Xiaofeng Tao scite author profile

more "winter" more "night" more "warm" more "moist" more "rain" more "autumn" Figure 1: Our method enables high-level editing of outdoor photographs. In this example, the user provides an input image (left) and six attribute queries corresponding to the desired changes, such as more "autumn". Our method hallucinates six plausible versions of the scene with the desired attributes (right), by learning local color transforms from a large dataset of annotated outdoor webcams. AbstractWe live in a dynamic visual world where the appearance of scenes changes dramatically from hour to hour or season to season. In this work we study "transient scene attributes" -high level properties which affect scene appearance, such as "snow", "autumn", "dusk", "fog". We define 40 transient attributes and use crowdsourcing to annotate thousands of images from 101 webcams. We use this "transient attribute database" to train regressors that can predict the presence of attributes in novel images. We demonstrate a photo organization method based on predicted attributes. Finally we propose a high-level image editing method which allows a user to adjust the attributes of a scene, e.g. change a scene to be "snowy" or "sunset". To support attribute manipulation we introduce a novel appearance transfer technique which is simple and fast yet competitive with the state-of-the-art. We show that we can convincingly modify many transient attributes in outdoor scenes.

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Neuronal Responses in Visual Area V2 (V2) of Macaque Monkeys with Strabismic Amblyopia

Bai

et al. 2011

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Amblyopia, a developmental disorder of spatial vision, is thought to result from a cascade of cortical deficits over several processing stages beginning at the primary visual cortex (V1). However, beyond V1, little is known about how cortical development limits the visual performance of amblyopic primates. We quantitatively analyzed the monocular and binocular responses of V1 and V2 neurons in a group of strabismic monkeys exhibiting varying depths of amblyopia. Unlike in V1, the relative effectiveness of the affected eye to drive V2 neurons was drastically reduced in the amblyopic monkeys. The spatial resolution and the orientation bias of V2, but not V1, neurons were subnormal for the affected eyes. Binocular suppression was robust in both cortical areas, and the magnitude of suppression in individual monkeys was correlated with the depth of their amblyopia. These results suggest that the reduced functional connections beyond V1 and the subnormal spatial filter properties of V2 neurons might have substantially limited the sensitivity of the amblyopic eyes and that interocular suppression was likely to have played a key role in the observed alterations of V2 responses and the emergence of amblyopia.

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Elevated IOP alters the space–time profiles in the center and surround of both ON and OFF RGCs in mouse

Sabharwal

Seilheimer

Tao

et al. 2017

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

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Glaucoma is a leading cause of blindness worldwide, and is characterized by progressive retinal ganglion cell (RGC) death. An experimental model of glaucoma has been established by elevating the intraocular pressure (IOP) via microbead occlusion of ocular fluid outflow in mice. Studies in this model have found visual dysfunction that varied with adaptational state, occurred before anatomical changes, and affected OFF RGCs more than ON RGCs. These results indicate subtle alterations in the underlying retinal circuitry that could help identify disease before irreversible RGC changes. Therefore, we looked at how RGC function was altered with elevated IOP under both photopic and scotopic conditions. We first found that responses to light offset are diminished with IOP elevation along with a concomitant decrease in receptive field center size for OFF RGCs. In addition, the antagonistic surround strength and size was reduced in ON RGCs. Furthermore, elevation of IOP significantly accelerated the photopic temporal tuning of RGC center responses in both ON and OFF RGCs. We found that some of the IOP-induced functional changes to OFF RGCs relied on ON cross-over pathways, indicating dysfunction in inner retinal circuitry. Overall, these results suggest that IOP alters multiple functions in the retina depending on the adaptational state. They provide a basis for designing multiple functional tests for early detection of glaucoma and for circuit-specific therapeutic targets in treatment of this blinding disease.retinal ganglion cell | glaucoma | IOP | receptive field | multielectrode array G laucoma is one of the leading causes of blindness worldwide (1). It is a progressive disease and most patients are only identified after an irreversible visual deficit is already present (2). Diagnosing patients with subtle functional deficits that occur before this irreversible visual deficit will significantly improve a patient's ability to preserve normal vision.Elevated intraocular pressure (IOP) is a critical risk factor for glaucoma and the central focus of glaucoma treatment (3, 4). Mouse models of glaucoma are also dependent on raising IOP. One method to elevate IOP is to inject microbeads into the eye to block normal fluid outflow (5). Previous studies on this mouse model have found that high IOP causes changes in retinal ganglion cell (RGC) anatomy and eventual cell death leading to irreversible vision loss as seen in glaucoma (5-7). Before these changes, functional properties, such as RGC light sensitivity and photopic receptive field (RF) center size, are altered (8-12). A better understanding of these functional changes may help to detect human disease before irreversible cell death.In addition to RGC changes, behavioral tests have found that spatiotemporal tuning under photopic and scotopic conditions is altered (10). These behavioral studies suggest alteration in additional functional properties related to spatiotemporal tuning, such as scotopic receptive field size, temporal tuning, and the antagonistic surround.To det...

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Early Monocular Defocus Disrupts the Normal Development of Receptive-Field Structure in V2 Neurons of Macaque Monkeys

et al. 2014

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Experiencing different quality images in the two eyes soon after birth can cause amblyopia, a developmental vision disorder. Amblyopic humans show the reduced capacity for judging the relative position of a visual target in reference to nearby stimulus elements (position uncertainty) and often experience visual image distortion. Although abnormal pooling of local stimulus information by neurons beyond striate cortex (V1) is often suggested as a neural basis of these deficits, extrastriate neurons in the amblyopic brain have rarely been studied using microelectrode recording methods. The receptive field (RF) of neurons in visual area V2 in normal monkeys is made up of multiple subfields that are thought to reflect V1 inputs and are capable of encoding the spatial relationship between local stimulus features. We created primate models of anisometropic amblyopia and analyzed the RF subfield maps for multiple nearby V2 neurons of anesthetized monkeys by using dynamic two-dimensional noise stimuli and reverse correlation methods. Unlike in normal monkeys, the subfield maps of V2 neurons in amblyopic monkeys were severely disorganized: subfield maps showed higher heterogeneity within each neuron as well as across nearby neurons. Amblyopic V2 neurons exhibited robust binocular suppression and the strength of the suppression was positively correlated with the degree of hereogeneity and the severity of amblyopia in individual monkeys. Our results suggest that the disorganized subfield maps and robust binocular suppression of amblyopic V2 neurons are likely to adversely affect the higher stages of cortical processing resulting in position uncertainty and image distortion.

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Parotid gland lesions: separate and combined diagnostic value of conventional MRI, diffusion-weighted imaging and dynamic contrast-enhanced MRI

Yuan¹,

Tang²,

Tao³

2016

BJR

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Xiaofeng Tao

Transient attributes for high-level understanding and editing of outdoor scenes

Neuronal Responses in Visual Area V2 (V2) of Macaque Monkeys with Strabismic Amblyopia

Elevated IOP alters the space–time profiles in the center and surround of both ON and OFF RGCs in mouse

Early Monocular Defocus Disrupts the Normal Development of Receptive-Field Structure in V2 Neurons of Macaque Monkeys

Parotid gland lesions: separate and combined diagnostic value of conventional MRI, diffusion-weighted imaging and dynamic contrast-enhanced MRI

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