Interhemispheric differences in extrastriate areas during visuo-spatial selective attention

Functional asymmetries between hemispheres have been reported in relation to spatial and temporal information processing. Here we used functional magnetic resonance imaging to investigate the influence of task on activity in extrastriate areas during selective spatial attention. During bilateral visual stimulation, subjects attended either the left or the right hemifield. Within the attended side, the task was either to discriminate the orientation of the stimuli or to judge their temporal characteristics. The bilateral stimulation caused symmetric activation of the left and right occipitotemporal junction. Within these regions we investigated the modulatory effects attention and the effect of task upon these. A region of interest approach was used to compare activity in the two hemispheres. The signal at occipitotemporal junction was analyzed in a 2 x 2 x 2 factorial design, with attended side, type of task, and hemisphere as factors. We found that, in both hemispheres, activity was higher when attention was directed to the contralateral hemifield compared with the ipsilateral hemifield. However, the size of these contralateral attentional modulations was dependent on the task. In the left occipitotemporal junction, contralateral modulations were stronger during the temporal task, while in the right occipitotemporal junction contralateral modulations were stronger during orientation discrimination. Overall, this pattern of activity lead to a significant three-way interaction between attended side, type of task, and hemisphere. We conclude that task characteristics influence brain activity associated with spatial selective attention. Our results support the hypothesis that temporal and orientation processing are preferentially associated with the left and right hemisphere, respectively.     

左侧空间忽略患者关联性注意捕捉效应的研究

目的:探讨脑损伤后致左侧空间忽略患者的注意捕捉效应。方法:本研究对右侧大脑半球损伤伴左侧忽略的患者及健康被试各20例,分别进行神经心理学背景测试及关联性注意捕捉效应测试,观察左侧空间忽略患者与健康被试之间注意捕捉效应的差异,分析影响关联性注意捕捉效应强度的因素。结果:①与健康对照组相比,左侧空间忽略组的数字捕捉正确率明显降低(P<0.01)。②健康对照组:无论干扰刺激颜色与目标刺激颜色是否一致,左侧视野出现干扰刺激时的数字捕捉正确率均明显低于右侧视野出现干扰刺激时(P<0.01);无论干扰刺激在目标刺激的左侧或右侧,当干扰刺激颜色与目标刺激颜色一致时,数字捕捉正确率低于干扰刺激颜色与目标刺激颜色不一致时(P<0.01,0.05)。③左侧空间忽略组:无论干扰刺激颜色与目标刺激颜色是否一致,右侧视野出现干扰刺激时的数字捕捉正确率均低于左侧视野出现干扰刺激时(P<0.05);左侧视野出现的干扰刺激颜色与目标刺激颜色一致或不一致时,对数字捕捉正确率的影响差异无统计学意义,而右侧视野出现的干扰刺激颜色与目标刺激颜色一致时,数字捕捉正确率低于颜色不一致时(P<0.05)。结论:左侧空间忽略患者的注意功能下降,但无论对于健康受试者或者左侧空间忽略患者,符合目标刺激颜色特征的干扰刺激均能够增强非随意性地注意捕捉效应。     

Effects of subjective preference of colors on attention-related occipital theta oscillations

Human daily behaviors are often affected by subjective preferences. Studies have shown that physical responses are affected by unconscious preferences before conscious decision making. Accordingly, attention-related neural activities could be influenced by unconscious preferences. However, few neurological data exist on the relationship between visual attention and subjective preference. To address this issue, we focused on lateralization during visual attention and investigated the effects of subjective color preferences on visual attention-related brain activities. We recorded electroencephalograph (EEG) data during a preference judgment task that required 19 participants to choose their preferred color from 2 colors simultaneously presented to the right and left hemifields. In addition, to identify oscillatory activity during visual attention, we conducted a control experiment in which the participants focused on either the right or the left color without stating their preference. The EEG results showed enhanced theta (4-6 Hz) and decreased alpha (10-12 Hz) activities in the right and left occipital electrodes when the participants focused on the color in the opposite hemifield. Occipital theta synchronizations also increased contralaterally to the hemifield to which the preferred color was presented, whereas the alpha desynchronizations showed no lateralization. The contralateral occipital theta activity lasted longer than the ipsilateral occipital theta activity. Interestingly, theta lateralization was observed even when the preferred color was presented to the unattended side in the control experiment, revealing the strength of the preference-related theta-modulation effect irrespective of visual attention. These results indicate that subjective preferences modulate visual attention-related brain activities.     

