The Thalamus in Attention

doi:10.1017/9781108674287.018

Chapter 17 - The Thalamus in Attention

from Section 7: - Cognition

Published online by Cambridge University Press: 12 August 2022

Sabine Kastner and

Michael J. Arcaro

Edited by

Michael M. Halassa

Show author details

Michael M. Halassa: Affiliation:
Massachusetts Institute of Technology

Book contents

Get access

Summary

Selective attention is a cognitive process that enables the preferential routing of behaviorally relevant information through the brain.The associated large-scale network includes regions in all major lobes as well as subcortical structures such as the thalamus. There is mounting evidence that the visual thalamus–the lateral geniculate nucleus (LGN), thalamic reticular nucleus (TRN), and pulvinar–plays an important functional role in this process. The LGN has been traditionally viewed to be a relay of retinal information to the cortex. However, it has been shown that neural gain is amplified in LGN neurons, possibly in pathway-specific ways and via TRN-regulated inhibitory control, to amplify neural representations in the focus of attention at the expense of those that are unattended, thereby boosting attention-related information and filtering unwanted distracter information at the earliest possible processing stage of the visual pathway. The pulvinar is the largest nucleus of the primate thalamus and is almost exclusively interconnected with the cortex. Its function has remained elusive for many decades. Recent evidence suggests at least two functions that may be interdependent. First, pulvinar influences on the cortex are necessary to enable regular cortical function so that information can be processed from one area to the next. Second, the pulvinar coordinates information processing across the cortical attention network by synchronizing local population activity, thereby optimizing information transfer. Taken together, emerging views suggest roles for the LGN–TRN circuit as the gatekeeper and for the pulvinar as the timekeeper of the cortex.

Keywords

thalamo-cortical loops cortical coordination space-based attention feature-based attention rhythmic sampling

Type: Chapter
Information: The Thalamus , pp. 324 - 339

DOI: https://doi.org/10.1017/9781108674287.018 [Opens in a new window]

Publisher: Cambridge University Press

Print publication year: 2022

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

Adams, M. M., Hof, P. R., Gattass, R., Webster, M. J. & Ungerleider, L. G. Visual cortical projections and chemoarchitecture of macaque monkey pulvinar. Journal of Comparative Neurology 419, 377–393 (2000).3.0.CO;2-E>CrossRef Google Scholar PubMed

Alonso, J.-M., Usrey, W. M. & Reid, R. C. Precisely correlated firing in cells of the lateral geniculate nucleus. Nature 383, 815–819 (1996).Google Scholar

Arcaro, M. J. & Livingstone, M. S. Retinotopic organization of scene areas in macaque inferior temporal cortex. Journal of Neuroscience 37, 7373 (2017).Google Scholar

Arcaro, M. J., Pinsk, M. A., Chen, J. & Kastner, S. Organizing principles of pulvino-cortical functional coupling in humans. Nature Communications 9, 5382 (2018).Google Scholar

Arcaro, M. J., Pinsk, M. A. & Kastner, S. The anatomical and functional organization of the human visual pulvinar. Journal of Neuroscience 35, 9848 (2015).Google Scholar

Arend, I., Rafal, R. & Ward, R. Spatial and temporal deficits are regionally dissociable in patients with pulvinar lesions. Brain 131, 2140–2152 (2008).Google Scholar

Baldwin, M. K. L., Balaram, P. & Kaas, J. H. The evolution and functions of nuclei of the visual pulvinar in primates. Journal of Comparative Neurology 525, 3207–3226 (2017).Google Scholar

Baleydier, C. & Mauguiere, F. Anatomical evidence for medial pulvinar connections with the posterior cingulate cortex, the retrosplenial area, and the posterior parahippocampal gyrus in monkeys. Journal of Comparative Neurology 232, 219–228 (1985).Google Scholar

Barron, D. S., Eickhoff, S. B., Clos, M. & Fox, P. T. Human pulvinar functional organization and connectivity. Human Brain Mapping 36, 2417–2431 (2015).Google Scholar

Bastos, A. M., Briggs, F., Alitto, H. J., Mangun, G. R. & Usrey, W. M. Simultaneous recordings from the primary visual cortex and lateral geniculate nucleus reveal rhythmic interactions and a cortical source for gamma-band oscillations. Journal of Neuroscience 34, 7639 (2014).Google Scholar

Battaglia‐Mayer, A. & Caminiti, R. Optic ataxia as a result of the breakdown of the global tuning fields of parietal neurones. Brain 125, 225–237 (2002).Google Scholar

Bekisz, M. & Wróbel, A. 20 Hz rhythm of activity in visual system of perceiving cat. Acta Neurobiologiae Experimentalis 53, 175–182 (1993).Google Scholar

