Publications:

2009

1. Time course of attentional modulation in the frontal eye field during curve tracing. Khayat PS, Pooresmaeili A, Roelfsema PR. J Neurophysiol. (2009) 101:1813-22. [PDF]
2. Matching of visual input to only one item at any one time. Houtkamp R, Roelfsema PR. Psychol Res. (2009) 73:317-26. [PDF]
3. Remembered but Unused: The Accessory Items in Working Memory that Do Not Guide Attention. Judith Peters, Rainer Goebel, and Pieter Roelfsema. J. Cogn. Neurosc. (2009) 21(6):1081–1091 [PDF]
4. Noise Correlations Have Little Influence on the Coding of Selective Attention in Area V1. Jasper Poort and Pieter R. Roelfsema. Cereb Cortex, (2009) 19(3):543-53. Epub 2008 Jun 13. [PDF]
5. Location and color biases have different influences on selective attention. Jillian H. Fecteau , Ilia Korjoukov a, Pieter R. Roelfsema. Vision Research (2009) 49:996-1005 [PDF]
6. Additive Effects of Attention and Stimulus Contrast in Primary Visual Cortex. Alexander Thiele, Arezoo Pooresmaeili, Louise S. Delicato, Jose L. Herrero and Pieter R. Roelfsema Cerebral Cortex (2009) 19:2970-2981 [PDF]

2008

1. Bottom-Up Dependent Gating of Frontal Signals in Early Visual Cortex. Leeland B. Ekstrom, Pieter R. Roelfsema, John T. Arsenault, Giorgio Bonmassar, Wim Van duffel. Science 321, 424-417(2008) [PDF]
   

2007

1. Interactions between higher and lower visual areas improve shape selectivity of higher level neurons—Explaining crowding phenomena. Janneke F.M. Jehee, Pieter R. Roelfsema, Gustavo Deco, Jaap M.J. Murre, Victor A.F. Lamme. Brain Res. 1157, 167-176 (2007) [PDF]
   
2. Boundary assignment in a recurrent network architecture. Janneke F.M. Jehee, Victor A.F. Lamme, Pieter R. Roelfsema. Vision Res. 47, 1153–1165 (2007) [PDF]
   
3. Different Processing Phases for Features, Figures, and Selective Attention in the Primary Visual Cortex. Pieter R. Roelfsema, Michiel Tolboom, and Paul S. Khayat. Neuron 56, 785–792, (2007) [PDF]
   Supplemental Data [PDF]
   Commentary: Early Vision Is Early in Time. Robert Shapley. Neuron 56, 765-766 (2007) [PDF]
   
4. A field of dreams Inner Presence: Consciousness as a Biological Phenomenon by Antti Revonsuo. Book review by: Matthew W. Self and Pieter R. Roelfsema. TRENDS in Cognitive Sciences 11(1), 6-7 [PDF]
   

 

2006

1. Synchrony dynamics in monkey V1 predict success in visual detection. Chris van der Togt, Stiliyan Kalitzin, Henk Spekreijse, Victor A.F. Lamme and Hans Supèr. Cereb Cortex. 2006 Jan;16(1):136-48. Epub 2005 Apr 20. [PDF]
   
2. Attention lights up new object representations before the old ones fade away. Khayat PS, Spekreijse H, Roelfsema PR. J Neurosci. 2006 Jan 4;26(1):138-42. [PDF]
   
3. The effect of Items in working memory on the deployment of attention and the eyes during visual search. Houtkamp, R., Roelfsema, P.R. (2006) J. Exp. Psych: Human Perception and Performance 2006, Vol. 32, No. 2, 423-442. [PDF]
   
4. Cortical algorithms for perceptual grouping. Pieter R. Roelfsema (2006) Annu. Rev. Neurosci. 29:203-227. [PDF]
   

 

2005

1. Chronic multi-unit recordings in behaving animals: advantages and limitations. Hans Supèr, and Pieter R. Roelfsema (2005) Prog. Brain Res., 147, 263-282. [PDF]
   
2. Elemental operations in vision. Roelfsema PR. (2005) Trends Cogn Sci. 9(5):226-33.
   
3. Neural responses in cat visual cortex reflect state changes in correlated activity. Chris van der Togt, Henk Spekreijse, Hans Supèr. (2005) Eur. J. Neurosci. 22(2):465-75. [PDF]
   
4. Attention-gated reinforcement learning of internal representations for classification. Roelfsema PR, van Ooyen A. (2005) Neural Comput. 17(10):2176-214.[PDF]
   

 

