Neural mechanisms of response inhibition

Current Opinion in Behavioral Sciences

Volumn 1, Issue , 2015, Pages 64-71

  Stuphorn, Veit ^a  

^a JOHNS HOPKINS UNIVERSITY SCHOOL OF MEDICINE   (United States)

Author keywords

[No Author keywords available]

Indexed keywords

ACCURACY; BASAL GANGLION; FRONTAL CORTEX; MOTOR CONTROL; MOTOR CORTEX; NERVE CELL NETWORK; NERVE POTENTIAL; NEUROPHYSIOLOGY; NONHUMAN; OCULOMOTOR SYSTEM; PRIMATE; REVIEW; RODENT; SPINAL CORD;

EID: 84920083329     PISSN: None     EISSN: 23521546     Source Type: Journal    
DOI: 10.1016/j.cobeha.2014.10.009     Document Type: Review

References (58)

1. Logan G.D., Cowan W.B., Davis K.A. On the ability to inhibit simple and choice reaction time responses: a model and a method. J Exp Psychol Hum Percept Perform 1984, 10:276-291.
2. Boucher L., Palmeri T.J., Logan G.D., Schall J.D. Inhibitory control in mind and brain: an interactive race model of countermanding saccades. Psychol Rev 2007, 114:376-397.
3. Schall J.D., Stuphorn V., Brown J.W. Monitoring and control of action by the frontal lobes. Neuron 2002, 36:309-322.
4. Schall J.D., Godlove D.C. Current advances and pressing problems in studies of stopping. Curr Opin Neurobiol 2012, 22:1012-1021.
5. Aron A.R., Durston S., Eagle D.M., Logan G.D., Stinear C.M., Stuphorn V. Converging evidence for a fronto-basal-ganglia network for inhibitory control of action and cognition. J Neurosci 2007, 27:11860-11864.
6. Stuphorn V., Emeric E.E. Proactive and reactive control by the medial frontal cortex. Front Neuroeng 2012, 5:9.
7. Brown J.W., Hanes D.P., Schall J.D., Stuphorn V. Relation of frontal eye field activity to saccade initiation during a countermanding task. Exp Brain Res 2008, 190:135-151.
8. Hanes D.P., Patterson W.F., Schall J.D. Role of frontal eye fields in countermanding saccades: visual, movement, and fixation activity. J Neurophysiol 1998, 79:817-834.
9. Hanes D.P., Schall J.D. Neural control of voluntary movement initiation. Science 1996, 274:427-430.
10. Paré M., Hanes D.P. Controlled movement processing: superior colliculus activity associated with countermanded saccades. J Neurosci 2003, 23:6480-6489.
11. Sparks D.L. Functional properties of neurons in the monkey superior colliculus: coupling of neuronal activity and saccade onset. Brain Res 1978, 156:1-16.
12. Everling S., Pare M., Dorris M.C., Munoz D.P. Comparison of the discharge characteristics of brain stem omnipause neurons and superior colliculus fixation neurons in monkey: implications for control of fixation and saccade behavior. J Neurophysiol 1998, 79:511-528.
13. Izawa Y., Suzuki H., Shinoda Y. Response properties of fixation neurons and their location in the frontal eye field in the monkey. J Neurophysiol 2009, 102:2410-2422.
14. Moschovakis A.K., Scudder C.A., Highstein S.M. The microscopic anatomy and physiology of the mammalian saccadic system. Prog Neurobiol 1996, 50:133-254.
15. Cheney P.D., Fetz E.E. Functional classes of primate corticomotoneuronal cells and their relation to active force. J Neurophysiol 1980, 44:773-791.
16. Fetz E.E., Cheney P.D. Postspike facilitation of forelimb muscle activity by primate corticomotoneuronal cells. J Neurophysiol 1980, 44:751-772.
17. Sawaguchi T., Yamane I., Kubota K. Application of the GABA antagonist bicuculline to the premotor cortex reduces the ability to withhold reaching movements by well-trained monkeys in visually guided reaching task. J Neurophysiol 1996, 75:2150-2156.
