Current advances and pressing problems in studies of stopping

Current Opinion in Neurobiology

Volumn 22, Issue 6, 2012, Pages 1012-1021

  Schall, Jeffrey D ^a   Godlove, David C ^a  

^a VANDERBILT UNIVERSITY SCHOOL OF MEDICINE   (United States)

Author keywords

[No Author keywords available]

Indexed keywords

ANIMAL; BIOLOGICAL MODEL; BRAIN; DECISION MAKING; EXECUTIVE FUNCTION; HUMAN; NERVE CELL INHIBITION; NEUROBIOLOGY; PHYSIOLOGY; PRIMATE; REVIEW; TRANSLATIONAL RESEARCH;

ANIMALS; BRAIN; DECISION MAKING; EXECUTIVE FUNCTION; HUMANS; MODELS, NEUROLOGICAL; NEURAL INHIBITION; NEUROBIOLOGY; PRIMATES; TRANSLATIONAL MEDICAL RESEARCH;

EID: 84878208266     PISSN: 09594388     EISSN: 18736882     Source Type: Journal    
DOI: 10.1016/j.conb.2012.06.002     Document Type: Review

References (91)

1. Aron A.R. From reactive to proactive and selective control: developing a richer model for stopping inappropriate responses. Biol Psychiatry 2011, 69:E55-E68.
2. Verbruggen F., Logan G.D. Response inhibition in the stop-signal paradigm. Trends Cogn Sci 2008, 12:418-424.
3. Logan G.D., Cowan W.B. On the ability to inhibit thought and action - a theory of an act of control. Psychol Rev 1984, 91:295-327.
4. Bissett P.G., Logan G.D. Balancing cognitive demands: control adjustments in the stop-signal paradigm. J Exp Psychol 2011, 37:392-404.
5. Bissett P.G., Logan G.D. Post-stop-signal adjustments: inhibition improves subsequent inhibition. J Exp Psychol Learn Mem Cogn 2012, [Epub ahead of print].
6. Boucher L., Stuphorn V., Logan G.D., Schall J.D., Palmeri T.J. Stopping eye and hand movements: are the processes independent?. Percept Psychophys 2007, 69:785-801.
7. Chamberlain S.R., Muller U., Blackwell A.D., Clark L., Robbins T.W., Sahakian B.J. Neurochemical modulation of response inhibition and probabilistic learning in humans. Science 2006, 311:861-863.
8. 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.
9. 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.
10. Swann N., Poizner H., Houser M., Gould S., Greenhouse I., Cai W.D., Strunk J., George J., Aron A.R. Deep brain stimulation of the subthalamic nucleus alters the cortical profile of response inhibition in the beta frequency band: a scalp EEG study in Parkinson's disease. J Neurosci 2011, 31:5721-5729.
11. Swann N., Tandon N., Canolty R., Ellmore T.M., McEvoy L.K., Dreyer S., DiSano M., Aron A.R. Intracranial EEG reveals a time- and frequency-specific role for the right inferior frontal gyrus and primary motor cortex in stopping initiated responses. J Neurosci 2009, 29:12675-12685.
12. Coxon J.P., Stinear C.M., Byblow W.D. Intracortical inhibition during volitional inhibition of prepared action. J Neurophysiol 2006, 95:3371-3383.
13. Greenhouse I., Oldenkamp C.L., Aron A.R. Stopping a response has global or nonglobal effects on the motor system depending on preparation. J Neurophysiol 2012, 107:384-392.
14. Stuphorn V., Schall J.D. Executive control of countermanding saccades by the supplementary eye field. Nat Neurosci 2006, 9:925-931.
15. Duann J.R., Ide J.S., Luo X., Li C.R. Functional connectivity delineates distinct roles of the inferior frontal cortex and presupplementary motor area in stop signal inhibition. J Neurosci 2009, 29:10171-10179.
16. Sharp D.J., Bonnelle V., De Boissezon X., Beckmann C.F., James S.G., Patel M.C., Mehta M.A. Distinct frontal systems for response inhibition, attentional capture, and error processing. Proc Natl Acad Sci USA 2010, 107:6106-6111.
17. Zandbelt B.B., Bloemendaal M., Neggers S.F.W., Kahn R.S., Vink M. Expectations and violations: delineating the neural network of proactive inhibitory control. Hum Brain Mapp 2012, [Epub ahead of print]. 10.1002/hbm.22047.
18. Zandbelt B.B., Vink M. On the role of the striatum in response inhibition. PLoS ONE 2010, 5.
19. Lipszyc J., Schachar R. Inhibitory control and psychopathology A meta-analysis of studies using the stop signal task. J Int Neuropsychol Soc 2010, 16:1064-1076.
20. Thakkar K.N., Schall J.D., Boucher L., Logan G.D., Park S. Response inhibition and response monitoring in a saccadic countermanding task in schizophrenia. Biol Psychiatry 2011, 69:55-62.