单侧后顶叶皮质过度活动对空间定向功能的影响

摘要 目的：探讨单侧后顶叶皮质的过度活动是否会造成对侧同源脑区的功能抑制并影响空间定向功能。 方法：按照一定的入选标准选取健康受试者30人,采用兴奋性间歇性短阵快速脉冲刺激,随机对左/右侧后顶叶皮质进行真/假刺激,结合注意网络测试系统评定受试者视空间注意功能的变化。 结果：间歇性短阵快速脉冲刺激右侧后顶叶皮质,可以提高警觉及定向功能（P＜0.05）;刺激左侧后顶叶皮质,定向功能受损（P＜0.05）。 结论：右侧后顶叶是空间定向活动的关键脑区,左侧后顶叶过度活动可以导致右侧后顶叶功能抑制。建立双侧半球间新的竞争性平衡,对实现单侧后顶叶损害空间定向功能的康复具有重要意义。     

Cerebral correlates of alerting, orienting and reorienting of visuospatial attention: an event-related fMRI study

The identification of brain systems contributing to different aspects of visuospatial attention is of both clinical and theoretical interest. Cued target detection tasks provide a simple means to dissociate attentional subcomponents, such as alerting, orienting or reorienting of attention. Event-related functional magnetic resonance imaging (fMRI) was used to study neural correlates of these distinct attentional processes. Volunteers were scanned while performing a centrally cued target detection task. Four different types of trials (no cue, neutral cue, valid cue and invalid cue trials) with targets appearing either in the right or left hemifield were randomly intermixed. Behaviourally, the data provided evidence for alerting, spatial orienting and reorienting of attention. Neurally, the alerting effect was seen in bilaterally increased extrastriatal blood oxygenation level-dependent (BOLD) activity in neutral as compared to no cue trials. Neural correlates of spatial orienting were seen in anterior cingulate cortex, which was more active during valid as compared to neutral cue trials. Neural correlates of reorienting of attention, that is, higher BOLD activity to invalid as compared to validly cued trials were evident in several brain regions including left and right intraparietal sulcus, right temporo-parietal junction and middle frontal gyrus bilaterally. The data suggest that frontal and parietal regions are specifically involved in reorienting rather than orienting attention to a spatial position. Alerting effects were seen in extrastriate regions which suggest that increased phasic alertness results in a top-down modulation of neural activity in visual processing areas.     

Occultation oculaire et négligence spatiale unilatérale. Intérêt en rééducation

The use of eye-patches allows to modulate the visual information treating process. Twelve subjects with a left unilateral spatial neglect, randomly divided into three groups — non treated, treated by right eye complete patching, treated by right hemifield patching — were assessed at 1 month and 3 months after acute episode, by means of functional and neuropsychological tests. Results in the subjects treated by complete eye-patch [5]show an improvement of all the assessment parameters whatever the unilateral spatial neglect seriousness degree may be. The progression is less convincing in the patients treated by eye-patch in right hemifield. The effects of the different modalities of occultation interpreted on the basis of anatomo-physiological and psychophysiological patterns of attention, suggest the role of ocular occultation in the initial, voluntary and directed, coven attention recovery and secondary of the automatic and divided overt attention.     

Anatomic dissociation of selective and suppressive processes in visual attention

Visual spatial attention is associated with activation in parietal regions as well as with modulation of visual activity in ventral occipital cortex. Within the parietal lobe, localisation of activity has been hampered by variation in individual anatomy. Using fMRI within regions of interest derived from individual functional maps, we examined the response of superior parietal lobule, intraparietal sulcus, and ventral occipital cortex in 11 normal adults as attention was directed to the left and right visual hemifields during bilateral visual stimulation. Activation in ventral occipital cortex was augmented contralateral to the attended hemifield (P < 0.006), while intraparietal activation was augmented ipsilaterally (P < 0.009), and superior parietal lobule showed no modulation of activity as a function of attended hemifield. These findings suggest that spatial enhancement of relevant stimuli in ventral occipital cortex is complemented by an intraparietal response associated with suppression of, or preparation of a reflexive shift of attention toward, irrelevant stimuli. The spatial attention system in superior parietal cortex, in contrast, may be driven to equal degrees by currently attended stimuli and by stimuli that are potential targets of attention.     

