Dysmetria and Errors in Predictions: The Role of Internal Forward Model.
cerebellar ataxias
cerebellum
dysmetria
internal forward model
prediction
Journal
International journal of molecular sciences
ISSN: 1422-0067
Titre abrégé: Int J Mol Sci
Pays: Switzerland
ID NLM: 101092791
Informations de publication
Date de publication:
20 Sep 2020
20 Sep 2020
Historique:
received:
28
08
2020
revised:
13
09
2020
accepted:
14
09
2020
entrez:
23
9
2020
pubmed:
24
9
2020
medline:
27
2
2021
Statut:
epublish
Résumé
The terminology of cerebellar dysmetria embraces a ubiquitous symptom in motor deficits, oculomotor symptoms, and cognitive/emotional symptoms occurring in cerebellar ataxias. Patients with episodic ataxia exhibit recurrent episodes of ataxia, including motor dysmetria. Despite the consensus that cerebellar dysmetria is a cardinal symptom, there is still no agreement on its pathophysiological mechanisms to date since its first clinical description by Babinski. We argue that impairment in the predictive computation for voluntary movements explains a range of characteristics accompanied by dysmetria. Within this framework, the cerebellum acquires and maintains an internal forward model, which predicts current and future states of the body by integrating an estimate of the previous state and a given efference copy of motor commands. Two of our recent studies experimentally support the internal-forward-model hypothesis of the cerebellar circuitry. First, the cerebellar outputs (firing rates of dentate nucleus cells) contain predictive information for the future cerebellar inputs (firing rates of mossy fibers). Second, a component of movement kinematics is predictive for target motions in control subjects. In cerebellar patients, the predictive component lags behind a target motion and is compensated with a feedback component. Furthermore, a clinical analysis has examined kinematic and electromyography (EMG) features using a task of elbow flexion goal-directed movements, which mimics the finger-to-nose test. Consistent with the hypothesis of the internal forward model, the predictive activations in the triceps muscles are impaired, and the impaired predictive activations result in hypermetria (overshoot). Dysmetria stems from deficits in the predictive computation of the internal forward model in the cerebellum. Errors in this fundamental mechanism result in undershoot (hypometria) and overshoot during voluntary motor actions. The predictive computation of the forward model affords error-based motor learning, coordination of multiple degrees of freedom, and adequate timing of muscle activities. Both the timing and synergy theory fit with the internal forward model, microzones being the elemental computational unit, and the anatomical organization of converging inputs to the Purkinje neurons providing them the unique property of a perceptron in the brain. We propose that motor dysmetria observed in attacks of ataxia occurs as a result of impaired predictive computation of the internal forward model in the cerebellum.
Identifiants
pubmed: 32962256
pii: ijms21186900
doi: 10.3390/ijms21186900
pmc: PMC7555030
pii:
doi:
Types de publication
Journal Article
Review
Langues
eng
Sous-ensembles de citation
IM
Références
J Neurophysiol. 1991 Mar;65(3):563-71
pubmed: 2051195
Ann Neurol. 1994 Jan;35(1):45-52
pubmed: 8285591
J Neurophysiol. 2011 Nov;106(5):2232-47
pubmed: 21795616
J Physiol. 1982 Mar;324:113-34
pubmed: 7097592
J Neurosci. 1990 Jan;10(1):142-52
pubmed: 2299389
Neurosci Res. 2016 Mar;104:72-9
pubmed: 26704591
J Comp Neurol. 1999 Aug 16;411(1):97-118
pubmed: 10404110
J Neurophysiol. 2003 Feb;89(2):896-908
pubmed: 12574467
J Neurosci. 2012 Oct 31;32(44):15345-58
pubmed: 23115173
Ann Neurol. 2020 May 17;:
pubmed: 32418250
J Neurol Neurosurg Psychiatry. 1977 Jul;40(7):683-6
pubmed: 915512
Trends Neurosci. 1997 Mar;20(3):112-6
pubmed: 9061864