21. Zandbelt B.B., van Buuren M., Kahn R.S., Vink M. Reduced proactive inhibition in schizophrenia is related to corticostriatal dysfunction and poor working memory. Biol Psychiatry 2011, 70:1151-1158.
22. Barch D.M., Braver T.S., Carter C.S., Poldrack R.A., Robbins T.W. CNTRICS final task selection: executive control. Schizophr Bull 2009, 35:115-135.
23. 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.
24. 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.
25. Paré M., Hanes D.P. Controlled movement processing: superior colliculus activity associated with countermanded saccades. J Neurosci 2003, 23:6480-6489.
26. Segraves M.A. Activity of monkey frontal eye field neurons projecting to oculomotor regions of the pons. J Neurophysiol 1992, 68:1967-1985.
27. Shinoda Y., Sugiuchi Y., Takahashi M., Izawa Y. Neural substrate for suppression of omnipause neurons at the onset of saccades. Ann NY Acad Sci 2011, 1233:100-106.
28. Hanes D.P., Schall J.D. Neural control of voluntary movement initiation. Science 1996, 274:427-430.
29. Ray S., Pouget P., Schall J.D. Functional distinction between visuomovement and movement neurons in macaque frontal eye field during saccade countermanding. J Neurophysiol 2009, 102:3091-3100.
30. Munakata Y., Herd S.A., Chatham C.H., Depue B.E., Banich M.T., O'Reilly R.C. A unified framework for inhibitory control. Trends Cogn Sci 2011, 15:453-459.
31. Murthy A., Ray S., Shorter S.M., Schall J.D., Thompson K.G. Neural control of visual search by frontal eye field: effects of unexpected target displacement on visual selection and saccade preparation. J Neurophysiol 2009, 101:2485-2506.
32. Brunamonti E., Thomas N.W.D., Paré M. The activity patterns of lateral intraparietal area neurons is not sufficient to control visually guided saccadic eye movements. Soc Neurosci Abstr 2008, 855.18.2008.
33. 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.
34. Isoda M., Hikosaka O. Switching from automatic to controlled action by monkey medial frontal cortex. Nat Neurosci 2007, 10:240-248.
35. Isoda M., Hikosaka O. Role for subthalamic nucleus neurons in switching from automatic to controlled eye movement. J Neurosci 2008, 28:7209-7218.
36. Stuphorn V., Taylor T.L., Schall J.D. Performance monitoring by the supplementary eye field. Nature 2000, 408:857-860.
37. 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.
38. Wong-Lin K., Eckhoff P., Holmes P., Cohen J.D. Optimal performance in a countermanding saccade task. Brain Res 2010, 1318:178-187.
39. Lo C.C., Boucher L., Paré M., Schall J.D., Wang X.J. Proactive inhibitory control and attractor dynamics in countermanding action: a spiking neural circuit model. J Neurosci 2009, 29:9059-9071.
40. Shenoy P., Yu A.J. Rational decision-making in inhibitory control. Front Hum Neurosci 2011, 5.
41. Aron A.R., Fletcher P.C., Bullmore E.T., Sahakian B.J., Robbins T.W. Stop-signal inhibition disrupted by damage to right inferior frontal gyrus in humans. Nat Neurosci 2003, 6:115-116.
42. 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.
43. van den Wildenberg W.P.M., van Boxtel G.J.M., van der Molen M.W., Bosch D.A., Speelman J.D., Brunia C.H.M. Stimulation of the subthalamic region facilitates the selection and inhibition of motor responses in Parkinson's disease. J Cogn Neurosci 2006, 18:626-636.
44. Aron A.R., Behrens T.E., Smith S., Frank M.J., Poldrack R.A. Triangulating a cognitive control network using diffusion-weighted magnetic resonance imaging (MRI) and functional MRI. J Neurosci 2007, 27:3743-3752.
45. Kühn A.A., Williams D., Kupsch A., Limousin P., Hariz M., Schneider G.H., Yarrow K., Brown P. Event-related beta desynchronization in human subthalamic nucleus correlates with motor performance. Brain 2004, 127:735-746.
46. Ray N.J., Brittain J.S., Holland P., Joundi R.A., Stein J., Aziz T.Z., Jenkinson N. The role of the subthalamic nucleus in response inhibition: evidence from local field potential recordings in the human subthalamic nucleus. Neuroimage 2012, 60:271-278.