Bender, D. B. Receptive-field properties of neurons in the macaque inferior pulvinar. Journal of Neurophysiology 48, 1–17 (1982).Google Scholar

Bender, D. B. & Youakim, M. Effect of attentive fixation in macaque thalamus and cortex. Journal of Neurophysiology 85, 219–234 (2001).Google Scholar

Bennett, C. et al. Higher-order thalamic circuits channel parallel streams of visual information in mice. Neuron 102, 477–492.e5 (2019).Google Scholar

Bereshpolova, Y. et al. Getting drowsy? Alert/nonalert transitions and visual thalamocortical network dynamics. Journal of Neuroscience 31, 17480 (2011).Google Scholar

Bickford, M. Thalamic circuit diversity: modulation of the driver/modulator framework. Frontiers in Neural Circuits 9, 86 (2016).Google Scholar

Bourne, J. A. & Morrone, M. C. Plasticity of visual pathways and function in the developing brain: is the pulvinar a crucial player? Frontiers in Systems Neuroscience 11, 3 (2017).Google Scholar

Bridge, H., Leopold, D. A. & Bourne, J. A. Adaptive pulvinar circuitry supports visual cognition. Trends in Cognitive Sciences 20, 146–157 (2016).Google Scholar

Briggs, F., Mangun, G. R. & Usrey, W. M. Attention enhances synaptic efficacy and the signal-to-noise ratio in neural circuits. Nature 499, 476–480 (2013).Google Scholar

Briggs, F. & Usrey, W. M. Parallel processing in the corticogeniculate pathway of the macaque monkey. Neuron 62, 135–146 (2009).Google Scholar

Buschman, T. J. & Kastner, S. From behavior to neural dynamics: an integrated theory of attention. Neuron 88, 127–144 (2015).CrossRef Google Scholar PubMed

Callaway, E. M. Structure and function of parallel pathways in the primate early visual system. Journal of Physiology 566, 13–19 (2005).Google Scholar

Cameron, E. L., Tai, J. C. & Carrasco, M. Covert attention affects the psychometric function of contrast sensitivity. Vision Research 42, 949–967 (2002).Google Scholar

Casagrande, V. A. & Xu, X. Parallel visual pathways: a comparative perspective. In The Visual Neurosciences (eds. Chalupa, L. M. & Werner, J. S.), 494–506 (MIT Press, 2004).Google Scholar

Caspari, N., Janssens, T., Mantini, D., Vandenberghe, R. & Vanduffel, W. Covert shifts of spatial attention in the macaque monkey. Journal of Neuroscience 35, 7695 (2015).Google Scholar

Chalfin, B. P., Cheung, D. T., Muniz, J. A. P. C., de Lima Silveira, L. C. & Finlay, B. L. Scaling of neuron number and volume of the pulvinar complex in new world primates: Comparisons with humans, other primates, and mammals. Journal of Comparative Neurology 504, 265–274 (2007).Google Scholar

Chalupa, L. & Abramson, B. Visual receptive fields in the striate-recipient zone of the lateral posterior-pulvinar complex. Journal of Neuroscience 9, 347 (1989).Google Scholar

Cheong, S. K., Tailby, C., Solomon, S. G. & Martin, P. R. Cortical-like receptive fields in the lateral geniculate nucleus of marmoset monkeys. Journal of Neuroscience 33, 6864 (2013).Google Scholar

Cohen, M. R. & Maunsell, J. H. R. Attention improves performance primarily by reducing interneuronal correlations. Nature Neuroscience 12, 1594–1600 (2009).Google Scholar

Corbetta, M. et al. A common network of functional areas for attention and eye movements. Neuron 21, 761–773 (1998).Google Scholar

Corbetta, M., Kincade, M. J., Lewis, C., Snyder, A. Z. & Sapir, A. Neural basis and recovery of spatial attention deficits in spatial neglect. Nature Neuroscience 8, 1603–1610 (2005).Google Scholar

Corbetta, M. & Shulman, G. L. Control of goal-directed and stimulus-driven attention in the brain. Nature Reviews Neuroscience 3, 201–215 (2002).Google Scholar

Cotton, P. L. & Smith, A. T. Contralateral visual hemifield representations in the human pulvinar nucleus. Journal of Neurophysiology 98, 1600–1609 (2007).Google Scholar

Crick, F. Function of the thalamic reticular complex: the searchlight hypothesis. Proceedings of the National Academy of Sciences of the United States of America 81, 4586 (1984).Google Scholar

Crick, F. & Koch, C. Constraints on cortical and thalamic projections: the no-strong-loops hypothesis. Nature 391, 245–250 (1998).Google Scholar

Danziger, S., Ward, R., Owen, V. & Rafal, R. The effects of unilateral pulvinar damage in humans on reflexive orienting and filtering of irrelevant information. Behavioural Neurology 13, 917570 (2002).Google Scholar

