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Abstract

Current theoretical approaches to consciousness and vision associate the dorsal cortical pathway, in which magnocellular (M) input is dominant, with nonconscious visual processing and the ventral cortical pathway, in which parvocellular (P) input is dominant, with conscious visual processing. We explored the known differences between M and P contrast-response functions to investigate the roles of these channels in vision. Simulations of contrast-dependent priming revealed that priming effects obtained with unmasked, visible primes were best modeled by equations characteristic of M channel responses, whereas priming effects obtained with masked, invisible primes were best modeled by equations characteristic of P channel responses. In the context of current theoretical approaches to conscious and nonconscious processing, our results indicate a surprisingly significant role of M channels in conscious vision. In a broader discussion of the role of M channels in vision, we propose a neurophysiologically plausible interpretation of the present results: M channels indirectly contribute to conscious object vision via top-down modulation of reentrant activity in the ventral object-recognition stream.

Keywords

priming consciousness perception

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References

Alexander

K. R.

Rajagopalan

A. S.

Seiple

Zemon

V. M.

Fishman

G. A.

(2005). Contrast response properties of magnocellular and parvocellular pathways in retinitis pigmentosa assessed by the visual evoked potential. Investigative Ophthalmology & Visual Science, 46, 2967–2973.

Bar

(2003). A cortical mechanism for triggering top-down facilitation in visual object recognition. Journal of Cognitive Neuroscience, 15, 600–609.

Bar

Kassam

K. S.

Ghuman

A. S.

Boshyan

Schmid

A. M.

Dale

A. M.

. . . Halgren

(2006). Top-down facilitation of visual recognition. Proceedings of the National Academy of Sciences, USA, 103, 449–454.

Boehler

C. N.

Schoenfled

M. A.

Heunze

H. J.

Hopf

J. M.

(2008). Rapid recurrent processing gates awareness in primary visual cortex. Proceedings of the National Academy of Sciences, USA, 105, 8742–8747.

Breitmeyer

B. G.

Öğmen

(2006). Visual masking: Time slices through conscious and unconscious vision. New York, NY: Oxford University Press.

Breitmeyer

B. G.

Öğmen

Ramon

Chen

(2005). Unconscious and conscious priming by forms and their parts. Visual Cognition, 12, 720–736.

Bullier

(2001). Integrated model of visual processing. Brain Research Reviews, 36, 96–107.

Chen

C.-M.

Lakatos

P. S.

Shah

A. S.

Mehta

A. D.

Givre

S. J.

Javitt

D. C.

Schroeder

C. E.

(2007). Functional anatomy and interaction of fast and slow visual pathways in macaque monkeys. Cerebral Cortex, 17, 1561–1569.

Crick

Koch

(2003). A framework for consciousness. Nature Neuroscience, 6, 119–126.

10.

Croner

L. J.

Kaplan

(1995). Receptive fields of P and M ganglion cells across the primate retina. Vision Research, 35, 7–24.

11.

DeYoe

E. A.

van Essen

D. C.

(1988). Concurrent processing streams in monkey visual cortex. Trends in Neurosciences, 11, 219–226.

12.

Dux

P. E.

Visser

T. A. W.

Goodhew

S. C.

Lipp

O. V.

(2010). Delayed reentrant processing impairs visual awareness: An object-substitution-masking study. Psychological Science, 21, 1242–1247.

13.

Enns

J. T.

Di Lollo

(2000). What’s new in visual masking? Trends in Cognitive Sciences, 4, 345–352.

14.

Fahrenfort

J. J.

Scholte

H. S.

Lamme

V. A. F.

(2007). Masking disrupts reentrant processing in human visual cortex. Journal of Cognitive Neuroscience, 19, 1488–1497.

15.

Hughes

H. C.

Nozawa

Kitterle

(1996). Global precedence, spatial frequency channels, and the statistics of natural images. Journal of Cognitive Neuroscience, 8, 197–230.

16.

Hupé

J. M.

James

A. C.

Payne

B. R.

Lomber

S. G.

Girard

Bullier

(1998). Cortical feedback improves discrimination between figure and background by V1, V2 and V3 neurons. Nature, 394, 784–787.

17.

Jehee

J. F. M.

Roelfsema

P. R.

Deco

Murre

J. M. J.

Lamme

V. A. F.

(2007). Interactions between higher and lower visual areas improve shape selectivity of higher level neurons: Explaining crowding phenomena. Brain Research, 1157, 167–178.