2004

1. Synchrony and covariation of firing primary visual cortex during contour grouping. Pieter R Roelfsema, Victor A F Lamme & Henk Spekreijse (2004) Nat. Neurosci. 7:982-991. [PDF]
   
2. Correlates of transsaccadic integration in the primary visual cortex of the monkey. Paul S. Khayat, Henk Spekreijse, and Pieter R. Roelfsema (2004) PNAS 101:12712–12717 [PDF]
   
3. Visual information transfer across eye movements in the monkey. Paul S. Khayat, Henk Spekreijse, and Pieter R. Roelfsema (2004) Vision Research 44:2901–2917 [PDF]
   
4. Correspondence of presaccadic activity in the monkey primary visual cortex with saccadic eye movements. Hans Supèr, Chris van der Togt, Henk Spekreijse, and Victor A.F.Lamme (2004) PNAS, March 2, 101(9) 3230-3235 [PDF]
   
5. The Integration of Colour and Motion by the Human Visual Brain. Matthew W. Self and S. Zeki Cerebral Cortex Advance Access published on December 22, 2004. [PDF]
   

 

2003

1. Internal State of Monkey Primary Visual Cortex (V1) Predicts Figure–Ground Perception. Supèr, H., van der Togt, C., Spekreijse, H. & Lamme, V. A. F. (2003) J. Neuroscience, 23:3407–3414 [PDF]
   
2. Subtask sequencing in the primary visual cortex. Roelfsema, P.R., Khayat, P.S. & Spekreijse, H. (2003) Proceedings of the National Academy of Sciences USA, 100, 5467-5472. [PDF]
   
3. Working memory in the primary visual cortex. Supèr, H. (2003) Archives of Neurology 60: 809-812.
   
4. Figure-ground activity in primary visual cortex (V1) of the monkey matches the speed of behavioral response. Supèr, H., Spekreijse, H., Lamme, V.A.F. (2003) Neurosci. Letters 344, 75-78.
   
5. Why do schizophrenic patients hallucinate? Roelfsema, P.R., Supèr, H. (2003) Brain Behavioral Science (in press).
   
6. Cortical evolution: No expansion without organization. Supèr, H. (2003) Brain Behavioral Science (in press).
   
7. A gradual spread of attention during mental curve tracing. Houtkamp,R., Spekreijse, H., Roelfsema, P.R. (2003) Perception & Psychophysics, 65 (7), 1136-1144 [PDF]
   

 

2002

1. Oscillatory neuronal synchronization in primary visual cortex as a correlate of perceptual stimulus selection. Fries, P., Schröder, J.-H., Singer, W., Roelfsema, P.R., Engel, A.K. (2002) J. Neurosci., 22, 3739-3754. [PDF]
   
2. Do neurons predict the future? Roelfsema, P.R. (2002) Science, 295, 227. [PDF]
   
3. Figure-ground segregation in a recurrent network architecture. Roelfsema, P.R., Lamme, V.A.F., Spekreijse, H. & Bosch, H. (2002) Journal of Cognitive Neuroscience, 14, 525-537. [PDF]
   
4. Ocular dominance in extrastriate cortex of strabismic amblyopic cats. Schröder, J.-H., Fries,P., Roelfsema, P.R., Singer, W., Engel, A.K. (2002). Vision Res., 42, 29-39. [PDF]
   
5. Cognitive functions in the primary visual cortex; from perception to memory. Supèr, H. (2002) Review in the Neurosciences, 13:287-298.
   
6. Masking interrupts figure-ground signals in V1. Lamme VA, Zipser K, Spekreijse H. J Cogn Neurosci. 2002 Oct 1;14(7):1044-53. [PDF]
   

 

2001

1. Which brain mechanism cannot count beyond four? Roelfsema, P.R. & Lamme, V.A.F. (2001) Behavioral & Brain Sciences, 24, 142-143.
   
2. The representation of erroneously perceived stimuli in the primary visual cortex. Roelfsema, P.R. & Spekreijse, H. (2001) Neuron 31, 853-863. [PDF]
   
3. The spatial profile of visual attention in mental curve tracing. Scholte, H.S., Spekreijse, H. & Roelfsema, P.R. (2001) Vision Research, 41, 2569-2580. [PDF]
   
4. A neural correlate of working memory in the monkey primary visual cortex. Super, H., Spekreijse, H. & Lamme, V.A. Science. (2001) 293, 120-4. [PDF]
   
5. Two distinct modes of sensory processing observed in monkey primary visual cortex (V1). Supèr, H., Spekreijse, H. & Lamme, V.A. Nat. Neurosci. (2001) 4, 304-10. [PDF]
   
6. The early differentiation of the neocortex: A hypothesis on neocortical evolution. Supèr, H., Uylings, H. B. M. (2001) Cerebral Cortex 11:1101-1109.
   

