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{{Use dmy dates|date=December 2022}}
{{Short description|Direct communication pathway between an enhanced or wired brain and an external device}}
[[File:Photograph-by-mikeCaiChen.jpg|alt=Participant in a brain-computer interface is Getting connected to a computer|thumb|Participant in a brain-computer interface is getting connected to a computer ]]▼
[[File:BrainGate.jpg|thumb|Dummy unit illustrating the design of a [[BrainGate]] interface]]
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====Donoghue, Schwartz, and Andersen====
Other laboratories that have developed BCIs and algorithms that decode neuron signals include [[John Donoghue (neuroscientist)|John Donoghue]] at the [[Carney Institute for Brain Science]] at [[Brown University]], Andrew Schwartz at the [[University of Pittsburgh]], and [[Richard A. Andersen (neuroscientist)|Richard Andersen]] at [[Caltech]]. These researchers produced working BCIs using recorded signals from far fewer neurons than Nicolelis (15–30 neurons versus 50–200 neurons).
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====Communication====
In May 2021, a Stanford University team reported a successful proof-of-concept test that enabled a quadraplegic participant to produce English sentences at about 86 characters per minute and 18 words per minute. The participant imagined moving his hand to write letters, and the system performed handwriting recognition on electrical signals detected in the motor cortex, utilizing [[Hidden Markov models]] and [[recurrent neural networks]].<ref>{{cite journal | vauthors = Willett FR, Avansino DT, Hochberg LR, Henderson JM, Shenoy KV | title = High-performance brain-to-text communication via handwriting | journal = Nature | volume = 593 | issue = 7858 | pages = 249–254 | date = May 2021 | pmid = 33981047 | pmc = 8163299 | doi = 10.1038/s41586-021-03506-2 | bibcode = 2021Natur.593..249W }}</ref><ref>{{cite book | vauthors = Willett FR |title=Brain-Computer Interface Research: A State-of-the-Art Summary 10|chapter=A High-Performance Handwriting BCI|date=2021 |pages=105–109| veditors = Guger C, Allison BZ, Gunduz A |series=SpringerBriefs in Electrical and Computer Engineering|place=Cham|publisher=Springer International Publishing|language=en|doi=10.1007/978-3-030-79287-9_11|isbn=978-3-030-79287-9 |s2cid=239736609}}</ref>
▲[[File:Photograph-by-mikeCaiChen.jpg|alt=Participant in a brain-computer interface is Getting connected to a computer|thumb|Participant in a brain-computer interface is getting connected to a computer ]]
Since researchers from [[University of California, San Francisco|UCSF]] initiated a brain-computer interface (BCI) study, numerous reports have been made. In 2021, they reported that a paralyzed and with [[Dysarthria|anarthria]] man was able to communicate fifteen words per minute using an implanted device that examined nerve cells controlling the muscles of the vocal tract.<ref>{{Cite journal |last1=Moses |first1=David A. |last2=Metzger |first2=Sean L. |last3=Liu |first3=Jessie R. |last4=Anumanchipalli |first4=Gopala K. |last5=Makin |first5=Joseph G. |last6=Sun |first6=Pengfei F. |last7=Chartier |first7=Josh |last8=Dougherty |first8=Maximilian E. |last9=Liu |first9=Patricia M. |last10=Abrams |first10=Gary M. |last11=Tu-Chan |first11=Adelyn |last12=Ganguly |first12=Karunesh |last13=Chang |first13=Edward F. |date=2021-07-14 |title=Neuroprosthesis for Decoding Speech in a Paralyzed Person with Anarthria |journal=New England Journal of Medicine |volume=385 |issue=3 |pages=217–227 |doi=10.1056/NEJMoa2027540 |issn=0028-4793 |pmc=8972947 |pmid=34260835}}</ref><ref>{{Cite journal |last1=Maiseli |first1=Baraka |last2=Abdalla |first2=Abdi T. |last3=Massawe |first3=Libe V. |last4=Mbise |first4=Mercy |last5=Mkocha |first5=Khadija |last6=Nassor |first6=Nassor Ally |last7=Ismail |first7=Moses |last8=Michael |first8=James |last9=Kimambo |first9=Samwel |date=2023-08-04 |title=Brain–computer interface: trend, challenges, and threats |journal=Brain Informatics |volume=10 |issue=1 |pages=20 |doi=10.1186/s40708-023-00199-3 |doi-access=free |issn=2198-4026 |pmc=10403483 |pmid=37540385}}</ref> In addition in 2022 it was announced that their implant could also be used to spell out words and entire sentences without speaking aloud. The first bilingual speech neuroprosthesis was reported to have been developed by the same team at the University of San Francisco, in 2024.<ref>{{Cite journal |last=Matsiko |first=Amos |date=2024-08-21 |title=Bilingual speech neuroprosthesis |url=https://www.science.org/doi/10.1126/scirobotics.ads4122 |journal=Science Robotics |volume=9 |issue=93 |pages=eads4122 |doi=10.1126/scirobotics.ads4122|url-access=subscription }}</ref><ref>{{Cite journal |last1=Silva |first1=Alexander B. |last2=Liu |first2=Jessie R. |last3=Metzger |first3=Sean L. |last4=Bhaya-Grossman |first4=Ilina |last5=Dougherty |first5=Maximilian E. |last6=Seaton |first6=Margaret P. |last7=Littlejohn |first7=Kaylo T. |last8=Tu-Chan |first8=Adelyn |last9=Ganguly |first9=Karunesh |last10=Moses |first10=David A. |last11=Chang |first11=Edward F. |date=August 2024 |title=A bilingual speech neuroprosthesis driven by cortical articulatory representations shared between languages |journal=Nature Biomedical Engineering |language=en |volume=8 |issue=8 |pages=977–991 |doi=10.1038/s41551-024-01207-5 |pmid=38769157 |pmc=11554235 |issn=2157-846X}}</ref><ref>{{Cite web |date=2024-05-28 |title=Bilingual AI brain implant helps stroke survivor communicate in Spanish and English |url=https://www.nbcnews.com/news/latino/bilingual-ai-brain-implant-spanish-english-stroke-patient-rcna154295 |access-date=2025-06-23 |website=NBC News |language=en}}</ref>
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==== Electrocorticography ====
[[Electrocorticography]] (ECoG) measures brain electrical activity from beneath the skull in a way similar to non-invasive electroencephalography, using electrodes embedded in a thin plastic pad placed above the cortex, beneath the [[dura mater]].<ref>{{cite book | last1=Serruya | first1=Mijail | last2=Donoghue | first2=John | chapter = Chapter III: Design Principles of a Neuromotor Prosthetic Device | title = Neuroprosthetics: Theory and Practice | veditors = Horch KW, Dhillon GS | publisher = Imperial College Press | year=2004 |pages=1158–1196 | doi=10.1142/9789812561763_0040 | archive-url=https://web.archive.org/web/20050404155139/http://donoghue.neuro.brown.edu/pubs/2003-SerruyaDonoghue-Chap3-preprint.pdf | archive-date=4 April 2005 |chapter-url=
Signals can be either subdural or epidural, but are not taken from within the brain [[parenchyma]]. Patients are required to have invasive monitoring for localization and resection of an epileptogenic focus.{{Citation needed|date=May 2024}}
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{{Footer Neuropsychology}}
{{emerging technologies|topics=yes|neuro=yes|infocom=yes}}
{{Authority control}}{{DEFAULTSORT:Brain-computer interface}}
[[Category:Brain–computer interface| ]]
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[[Category:Neural engineering|*]]
[[Category:User interface techniques]]
[[Category:Computing input devices]]
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