Danziger, S., Ward, R., Owen, V. & Rafal, R. Contributions of the human pulvinar to linking vision and action. Cognitive, Affective, & Behavioral Neuroscience 4, 89–99 (2004).Google Scholar

Darian-Smith, C., Tan, A. & Edwards, S. Comparing thalamocortical and corticothalamic microstructure and spatial reciprocity in the macaque ventral posterolateral nucleus (VPLc) and medial pulvinar. Journal of Comparative Neurology 410, 211–234 (1999).Google Scholar

de Souza, B. O. F., Cortes, N. & Casanova, C. Pulvinar modulates contrast responses in the visual cortex as a function of cortical hierarchy. Cerebral Cortex 30, 1068–1086 (2019).Google Scholar

Denison, R. N., Vu, A. T., Yacoub, E., Feinberg, D. A. & Silver, M. A. Functional mapping of the magnocellular and parvocellular subdivisions of human LGN. NeuroImage 102, 358–369 (2014).Google Scholar

Derrington, A. M. & Lennie, P. Spatial and temporal contrast sensitivities of neurones in lateral geniculate nucleus of macaque. Journal of Physiology 357, 219–240 (1984).Google Scholar

DeSimone, K., Viviano, J. D. & Schneider, K. A. Population receptive field estimation reveals new retinotopic maps in human subcortex. Journal of Neuroscience 35, 9836 (2015).Google Scholar

DeWeerd, P., Peralta, M. R., Desimone, R. & Ungerleider, L. G. Loss of attentional stimulus selection after extrastriate cortical lesions in macaques. Nature Neuroscience 2, 753–758 (1999).Google Scholar

Dominguez-Vargas, A.-U., Schneider, L., Wilke, M. & Kagan, I. Electrical microstimulation of the pulvinar biases saccade choices and reaction times in a time-dependent manner. Journal of Neuroscience 37, 2234 (2017).Google Scholar

Eradath, M. K., Pinsk, M. A. & Kastner, S. Causal role of pulvinar in resting state cortico-cortical interactions. Journal of Comparative Neurology 529, 3772–3784 (2020).Google Scholar

Felsten, G. Different approaches to physiological psychology. Psyccritiques 28, 38–40 (1983).Google Scholar

Fiebelkorn, I. C. & Kastner, S. A rhythmic theory of attention. Trends in Cognitive Sciences 23, 87–101 (2019).Google Scholar

Fiebelkorn, I. C. & Kastner, S. Functional specialization in the attention network. Annual Review of Psychology 71, 221–249 (2020).Google Scholar

Fiebelkorn, I. C., Pinsk, M. A. & Kastner, S. A dynamic interplay within the frontoparietal network underlies rhythmic spatial attention. Neuron 99, 842–853.e8 (2018).Google Scholar

Fiebelkorn, I. C., Pinsk, M. A. & Kastner, S. The mediodorsal pulvinar coordinates the macaque fronto-parietal network during rhythmic spatial attention. Nature Communications 10, 215 (2019).Google Scholar

Fiebelkorn, I. C., Saalmann, Y. B. & Kastner, S. Rhythmic sampling within and between objects despite sustained attention at a cued location. Current Biology 23, 2553–2558 (2013).Google Scholar

Fischer, J. & Whitney, D. Attention gates visual coding in the human pulvinar. Nature Communications 3, 1051 (2012).Google Scholar

Foxe, J. & Snyder, A. The role of alpha-band brain oscillations as a sensory suppression mechanism during selective attention. Frontiers in Psychology 2, 154 (2011).Google Scholar

Friedman-Hill, S. R., Robertson, L. C., Desimone, R. & Ungerleider, L. G. Posterior parietal cortex and the filtering of distractors. Proceedings of the National Academy of Sciences of the United States of America 100, 4263 (2003).Google Scholar

Friedman-Hill, S. R., Robertson, L. C., & Treisman, A. Parietal contributions to visual feature binding: evidence from a patient with bilateral lesions. Science 269, 853 (1995).Google Scholar

Fries, P., Reynolds, J. H., Rorie, A. E. & Desimone, R. Modulation of oscillatory neuronal synchronization by selective visual attention. Science 291, 1560 (2001).ssGoogle Scholar

Gallant, J. L., Shoup, R. E. & Mazer, J. A. A human extrastriate area functionally homologous to macaque V4. Neuron 27, 227–235 (2000).Google Scholar

Ganguli, S. et al. One-dimensional dynamics of attention and decision making in LIP. Neuron 58, 15–25 (2008).Google Scholar

Gottlieb, J. & Balan, P. Attention as a decision in information space. Trends in Cognitive Sciences 14, 240–248 (2010).Google Scholar

