The Brain's Silent Messenger: Using Selective Attention to Decode Human Thought for Brain-based Communication

Overview

Journal J Neurosci

Specialty Neurology

Date 2013 May 31

PMID 23719806

Citations 20

Authors

Lorina Naci

Rhodri Cusack

Vivian Z Jia

Adrian M Owen

Affiliations

Soon will be listed here.

Abstract

The interpretation of human thought from brain activity, without recourse to speech or action, is one of the most provoking and challenging frontiers of modern neuroscience. In particular, patients who are fully conscious and awake, yet, due to brain damage, are unable to show any behavioral responsivity, expose the limits of the neuromuscular system and the necessity for alternate forms of communication. Although it is well established that selective attention can significantly enhance the neural representation of attended sounds, it remains, thus far, untested as a response modality for brain-based communication. We asked whether its effect could be reliably used to decode answers to binary (yes/no) questions. Fifteen healthy volunteers answered questions (e.g., "Do you have brothers or sisters?") in the fMRI scanner, by selectively attending to the appropriate word ("yes" or "no"). Ninety percent of the answers were decoded correctly based on activity changes within the attention network. The majority of volunteers conveyed their answers with less than 3 min of scanning, suggesting that this technique is suited for communication in a reasonable amount of time. Formal comparison with the current best-established fMRI technique for binary communication revealed improved individual success rates and scanning times required to detect responses. This novel fMRI technique is intuitive, easy to use in untrained participants, and reliably robust within brief scanning times. Possible applications include communication with behaviorally nonresponsive patients.

Citing Articles

Responsiveness variability during anaesthesia relates to inherent differences in brain structure and function of the frontoparietal networks.

Deng F, Taylor N, Owen A, Cusack R, Naci L Hum Brain Mapp. 2023; 44(6):2142-2157.

PMID: 36617994 PMC: 10028637. DOI: 10.1002/hbm.26199.

Topographic Somatosensory Imagery for Real-Time fMRI Brain-Computer Interfacing.

Kaas A, Goebel R, Valente G, Sorger B Front Hum Neurosci. 2020; 13:427.

PMID: 31920588 PMC: 6915074. DOI: 10.3389/fnhum.2019.00427.

Consilience, clinical validation, and global disorders of consciousness.

Peterson A Neurosci Conscious. 2018; 2016(1):niw011.

PMID: 30356913 PMC: 6192376. DOI: 10.1093/nc/niw011.

Functional diversity of brain networks supports consciousness and verbal intelligence.

Naci L, Haugg A, MacDonald A, Anello M, Houldin E, Naqshbandi S Sci Rep. 2018; 8(1):13259.

PMID: 30185912 PMC: 6125486. DOI: 10.1038/s41598-018-31525-z.

Do Patients Thought to Lack Consciousness Retain the Capacity for Internal as Well as External Awareness?.

Haugg A, Cusack R, Gonzalez-Lara L, Sorger B, Owen A, Naci L Front Neurol. 2018; 9:492.

PMID: 29997565 PMC: 6030833. DOI: 10.3389/fneur.2018.00492.

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