lebedev MA (2016) Brain-computer interface: the future in the present. Vestnik RGMU 2.

86. Ordikhani-Seyedlar M, Lebedev MA, Sorensen HB, Puthusserypady S (2016) Neurofeedback therapy for enhancing visual attention: state-of-the-art and challenges. Front Neurosci 10: 352.

87. Opris I, Lebedev MA, Nelson RJ (2016) Neostriatal neuronal activity correlates better with movement kinematics under certain rewards. Front Neurosci 10: 336.

88. Lebedev M, Ionta S (2015) Health, pathology, and rehabilitation of the sensory-motor loop. Neuropsychologia 79(Pt B):173-174.

89. Pais-Vieira M, Kunicki C, Tseng PH, Martin J, Lebedev MA, Nicolelis MA (2015) Cortical and thalamic contributions to response dynamics across layers of the primary somatosensory cortex during tactile discrimination. J Neurophys 114:1652-1676.

90. Pais-Vieira M, Chiuffa G, Lebedev M, Yadav A, Nicolelis MA (2015) Building an organic computing device with multiple interconnected brains. Sci Rep 5:11869.

91. Ramakrishnan A, Ifft PJ, Pais-Vieira M, Woo Byun Y, Zhuang KZ, Lebedev MA, Nicolelis MA (2015) Computing arm movements with a monkey brainet. Sci Rep 5:10767.

92. Rajangam S, Tseng PH, Yin A, Lebedev MA, Nicolelis MA (2015) Direct Cortical Control of Primate Whole-Body Navigation in a Mobile Robotic Wheelchair. arXiv preprint arXiv:1504.02496. [pdf]

93. Okorokova E, Lebedev M, Linderman M, Ossadtchi A (2015) A dynamical model improves reconstruction of handwriting from multichannel electromyographic recordings. Front Neurosci 9:389.

94. Zhuang KZ, Lebedev MA, Nicolelis MAL (2014) Joint cross-correlation analysis reveals complex, time-dependent functional relationship between cortical neurons and arm electromyograms. J Neurophys 112: 2865-2887.

95. Schwarz DA, Lebedev MA, Hanson TL, Dimitrov DF, Lehew G, Meloy J, Rajangam S, Subramanian V, Ifft PJ, Li Z, Ramakrishnan A, Tate A, Zhuang KZ, Nicolelis MAL (2014) Chronic, wireless recordings of large-scale brain activity in freely moving rhesus monkeys. Nature Meth 11: 670-676.

96. Lebedev MA (2014). Brain-machine interfaces: an overview. Transl Neurosci 5: 99-110. [pdf]

97. Zacksenhouse M, Lebedev MA, Nicolelis MAL (2014) Signal-independent timescale analysis (SITA) and its application for neural coding during reaching and walking. Front Computat Neurosci 8:91.

98. Lebedev MA (2014) How to read neuron-dropping curves? Front Systems Neurosci 8: 102.

99. Ifft PJ, Shokur S, Li Z, Lebedev MA, Nicolelis MA (2013). A Brain-machine interface enables bimanual arm movements in monkeys. Science Transl Med, 5: 210ra154-210ra154.

100. Shokur S, O'Doherty JE, Winans JA, Bleuler H, Lebedev MA, Nicolelis MA (2013) Expanding the primate body schema in sensorimotor cortex by virtual touches of an avatar. Proc Natl Acad Sci U S A 110: 15121-15126.

101. Pais-Vieira M, Lebedev M, Kunicki C, Wang J, Nicolelis M (2013) A brain-to-brain interface for real-time sharing of sensorimotor information. Scientific Reports 3, doi:10.1038/srep01319.

102. Pais-Vieira M, Lebedev MA, Wiest MC, and Nicolelis MAL (2013) Simultaneous top-down modulation of the primary somatosensory cortex and thalamic nuclei during active tactile discrimination. J Neurosci 33: 4076-4093.

103. Medina LE, Lebedev MA, O'Doherty JE, Nicolelis MA (2012) Stochastic facilitation of artificial tactile sensation in primates. J Neurosci 32: 14271-14275.