47. Hartmann-von Monakow K., Akert K., Kunzle H. Projections of the precentral motor cortex and other cortical areas of the frontal-lobe to the subthalamic nucleus in the monkey. Acta Anat (Basel) 1978, 105:112-113.
48. Nambu A. Somatotopic organization of the primate basal ganglia. Front Neuroanat 2011, 5.
49. Lambert C., Zrinzo L., Nagy Z., Lutti A., Hariz M., Foltynie T., Draganski B., Ashburner J., Frackowiak R. Confirmation of functional zones within the human subthalamic nucleus: patterns of connectivity and sub-parcellation using diffusion weighted imaging. Neuroimage 2012, 60:83-94.
50. Eagle D.M., Baunez C. Is there an inhibitory-response-control system in the rat? Evidence from anatomical and pharmacological studies of behavioral inhibition. Neurosci Biobehav Rev 2010, 34:50-72.
51. Parent A. Extrinsic connections of the basal ganglia. Trends Neurosci 1990, 13:254-258.
52. Duncan J. EPS Mid-Career Award 2004 - brain mechanisms of attention. Q J Exp Psychol 2006, 59:2-27.
53. Hampshire A., Chamberlain S.R., Monti M.M., Duncan J., Owen A.M. The role of the right inferior frontal gyrus: inhibition and attentional control. Neuroimage 2010, 50:1313-1319.
54. Arrington C.M., Carr T.H., Mayer A.R., Rao S.M. Neural mechanisms of visual attention: object-based selection of a region in space. J Cogn Neurosci 2000, 12:106-117.
55. Asplund C.L., Todd J.J., Snyder A.P., Marois R. A central role for the lateral prefrontal cortex in goal-directed and stimulus-driven attention. Nat Neurosci 2010, 13. 507-U136.
56. Shulman G.L., Astafiev S.V., Franke D., Pope D.L.W., Snyder A.Z., McAvoy M.P., Corbetta M. Interaction of stimulus-driven reorienting and expectation in ventral and dorsal frontoparietal and basal ganglia-cortical networks. J Neurosci 2009, 29:4392-4407.
57. Vossel S., Thiel C.M., Fink G.R. Cue validity modulates the neural correlates of covert endogenous orienting of attention in parietal and frontal cortex. Neuroimage 2006, 32:1257-1264.
58. Corbetta M., Patel G., Shulman G.L. The reorienting system of the human brain: from environment to theory of mind. Neuron 2008, 58:306-324.
59. Nakahara K., Hayashi T., Konishi S., Miyashita Y. Functional MRI of macaque monkeys performing a cognitive set-shifting task. Science 2002, 295:1532-1536.
60. Chen X.M., Scangos K.W., Stuphorn V. Supplementary motor area exerts proactive and reactive control of arm movements. J Neurosci 2010, 30:14657-14675.
61. Ray N.J., Jenkinson N., Brittain J.S., Holland P., Joint C., Nandi D., Bain P.G., Yousif N., Green A., Stein J.S., et al. The role of the subthalamic nucleus in response inhibition: evidence from deep brain stimulation for Parkinson's disease. Neuropsychologia 2009, 47:2828-2834.
62. Cavanagh J.F., Wiecki T.V., Cohen M.X., Figueroa C.M., Samanta J., Sherman S.J., Frank M.J. Subthalamic nucleus stimulation reverses mediofrontal influence over decision threshold. Nat Neurosci 2011, 14. 1462-U1140.
63. Frank M.J., Samanta J., Moustafa A.A., Sherman S.J. Hold your horses: impulsivity, deep brain stimulation, and medication in parkinsonism. Science 2007, 318:1309-1312.
64. Hälbig T.D., Tse W., Frisina P.G., Baker B.R., Hollander E., Shapiro H., Tagliati M., Koller W.C., Olanow C.W. Subthalamic deep brain stimulation and impulse control in Parkinson's disease. Eur J Neurol 2009, 16:493-497.
65. Wylie S.A., Ridderinkhof K.R., Elias W.J., Frysinger R.C., Bashore T.R., Downs K.E., van Wouwe N.C., van den Wildenberg W.P.M. Subthalamic nucleus stimulation influences expression and suppression of impulsive behaviour in Parkinson's disease. Brain 2010, 133:3611-3624.
66. Li C.S.R., Yan P., Sinha R., Lee T.W. Subcortical processes of motor response inhibition during a stop signal task. Neuroimage 2008, 41:1352-1363.
67. Hanes D.P., Schall J.D. Countermanding saccades in macaque. Vis Neurosci 1995, 12:929-937.
68. Ko Y.T., Miller J. Nonselective motor-level changes associated with selective response inhibition: evidence from response force measurements. Psychon Bull Rev 2011, 18:813-819.