The Spatial and Temporal Deployment of Voluntary Attention across the Visual Field

Several studies have addressed the question of the time it takes for attention to shift from one position in space to another. Here we present a behavioural paradigm which offers a direct access to an estimate of voluntary shift time by comparing, in the same task, a situation in which subjects are required to re-engage their attention at the same spatial location with a situation in which they need to shift their attention to another location, all other sensory, cognitive and motor parameters being equal. We show that spatial attention takes on average 55 ms to voluntarily shift from one hemifield to the other and 38 ms to shift within the same hemifield. In addition, we show that across and within hemifields attentional processes are different. In particular, attentional spotlight division appears to be more difficult to operate within than across hemifields.     

Differential cortical activation during voluntary and reflexive saccades in man

A saccade involves both a step in eye position and an obligatory shift in spatial attention. The traditional division of saccades into two types, the "reflexive" saccade made in response to an exogenous stimulus change in the visual periphery and the "voluntary" saccade based on an endogenous judgement to move gaze, is supported by lines of evidence which include the longer onset latency of the latter and the differential effects of lesions in humans and primates on each. It has been supposed that differences between the two types of saccade derive from differences in how the spatial attention shifts involved in each are processed. However, while functional imaging studies have affirmed the close link between saccades and attentional shifts by showing they activate overlapping cortical networks, attempts to contrast exogenous with endogenous ("covert") attentional shifts directly have not revealed separate patterns of cortical activation. We took the "overt" approach, contrasting whole reflexive and voluntary saccades using event-related fMRI. This demonstrated that, relative to reflexive saccades, voluntary saccades produced greater activation within the frontal eye fields and the saccade-related area of the intraparietal sulci. The reverse contrast showed reflexive saccades to be associated with relative activation of the angular gyrus of the inferior parietal lobule, strongest in the right hemisphere. The frequent involvement of the right inferior parietal lobule in lesions causing hemispatial neglect has long implicated this parietal region in an important, though as yet uncertain, role in the awareness and exploration of space. This is the first study to demonstrate preferential activation of an area in its posterior part, the right angular gyrus, during production of exogenously triggered rather than endogenously generated saccades, a finding which we propose is consistent with an important role for the angular gyrus in exogenous saccadic orienting.     

Neural mechanisms associated with attention to temporal synchrony versus spatial orientation: an fMRI study

Previous neuropsychological and functional imaging studies have suggested that the right hemisphere is crucially involved in spatial cognition. By contrast, much less is known about the putative left hemisphere specialization for aspects of temporal cognition. Accordingly, we studied with functional magnetic resonance imaging the neural mechanisms underlying attention to stimulus onset synchrony or orientational congruence with identical pairs of geometric figures. In each trial, two rhombuses were presented, each 4 degrees peripheral to a central fixation cross, in the left and right visual hemifields. In half of the trials, subjects were asked to judge and indicate via button presses whether the rhombuses appeared simultaneously. In the other half of the trials, subjects indicated whether the orientation of the rhombuses was the same (Factor 1, task, temporal synchrony, orientation). In half of the trials, subjects responded with their right hand and in the other half with their left hand (Factor 2, hand, right, left). Data were analyzed using SPM99 and a random-effects model. Attention to orientation differentially activated right temporo-occipital cortex. Attention to stimulus onset synchrony activated left anterior superior temporal gyrus, left inferior parietal cortex, left medial frontal gyrus, and right operculum. Activation of right temporo-occipital cortex for attention to stimulus orientation is in good agreement with previous functional neuroimaging studies of stimulus orientation. More importantly, activation of a predominantly left-hemispheric network with attention to stimulus onset synchrony extends the results of previous functional imaging, psychophysical, and neuropsychological studies of temporal processing.     