104. Rupasov VI, Lebedev MA, Erlichman JS, Lee SL, Leiter JC, Linderman M (2012) Time-Dependent statistical and correlation properties of neural signals during handwriting. PLoS One 7: e43945. [pdf]

105. Ifft PJ, Lebedev MA, Nicolelis MA (2012) Reprogramming movements: extraction of motor intentions from cortical ensemble activity when movement goals change. Front Neuroeng 5:16. [pdf]

106. Hanson TL, Fuller AM, Lebedev MA, Turner DA, Nicolelis MAL (2012) Subcortical neuronal ensembles: an analysis of motor task association, tremor, oscillations, and synchrony in human patients. J Neurosci 32: 8620-8632.

107. Hanson T, Omarsson B, O'Doherty J, Peikon I, Lebedev MA, Nicolelis MAL (2012) High-side digitally current controlled biphasic bipolar microstimulator. IEEE Trans Neural Syst Rehabil Eng 20: 331-340.

108. Rupasov VI, Lebedev MA, Erlichman JS, Linderman M (2012) Neuronal variability during handwriting: lognormal distribution. PLoS One 7: e34759. [pdf]

109. Ifft PJ, Lebedev MA, Nicolelis MA (2012) Cortical correlates of Fitts' law. Front Integr Neurosci 5: 85. [pdf]

110. O'Doherty JE, Lebedev MA, Li Z, Nicolelis MAL (2012) Virtual active touch using randomly patterned intracortical microstimulation. IEEE Trans Neural Syst Rehabil Eng 20: 85-93. [pdf]

111. O'Doherty JE, Lebedev MA, Ifft PJ, Zhuang KZ, Shokur S, Bleuler H, Nicolelis MAL (2011) Active tactile exploration enabled by a brain-machine-brain interface. Nature 479: 228-231. [pdf]

112. Lebedev MA, Nicolelis MAL (2011) Towards a whole body neuroprosthetic. Prog Brain Res 194: 47-60.

113. Li Z, O'Doherty JE, Lebedev MA, Nicolelis MAL (2011) Adaptive decoding for brain-machine interfaces through Bayesian parameter updates. Neural Comput 23: 3162-3204. [pdf]

114. Lebedev MA, Tate AJ, Hanson TL, Li Z, O'Doherty JE, Winans JA, Ifft PJ, Zhuang KZ, Fitzsimmons NA, Schwarz DA, Fuller AM, An JH, Nicolelis MA (2011) Future developments in brain-machine interface research. Clinics (Sao Paulo), 66 Suppl 1: 25-32. [pdf]

115. Opris I, Lebedev MA, Nelson RJ (2011) Motor planning under unpredictable reward: modulations of movement vigor and primate striatum activity. Front Neurosci 5: 61. [pdf]

116. Thiagarajan TC, Lebedev MA, Nicolelis MA, Plenz D (2010) Coherence potentials: loss-less, all-or-none network events in the cortex. PLoS Biol 8: e1000278. [pdf]

117. O'Doherty JE, Lebedev MA, Hanson TL, Fitzsimmons NA, Nicolelis MA (2009) A brain-machine interface instructed by direct intracortical microstimulation. Front Integr Neurosci 3: 20.

118. Li Z, O'Doherty JE, Hanson TL, Lebedev MA, Henriquez CS, Nicolelis MAL (2009) Unscented Kalman filter for brain-machine Interfaces. PLoS ONE, 4: e6243.

119. Petermann T, Thiagarajan TC, Lebedev MA, Nicolelis MA, Chialvo RC, Plenz D (2009) Spontaneous cortical activity in awake monkeys composed of neuronal avalanches. Proc Natl Acad Sci USA 106: 15921-15926.

120. Nicolelis MAL, Lebedev MA (2009) Principles of neural ensemble physiology underlying the operation of brain-machine interfaces. Nature Rev Neurosci 10: 530-540.

121. Linderman M, Lebedev MA, Erlichman JS (2009) Recognition of handwriting from electromyography. PLoS ONE 4: e6791.

122. Messinger A, Lebedev MA, Kralik JD, Wise SP (2009) Multitasking of attention and memory functions in the primate prefrontal cortex. J Neurosci 29: 5640-5653.

123. Fitzsimmons NA, Lebedev MA, Peikon ID, Nicolelis MAL (2009) Extracting kinematic parameters for monkey bipedal walking from cortical neuronal ensemble activity. Front Integr Neurosci 3 (Article 3): 1-19.

124. Peikon ID, Fitzsimmons NA, Lebedev MA, Nicolelis MAL (2009) Three-dimensional, automated, real-time video system for tracking limb motion in brain-machine interface studies. J Neurosci Meth 180: 224-33.