18. Duque J., Labruna L., Verset S., Olivier E., Ivry R.B. Dissociating the role of prefrontal and premotor cortices in controlling inhibitory mechanisms during motor preparation. J Neurosci 2012, 32:806-816.
19. Duque J., Lew D., Mazzocchio R., Olivier E., Ivry R.B. Evidence for two concurrent inhibitory mechanisms during response preparation. J Neurosci 2010, 30:3793-3802.
20. Duque J., Ivry R.B. Role of corticospinal suppression during motor preparation. Cereb Cortex 2009, 19:2013-2024.
21. Coxon J.P., Stinear C.M., Byblow W.D. Intracortical inhibition during volitional inhibition of prepared action. J Neurophysiol 2006, 95:3371-3383.
22. Kaufman M.T., Churchland M.M., Santhanam G., Yu B.M., Afshar A., Ryu S.I., et al. Roles of monkey premotor neuron classes in movement preparation and execution. J Neurophysiol 2010, 104:799-810.
23. Kaufman M.T., Churchland M.M., Shenoy K.V. The roles of monkey M1 neuron classes in movement preparation and execution. J Neurophysiol 2013, 110:817-825.
24. Kaufman M.T., Churchland M.M., Ryu S.I., Shenoy K.V. Cortical activity in the null space: permitting preparation without movement. Nat Neurosci 2014, 17:440-448.
25. Mirabella G., Pani P., Ferraina S. Neural correlates of cognitive control of reaching movements in the dorsal premotor cortex of rhesus monkeys. J Neurophysiol 2011, 106:1454-1466.
26. Godlove D.C., Garr A.K., Woodman G.F., Schall J.D. Measurement of the extraocular spike potential during saccade countermanding. J Neurophysiol 2011, 106:104-114.
27. Mink J.W. The basal ganglia: focused selection and inhibition of competing motor programs. Prog Neurobiol 1996, 50:381-425.
28. Aron A.R., Poldrack R.A. Cortical and subcortical contributions to Stop signal response inhibition: role of the subthalamic nucleus. J Neurosci 2006, 26:2424-2433.
29. Schmidt R., Leventhal D.K., Mallet N., Chen F., Berke J.D. Canceling actions involves a race between basal ganglia pathways. Nat Neurosci 2013, 16:1118-1124.
30. Benis D., David O., Lachaux J.P., Seigneuret E., Krack P., Fraix V., et al. Subthalamic nucleus activity dissociates proactive and reactive inhibition in patients with Parkinson's disease. Neuroimage 2014, 91:273-281.
31. Turner R.S., Desmurget M. Basal ganglia contributions to motor control: a vigorous tutor. Curr Opin Neurobiol 2010, 20:704-716.
32. Hikosaka O., Isoda M. Switching from automatic to controlled behavior: cortico-basal ganglia mechanisms. Trends Cogn Sci 2010, 14:154-161.
33. Isoda M., Hikosaka O. Role for subthalamic nucleus neurons in switching from automatic to controlled eye movement. J Neurosci 2008, 28:7209-7218.
34. Cohen O., Sherman E., Zinger N., Perlmutter S., Prut Y. Getting ready to move: transmitted information in the corticospinal pathway during preparation for movement. Curr Opin Neurobiol 2010, 20:696-703.
35. Prut Y., Fetz E.E. Primate spinal interneurons show pre-movement instructed delay activity. Nature 1999, 401:590-594.
36. Braver T.S., Gray J.R., Burgess G.C. Explaining the many varieties of working memory variation: dual mechanisms of cognitive control. Variation in working memory 2007, Oxford University Press, Oxford. A.R.A. Conway, C. Jarrold, M.J. Kane, A. Miyake, J.N. Towse (Eds.).
