original research

  1. Grasso, C. L., Ziegler, J. C., Coull, J. T., & Montant, M. (2022). Embodied time: Effect of reading expertise on the spatial representation of past and future. PloS one, 17(10), e0276273.

  2. Korolczuk, I., Burle, B., Coull, J. T., & Śmigasiewicz, K. (2022). Time for Action: Neural Basis of the Costs and Benefits of Temporal Predictability for Competing Response Choices. Journal of cognitive neuroscience, 34(2), 273–289.

  3. Grasso CL, Ziegler JC, Mirault J, Coull JT, Montant M (2021) As time goes by: Space-time compatibility effects in word recognition J Exp Psychol Learn Mem 48(2): 304–319

  4. Chassignolle M, Jovanovic L, Schmidt-Mutter C, Behr G, Giersch A, Coull JT (2021) Dopamine precursor depletion in healthy volunteers impairs processing of duration but not temporal order. J. Cogn. Neurosci. 33: 946-963

  5. Chassignolle M, Giersch A, Coull JT (2021) Evidence for visual temporal order processing below the threshold for conscious perception. Cognition 207:104528

  6. Korolczuk I, Burle B, Coull JT, Smigasiewicz K (2020) Mechanisms of impulsive responding to temporally predictable events as revealed by electromyography. Neuroscience 428: 13-22

  7. Thomas E, French R, Alizee G, Coull JT (2019). Having your cake and eating it: Faster responses with reduced muscular activation while learning a temporal interval. Neuroscience 410: 68-75.

  8. Monier F, Droit-Volet S, Coull JT (2019) The beneficial effect of synchronized action on motor and perceptual timing in children. Dev. Sci. 22: e12821

  9. Shafiei G, Zeighami Y, Clark CA, Coull JT, Nagano-Saito A, Leyton M, Dagher A, Mišic B (2019) Dopamine Signaling Modulates the Stability and Integration of Intrinsic Brain Networks. Cereb Cortex. 29:397-409

  10. Droit-Volet S, Lorandi F, Coull JT (2019) Explicit and implicit timing in aging. Acta Psychol 193:180-189.

  11. Korolczuk I, Burle B, Coull JT (2018) The costs and benefits of temporal predictability: impaired inhibition of prepotent responses accompanies increased activation of task-relevant responses. Cognition 179: 102-110

  12. Coull JT, Johnson KA, Droit-Volet S (2018) A mental timeline for duration from the age of 5 years old. Front. Psychol. 9: 1155

  13. Martin B, Franck N, Cermolacce M, Coull JT, Giersch A (2018) Minimal Self and Timing Disorders in Schizophrenia: A Case Report. Front Hum Neurosci. 12:132.

  14. Ciullo V. Piras F, Vecchio D, Banai N, Coull JT, Spalletta G (2018) Predictive timing disturbance is a precise marker of schizophrenia. Schiz Res: Cogn 12: 42-49

  15. Martin B, Franck N, Cermolacce M, Falco A, Benair A, Etienne E, Weibel S, Coull JT, Giersch A (2017) Fragile temporal prediction in patients with schizophrenia is related to minimal self disorders. Sci Rep. 7(1):8278.

  16. Comte M, Zendjidjian XY, Coull JT, Cancel A, Boutet C, Schneider FC, Sage T, Lazerges PE, Jaafari N, Ibrahim EC, Azorin JM, Blin O, Fakra E (2017) Impaired cortico-limbic functional connectivity in schizophrenia patients during emotion processing. Soc Cogn Affect Neurosci. 13: 381-390

  17. Charras P, Droit-Volet S, Brechet C, Coull JT (2017) The spatial representation of time can be flexibly oriented in the frontal or lateral planes from an early age. J. Exp Psychol: HPP 43:832-845.

  18. Johnson KA, Bryan M, Polonowita K, Decroupet D, Coull JT (2016) Isochronous sequential presentation helps children orient their attention in time. Front. Psychol. 7:1417

  19. Coull JT, Cotti J, Vidal F (2016) Differential roles for parietal and frontal cortices in fixed versus evolving temporal expectations: Dissociating prior from posterior temporal probabilities with fMRI. Neuroimage 141: 40-51

  20. Droit-Volet S, Coull JT (2016) Distinct developmental trajectories for explicit and implicit timing. J Exp Child Psychol 150:141-54

  21. Comte M, Schön D, Coull JT, Reynaud E, Khalfa S, Belzeaux R, Ibrahim EC, Guedj E, Blin O, Weinberger DR, Fakra E (2016) Dissociating bottom-up and top-down mechanisms in the cortico-limbic system during emotion processing. Cereb Cortex. 26:144-55.