125. Zacksenhouse M, Nemets S, Lebedev MA, Nicolelis MAL (2009) Robust satisficing linear regression: robustness/performance trade-off and consistency criterion. Mech Syst Signal Process 23: 1954-1964.

126. Lebedev MA, O'Doherty JE, Nicolelis MAL (2008) Decoding of temporal intervals from cortical ensemble activity. J Neurophys 99: 166-186.

127. Zacksenhouse M, Lebedev MA, Carmena JM, O'Doherty JE, Henriquez CS, Nicolelis MAL (2007) Cortical modulations increase in early sessions with brain-machine interface. PlosOne 2: e619. doi:10.1371/journal.pone.0000619

128. Fitzsimmons NA, Drake W, Hanson TL, Lebedev MA, Nicolelis MAL (2007) Primate reaching cued by multichannel spatiotemporal cortical microstimulation. J Neurosci 27: 5593-5602.

129. Lebedev MA, Nicolelis MAL (2006) Brain-machine interfaces: past, present and future. Trends in Neurosci 29: 493-546.

130. Kim SP, Sanchez JC, Rao YN, Erdogmus D, Carmena JM, Lebedev MA, Nicolelis MAL, Principe JC (2006) A comparison of optimal MIMO linear and nonlinear models for brain-machine interfaces. J Neural Eng 3: 145-161.

131. Kim HK, Biggs SJ, Schloerb DW, Carmena JM, Lebedev MA, Nicolelis MAL, Srinivasan MA (2006). Continuous shared control stabilizes reach and grasping with brain-machine interfaces.IEEE Trans on Biomed Eng 53(6): 1164-1173.

132. Lebedev MA, Carmena JM, O'Doherty JE, Zacksenhouse M, Henriquez CS, Principe JC, Nicolelis MAL (2005) Cortical ensemble adaptation to represent actuators controlled by a brain machine interface. J Neurosci 25: 4681-4693.

133. Santucci DM, Kralik JD, Lebedev MA, Nicolelis MAL (2005) Frontal and parietal cortical ensembles predict single-trial muscle activity during reaching movements. Eur J Neurosci 22: 1529-1540.

134. Carmena JM, Lebedev MA, Henriquez CS, Nicolelis MAL (2005) Stable ensemble performance with single neuron variability during reaching movements in primates. J Neurosci 25: 10712-10716.

135. Lebedev MA, Messinger A, Kralik JD, Wise SP (2004) Representation of attended versus remembered locations in prefrontal cortex. PLoS Biology 2: 1919-1935.

136. Sanchez JC, Carmena JM, Lebedev MA, Nicolelis MA, Harris JG, Principe JC (2004) Ascertaining the importance of neurons to develop better brain machine interfaces. IEEE Trans Biomed Eng 51: 943-953.

137. Carmena JM, Lebedev MA, Crist RE, O'Doherty JE, Santucci DM, Dimitrov DF, Patil PG, Henriquez CS, Nicolelis MAL (2003) Learning to control a brain-machine interface for reaching and grasping by primates. PLoS Biology 1: 193-208.

138. Lebedev MA, Wise SP (2002) Insights into seeing and grasping: distinguishing the neural correlates of perception and action. Behavioral and Cognitive Neuroscience Reviews 1: 108-129.

139. Erchova I, Lebedev MA, Diamond ME (2002) Somatosensory cortical neuronal population activity across states of anesthesia. Eur J Neurosci 15: 744-752.

140. Lebedev MA, Wise SP (2001) Tuning for the orientation of spatial attention in dorsal premotor cortex. Eur J Neurosci 13: 1002-1008.

141. Lebedev, M.A., Douglass, D.K., Moody, S.L., Wise, S.P. (2001) Prefrontal cortex neurons reflecting reports of a visual illusion. J. Neurophysiol., 85: 1395-1411.

142. Panzeri S, Petersen RS, Schultz SR, Lebedev MA, Diamond ME (2001) The role of spike timing in the coding of stimulus location in rat somatosensory cortex. Neuron 29: 769-777.

143. Panzeri S, Peterrsen RS, Schultz SR, Lebedev MA, Diamond ME (2001) Coding of stimulus location by spike timing in rat somatosensory cortex. Neurocomputing, 44: 573-578.

144. Mitz AR, Boring SA, Wise SP, Lebedev MA (2001) A novel food-delivery device for neurophysiological and neuropsychological studies in monkeys. J Neurosci Methods 109: 129-135.