Gouws, A. D. et al. On the role of suppression in spatial attention: evidence from negative BOLD in human subcortical and cortical structures. Journal of Neuroscience 34, 10347–10360 (2014).Google Scholar

Gregoriou, G. G., Gotts, S. J. & Desimone, R. Cell-type-specific synchronization of neural activity in FEF with V4 during attention. Neuron 73, 581–594 (2012).Google Scholar

Grieve, K. L., Acuña, C. & Cudeiro, J. The primate pulvinar nuclei: vision and action. Trends in Neurosciences 23, 35–39 (2000).Google Scholar

Guedj, C. & Vuilleumier, P. Functional connectivity fingerprints of the human pulvinar: Decoding its role in cognition. NeuroImage 221, 117162 (2020).Google Scholar

Gutierrez, C., Yaun, A. & Cusick, C. G. Neurochemical subdivisions of the inferior pulvinar in macaque monkeys. Journal of Comparative Neurology 363, 545–562 (1995).Google Scholar

Haegens, S., Nácher, V., Luna, R., Romo, R. & Jensen, O. α-Oscillations in the monkey sensorimotor network influence discrimination performance by rhythmical inhibition of neuronal spiking. Proceedings of the National Academy of Sciences of the United States of America 108, 19377 (2011).Google Scholar

Halassa, M. M. & Acsády, L. Thalamic inhibition: diverse sources, diverse scales. Trends in Neurosciences 39, 680–693 (2016).Google Scholar

Halassa, M. M. & Kastner, S. Thalamic functions in distributed cognitive control. Nature Neuroscience 20, 1669–1679 (2017).Google Scholar

Harris, J. A. et al. Hierarchical organization of cortical and thalamic connectivity. Nature 575, 195–202 (2019). 1.Google Scholar

Haynes, J.-D., Deichmann, R. & Rees, G. Eye-specific effects of binocular rivalry in the human lateral geniculate nucleus. Nature 438, 496–499 (2005).Google Scholar

Helfrich, R. F. et al. Neural mechanisms of sustained attention are rhythmic. Neuron 99, 854–865.e5 (2018).Google Scholar

Hendry, S. H. C. & Reid, R. C. The koniocellular pathway in primate vision. Annual Review of Neuroscience 23, 127–153 (2000).Google Scholar

Hickey, T. L. & Guillery, R. W. Variability of laminar patterns in the human lateral geniculate nucleus. Journal of Comparative Neurology 183, 221–246 (1979).Google Scholar

Hirsch, J. A., Wang, X., Sommer, F. T. & Martinez, L. M. How inhibitory circuits in the thalamus serve vision. Annual Review of Neuroscience 38, 309–329 (2015).Google Scholar

Homman-Ludiye, J., Mundinano, I. C., Kwan, W. C. & Bourne, J. A. Extensive connectivity between the medial pulvinar and the cortex revealed in the marmoset monkey. Cerebral Cortex 30, 1797–1812 (2019).Google Scholar

Hubel, D. H. & Wiesel, T. N. Receptive fields, binocular interaction and functional architecture in the cat’s visual cortex. Journal of Physiology 160, 106–154 (1962).Google Scholar

Jaramillo, J., Mejias, J. F. & Wang, X.-J. Engagement of pulvino-cortical feedforward and feedback pathways in cognitive computations. Neuron 101, 321–336.e9 (2019).Google Scholar

Jensen, O. & Mazaheri, A. Shaping functional architecture by oscillatory alpha activity: gating by inhibition. Frontiers in Human Neuroscience 4, 186 (2010).Google Scholar

Jones, E. G. The thalamus (Springer Science & Business Media, 2007).Google Scholar

Kaas, J. H. & Lyon, D. C. Pulvinar contributions to the dorsal and ventral streams of visual processing in primates. Brain Research Reviews 55, 285–296 (2007).Google Scholar

Karnath, H., Himmelbach, M. & Rorden, C. The subcortical anatomy of human spatial neglect: putamen, caudate nucleus and pulvinar. Brain 125, 350–360 (2002).Google Scholar

Kastner, S. et al. Functional imaging of the human lateral geniculate nucleus and pulvinar. Journal of Neurophysiology 91, 438–448 (2004).Google Scholar

Kastner, S., Chen, Q., Jeong, S. K. & Mruczek, R. E. B. A brief comparative review of primate posterior parietal cortex: a novel hypothesis on the human toolmaker. Neuropsychologia 105, 123–134 (2017).Google Scholar

Kastner, S., Fiebelkorn, I. C., & Eradath, M. K. Dynamic pulvino-cortical interactions in the primate attention network. Current Opinion in Neurobiology 65, 10–19 (2020).Kastner, S., Pinsk, M. A., De Weerd, P., Desimone, R. & Ungerleider, L. G. Increased activity in human visual cortex during directed attention in the absence of visual stimulation. Neuron 22, 751–761 (1999).Google Scholar