 

2000

1. The effects of pair-wise and higher order correlations on the firing rate of a post-synaptic neuron. Bohte, S., Spekreijse, H. & Roelfsema, P.R. (2000) Neural Computation, 12, 153-179. [PDF]
   
2. The role of primary visual cortex (V1) in visual awareness. Lamme, V.A.F., Supèr, H., Landman, R., Roelfsema, P.R. & Spekreijse, H. (2000) Vision Research,40, 1507-1521.
   
3. The distinct modes of vision offered by feedforward and recurrent processing. Lamme, V.A.F. & Roelfsema, P.R. (2000) Trends in Neuroscience, 23, 571-579. [PDF]
   
4. The implementation of visual routines. Roelfsema, P.R., Lamme, V.A.F. & Spekreijse, H. (2000) Vision Research, 40, 1385-1411. [PDF]
   

 

1999

1. Temporal constraints on the grouping of contour segments into spatially extended objects. Roelfsema, P.R., Scholte, S. & Spekreijse, H. (1999) Vision Research, 39, 1509-1529. [PDF]
   
2. Cajal-Retzius cellen in de ontwikkeling van de cerebrale schors. Supèr,H. (1999) Neuropraxis 3:14-20.
   
3. The early development of thalamocortical and corticothalamic projections in mouse. Auladell, C., Perez Sust, P., Supèr, H., Soriano, E. (1999) Anatomy and Embryology 201:169-179 (2000).
   
4. Disruption of neuronal migration and radial glia in the developing cerebral cortex following ablation of Cajal-Retzius cells. Supèr H, Del Rio JA, Martinez A, Soriano E (1999) Cerebral Cortex 10(6): 602-13.
   
5. Algorithms for the detection of connectedness and their neural implementation. Roelfsema, P.R., Bohte, S. & Spekreijse, H. (1999) In: Burdet, G., Combe, P. & Parodi,O. (Eds.) Neuronal Information Processing: From Biological Data to Modelling and Applications. Series in Mathematical Biology and Medicine, Vol. 7. Singapore: World Scientific[PDF]
   

 

1998

1. Detecting connectedness. Roelfsema, P.R. & Singer, W. (1998) Cerebral Cortex, 8, 385-396.
   
2. Solutions for the binding problem. Roelfsema, P.R. (1998) Zeitschrift für Naturforschung C, 53, 691-715.
   
3. Object-based attention in the primary visual cortex of the macaque monkey. Roelfsema, P.R., Lamme, V.A.F. & Spekreijse, H. (1998) Nature, 395, 376-381. [PDF]
   
4. Functional connectivity within the visual cortex of the rat shows state changes. van der Togt, C., Lamme, V.A.F. & Spekreijse, H. (1998) Eur.J.Neuroscience, 10:1490-1507.[PDF]
   
5. Characterization of a directional selective inhibitory input from the medial terminal nucleus to the pretectal nuclear complex in the rat. Schmidt, M., van der Togt, C., Wahle, P., Hoffmann, K.P. (1998) Eur. J. Neurosci. 10:1533-43.
   
6. Involvement of distinct pioneer neurons in the formation of layer-specific connections in the hippocampus. Supèr H, Martinez A, Del Rio JA, Soriano E (1998) J. Neurosci. 18:4616-4626.
   
7. The functions of the preplate in development and evolution of the neocortex and hippocampus. Supèr, H, Soriano, E, Uylings, HBM. (1998) Brain Res. Reviews 27:40-64.
8. Feedforward, horizontal, and feedback interactions in visual cortical processing. Lamme, V.A.F., Supèr, H., Spekreijse, H. (1998) Current Opinions in Neurobiology 8:529-535.
   

 

1997

1. Role of temporal domain for response selection and perceptual binding. Engel, A.K., Roelfsema, P.R., Fries, P., Brecht, M. & Singer, W. (1997) Cerebral Cortex, 7, 571-582.
   
2. Binding and response selection in the temporal domain - a new paradigm for neurobiological research. Engel, A.K., Roelfsema, P.R., Fries, P., Brecht, M., Singer, W. (1997). Theory in Biosciences, 116, 241-266.
   