37. Braver T.S., Paxton J.L., Locke H.S., Barch D.M. Flexible neural mechanisms of cognitive control within human prefrontal cortex. Proc Natl Acad Sci USA 2009, 106:7351-7356.
38. Bogacz R., Wagenmakers E.J., Forstmann B.U., Nieuwenhuis S. The neural basis of the speed-accuracy tradeoff. Trends Neurosci 2009, 33:10-16.
39. Stuphorn V., Schall J.D. Executive control of countermanding saccades by the supplementary eye field. Nat Neurosci 2006, 9:925-931.
40. Verbruggen F., Liefooghe B., Vandierendonck A. The effect of interference in the early processing stages on response inhibition in the stop signal task. Q J Exp Psychol (Colchester) 2006, 59:190-203.
41. Verbruggen F., Liefooghe B., Vandierendonck A. The interaction between stop signal inhibition and distractor interference in the flanker and Stroop task. Acta Psychol (Amst) 2004, 116:21-37.
42. Emeric E.E., Brown J.W., Boucher L., Carpenter R.H., Hanes D.P., Harris R., et al. Influence of history on saccade countermanding performance in humans and macaque monkeys. Vision Res 2007, 47:35-49.
43. Nelson M.J., Boucher L., Logan G.D., Palmeri T.J., Schall J.D. Nonindependent and nonstationary response times in stopping and stepping saccade tasks. Atten Percept Psychophys 2010, 72:1913-1929.
44. Bissett P.G., Logan G.D. Balancing cognitive demands: control adjustments in the stop-signal paradigm. J Exp Psychol Learn Mem Cogn 2011, 37:392-404.
45. Aron A.R. From reactive to proactive and selective control: developing a Richer model for stopping inappropriate responses. Biol Psychiatry 2010.
46. Cai W., Oldenkamp C.L., Aron A.R. A proactive mechanism for selective suppression of response tendencies. J Neurosci 2011, 31:5965-5969.
47. Majid D.S., Cai W., Corey-Bloom J., Aron A.R. Proactive selective response suppression is implemented via the basal ganglia. J Neurosci 2013, 33:13259-13269.
48. Cui G., Jun S.B., Jin X., Pham M.D., Vogel S.S., Lovinger D.M., et al. Concurrent activation of striatal direct and indirect pathways during action initiation. Nature 2013, 494:238-242.
49. Nambu A. Seven problems on the basal ganglia. Curr Opin Neurobiol 2008, 18:595-604.
50. Mink J.W. The basal ganglia: focused selection and inhibition of competing motor programs. Prog Neurobiol 1996, 50:381-425.
51. Chen X., Scangos K.W., Stuphorn V. Supplementary motor area exerts proactive and reactive control of arm movements. J Neurosci 2010, 30:14657-14675.
52. Scangos K.W., Stuphorn V. Medial frontal cortex motivates but does not control movement initiation in the countermanding task. J Neurosci 2010, 30:1968-1982.
53. Stuphorn V., Brown J.W., Schall J.D. Role of supplementary eye field in saccade initiation: executive, not direct, control. J Neurophysiol 2010, 103:801-816.
54. Bogacz R., Wagenmakers E.J., Forstmann B.U., Nieuwenhuis S. The neural basis of the speed-accuracy tradeoff. Trends Neurosci 2010, 33:10-16.
55. Heitz R.P., Schall J.D. Neural mechanisms of speed-accuracy tradeoff. Neuron 2012, 76:616-628.
56. Kiani R., Shadlen M.N. Representation of confidence associated with a decision by neurons in the parietal cortex. Science 2009, 324:759-764.
57. Thura D., Cisek P. Deliberation and commitment in the premotor and primary motor cortex during dynamic decision making. Neuron 2014, 81:1401-1416.
58. Middlebrooks P.G., Schall J.D. Response inhibition during perceptual decision making in humans and macaques. Atten Percept Psychophys 2014, 76:353-366.