Kastner, S., & Ungerleider, L. G. Mechanisms of visual attention in the human cortex. Annual Review of Neuroscience 23, 315–341 (2000).Google Scholar

Komura, Y., Nikkuni, A., Hirashima, N., Uetake, T. & Miyamoto, A. Responses of pulvinar neurons reflect a subject’s confidence in visual categorization. Nature Neuroscience 16, 749–755 (2013).Google Scholar

Lakatos, P., O’Connell, M. N. & Barczak, A. Pondering the pulvinar. Neuron 89, 5–7 (2016).Google Scholar

Landau, A. N. & Fries, P. Attention samples stimuli rhythmically. Current Biology 22, 1000–1004 (2012).Google Scholar

Lee, S., Kruglikov, I., Huang, Z. J., Fishell, G. & Rudy, B. A disinhibitory circuit mediates motor integration in the somatosensory cortex. Nature Neuroscience 16, 1662–1670 (2013).Google Scholar

Lehky, S. R. & Maunsell, J. H. R. No binocular rivalry in the LGN of alert macaque monkeys. Vision Research 36, 1225–1234 (1996).Google Scholar

Ling, S., Pratte, M. S. & Tong, F. Attention alters orientation processing in the human lateral geniculate nucleus. Nature Neuroscience 18, 496–498 (2015).CrossRef Google Scholar PubMed

Livingstone, M. & Hubel, D. Segregation of form, color, movement, and depth: anatomy, physiology, and perception. Science 240, 740 (1988).Google Scholar

Livingstone, M. S. & Hubel, D. H. Effects of sleep and arousal on the processing of visual information in the cat. Nature 291, 554–561 (1981).Google Scholar

Lu, Z.-L. & Dosher, B. A. External noise distinguishes attention mechanisms. Vision Research 38, 1183–1198 (1998).Google Scholar

Luck, S. J., Chelazzi, L., Hillyard, S. A. & Desimone, R. Neural mechanisms of spatial selective attention in areas V1, V2, and V4 of macaque visual cortex. Journal of Neurophysiology 77, 24–42 (1997).Google Scholar

Lückmann, H. C., Jacobs, H. I. L. & Sack, A. T. The cross-functional role of frontoparietal regions in cognition: internal attention as the overarching mechanism. Progress in Neurobiology 116, 66–86 (2014).Google Scholar

Lyon, D. C., Nassi, J. J. & Callaway, E. M. A disynaptic relay from superior colliculus to dorsal stream visual cortex in macaque monkey. Neuron 65, 270–279 (2010).Google Scholar

Malpeli, J. G., Lee, D. & Baker, F. H. Laminar and retinotopic organization of the macaque lateral geniculate nucleus: magnocellular and parvocellular magnification functions. Journal of Comparative Neurology 375, 363–377 (1996).Google Scholar

Marion, R., Li, K., Purushothaman, G., Jiang, Y. & Casagrande, V. A. Morphological and neurochemical comparisons between pulvinar and V1 projections to V2. Journal of Comparative Neurology 521, 813–832 (2013).Google Scholar

Markov, N. T. et al. Anatomy of hierarchy: feedforward and feedback pathways in macaque visual cortex. Journal of Comparative Neurology 522, 225–259 (2014).Google Scholar

Martin, A. B. et al. Temporal dynamics and response modulation across the human visual system in a spatial attention task: an ECoG study. Journal of Neuroscience 39, 333–352 (2019).Google Scholar

Martin, P. R., White, A. J. R., Goodchild, A. K., Wilder, H. D. & Sefton, A. E. Evidence that blue-on cells are part of the third geniculocortical pathway in primates. European Journal of Neuroscience 9, 1536–1541 (1997).Google Scholar

McAlonan, K., Cavanaugh, J. & Wurtz, R. H. Attentional modulation of thalamic reticular neurons. Journal of Neuroscience 26, 4444 (2006).Google Scholar

McAlonan, K., Cavanaugh, J. & Wurtz, R. H. Guarding the gateway to cortex with attention in visual thalamus. Nature 456, 391–394 (2008).Google Scholar

McCormick, D. A., McGinley, M. J. & Salkoff, D. B. Brain state dependent activity in the cortex and thalamus. Current Opinion in Neurobiology 31, 133–140 (2015).Google Scholar

Mehta, A. D., Ulbert, I. & Schroeder, C. E. Intermodal selective attention in monkeys. I: distribution and timing of effects across visual areas. Cerebral Cortex 10, 343–358 (2000).Google Scholar