145. Lebedev MA, Mirabella G, Erchova I, Diamond ME (2000) Experience-dependent plasticity of rat barrel cortex: redistribution of activity across barrel-columns. Cerebral Cortex 10: 23-31.

146. Lebedev MA, Wise SP (2000) Oscillations in the premotor cortex: single-unit activity from awake, behaving monkeys. Exp Brain Res 130: 195-215.

147. Lebedev MA, Nelson RJ (1999) Rhythmically firing neostriatal neurons in monkeys: activity patterns during reaction-time hand movements. J Neurophysiol 82: 1832-1842.

148. Lebedev MA, Nelson RJ. (1996) High-frequency vibratory sensitive neurons in monkey primary somatosensory cortex: entrained and non-entrained responses to vibration during the performance of vibratory-cued hand movements. Exp Brain Res 111: 313-325.

149. Lebedev MA, Nelson RJ (1995) Rhythmically firing (20-50 Hz) neurons in monkey primary somatosensory cortex: activity patterns during initiation of vibratory-cued hand movements. J Comput Neurosci 2: 313-334.

150. Lebedev MA, Denton JM, Nelson RJ (1994) Vibration-entrained and premovement activity in monkey primary somatosensory cortex. J Neurophysiol 72: 1654-1673.

151. Lebedev MA (1993) Further observations on ischemic suppression of motor units in human soleus muscle. A single case study. J Electromyography and Kinesiology 3: 183-186.

152. Gurfinkel VS, Lebedev MA, Levik YS (1992) Effects of reversal in the human equilibrium regulation system. Neirofiziologiya (Kiev) 24: 462-470. Translation into English: Neurophysiology 24: 297-304.

153. Gurfinkel VS, Lebedev MA, Levik YS (1992) The sensory effects caused by neck afferentation. Sensory Systems 6: 83-87.

154. Lebedev MA, Polyakov AV (1992) Analysis of surface EMG of human soleus muscle subjected to vibration. J Electromyography and Kinesiology 2: 26-35.

155. Lebedev MA (1991) Impairment of human soleus motor units during ischemia. J Electromyography and Kinesiology 1: 244-249.

156. Lebedev MA, Polyakov AV (1991) Analysis of the interference electromyogram of the human soleus muscle under vibrational stimulation. Neirofiziologiya (Kiev) 23: 57-65. Translation into English: Neurophysiology 23: 47-54.

157. Gurfinkel VS, Levik YS, Lebedev MA (1989) Immediate and remote postactivation effects in the human motor system. Neirofiziologiya (Kiev) 21: 343-351. Translation into English: Neurophysiology 21: 247-253.

158. Gurfinkel VS, Levik YS, Lebedev MA (1989) The postural automatism revealed by enhancement of the tonic background. Doklady Akademii Nauk SSSR 305:1266-1269.

Chapters

1. Lebedev MA, Ossadtchi AE, Okorokova E, Erlichman JS, Rupasov VI., & Linderman, M. (2020). Generating handwriting from multichannel electromyographic activity. In: Brain–Computer Interface Research (pp. 11-23). Springer, Cham.

2. Lebedev MA, Ossadtchi A (2018) Bidirectional neural interfaces. In: Brain–Computer Interfaces Handbook: Technological and Theoretical Advances

3. Ordikhani-Seyedlar M, Lebedev MA (2018) Augmenting attention with brain-computer interfaces. In: Brain–Computer Interfaces Handbook: Technological and Theoretical Advances

4. Ordikhani-Seyedlar M, Lebedev MA (2018) Controlling attention with neurofeedback. In: The Physics of the Mind and Brain Disorders: Integrated Neural Circuits Supporting the Emergence of Mind

5. Opris I, Casanova MF, Lebedev MA, Popescu AI (2017) Prefrontal cortical microcircuits support the emergence of mind. In: The Physics of the Mind and Brain Disorders: Integrated Neural Circuits Supporting the Emergence of Mind

6. Guger C, Allison B, Lebedev M (2017) Introduction. In: Brain-Computer Interface Research: A State-of-the-Art Summary 6 (SpringerBriefs in Electrical and Computer Engineering), Springer: 1-8.

7. Guger C, Allison B, Lebedev M (2017) Recent advances in brain-computer interface research — a summary of the BCI Award 2016 and BCI research trends. In: Brain-Computer Interface Research: A State-of-the-Art Summary 6 (SpringerBriefs in Electrical and Computer Engineering), Springer: 127-134.