  22. Coull JT, Charras P, Donadieu M, Droit-Volet S, Vidal F. (2015). SMA Selectively Codes the Active Accumulation of Temporal, Not Spatial, Magnitude. J Cogn Neurosci. 27:2281-298

  23. Droit-Volet S, Coull JT (2015). The Developmental Emergence of the Mental Time-Line: Spatial and Numerical Distortion of Time Judgement.PLoS One 10(7): e0130465

  24. Johnson KA, Burrowes E, Coull JT (2015) Children can implicitly, but not voluntarily, direct attention in time. PlosONE 10(4): e0123625

  25. Comte M, Cancel A, Coull JT, Schön D, Reynaud E, Boukezzi S, Rousseau PF, Robert G, Khalfa S, Guedj E, Blin O, Weinberger DR, Fakra E (2015) Effect of trait anxiety on prefrontal control mechanisms during emotional conflict. Human Brain Mapping 36(6): 2207-2214

  26. Bolger D, Coull JT, Schön D (2014) Metrical rhythm implicitly orients attention in time, as indexed by improved target detection and left inferior parietal activation. Journal of Cognitive Neuroscience 26: 593-605

  27. Coull JT, Hwang HJ, Leyton M, Dagher A (2013) Dopaminergic Modulation of Motor Timing in Healthy Volunteers Differs as a Function of Baseline DA Precursor Availability. Timing and Time Perception 1:77-98

  28. Coull JT, Davranche K, Nazarian B, Vidal F (2013) Functional anatomy of timing differs for production versus prediction of time intervals. Neuropsychologia 51:309-319

  29. Coull JT, Hwang HJ, Leyton M, Dagher A (2012) Dopamine Precursor Depletion Impairs Timing in Healthy Volunteers by Attenuating Activity in Putamen and Supplementary Motor Area. J Neurosci. 32(47): 16704-1671

  30. Vangkilde S, Coull JT, Bundesen C (2012) Great Expectations: Temporal Expectation Modulates Perceptual Processing Speed. Journal of Experimental Psychology: Human Perception and Performance 38:1183-1191

  31. Vangkilde S, Bundesen C, Coull JT (2011) Prompt but inefficient: nicotine differentially modulates discrete components of attention. Psychopharmacology 218: 667-680

  32. Coull JT, Morgan H, Cambridge, VC, Moore JW, Giorlando F, Adapa R, Corlett PR, Fletcher PC (2011) Ketamine perturbs perception of the flow of time in healthy volunteers. Psychopharmacology 218:543-56

  33. Davranche K, Nazarian B, Vidal F, Coull JT (2011) Orienting Attention in Time Activates Left Intraparietal Sulcus for Perceptual and Motor Task Goals. J Cogn Neurosci 23: 3318-3330

  34. Piras F, Coull JT (2011) Implicit, Predictive Timing Draws upon the Same Scalar Representation of Time as Explicit Timing. PLoS One 6:e18203

  35. Rohenkohl G, Coull JT, Nobre AC (2011) Behavioural dissociation between exogenous and endogenous temporal orienting of attention. PLOS One 6:e14620

  36. Cotti J, Rohenkohl G, Stokes M, Nobre AC, Coull JT (2011) Functionally dissociating temporal and motor components of response preparation in left intraparietal sulcus. Neuroimage 54: 1221-1230

  37. Coull JT, Vidal F, Goulon C, Nazarian B, Craig C (2008) Using Time-to-Contact Information to Assess Potential Collision Modulates Both Visual and Temporal Prediction Networks. Front Hum Neurosci. 2:10.

  38. Coull JT, Nazarian B, Vidal F (2008) Timing, storage, and comparison of stimulus duration engage discrete anatomical components of a perceptual timing network. J Cogn Neurosci. 20:2185-2197.

  39. Macar F, Coull JT, Vidal F (2006) The supplementary motor area in motor and perceptual time processing: fMRI studies. Cognitive Processing 7: 89-94

  40. Coull JT, Vidal F, Nazarian B, Macar F (2004) Functional anatomy of the attentional modulation of time estimation, Science 303: 1506-1508

  41. Coull JT, Jones MEP, Egan TD, Frith CD and Maze M (2004) Attentional effects of noradrenaline vary with arousal level: selective activation of thalamic pulvinar in humans. Neuroimage, 22:315-322

  42. Nobre AC, Coull JT, Maquet P, Frith CD, Vandenberghe R and Mesulam MM (2004) Orienting Attention to Locations in Perceptual Versus Mental Representations Journal of Cognitive Neuroscience 16: 363-373

