Rafael Malach scite author profile

To what extent do all brains work alike during natural conditions? We explored this question by letting five subjects freely view half an hour of a popular movie while undergoing functional brain imaging. Applying an unbiased analysis in which spatiotemporal activity patterns in one brain were used to "model" activity in another brain, we found a striking level of voxel-by-voxel synchronization between individuals, not only in primary and secondary visual and auditory areas but also in association cortices. The results reveal a surprising tendency of individual brains to "tick collectively" during natural vision. The intersubject synchronization consisted of a widespread cortical activation pattern correlated with emotionally arousing scenes and regionally selective components. The characteristics of these activations were revealed with the use of an open-ended "reverse-correlation" approach, which inverts the conventional analysis by letting the brain signals themselves "pick up" the optimal stimuli for each specialized cortical area.

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Object-related activity revealed by functional magnetic resonance imaging in human occipital cortex.

Malach

Reppas

Benson

et al. 1995

Proc. Natl. Acad. Sci. U.S.A.

1,630

100

1,165

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The stages of integration leading from local feature analysis to object recognition were explored in human visual cortex by using the technique of functional magnetic resonance imaging. Here we report evidence for object-related activation. Such activation was located at the lateral-posterior aspect of the occipital lobe, just abutting the posterior aspect of the motion-sensitive area MT/V5, in a region termed the lateral occipital complex (LO). LO showed preferential activation to images of objects, compared to a wide range of texture patterns. This activation was not caused by a global difference in the Fourier spatial frequency content of objects versus texture images, since object images produced enhanced LO activation compared to textures matched in power spectra but randomized in phase. The preferential activation to objects also could not be explained by different patterns of eye movements: similar levels of activation were observed when subjects fixated on the objects and when they scanned the objects with their eyes. Additional manipulations such as spatial frequency filtering and a 4-fold change in visual size did not affect LO activation. These results' suggest that the enhanced responses to objects were not a manifestation of low-level visual processing. A striking demonstration that activity in LO is uniquely correlated to object detectability was produced by the "Lincoln" illusion, in which blurring of objects digitized into large blocks paradoxically increases their recognizability. Such blurring led to significant enhancement of LO activation. Despite the preferential activation to objects, LO did not seem to be involved in the final, "semantic," stages of the recognition process. Thus, objects varying widely in their recognizability (e.g., famous faces, common objects, and unfamiliar three-dimensional abstract sculptures) activated it to a similar degree. These results are thus evidence for an intermediate link in the chain of processing stages leading to object recognition in human visual cortex.Extensive research involving single-unit recording, anatomical studies, and behavioral experiments in the monkey (for review see, e.g., ref. 1) have suggested that object recognition is a multistage process leading progressively from localized feature analysis in primary visual cortex, through a sequence of cortical areas, to more global object recognition in the inferotemporal cortex. More recently, studies in human visual cortex using positron emission tomography (PET) revealed selective activation of ventral and temporal regions associated with face recognition and attention to shapes (2-4). However, the exact location and nature of the areas contributing to object recognition in the human cerebral cortex remain unclear.Using functional magnetic resonance imaging (fMRI) (5-8), which has relatively high spatial resolution and allows repeated testing, we looked for potential cortical "building blocks" participating in the object recognition process. METHODSThis study is based on fMRI scans cond...

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Differential Processing of Objects under Various Viewing Conditions in the Human Lateral Occipital Complex

Grill-Spector

Kushnir

Edelman

et al. 1999

Neuron

1,100

128

813

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The invariant properties of human cortical neurons cannot be studied directly by fMRI due to its limited spatial resolution. Here, we circumvented this limitation by using fMR adaptation, namely, reduction of the fMR signal due to repeated presentation of identical images. Object-selective regions (lateral occipital complex [LOC]) showed a monotonic signal decrease as repetition frequency increased. The invariant properties of fMR adaptation were studied by presenting the same object in different viewing conditions. LOC exhibited stronger fMR adaptation to changes in size and position (more invariance) compared to illumination and viewpoint. The effect revealed two putative subdivisions within LOC: caudal-dorsal (LO), which exhibited substantial recovery from adaptation under all transformations, and posterior fusiform (PF/LOa), which displayed stronger adaptation. This study demonstrates the utility of fMR adaptation for revealing functional characteristics of neurons in fMRI studies.

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Rafael Malach

Intersubject Synchronization of Cortical Activity During Natural Vision

Object-related activity revealed by functional magnetic resonance imaging in human occipital cortex.

Differential Processing of Objects under Various Viewing Conditions in the Human Lateral Occipital Complex

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