8. Lebedev M, Opris I (2015). Brain-Machine Interfaces: From Macro-to Microcircuits. In: Recent Advances on the Modular Organization of the Cortex, Springer: 407-428.

9. Lebedev MA (2015) Brain-machine interface In: Ishibuchi H (Ed) Computational Intelligence Volume 1: 308-344

10. Lebedev MA, Crist RE, Nicolelis MAL (2007) Building brain-machine interfaces to restore neurological functions - chapter 11. In: Nicolelis M.A.L. (Ed.) Methods for Neural Ensemble Recordings, CRC Press.

11. Crist RE, Lebedev MA (2007) Multielectrode recordings in behaving monkeys - chapter 9. In: Nicolelis MAL (Ed) Methods for Neural Ensemble Recordings, CRC Press.

12. Nelson RJ, Lebedev MA (2001) Deciphering the code - dynamic modulation of neural activity during tactile behavior - chapter 10. In: Nelson RJ (Ed) Somatosensory System: Deciphering the Brain's Own Body Image, CRC Press.

13. Mirabella G, Lebedev MA, Diamond ME (1999) Integration and storage of sensory events in adult rat barrel cortex. In: M Kossut (Ed) Plasticity of Adult Rat Barrel Cortex, FP Graham, Johnson City, TN: 97-126.

14. Gurfinkel VS, Lebedev MA, Levick YS (1992) What about the so-called neck reflexes in humans? In: A Bertoz, W Graf, PP Vidal (Eds) The Head-Neck Sensory Motor System, New York, Oxford, Oxford University Press: 543-547.

15. Gurfinkel VS, Levick YS, Lebedev MA (1991) Body scheme concept and motor control. Body scheme in the postural automatisms regulation. In: Intellectual Processes and Their Modelling, Moscow, Nauka: 24-53.

16. Lebedev MA, Polyakov AV (1990) The analysis of surface EMG of human soleus muscle during vibration. In: Systems of Information Transmission and Processing. Institute for the Problems of Information Transmission, USSR Acad. Sci, Moscow: 34-38.

17. Lebedev MA, Polyakov AV (1989) Switched vibratory activation of muscle. 1. Spectral analysis of surface EMG. In: Systems of Information Transmission and Processing. Institute for the Problems of Information Transmission USSR Acad Sci Moscow: 54-58.

18. Polyakov AV, Lebedev MA (1989) Switched vibratory activation of muscle. 2. Motor unit firing. In: Systems of Information Transmission and Processing. Institute for the Problems of Information Transmission, USSR Acad Sci Moscow: 59-61.

19. Lebedev MA (1988) Domination of peripheral visual field in human vertical posture control. In: Systems of Information Transmission and Processing. Part 1. Institute for the Problems of Information Transmission, USSR Acad Sci Moscow: 61-63.

20. Lebedev MA (1988) Research methods of basic postural control mechanisms. In: Systems of Information Transmission and Processing. Part 2. Institute for the Problems of Information Transmission, USSR Acad Sci Moscow: 64-67.

Conference Abstracts

1. Zhuang, K. Z., Lebedev, M. A. & Nicolelis, M. A. L. Decoding rhythmic versus discrete movements from cortical ensembles. Society for Neuroscience Abstract Viewer and Itinerary Planner 43 (2013).

2. Subramanian, V. A. et al. Sparse subspace clustering for automated spike sorting. Society for Neuroscience Abstract Viewer and Itinerary Planner 43 (2013).

3. Schwarz, D. et al. Multichannel wireless recordings of freely moving rhesus monkey behaviors. Society for Neuroscience Abstract Viewer and Itinerary Planner 43 (2013).

4. Sankaranarayani, R. et al. Navigation through space enabled by a brain-machine interface. Society for Neuroscience Abstract Viewer and Itinerary Planner 43 (2013).

5. Ramakrishnan, A. et al. Brain-machine interface featuring cooperation and social interaction. Society for Neuroscience Abstract Viewer and Itinerary Planner 43 (2013).

6. Pais-Vieira, M., Oliveira, L. M., Lebedev, M., Kunicki, C. & Nicolelis, M. A. L. Development of a brain-to-brain interface for real-time sharing of sensorimotor information. Society for Neuroscience Abstract Viewer and Itinerary Planner 43 (2013).