Asymmetric modulation of human visual cortex activity during 10 degrees lateral gaze (fMRI study)

We used BOLD fMRI to study the differential effects of the direction of gaze on the visual and the ocular motor systems. Fixation of a target straight ahead was compared to fixation of a target 10 degrees to the right and 10 degrees to the left from gaze straight ahead, and to eyes open in complete darkness in thirteen healthy volunteers. While retinotopic coordinates remained the same in all fixation conditions, the fixation target shifted with respect to a head-centered frame of reference. During lateral fixation, deactivations in higher-order visual areas (one ventral cluster in the lingual and fusiform gyri and one dorsal cluster in the postero-superior cuneus) and, as a trend, activations in early visual cortical areas were found predominantly in the hemisphere contralateral to the fixation target. We propose that visual processing is performed predominantly in the hemisphere contralateral to gaze direction, even during small gaze shifts into one visual hemifield. The excitability of visual neurons may be modulated depending on eye position to construct a head-centered frame of reference from a retinotopic input, thus allowing perceptual stability of space during eye movements. A further finding was that BOLD signal increases in fronto-parietal ocular motor and attentional structures were more pronounced during lateral than central fixation.     

An interface to enhance mobility for people with hemispatial neglect

The objective was to develop and test a control interface to enable people with hemispatial neglect to maneuver a powered wheelchair with increased attention to their environment. A single case study was conducted using a female (aged 72 years) who had a right cerebro vascular accident five years earlier. She drove a powered wheelchair through 20 different test courses (mazes) while a computer recorded frequency of looking to the left (left checks) and an observer recorded visual targets missed and wheelchair collisions with walls and obstacles. The Mann-Whitney test was used to determine significant differences in left checks, left collisions, right collisions, and percent left checks targets missed between baseline and strategy phases. With the interface strategy, the subject significantly increased the number of left checks and missed fewer left targets in the test course. These results indicate that a powered-wheelchair control interface shows promise in enabling people with mild hemispatial neglect to maneuver a powered chair with greater environmental awareness and ease.     

Visual search and memory search engage extensive overlapping cerebral cortices: an fMRI study

Previous studies have investigated neural correlates of visual search and memory search independently, but none of those studies examined whether cortical regions involved in these searches are overlapping or segregated by directly comparing the two types of search. In this study, we compared the cortical regions involved in visual search and memory search in the same functional magnetic resonance imaging (fMRI) experiment run on the same subjects, using identical stimuli and time courses of stimulus presentation. The right dorsolateral prefrontal cortex (DLPFC), the left frontal eye field (FEF), the right precuneus and cuneus, and the left cerebellum were activated by both visual search and memory search. We suggest that the right DLPFC is associated with the process of monitoring and manipulating multiple elements, while the left FEF is involved in cognitive planning. We also propose that the right precuneus and cuneus as well as the left cerebellum are responsible for both spatial and nonspatial shifts of attention, including attentional shifts in long-term memory, although each of these regions has a slightly different role.     

右侧额顶网络在空间注意认知过程中的作用机制

目的:探讨右侧额顶网络(FPN)与视空间注意认知功能的关联性和作用机制.方法:选取志愿受试者60人参加本实验,随机分为顶叶组和额叶组.采用持续短阵快速脉冲(cTBS)经颅磁刺激(rTMS)右侧背外侧前额叶(DLPFC)和后顶叶皮质(DPC)后进行注意网络测试(ANT),所有受试者均按照随机顺序进行真/假刺激.结果:持续短阵快速脉冲经颅磁刺激施加于前额叶和后顶叶,不同提示和刺激类型的平均反应时均无明显改变.右侧后顶叶抑制,警觉和定向功能受损(P＜0.05);右侧额叶抑制,执行功能受损(P＜0.05),而定向功能增强(P＜0.05).结论:在视空间注意过程中,右侧后顶叶是定向功能的关键区,右侧前额叶是执行功能的关键区,并且右侧额顶区之间存在竞争性抑制现象.     