Trends Cogn Sci. 1998 Sep 1;2(9):338-47
pubmed: 21227230
Nat Neurosci. 2015 Dec;18(12):1798-803
pubmed: 26551541
J Neurosci. 2005 Apr 13;25(15):3919-31
pubmed: 15829644
J Neurophysiol. 2016 Jan 1;115(1):255-70
pubmed: 26467515
J Physiol. 1983 Jun;339:379-94
pubmed: 6887028
Neuron. 2004 Sep 2;43(5):745-57
pubmed: 15339654
Front Syst Neurosci. 2014 Jun 17;8:113
pubmed: 24987338
Nature. 2015 Oct 15;526(7573):439-42
pubmed: 26469054
Brain. 1998 Feb;121 ( Pt 2):357-72
pubmed: 9549511
Cerebellum. 2012 Jun;11(2):426-33
pubmed: 22396331
Eur J Neurosci. 2016 Apr;43(8):1075-81
pubmed: 26900871
Neurosci Lett. 2019 Jan 1;688:62-75
pubmed: 29997061
J Neurol Sci. 1998 Apr 15;157(1):42-51
pubmed: 9600676
Cerebellum. 2012 Jun;11(2):457-87
pubmed: 22161499
PLoS One. 2014 Oct 03;9(10):e108774
pubmed: 25279763
J Neurosci. 2006 Apr 5;26(14):3642-5
pubmed: 16597717
Proc Biol Sci. 2018 Aug 29;285(1885):
pubmed: 30158304
Elife. 2019 Oct 29;8:
pubmed: 31661073
Neural Netw. 1996 Nov;9(8):1265-1279
pubmed: 12662535
Cortex. 2010 Jul-Aug;46(7):845-57
pubmed: 19665115
Cerebellum. 2014 Feb;13(1):139-50
pubmed: 23964018
Exp Neurol. 1985 Dec;90(3):619-34
pubmed: 4065278
Brain. 1972;95(3):579-90
pubmed: 4655283
PLoS One. 2015 Jul 17;10(7):e0132983
pubmed: 26186225
Front Syst Neurosci. 2020 Apr 09;14:19
pubmed: 32327978
J Neurophysiol. 1992 Mar;67(3):547-60
pubmed: 1578244
Exp Brain Res. 1985;59(3):470-7
pubmed: 4029322
Physiol Rev. 1974 Oct;54(4):957-1006
pubmed: 4370744
Brain. 2006 Feb;129(Pt 2):290-2
pubmed: 16434422
J Neurosci. 2003 Sep 10;23(23):8432-44
pubmed: 12968006
J Physiol. 2010 May 15;588(Pt 10):1709-17
pubmed: 20351049
Science. 1995 Sep 29;269(5232):1880-2
pubmed: 7569931
Proc Biol Sci. 2010 Dec 7;277(1700):3563-8
pubmed: 20591871
Neuroimage. 2020 May 1;211:116624
pubmed: 32058002
J Neurol Neurosurg Psychiatry. 1975 Dec;38(12):1154-62
pubmed: 1219079
Nature. 1998 Apr 2;392(6675):494-7
pubmed: 9548253
Hum Neurobiol. 1987;6(1):27-37
pubmed: 3034839
J Neurophysiol. 1998 Jun;79(6):3272-8
pubmed: 9636126
J Physiol. 1979 Sep;294:33-50
pubmed: 512949
Neurosci Lett. 1996 Aug 30;215(1):60-4
pubmed: 8880754
J Neurophysiol. 2011 Nov;106(5):2322-45
pubmed: 21795627
J Physiol. 1980 Aug;305:171-95
pubmed: 7441552
Cerebellum. 2019 Jun;18(3):349-371
pubmed: 30627965
J Neurol Neurosurg Psychiatry. 1975 Dec;38(12):1163-9
pubmed: 1219080
Front Syst Neurosci. 2014 Jan 30;8:9
pubmed: 24523678
Handb Clin Neurol. 2018;154:59-70
pubmed: 29903452
Mov Disord. 1998;13 Suppl 3:43-8
pubmed: 9827594
Front Neural Circuits. 2013 Jan 10;6:116
pubmed: 23335884
Annu Rev Neurosci. 2010;33:89-108
pubmed: 20367317
Brain Res. 1984 Dec 10;323(2):330-4
pubmed: 6241010
Annu Rev Neurosci. 1989;12:157-83
pubmed: 2648948
Cerebellum. 2019 Apr;18(2):266-286
pubmed: 30259343
Ann Neurol. 1996 Feb;39(2):271-4
pubmed: 8967761
Trends Cogn Sci. 2013 May;17(5):241-54
pubmed: 23579055
Nat Neurosci. 2004 Sep;7(9):907-15
pubmed: 15332089
Cerebellum. 2018 Oct;17(5):654-682
pubmed: 29876802
Biol Cybern. 1987;57(3):169-85
pubmed: 3676355
Cerebellum. 2013 Jun;12(3):331-3
pubmed: 23361619
J Neurophysiol. 1986 Jul;56(1):123-36
pubmed: 3746391
J Neurophysiol. 1986 Jun;55(6):1221-33
pubmed: 3734856
Front Hum Neurosci. 2019 Jun 26;13:216
pubmed: 31297053
Nat Rev Neurosci. 2009 Sep;10(9):670-81
pubmed: 19693030
J Neuroeng Rehabil. 2009 Apr 13;6:10
pubmed: 19364396
Cerebellum. 2016 Apr;15(2):213-32
pubmed: 25823827
Annu Rev Neurosci. 2009;32:413-34
pubmed: 19555291
J Neurophysiol. 2007 Jul;98(1):54-62
pubmed: 17507504
Neuroimage. 2018 May 15;172:437-449
pubmed: 29408539
Annu Rev Neurosci. 1992;15:403-42
pubmed: 1575449
Cerebellum. 2007;6(3):221-31
pubmed: 17786818
eNeuro. 2017 Apr 11;4(2):
pubmed: 28413823
Cerebellum. 2004;3(4):227-35
pubmed: 15686101
Cerebellum. 2011 Sep;10(3):334-50
pubmed: 20967577
Neuropsychologia. 2007 Mar 2;45(4):696-703
pubmed: 16979674
Brain Res. 1984 Jun 18;304(1):183-7
pubmed: 6744037