7. Pais-Vieira, M., Lebedev, M. & Nicolelis, M. Top-down modulation of the thalamocortical loop during active tactile discrimination. Society for Neuroscience Abstract Viewer and Itinerary Planner 43 (2013).

8. Ifft, P., Lebedev, M. A. & Nicolelis, M. A. L. Correlation dynamics of large-scale cortical ensemble activity during upper-limb reaching tasks. Society for Neuroscience Abstract Viewer and Itinerary Planner 43 (2013).

9. Shokur, S. et al. Beyond the homunculus: Visual responses of primary somatosensory cortex (S1) neurons to virtual touch of a virtual arm. Society for Neuroscience Abstract Viewer and Itinerary Planner 42 (2012).

10. Medina, L. E., Lebedev, M. A., O'Doherty, J. E. & Nicolelis, M. A. L. Noise-enhanced intracortical microstimulation for virtual touch. Society for Neuroscience Abstract Viewer and Itinerary Planner 42 (2012).

11. Ifft, P., Lebedev, M. A., Li, Z. & Nicolelis, M. A. L. Bimanual brain-machine interface. Society for Neuroscience Abstract Viewer and Itinerary Planner 42 (2012).

12. Zhuang, K. Z., O'Doherty, J. E., Lebedev, M. A. & Nicolelis, M. A. L. Joint cross-correlation analysis reveals dynamic relationship between cortical and EMG activity. Society for Neuroscience Abstract Viewer and Itinerary Planner 41 (2011).

13. Raghavan, R. T., Lebedev, M. A., O'Doherty, J. E. & Nicolelis, M. A. L. Emergent preparatory neural activity underlying learning in premotor and primary motor cortex. Society for Neuroscience Abstract Viewer and Itinerary Planner 41 (2011).

14. O'Doherty, J. E., Li, Z., Lebedev, M. A. & Nicolelis, M. A. L. Towards a brain-machine-brain interface with virtual active touch using randomly patterned intracortical microstimulation. Society for Neuroscience Abstract Viewer and Itinerary Planner 41 (2011).

15. Li, Z., Tate, A. J., Lebedev, M. A. & Nicolelis, M. A. L. Software-based scalable multichannel spike acquisition. Society for Neuroscience Abstract Viewer and Itinerary Planner 41 (2011).

16. Ifft, P., Lebedev, M. A. & Nicolelis, M. A. L. Neural correlates of Fitts' law. Society for Neuroscience Abstract Viewer and Itinerary Planner 41 (2011).

17. Hanson, T. L., Lebedev, M. & Nicolelis, M. A. L. Wireless multichannel system for recording neuronal ensemble activity from the primate brain. Society for Neuroscience Abstract Viewer and Itinerary Planner 41 (2011).

18. Fuller, A. M., Hanson, T. L., Lebedev, M. A. & Nicolelis, M. A. L. Multichannel multiplexing of stimulation and recording in brain-machine-brain interfaces. Society for Neuroscience Abstract Viewer and Itinerary Planner 41 (2011).

19. An, J. H., O'Doherty, J. E., Lebedev, M. A. & Nicolelis, M. A. L. Active exploration of invisible targets assisted by an artificial touch sensation based on intracortical microstimulation. Society for Neuroscience Abstract Viewer and Itinerary Planner 41 (2011).

20. Zhuang, K. Z., O'Doherty, J. E., Lebedev, M. A. & Nicolelis, M. A. L. Extraction of EMGs from cortical ensemble activity during a motor timing task. Society for Neuroscience Abstract Viewer and Itinerary Planner 40 (2010).

21. Winans, J. A., Tate, A. J., Lebedev, M. A. & Nicolelis, M. A. L. Extraction of leg kinematics from the sensorimotor cortex representation of the whole body. Society for Neuroscience Abstract Viewer and Itinerary Planner 40 (2010).

22. Shokur, S., O'Doherty, J. E., Lebedev, M. A., Bleuler, H. & Nicolelis, M. A. L. Integration of a virtual reality based arm in primary somatosensory cortex. Society for Neuroscience Abstract Viewer and Itinerary Planner 40 (2010).

23. O'Doherty, J. E., Ifft, P. J., Zhuang, K. Z., Lebedev, M. A. & Nicolelis, M. A. L. Brain-machine-brain interface using simultaneous recording and intracortical microstimulation feedback. Society for Neuroscience Abstract Viewer and Itinerary Planner 40 (2010).