Mitchell, J. F., Sundberg, K. A. & Reynolds, J. H. Spatial attention decorrelates intrinsic activity fluctuations in macaque area V4. Neuron 63, 879–888 (2009).Google Scholar

Murray, J. D., Jaramillo, J. & Wang, X.-J. Working memory and decision-making in a frontoparietal circuit model. Journal of Neuroscience 37, 12167 (2017).Google Scholar

Moore, T., & Fallah, M. Control of eye movements and spatial attention. Proceedings of the national Academy of Sciences of the United States of America 98, 1273–1276 (2001).Google Scholar

O’Connor, D. H., Fukui, M. M., Pinsk, M. A. & Kastner, S. Attention modulates responses in the human lateral geniculate nucleus. Nature Neuroscience 5, 1203–1209 (2002).Google Scholar

Parvizi, J. Corticocentric myopia: old bias in new cognitive sciences. Trends in Cognitive Sciences 13, 354–359 (2009).Google Scholar

Petersen, S. E., Robinson, D. L. & Keys, W. Pulvinar nuclei of the behaving rhesus monkey: visual responses and their modulation. Journal of Neurophysiology 54, 867–886 (1985).CrossRef Google Scholar PubMed

Petersen, S. E., Robinson, D. L. & Morris, J. D. Contributions of the pulvinar to visual spatial attention. Neuropsychologia 25, 97–105 (1987).Google Scholar

Phillips, J. M. et al. Topographic organization of connections between prefrontal cortex and mediodorsal thalamus: evidence for a general principle of indirect thalamic pathways between directly connected cortical areas. NeuroImage 189, 832–846 (2019).Google Scholar

Pogosyan, A., Gaynor, L. D., Eusebio, A. & Brown, P. Boosting cortical activity at beta-band frequencies slows movement in humans. Current Biology 19, 1637–1641 (2009).Google Scholar

Posner, M. I. & Petersen, S. E. The attention system of the human brain. Annual Review of Neuroscience 13, 25–42 (1990).Google Scholar

Posner, M. I., Snyder, C. R. & Davidson, B. J. Attention and the detection of signals. Journal of Experimental Psychology: General 109, 160–174 (1980).Google Scholar

Purushothaman, G., Marion, R., Li, K. & Casagrande, V. A. Gating and control of primary visual cortex by pulvinar. Nature Neuroscience 15, 905–912 (2012).Google Scholar

Qian, Y. et al. Robust functional mapping of layer-selective responses in human lateral geniculate nucleus with high-resolution 7T fMRI. Proceedings of the Royal Society B: Biological Sciences 287, 20200245 (2020).Google Scholar

Quax, S., Jensen, O. & Tiesinga, P. Top-down control of cortical gamma-band communication via pulvinar induced phase shifts in the alpha rhythm. PLOS Computational Biology 13, e1005519 (2017).CrossRef Google Scholar PubMed

Rafal, R. D. & Posner, M. I. Deficits in human visual spatial attention following thalamic lesions. Proceedings of the National Academy of Sciences of the United States of America 84, 7349 (1987).Google Scholar

Rockland, K. S. Convergence and branching patterns of round, type 2 corticopulvinar axons. Journal of Comparative Neurology 390, 515–536 (1998).Google Scholar

Rockland, K. S., Andresen, J., Cowie, R. J. & Robinson, D. L. Single axon analysis of pulvinocortical connections to several visual areas in the macaque. Journal of Comparative Neurology 406, 221–250 (1999).Google Scholar

Romanski, L. M., Giguere, M., Bates, J. F. & Goldman-Rakic, P. S. Topographic organization of medial pulvinar connections with the prefrontal cortex in the rhesus monkey. Journal of Comparative Neurology 379, 313–332 (1997).Google Scholar

Rovó, Z., Ulbert, I. & Acsády, L. Drivers of the primate thalamus. Journal of Neuroscience 32, 17894 (2012).CrossRef Google Scholar PubMed

Roy, S. et al. Segregation of short-wavelength-sensitive (S) cone signals in the macaque dorsal lateral geniculate nucleus. European Journal of Neuroscience 30, 1517–1526 (2009).CrossRef Google Scholar PubMed

Saalmann, Y. B. & Kastner, S. Cognitive and perceptual functions of the visual thalamus. Neuron 71, 209–223 (2011).Google Scholar

Saalmann, Y. B., Pinsk, M. A., Wang, L., Li, X. & Kastner, S. The pulvinar regulates information transmission between cortical areas based on attention demands. Science 337, 753 (2012).Google Scholar

Schmahmann, J. D. & Pandya, D. N. Anatomical investigation of projections from thalamus to posterior parietal cortex in the rhesus monkey: a WGA-HRP and fluorescent tracer study. Journal of Comparative Neurology 295, 299–326 (1990).Google Scholar

