The control and training of single motor units in isometric tasks are constrained by a common input signal.
common synaptic input
human
motor control
motor unit
neuroscience
real-time decomposition
Journal
eLife
ISSN: 2050-084X
Titre abrégé: Elife
Pays: England
ID NLM: 101579614
Informations de publication
Date de publication:
07 06 2022
07 06 2022
Historique:
received:
10
08
2021
accepted:
06
06
2022
pubmed:
8
6
2022
medline:
23
6
2022
entrez:
7
6
2022
Statut:
epublish
Résumé
Recent developments in neural interfaces enable the real-time and non-invasive tracking of motor neuron spiking activity. Such novel interfaces could provide a promising basis for human motor augmentation by extracting potentially high-dimensional control signals directly from the human nervous system. However, it is unclear how flexibly humans can control the activity of individual motor neurons to effectively increase the number of degrees of freedom available to coordinate multiple effectors simultaneously. Here, we provided human subjects (N = 7) with real-time feedback on the discharge patterns of pairs of motor units (MUs) innervating a single muscle (tibialis anterior) and encouraged them to independently control the MUs by tracking targets in a 2D space. Subjects learned control strategies to achieve the target-tracking task for various combinations of MUs. These strategies rarely corresponded to a volitional control of independent input signals to individual MUs during the onset of neural activity. Conversely, MU activation was consistent with a common input to the MU pair, while individual activation of the MUs in the pair was predominantly achieved by alterations in de-recruitment order that could be explained by history-dependent changes in motor neuron excitability. These results suggest that flexible MU recruitment based on independent synaptic inputs to single MUs is unlikely, although de-recruitment might reflect varying inputs or modulations in the neuron's intrinsic excitability.
Identifiants
pubmed: 35670561
doi: 10.7554/eLife.72871
pii: 72871
pmc: PMC9208758
doi:
pii:
Types de publication
Journal Article
Research Support, Non-U.S. Gov't
Langues
eng
Sous-ensembles de citation
IM
Informations de copyright
© 2022, Bräcklein et al.
Déclaration de conflit d'intérêts
MB, DB, JI, JE, EB, CM, DF No competing interests declared
Références
Exp Brain Res. 2009 Aug;197(2):125-33
pubmed: 19565231
Exp Brain Res. 1994;100(3):503-8
pubmed: 7813686
Prog Neurobiol. 1992;38(4):335-78
pubmed: 1315446
J Physiol. 2009 Oct 1;587(Pt 19):4737-48
pubmed: 19703968
Front Neural Circuits. 2014 Jul 29;8:81
pubmed: 25120435
Int J Sports Med. 2002 May;23(4):285-9
pubmed: 12015630
J Neurosci. 2021 Jun 2;41(22):4867-4879
pubmed: 33893222
J Neurophysiol. 1965 May;28(3):599-620
pubmed: 5835487
Nat Commun. 2022 Mar 15;13(1):1345
pubmed: 35292665
J Neurophysiol. 2012 Feb;107(3):808-23
pubmed: 22031773
J Neurophysiol. 1987 Sep;58(3):525-42
pubmed: 3655881
BMC Med Res Methodol. 2012 Jun 19;12:81
pubmed: 22712852
J Neurophysiol. 1993 Dec;70(6):2470-88
pubmed: 8120594
Neuroscientist. 2008 Jun;14(3):264-75
pubmed: 18381974
Clin Neurophysiol. 2009 Dec;120(12):2040-2054
pubmed: 19783207
J Neurophysiol. 1987 Jan;57(1):311-24
pubmed: 3559678
J Neurosci. 2015 Sep 02;35(35):12207-16
pubmed: 26338331
Exp Neurol. 1984 Sep;85(3):631-50
pubmed: 6468581
J Neurophysiol. 1988 Nov;60(5):1523-48
pubmed: 3199172
Nat Rev Neurosci. 2005 May;6(5):389-97
pubmed: 15861181
J Neurophysiol. 2003 Nov;90(5):2919-27
pubmed: 14615422
Front Hum Neurosci. 2018 Jun 11;12:207
pubmed: 29942254
Exp Brain Res. 1995;104(1):99-106
pubmed: 7621944
J Neurophysiol. 1977 Nov;40(6):1432-43
pubmed: 925737
J Physiol. 1989 Feb;409:451-71
pubmed: 2585297
Nature. 1977 Jun 23;267(5613):717-9
pubmed: 876393
J Neurosci Methods. 2005 Dec 15;149(2):121-33
pubmed: 16026846
Exp Neurol. 1978 May 1;59(3):384-97
pubmed: 648610
J Neurophysiol. 2015 Mar 1;113(5):1310-22
pubmed: 25475356
J Physiol. 2014 Aug 15;592(16):3427-41
pubmed: 24860172
J Neurophysiol. 1986 May;55(5):1017-29
pubmed: 3711964
J Physiol. 2016 Oct 1;594(19):5491-505
pubmed: 27151459
Prog Brain Res. 2004;143:77-95
pubmed: 14653153
J Electromyogr Kinesiol. 2020 Aug;53:102426
pubmed: 32438235
J Neurophysiol. 2006 Oct;96(4):2144-50
pubmed: 16807351
Nat Neurosci. 2007 Mar;10(3):363-9
pubmed: 17293858
J Neurophysiol. 2002 Apr;87(4):1859-66
pubmed: 11929907
Muscle Nerve. 2005 Feb;31(2):135-56
pubmed: 15736297
Physiology (Bethesda). 2020 Jan 1;35(1):31-39
pubmed: 31799904
J Physiol. 2008 Mar 1;586(5):1225-31
pubmed: 17947305
J Physiol. 1977 Jan;264(3):673-93
pubmed: 845820
J Neural Eng. 2021 Feb 11;18(1):
pubmed: 33237879
J Neurophysiol. 1974 Nov;37(6):1338-49
pubmed: 4436704
J Neurophysiol. 1988 Dec;60(6):1946-66
pubmed: 3236057
J Neurosci. 2021 Aug 11;41(32):6878-6891
pubmed: 34210782
Science. 1957 Dec 27;126(3287):1345-7
pubmed: 13495469
Compr Physiol. 2012 Oct;2(4):2629-82
pubmed: 23720261
J Neurosci. 2013 Feb 6;33(6):2365-75
pubmed: 23392666
J Neural Eng. 2016 Apr;13(2):026027
pubmed: 26924829
Science. 1981 Nov 20;214(4523):933-6
pubmed: 7302570
J Neurosci. 2022 Apr 27;42(17):3611-3621
pubmed: 35351832
Science. 1963 Aug 2;141(3579):440-1
pubmed: 13969854
IEEE Trans Biomed Eng. 2021 Mar;68(3):926-935
pubmed: 32746024
J Neural Eng. 2021 Nov 23;18(6):
pubmed: 34727532