24. Muldrew, D., Lebedev, M. A., Kralik, J. D. & Messinger, A. Columnar organization of spatial attention and spatial working memory in the frontal cortex of primates. Society for Neuroscience Abstract Viewer and Itinerary Planner 40 (2010).

25. Li, Z., O'Doherty, J. E., Lebedev, M. A. & Nicolelis, M. A. L. Closed-loop adaptive decoding using bayesian regression self-training. Society for Neuroscience Abstract Viewer and Itinerary Planner 40 (2010).

    1. Han, Z., Li, Z., O'Doherty, J., Lebedev, M. & Nicolelis, M. Decoding self-timed motor behavior with hidden Markov models. Society for Neuroscience Abstract Viewer and Itinerary Planner 40 (2010).

26. Tate, A. J., Lebedev, M. A. & Nicolelis, M. A. L. Neural activity associated with changes in posture in rhesus macaques. Society for Neuroscience Abstract Viewer and Itinerary Planner 39 (2009).

27. Li, Z., O'Doherty, J. E., Lebedev, M. A. & Nicolelis, M. A. L. Simultaneous BMI decoding and tuning model update using Bayesian regression. Society for Neuroscience Abstract Viewer and Itinerary Planner 39 (2009).

28. Fitzsimmons, N. A., An, J., Lebedev, M. & Nicolelis, M. A. L. Towards a bi-directional brain-machine interface: Simultaneous microstimulation and recording in owl monkeys. Society for Neuroscience Abstract Viewer and Itinerary Planner 39 (2009).

29. Thiagarajan, T., Lebedev, M., Nicolelis, M. & Plenz, D. Coherence Potentials: a network level action potential-like phenomenon in the cortex. Society for Neuroscience Abstract Viewer and Itinerary Planner 38 (2008).

30. Peikon, I. D., Fitzsimmons, N. A., Lebedev, M. A. & Nicolelis, M. A. L. Unconstrained video-tracking for brain-machine interfaces. Society for Neuroscience Abstract Viewer and Itinerary Planner 38 (2008).

31. O'Doherty, J. E., Lebedev, M. A. & Nicolelis, M. A. L. Closed-loop brain-controlled reaching guided by cortical microstimulation. Society for Neuroscience Abstract Viewer and Itinerary Planner 38 (2008).

32. Li, Z. et al. Unscented Kalman filter for brain-machine interfaces. Society for Neuroscience Abstract Viewer and Itinerary Planner 38 (2008).

33. Hodak, M. J., O'Doherty, J. E., Lebedev, M. A. & Nicolelis, M. A. L. Transformational mapping in an online brain-machine interface for reaching. Society for Neuroscience Abstract Viewer and Itinerary Planner 38 (2008).

34. Hanson, T., Clayton, D. A., Lebedev, M., Nicolelis, M. & Turner, D. A. Multineuron recordings in human subcortical regions in relationship to hand motor task: tuning and motor responses. Society for Neuroscience Abstract Viewer and Itinerary Planner 38 (2008).

35. Grant, B. D. et al. Multipurpose, expandable suite for brain-machine interfaces. Society for Neuroscience Abstract Viewer and Itinerary Planner 38 (2008).

36. Fitzsimmons, N. A., Lebedev, M. A., Peikon, I. D. & Nicolelis, M. A. L. Cortical neuronal ensembles accurately predict leg kinematic parameters and EMG patterns during bipedal locomotion in monkeys. Society for Neuroscience Abstract Viewer and Itinerary Planner 38 (2008).

37. Yun, K., Lebedev, M. & Nicolelis, M. A. L. in World Congress on Medical Physics and Biomedical Engineering 2006, Vol 14, Pts 1-6 Vol. 14 IFMBE Proceedings (eds S. I. Kim & T. S. Suh) 1005-1008 (2007).

38. Rao, Y. N. et al. in 2005 Ieee International Conference on Acoustics, Speech, and Signal Processing, Vols 1-5: Speech Processing International Conference on Acoustics Speech and Signal Processing ICASSP 233-236 (2005).

39. Santucci, D. M., Kralik, J. D., Carmena, J. M., Lebedev, M. A. & Nicolelis, M. A. L. EMG prediction from multisite, multielectrode recordings in new world monkeys and Rhesus macaques. Society for Neuroscience Abstract Viewer and Itinerary Planner 2003, Abstract No. 279.223-Abstract No. 279.223 (2003).