Schneider, K. A. Subcortical mechanisms of feature-based attention. Journal of Neuroscience 31, 8643 (2011).Google Scholar

Schneider, K. A. & Kastner, S. Effects of sustained spatial attention in the human lateral geniculate nucleus and superior colliculus. Journal of Neuroscience 29, 1784 (2009).Google Scholar

Schneider, K. A., Richter, M. C. & Kastner, S. Retinotopic organization and functional subdivisions of the human lateral geniculate nucleus: a high-resolution functional magnetic resonance imaging study. Journal of Neuroscience 24, 8975 (2004).Google Scholar

Sclar, G., Maunsell, J. H. R. & Lennie, P. Coding of image contrast in central visual pathways of the macaque monkey. Vision Research 30, 1–10 (1990).Google Scholar

Sherman, S. M. & Guillery, R. W. On the actions that one nerve cell can have on another: Distinguishing “drivers” from “modulators.” Proceedings of the National Academy of Sciences of the United States of America 95, 7121 (1998).CrossRef Google Scholar PubMed

Sherman, S. M. & Guillery, R. W. Functional connections of cortical areas: a new view from the thalamus (MIT Press, 2013).CrossRef Google Scholar

Sherman, S. M. & Koch, C. The control of retinogeniculate transmission in the mammalian lateral geniculate nucleus. Experimental Brain Research 63, 1–20 (1986).CrossRef Google Scholar PubMed

Shipp, S. The functional logic of cortico–pulvinar connections. Philosophical Transactions of the Royal Society of London. Series B: Biological Sciences 358, 1605–1624 (2003).Google Scholar

Shiu, L.-P. & Pashler, H. Spatial attention and vernier acuity. Vision Research 35, 337–343 (1995).Google Scholar

Smaers, J. B., Gómez-Robles, A., Parks, A. N. & Sherwood, C. C. Exceptional evolutionary expansion of prefrontal cortex in great apes and humans. Current Biology 27, 714–720 (2017).Google Scholar

Smith, A. T., Cotton, P. L., Bruno, A. & Moutsiana, C. Dissociating vision and visual attention in the human pulvinar. Journal of Neurophysiology 101, 917–925 (2009).Google Scholar

Smith, P. L. & Ratcliff, R. An integrated theory of attention and decision making in visual signal detection. Psychological Review 116, 283–317 (2009).Google Scholar

Snow, J. C., Allen, H. A., Rafal, R. D. & Humphreys, G. W. Impaired attentional selection following lesions to human pulvinar: evidence for homology between human and monkey. Proceedings of the National Academy of Sciences of the United States of America 106, 4054 (2009).Google Scholar

Song, K., Meng, M., Chen, L., Zhou, K. & Luo, H. Behavioral oscillations in attention: rhythmic α pulses mediated through θ band. Journal of Neuroscience 34, 4837 (2014).Google Scholar

Stepniewska, I. & Kaas, J. H. Architectonic subdivisions of the inferior pulvinar in New World and Old World monkeys. Visual Neuroscience 14, 1043–1060 (1997).Google Scholar

Steriade, M. Acetylcholine systems and rhythmic activities during the waking–sleep cycle. Progress in Brain Research 145, 179–196 (2004).Google Scholar

Strumpf, H. et al. The role of the pulvinar in distractor processing and visual search. Human Brain Mapping 34, 1115–1132 (2013).Google Scholar

Szczepanski, S. M. & Kastner, S. Shifting attentional priorities: control of spatial attention through hemispheric competition. Journal of Neuroscience 33, 5411 (2013).Google Scholar

Szczepanski, S. M., Konen, C. S. & Kastner, S. Mechanisms of spatial attention control in frontal and parietal cortex. Journal of Neuroscience 30, 148 (2010).Google Scholar

Theyel, B. B., Llano, D. A. & Sherman, S. M. The corticothalamocortical circuit drives higher-order cortex in the mouse. Nature Neuroscience 13, 84–88 (2010).Google Scholar

Thompson, K. G., Biscoe, K. L. & Sato, T. R. Neuronal basis of covert spatial attention in the frontal eye field. Journal of Neuroscience 25, 9479 (2005).Google Scholar

Treisman, A. M. & Gelade, G. A feature-integration theory of attention. Cognitive Psychology 12, 97–136 (1980).Google Scholar

Ungerleider, L. G., Desimone, R., Galkin, T. W. & Mishkin, M. Subcortical projections of area MT in the macaque. Journal of Comparative Neurology 223, 368–386 (1984).CrossRef Google Scholar PubMed

Usrey, W. M. & Alitto, H. J. Visual functions of the thalamus. Annual Review of Vision Science 1, 351–371 (2015).Google Scholar