Study on the occurrence and neural bases of hemispatial neglect with different reference frames

Yue Y, Song W, Huo S, Wang M. Study on the occurrence and neural bases of hemispatial neglect with different reference frames.ObjectivesTo study the distributions and the neural correlates of left hemispatial neglect with different reference frames.DesignData were collected from patients with right brain injury who participated in a case series.SettingHospital departments of rehabilitation and neurology.ParticipantsRight brain-damaged patients (N=110).InterventionsNot applicable.Main Outcome MeasuresThe frequency of left hemispatial neglect with different reference frames was investigated, and the respective brain lesions were displayed and analyzed.ResultsNot all subjects finished predesigned neglect tests because of their condition: 8 of the 55 neglect patients were unable to complete the test for classification. Thirty (63.83%) of 47 subjects with neglect displayed both allocentric and egocentric neglect, while 17 subjects showed pure egocentric neglect. The lesions in the inferior frontal gyrus, precentral gyrus, postcentral gyrus, superior temporal gyrus (STG), middle temporal gyrus (MTG), insula, and surrounding white matters were more frequent in the neglect group than in the control group. Compared with the egocentric neglect group, the lesions in the right STG, MTG, lenticular nucleus, and the surrounding white matter were damaged more frequently in the group displaying both allocentric and egocentric neglect.ConclusionsMore than half of the subjects with left neglect after right brain injury have both egocentric and allocentric neglect. The right inferior frontal gyrus, precentral gyrus, postcentral gyrus, STG, MTG, insula, and the surrounding white matter are associated with left hemispatial neglect. Left allocentric neglect is associated with the right STG, MTG, and lenticular nucleus.     

Spatio-temporal indications of sub-cortical involvement in leftward bias of spatial attention

A leftward bias is well known in humans and animals, and commonly related to the right hemisphere dominance for spatial attention. Our previous fMRI study suggested that this bias is mediated by faster conduction from the right to left parietal cortices, than the reverse (Siman-Tov et al., 2007). However, the limited temporal resolution of fMRI and evidence on the critical involvement of sub-cortical regions in orienting of spatial attention suggested further investigation of the leftward bias using multi-scale measurement. In this simultaneous EEG-fMRI study, healthy participants were presented with face pictures in either the right or left visual fields while performing a central fixation task. Temporo-occipital event related potentials, time-locked to the stimulus onset, showed an association between faster conduction from the right to the left hemisphere and higher fMRI activation in the left pulvinar nucleus following left visual field stimulation. This combined-modal finding provides original evidence of the involvement of sub-cortical central attention-related regions in the leftward bias. This assertion was further strengthened by a DCM analysis designated at cortical (i.e., inferior parietal sulcus; IPS) and sub-cortical (pulvinar nucleus) attention-related nodes that revealed: 1. Stronger inter-hemispheric connections from the right to left than vice versa, already at the pulvinar level. 2. Stronger connections within the right than the left hemisphere, from the pulvinar to the IPS. This multi-level neural superiority can guide future efforts in alleviating attention deficits by focusing on improving network connectivity.     

Multisensory stimulation with or without saccades: fMRI evidence for crossmodal effects on sensory-specific cortices that reflect multisensory location-congruence rather than task-relevance

During covert attention to peripheral visual targets, presenting a concurrent tactile stimulus at the same location as a visual target can boost neural responses to it, even in sensory-specific occipital areas. Here, we examined any such crossmodal spatial-congruence effects in the context of overt spatial orienting, when saccadic eye-movements were directed to each peripheral target or central fixation maintained. In addition, we tested whether crossmodal spatial-congruence effects depend on the task-relevance of visual or tactile stimuli. On each trial, subjects received spatially congruent (same location) or incongruent (opposite hemifields) visuo-tactile stimulation. In different blocks, they made saccades either to the location of each visual stimulus, or to the location of each tactile stimulus; or else passively received the multisensory stimulation. Activity in visual extrastriate areas and in somatosensory parietal operculum was modulated by spatial congruence of the multisensory stimulation, with stronger activations when concurrent visual and tactile stimuli were both delivered at the same contralateral location. Critically, lateral occipital cortex and parietal operculum showed such crossmodal spatial effects irrespective of which modality was task relevant; and also of whether the stimuli were used to guide eye-movements or were just passively received. These results reveal crossmodal spatial-congruence effects upon visual and somatosensory sensory-specific areas that are relatively 'automatic', determined by the spatial relation of multisensory input rather than by its task-relevance.     