3. Synchronization of oscillatory responses in visual cortex correlates with perception in interocular rivalry. Fries, P., Roelfsema, P.R., Engel, A. K., König, P. & Singer, W. (1997) Proceedings of the National Academy of Sciences USA, 94, 12699-12704. [PDF]
   
4. Visuomotor integration is associated with zero time-lag synchronization among cortical areas. Roelfsema, P.R., Engel, A.K., König, P. & Singer, W. (1997) Nature, 385, 157-161.
   
5. Neuronal assemblies: necessity, significance, and detectability. Singer, W., Engel, A.K., Kreiter, A.K., Munk, M.H.J., Neuenschwander, S. & Roelfsema, P.R. (1997) Trends in Cognitive Sciences, 1, 252-261.[PDF]
   

1996

1. The role of neuronal synchronization in response selection: a biologically plausible theory of structured representations in the visual cortex, Journal of Cognitive Neuroscience, 8, 603-625. Roelfsema, P.R., Engel, A.K., König, P. & Singer, W. (1996)
   
2. Role of reticular activation in the modulation of intracortical synchronization. Munk, M.H.J., Roelfsema, P.R., König, P., Engel, A.K., & Singer, W. (1996) Science, 272, 271-274.
   
3. Precise timing of neuronal discharges within and across cortical areas: Implications for synaptic transmission. Singer, W., Kreiter, A.K., Engel, A.K., Fries, P., Roelfsema, P.R. & Volgushev, M.(1996) Journal of Physiology (Paris), 90, 221-222
   
4. Differential survival of Cajal-Retzius cells in organotypic cultures of hippocampus and neocortex. Del Rio JA, Heimrich B, Supèr H, Frotscher M, Soriano E (1996) J. Neurosci. 16:6896-6907.
   

5. Degeneration of Cajal-Retzius cells in the developing cerebral cortex of the mouse after ablation of meningeal cells by 6-hydroxydopamine. Supèr H, Martinez A, Soriano E (1996) Dev. Brain Res 98:15-20.
   

6. Survival of Cajal-Retzius cells after cortical lesions in newborn mice: A possible role for Cajal-Retzius cells in brain-repair. Supèr H, Perez Sust P, Soriano E (1996) Dev. Brain Res 98:9-14.
   

   
   

1995

1. Migrating neurons in the developing cerebral cortex of the mouse send callosal axons. Auladell C, Martinez A, Alcantara S, Supèr H, Soriano E (1995) Neurosci.64:1091-1103.
   

1994

1. Inhibition of neuronal activity in the nucleus of the optic tract due to electrical stimulation of the medial terminal nucleus in the rat. van der Togt, C., Schmidt, M. (1994) Eur. J. Neurosci. 6:558-64.
   
2. The contribution of GABA-mediated inhibition to response properties of neurons in the nucleus of the optic tract in the rat. Schmidt, M., Lewald, J., van der Togt, C., Hoffmann, K.P. (1994) Eur. J. Neurosci. 6:1656-61.
3. Organization of the embryonic and early postnatal murine hippocampus I.-Immunocytochemical characterization of neuronal populations in the subplate and marginal zone. (1994) J. Comp. Neurol. 342:571-595
   

4. The organization of the embryonic and early postnatal murine hippocampus II.-Development of entorhinal, commissural, and septal connections studied with the lipophilic tracer DiI. Supèr H, Soriano E (1994) J. Comp. Neurol. 344:101-120
   

1992

1. GABAergic neurons and circuits in the pretectal nuclei and the accessory optic system of mammals. van der Want, J.J., Nunes Cardozo. J.J., van der Togt, C. (1992) Prog. Brain Res. 90:283-305. Review.
   
2. Variation in form and axonal termination in the nucleus of the optic tract of the rat: the medial terminal nucleus input on neurons projecting to the inferior olive. van der Togt, C., van der Want, J. (1992) J. Comp. Neurol. 325:446-61.
   

1991

1. Medial terminal nucleus terminals in the nucleus of the optic tract contain GABA: an electron microscopical study with immunocytochemical double labeling of GABA and PHA-L. van der Togt, C., Nunes Cardozo, B., van der Want, J. (1991) J. Comp. Neurol. 312:231-41.v

1990

1. Post-fixation horseradish peroxidase tracing in rat fetus and pups. van der Togt, C., Feirabend, H.K. (1990) J. Neurosci Methods. 31:65-73.
   

1986

1. Gangliosides restore the specificity of afferent projection patterns in spinal cord explants chronically exposed to tetrodotoxin. Baker, R.E., van der Togt, C. (1986) Neurosci Lett. 67:285-8