Usrey, W. M., Reppas, J. B. & Reid, R. C. Paired-spike interactions and synaptic efficacy of retinal inputs to the thalamus. Nature 395, 384–387 (1998).CrossRef Google Scholar

VanRullen, R. Perceptual cycles. Trends in Cognitive Sciences 20, 723–735 (2016).Google Scholar

VanRullen, R., Carlson, T. & Cavanagh, P. The blinking spotlight of attention. Proceedings of the National Academy of Sciences of the United States of America 104, 19204 (2007).Google Scholar

Ward, R., Danziger, S., Owen, V. & Rafal, R. Deficits in spatial coding and feature binding following damage to spatiotopic maps in the human pulvinar. Nature Neuroscience 5, 99–100 (2002).Google Scholar

Warner, C. E., Kwan, W. C. & Bourne, J. A. The early maturation of visual cortical area MT is dependent on input from the retinorecipient medial portion of the inferior pulvinar. Journal of Neuroscience 32, 17073 (2012).Google Scholar

Wells, M. F., Wimmer, R. D., Schmitt, L. I., Feng, G. & Halassa, M. M. Thalamic reticular impairment underlies attention deficit in Ptchd1Y/− mice. Nature 532, 58–63 (2016).Google Scholar

Whittington, M. A., Traub, R. D., Kopell, N., Ermentrout, B. & Buhl, E. H. Inhibition-based rhythms: experimental and mathematical observations on network dynamics. International Journal of Psychophysiology 38, 315–336 (2000).Google Scholar

Wiesel, T. N. & Hubel, D. H. Spatial and chromatic interactions in the lateral geniculate body of the rhesus monkey. Journal of Neurophysiology 29, 1115–1156 (1966).Google Scholar

Wilke, M., Turchi, J., Smith, K., Mishkin, M. & Leopold, D. A. Pulvinar inactivation disrupts selection of movement plans. Journal of Neuroscience 30, 8650 (2010).Google Scholar

Wimmer, R. D. et al. Thalamic control of sensory selection in divided attention. Nature 526, 705–709 (2015).Google Scholar

Womelsdorf, T. et al. Modulation of neuronal interactions through neuronal synchronization. Science 316, 1609 (2007).Google Scholar

Wróbel, A., Bekisz, M. & Waleszczyk, W. 20 Hz bursts of activity in the cortico-thalamic pathway during attentive perception. In Oscillatory Event-Related Brain Dynamics (eds. Pantev, C., Elbert, T. & Lütkenhöner, B.), 311–324 (Springer US, 1994).Google Scholar

Wunderlich, K., Schneider, K. A. & Kastner, S. Neural correlates of binocular rivalry in the human lateral geniculate nucleus. Nature Neuroscience 8, 1595–1602 (2005).Google Scholar

Xu, X. et al. A comparison of koniocellular, magnocellular and parvocellular receptive field properties in the lateral geniculate nucleus of the owl monkey (Aotus trivirgatus). Journal of Physiology 531, 203–218 (2001).Google Scholar

Yeshurun, Y. & Carrasco, M. Attention improves or impairs visual performance by enhancing spatial resolution. Nature 396, 72–75 (1998).Google Scholar

Yeterian, E. H. & Pandya, D. N. Corticothalamic connections of the posterior parietal cortex in the rhesus monkey. Journal of Comparative Neurology 237, 408–426 (1985).Google Scholar

Zeater, N., Cheong, S. K., Solomon, S. G., Dreher, B. & Martin, P. R. Binocular visual responses in the primate lateral geniculate nucleus. Current Biology 25, 3190–3195 (2015).Google Scholar

Zhang, P., Zhou, H., Wen, W. & He, S. Layer-specific response properties of the human lateral geniculate nucleus and superior colliculus. NeuroImage 111, 159–166 (2015).Google Scholar

Zhang, Y., Chen, Y., Bressler, S. L. & Ding, M. Response preparation and inhibition: the role of the cortical sensorimotor beta rhythm. Neuroscience 156, 238–246 (2008).Google Scholar

Zhou, H., Schafer, R. J. & Desimone, R. Pulvinar-cortex interactions in vision and attention. Neuron 89, 209–220 (2016).CrossRef Google Scholar PubMed

Zikopoulos, B. & Barbas, H. Prefrontal projections to the thalamic reticular nucleus form a unique circuit for attentional mechanisms. Journal of Neuroscience 26, 7348 (2006).Google Scholar

Zikopoulos, B. & Barbas, H. Pathways for emotions and attention converge on the thalamic reticular nucleus in primates. Journal of Neuroscience 32, 5338 (2012).Google Scholar

Book contents

Chapter 17 - The Thalamus in Attention

Summary

Keywords

Access options

References

Save book to Kindle

Save book to Dropbox

Save book to Google Drive