69. Corneil B.D., Elsley J.K. Countermanding eye-head gaze shifts in humans: marching orders are delivered to the head first. J Neurophysiol 2005, 94:883-895.
70. Goonetilleke S.C., Doherty T.J., Corneil B.D. A within trial measure of the stop signal reaction time in a head-unrestrained oculomotor countermanding task. J Neurophysiol 2010, 104:3677-3690.
71. 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.
72. Chikazoe J., Jimura K., Hirose S., Yamashita K., Miyashita Y., Konishi S. Preparation to inhibit a response complements response inhibition during performance of a stop-signal task. J Neurosci 2009, 29:15870-15877.
73. So N.Y., Stuphorn V. Supplementary eye field encodes option and action value for saccades with variable reward. J Neurophysiol 2010, 104:2634-2653.
74. Aron A.R., Verbruggen F. Stop the presses: dissociating a selective from a global mechanism for stopping. Psychol Sci 2008, 19:1146-1153.
75. Camalier C.R., Gotler A., Murthy A., Thompson K.G., Logan G.D., Palmeri T.J., Schall J.D. Dynamics of saccade target selection: race model analysis of double step and search step saccade production in human and macaque. Vision Res 2007, 47:2187-2211.
76. De Jong R., Coles M.G.H., Logan G.D. Strategies and mechanisms in nonselective and selective inhibitory motor control. J Exp Psychol Hum Percept Perform 1995, 21:498-511.
77. van de Laar M.C., van den Wildenberg W.P.M., van Boxtel G.J.M., van der Molen M.W. Processing of global and selective stop signals application of donders' subtraction method to stop-signal task performance. Exp Psychol 2010, 57:149-159.
78. Ito S., Stuphorn V., Brown J.W., Schall J.D. Performance monitoring by the anterior cingulate cortex during saccade countermanding. Science 2003, 302:120-122.
79. Emeric E.E., Brown J.W., Leslie M., Pouget P., Stuphorn V., Schall J.D. Performance monitoring local field potentials in the medial frontal cortex of primates: anterior cingulate cortex. J Neurophysiol 2008, 99:759-772.
80. Nakamura K., Roesch M.R., Olson C.R. Neuronal activity in macaque SEF and ACC during performance of tasks involving conflict. J Neurophysiol 2005, 93:884-908.
81. Cole M., Yeung N., Freiwald W.A., Botvinick M. Cingulate cortex: diverging data from humans and monkeys. Trends Neurosci 2009, 32:566-574.
82. Schall J.D., Emeric E.E. Conflict in cingulate cortex function between humans and macaque monkeys: more apparent than real. Comment on " Cingulate cortex: diverging data from humans and monkeys". Brain Behav Evol 2010, 75:237-238.
83. Gehring W.J., Liu Y., Orr J.M., Carp J. The error-related negativity (ERN/Ne). Oxford Handbook of Event-related Potential Components 2012, Oxford University Press. S.J. Luck, E. Kappenman (Eds.).
84. Emeric E.E., Leslie M., Pouget P., Schall J.D. Performance monitoring local field potentials in the medial frontal cortex of primates: supplementary eye field. J Neurophysiol 2010, 104:1523-1537.
85. Godlove D.C., Emeric E.E., Segovis C.M., Young M.S., Schall J.D., Woodman G.F. Event-related potentials elicited by errors during the stop-signal task. I. macaque monkeys. J Neurosci 2011, 31:15640-15649.
86. Reinhart R.M.G., Carlisle N.B., Kang M.S., Woodman G.F. Event-related potentials elicited by errors during the stop-signal task. II: Human effector specific error responses. J Neurophysiol 2012, 107:2794-2807.
87. Emeric E.E., Brown J.W., Boucher L., Carpenter R.H.S., Hanes D.P., Harris R., Logan G.D., Mashru R.N., Paré M., Pouget P., et al. Influence of history on saccade countermanding performance in humans and macaque monkeys. Vision Res 2007, 47:35-49.
88. Nelson M., 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.
89. Bissett P.G., Logan G.D. Post-stop-signal slowing: Strategies dominate reflexes and implicit learning. J Exp Psychol Hum Percept Perform 2012, 38:746-757.
90. Pouget P., Logan G.D., Palmeri T.J., Boucher L., Paré M., Schall J.D. Neural basis of adaptive response time adjustment during saccade countermanding. J Neurosci 2011, 31:12604-12612.
91. Leotti L.A., Wager T.D. Motivational influences on response inhibition measures. J Exp Psychol Hum Percept Perform 2010, 36:430-447.