18.

Kaplan

Shapley

R. M.

(1986). The primate retina contains two types of ganglion cells, with high and low contrast sensitivity. Proceedings of the National Academy of Sciences, USA, 83, 2755–2757.

19.

Kihlstrom

J. F.

(1996). Perception without awareness of what is perceived, learning without awareness of what is learned. In Velman

(Ed.), The science of consciousness (pp. 23–46). London, England: Routledge.

20.

Kim

C. Y.

Blake

(2005). Psychophysical magic: Rendering the visible ‘invisible.’ Trends in Cognitive Neurosciences, 9, 381–388.

21.

Klotz

Neumann

(1999). Motor activation without conscious discrimination in metacontrast masking. Journal of Experimental Psychology: Human Perception and Performance, 25, 976–992.

22.

Koch

(2004). The quest for consciousness: A neurobiological approach. Englewood, CO: Roberts.

23.

Kveraga

Boshyan

Bar

(2007). Magnocellular projections as the trigger of top-down facilitation in recognition. Journal of Neuroscience, 27, 13232–13240.

24.

Lamme

V. A. F.

(2006). Towards a true neural stance on consciousness. Trends in Cognitive Sciences, 10, 494–501.

25.

Maunsell

J. H. R.

Nealy

T. A.

DePriest

D. D.

(1990). Magnocellular and parvocellular contributions to responses in the middle temporal visual area (MT) of the macaque monkey. Journal of Neuroscience, 10, 3323–3334.

26.

Merigan

W. H.

Maunsell

J. H. R.

(1993). How parallel are the primate visual pathways? Annual Review of Neuroscience, 16, 369–402.

27.

Milner

A. D.

Goodale

M. A.

(1995). The visual brain in action. Oxford, England: Oxford University Press.

28.

Nassi

J. J.

Callaway

E. M.

(2007). Specialized circuits from primary visual cortex to V2 and area MT. Neuron, 55, 799–808.

29.

Nassi

J. J.

Callaway

E. M.

(2009). Parallel processing strategies of the primate visual system. Nature Reviews Neuroscience, 10, 360–372.

30.

Perry

V. H.

Cowey

(1984). Retinal ganglion cells that project to the superior colliculus and pretectum in the macaque monkey. Neuroscience, 12, 1125–1137.

31.

Peyrin

Michel

C. M.

Schwartz

Thut

Seghier

Landis

. . . Vuilleumier

(2010). The neural substrates and timing of top-down processes during coarse-to-fine categorization of visual scenes: A combined fMRI and ERP study. Journal of Cognitive Neuroscience, 22, 2768–2780.

32.

Rafal

Smith

Krantz

Cohen

Brennan

(1990). Extrageniculate vision in hemianopic humans: Saccade inhibition by signals in the blind field. Science, 250, 118–121.

33.

Shelton

Lee

O. L.

Chang

(2004). Extrageniculate mediation of unconscious vision in transcranial magnetic stimulation-induced blindsight. Proceedings of the National Academy of Sciences, USA, 101, 9933–9935.

34.

Singhal

Breitmeyer

Garcia

(2008). Unconscious processing of color and form in metacontrast masking. Attention, Perception, & Psychophysics, 71, 95–103.

35.

Schyns

P. G.

Oliva

(1994). From blobs to boundary edges: Evidence for time- and spatial-scale-dependent scene recognition. Psychological Science, 5, 195–200.

36.

Stoerig

Cowey

(1997). Blindsight in man and monkey. Brain, 120, 535–559.

37.

Tapia

Breitmeyer

B. G.

Shooner

C. R.

(2010). Role of task directed attention in nonconscious and conscious response priming by form and color. Journal of Experimental Psychology: Human Perception and Performance, 36, 74–87.

38.

Ungerleider

L. G.

(1985). The corticocortical pathways for object recognition and spatial perception. In Chagas

Gattas

Gross

(Eds.), Pattern recognition mechanisms (pp. 21–27). Vatican City, Italy: Pontifical Academy of Sciences.

39.

van Essen

D. C.

Anderson

C. H.

Felleman

D. J.

(1992). Information processing in the primate visual system: An integrated systems perspective. Science, 255, 419–423.

40.

Weiskrantz

Warrington

E. K.

Sanders

M. D.

Marshall

(1974). Visual capacity in the hemianopic field following a restricted occipital ablation. Brain, 97, 709–728.

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Visual Consciousness Revisited

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