  43. Coull JT, Walsh V, Frith CD and Nobre AC (2003) Distinct neural substrates for visual search amongst spatial versus temporal distractors. Cognitive Brain Research 17: 368-379

  44. Nobre AC, Coull JT, Walsh V and Frith CD (2003) Brain activations during visual search: contributions of search efficiency versus feature binding. Neuroimage 18: 91-103

  45. Coull JT, Nobre AC and Frith CD (2001) The noradrenergic alpha2 agonist clonidine modulates behavioural and neuroanatomical correlates of human attentional orienting and alerting. Cerebral Cortex 11: 73-84

  46. Coull JT, Frith CD, Büchel C and Nobre AC (2000) Orienting attention in time: behavioural and neuroanatomical distinction between exogenous and endogenous shifts. Neuropsychologia 38: 808-819

  47. Büchel C, Coull JT and Friston KJ (1999) The predictive value of changes in effective connectivity for human learning. Science 283:1538-1541

  48. Coull JT, Büchel C, Friston KJ and Frith CD (1999) Noradrenergically-mediated plasticity in a human attentional neuronal network. Neuroimage 10:705-715

  49. Coull JT, Frith CD and Dolan RJ (1999) Dissociating neuromodulatory effects of diazepam on episodic memory encoding and executive function. Psychopharmacology 145: 213-222

  50. Miniussi C, Wilding EL, Coull JT and Nobre AC (1999) Orienting attention in time: Modulation of brain potentials. Brain 122: 1507-1518

  51. Nobre AC, Coull JT, Frith CD and Mesulam MM (1999) Orbitofrontal cortex is activated during breaches of expectation in tasks of visual attention. Nature Neuroscience 2: 11-12

  52. Coull JT and Frith CD (1998) Differential activation of right superior parietal cortex and intraparietal sulcus by spatial and nonspatial attention. Neuroimage 8: 176-187

  53. Coull JT and Nobre AC (1998) Where and When to Pay Attention: The Neural Systems for Directing Attention to Spatial Locations and to Time Intervals as Revealed by Both PET and fMRI. Journal of Neuroscience 18: 7426-7435

  54. Coull JT, Frackowiak RSJ and Frith CD (1998) Monitoring for target objects: activation of right frontal and parietal cortices with increasing time on task. Neuropsychologia 36:1325-1334

  55. Richardson MP, Koepp MJ, Brooks DJ, Coull JT, Grasby P, Fish DR and Duncan JS (1998) Cerebral activation in malformations of cortical development. Brain 121: 1295-1304

  56. Coull JT, Frith CD, Dolan RJ, Frackowiak RSJ and Grasby PM (1997) The neural correlates of the noradrenergic modulation of human attention, arousal and learning. European Journal of Neuroscience 9: 589-598

  57. Coull JT, Frith CD, Frackowiak RSJ and Grasby PM (1996) A fronto-parietal network for rapid visual information processing: a PET study of sustained attention and working memory. Neuropsychologia 34: 1085-1095

  58. Coull JT, Hodges JR and Sahakian BJ (1996) The alpha2 antagonist idazoxan remediates certain attentional and executive dysfunction in patients with dementia of frontal type. Psychopharmacology 123: 239-249

  59. Coull JT, Sahakian BJ, Middleton HC, Young AH, Park SB, McShane RH, Cowen PJ and Robbins TW (1995) Differential effects of clonidine, haloperidol, diazepam and tryptophan depletion on focused attention and attentional search. Psychopharmacology 121: 222-230

  60. Coull JT, Middleton HC, Robbins TW and Sahakian BJ (1995) Clonidine and diazepam have differential effects on tests of attention and learning. Psychopharmacology 120: 322-332

  61. Coull JT, Middleton HC, Robbins TW and Sahakian BJ (1995) Contrasting effects of clonidine and diazepam on tests of working memory and planning. Psychopharmacology 120: 311-321

  62. Middleton HC, Coull JT, Sahakian BJ and Robbins TW (1994) Clonidine-induced changes in the spectral distribution of heart-rate variability correlate with performance on a test of sustained attention. Journal of Psychopharmacology 8: 1-7

  63. Sahakian BJ, Coull JT and Hodges JR (1994) Selective enhancement of executive function by idazoxan in a patient with dementia of the frontal lobe type. Journal of Neurology, Neurosurgery and Psychiatry 57: 120-121

  64. Park SB, Coull JT, McShane RH, Young AH, Sahakian BJ, Robbins TW and Cowen PJ (1994) Tryptophan depletion in normal volunteers produces selective deficits in learning and memory. Neuropharmacology 33: 575-588