40. Messinger, A., Lebedev, M. A., Kralik, J. D. & Wise, S. P. Representation of context in primate prefrontal cortex during visually guided saccadic eye movements. Society for Neuroscience Abstract Viewer and Itinerary Planner 2003, Abstract No. 722.714-Abstract No. 722.714 (2003).

41. Lebedev, M. A., Carmena, J. M. & Nicolelis, M. A. Directional tuning of frontal and parietal neurons during operation of brain - machine interface. Society for Neuroscience Abstract Viewer and Itinerary Planner 2003, Abstract No. 279.222-Abstract No. 279.222 (2003).

42. Carmena, J. M., Lebedev, M. A., O'Doherty, J. E., Henriquez, C. S. & Nicolelis, M. A. L. Fronto - parietal reorganization underlies incorporation of robot dynamics by the primate cortex during operation of a reaching and grasping brain - machine interface. Society for Neuroscience Abstract Viewer and Itinerary Planner 2003, Abstract No. 279.221-Abstract No. 279.221 (2003).

43. Lebedev, M. A. & Wise, S. P. Relative-location tuning in five areas of frontal cortex. Society for Neuroscience Abstracts 27, 336-336 (2001).

44. Petersen, R. S., Panzeri, S., Schultz, S. R., Lebedev, M. & Diamond, M. E. Coding of stimulus location by spike timing in the rat barrel cortex. Society for Neuroscience Abstracts 26, Abstract No.-157.120 (2000).

45. Lebedev, M. A. & Wise, S. P. Spatial tuning in premotor cortex. Society for Neuroscience Abstracts 26, Abstract No.-590.596 (2000).

46. Lebedev, M. A., Douglass, D. K., Moody, S. L. & Wise, S. P. Neuronal activity in prefrontal cortex reflects misreported displacements of visual stimuli. Society for Neuroscience Abstracts 25, 360-360 (1999).

47. Erchova, I. A., Lebedev, M. A. & Diamond, M. E. Somatosensory cortical neuronal population activity across states of anesthesia. Society for Neuroscience Abstracts 25, 2194-2194 (1999).

48. Mirabella, G., Lebedev, M., Erchova, I. & Diamond, M. E. Redistribution of activity across rat barrel cortex after altered tactile experience is coupled to modification of connections between cortical barrel columns. Pflugers Archiv-European Journal of Physiology 435, R35-R35 (1998).

49. Petersen, R., Treves, A., Lebedev, M. & Diamond, M. E. Information theoretic analysis of the responses of rat cortical neurons to vibrissal stimulation. Society for Neuroscience Abstracts 23, 2345-2345 (1997).

50. Nelson, R. J., Lebedev, M. A., Opris, I. & Denton, J. M. Neostriatal neuronal activity becomes better related to movements when conditions become unpredictable. Society for Neuroscience Abstracts 22, 1085-1085 (1996).

51. Lebedev, M., Mirabella, G. & Diamond, M. E. Functional connections between barrel-columns in rat cortex: Recordings of multiple single neurons. Society for Neuroscience Abstracts 22, 1358-1358 (1996).

52. Nelson, R. J. & Lebedev, M. A. The relationships of monkey neostriatal neuronal activity to task events change with the modality of sensory go-cues. Society for Neuroscience Abstracts 21, 412-412 (1995).

53. Nelson, R. J., Denton, J. M. & Lebedev, M. A. Activity of monkey sensorimotor cortical (SMC) and neostriatal (NS) neurons during hand movements made under unpredictable conditions. Society for Neuroscience Abstracts 20, 983-983 (1994).

54. Lebedev, M. A. & Nelson, R. J. Two types of vibratory responsive pacinian-like neurons in monkey primary somatosensory cortex (SI) studied during active hand movements. Society for Neuroscience Abstracts 20, 1388-1388 (1994).

55. Lebedev, M. A. & Nelson, R. J. Modulation of rhythmic firing of monkey primary somatosensory cortical (SI) and neostriatal (NS) neurons during active hand movements. Society for Neuroscience Abstracts 19, 781-781 (1993).

56. Lebedev, M. A. & Nelson, R. J. The activity of vibratory-response monkey primary somatosensory cortical neurons is modulated prior to hand movement. Society for Neuroscience Abstracts 18, 503-503 (1992).

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