The left parietal and premotor cortices: motor attention and selection

It is well established that the premotor cortex has a central role in the selection of movements. The role of parts of the parietal cortex in movement control has proved more difficult to describe but appears to be related to the preparation and the redirection of movements and movement intentions. We have referred to some of these processes as motor attention. It has been known since the time of William James that covert motor attention can be directed to an upcoming movement just as visuospatial attention can be directed to a location in space. While some parietal regions, particularly in the right hemisphere, are concerned with covert orienting and the redirecting of covert orienting it may be useful to consider other parietal regions, in the anterior inferior parietal lobule and in the posterior superior parietal lobule, particularly in the left hemisphere, as contributing to motor attention. Such parts of the parietal lobe are activated in neuroimaging experiments when subjects covertly prepare movements or switch intended movements. Lesions or transcranial magnetic stimulation (TMS) affect the redirecting of motor attention. The difficulties apraxic patients experience when sequencing movements may partly be due to an inability to redirect motor attention from one movement to another. The role of the premotor cortex in selecting movements is also lateralized to the left hemisphere. Damage to left hemisphere movement selection mechanisms may also contribute to apraxia. If, however, it remains intact after a stroke then the premotor cortex may contribute to the recovery of arm movements. A group of patients with unilateral left hemisphere lesions and impaired movements in the contralateral right hand was studied. Functional magnetic resonance imaging showed that in some cases the premotor cortex in the intact hemisphere was more active when the stroke-affected hand was used. TMS in the same area in the same patients had the most disruptive effect on movements. In summary, patterns of motor impairment and recovery seen after strokes can partly be explained with reference to the roles of the parietal and premotor cortices in motor attention and selection.     

Limb activation effects in hemispatial neglect

OBJECTIVE: To assess the efficacy of passive and active limb movement to improve visual scanning in patients with hemispatial neglect. DESIGN: Before-after trial: behavioral analyses of a case series. SETTING: Stroke rehabilitation unit in a tertiary care hospital. PARTICIPANTS: Nine individuals with right-hemisphere stroke (mean time poststroke, 19.5 mo) and left-sided neglect, as assessed by the Sunnybrook Bedside Neglect Battery. INTERVENTION: Active left limb movement (button push; n=3) or passive left limb movement (n=8) with functional electric stimulation (FES) administered during visual scanning testing. MAIN OUTCOME MEASURES: Performance on visual scanning tests involving naming of letters and numbers. RESULTS: Both active and passive movement significantly improved target detection on the left side, but not on the right side, on the visual scanning task. Positive results were seen in 2 of 3 active movement patients and 6 of 8 passive movement patients. CONCLUSIONS: Both active and FES-stimulated passive movements are potential techniques for the treatment of hemispatial neglect.     

Spatial attention to thermal pain stimuli in subjects with visual spatial hemi-neglect: extinction, mislocalization and misidentification of stimulus modality

One approach to the study of disordered spatial attention is to carry out tests of extinction, in which stimuli are detected on the left when they are presented on the left alone, but not when both sides are stimulated simultaneously in a dual simultaneous stimulation (DSS) protocol. Extinction has been documented for multiple sensory modalities, but not for thermal pain stimuli, to our knowledge. We now test the hypothesis that subjects with visual spatial neglect (hemi-neglect) will have alterations in thermal pain sensation which are related to abnormal spatial attention. The results demonstrate that thermal pain extinction of hot and cold pain stimuli occurs in a proportion of subjects with hemi-neglect. In the subjects with visual spatial hemi-neglect but without thermal pain extinction, the sensation of the thermal pain stimulus on the affected (left) side was not extinguished but was often localized to the unaffected (right) side, and the submodality of the stimulus (cold or hot) was often misidentified. Ratios indicating the magnitude of extinction, mislocalization and misidentification were significantly larger on the left side of subjects with visual spatial neglect than in healthy controls or in controls with stroke but without hemineglect. The proportion of subjects with thermal pain extinction, mislocalization, or misidentification was significantly higher in subjects with hemi-neglect than those in either control group. These results demonstrate that disordered attention exerts a powerful effect upon the perception of both the location and the quality of thermal pain stimuli.