Elie Lobel

The neural basis of egocentric and allocentric coding of space in humans: a functional magnetic resonance study

Abstract. The spatial location of an object can be represented in the brain with respect to different classes of reference frames, either relative to or independent of the subjects position. We used functional magnetic resonance imaging to identify regions of the healthy human brain subserving mainly egocentric or allocentric (object-based) coordinates by asking subjects to judge the location of a visual stimulus with respect to either their body or an object. A color-judgement task, matched for stimuli, difficulty, motor and oculomotor responses, was used as a control. We identified a bilateral, though mainly right-hemisphere based, fronto-parietal network involved in egocentric processing. A subset of these regions, including a much less extensive unilateral, right fronto-parietal network, was found to be active during object-based processing. The right-hemisphere lateralization and the partial superposition of the egocentric and the object-based networks is discussed in the light of neuropsychological findings in brain-damaged patients with unilateral spatial neglect and of neurophysiological studies in the monkey.

Latencies in fMRI time-series: Effect of slice acquisition order and perception

In BOLD fMRI a detailed analysis of the MRI signal time course sometimes shows time differences between different activated regions. Some researchers have suggested that these latencies could be used to infer the temporal order of activation of these cortical regions. Several effects must be considered, however, before interpreting these latencies. The effect of a slice‐dependent time shift (SDTS) with multi‐slice acquisitions, for instance, may be important for regions located on different slices. After correction for this SDTS effect the time dispersion between activated regions is significantly decreased and the correlation between the MRI signal time course and the stimulation paradigm is improved. Another effect to consider is the latency which may exist between perception and stimulus presentation. It is shown that the control of perception can be achieved using a finger‐spanning technique during the fMRI acquisition. The use of this perception profile rather than an arbitrary waveform derived from the paradigm proves to be a powerful alternative to fMRI data processing, especially with chemical senses studies, when return to baseline is not always correlated to stimulus suppression. This approach should also be relevant to other kinds of stimulation tasks, as a realistic way of monitoring the actual task performance, which may depend on attention, adaptation, fatigue or even variability of stimulus presentation.

Cortical areas activated by bilateral galvanic vestibular stimulation.

Abstract: The brain areas activated by bilateral galvanic vestibular stimulation (GVS) were studied using functional magnetic resonance imaging. In six human volunteers, GVS led to activation in the region of the temporoparietal junction, the central sulcus, and the anterior interior intraparietal sulcus, which may correspond to macaque areas PIVC, 3aV, and 2v, respectively. In addition, activation was found in premotor regions of the frontal lobe, presumably analogous to areas 6pa and 8a in the monkey. Since these areas were not detected in previous studies using caloric vestibular stimulation, they could be related to the modulation of otolith afferent activity by GVS. However, the simple paradigm used did not allow separation of the otolithic and semicircular canal effects of GVS. Further studies must be performed to clarify the question of cortical representation of the otolithic information in the human and monkey brain.

Intraoperative frontal eye field stimulation elicits ocular deviation and saccade suppression.

Cortical stimulation is a useful way of elucidating the cortical control of eye movements. The aim of this study was to determine the type of eye movements evoked in response to intraoperative electrical stimulation of the frontal eye field (FEF) region in a fully awake patient during surgery for a frontal lobe glioma. A train of low-intensity electrical pulses within an area in the precentral gyrus evoked contraversive smooth eye movements (SEM) recorded electro-oculographically. Stimulation of an anterior sub-region of this electrically determined FEF disclosed both SEM and suppression of self-paced saccades. However, electrical stimulation of this region evoked no saccades in agreement with pre-operative fMRI using a self-paced saccade paradigm, which did not show activation within the ipsilateral FEF. In humans, intraoperative FEF stimulation may elicit recordable contraversive SEM, and interfere with oculomotor behaviour, suppressing self-paced saccades.

Cortical Mechanisms of Saccade Generation from Execution to Decision

Abstract: Several cortical areas are involved in the control of ocular motor behavior, but little is known about the cognitive processes occurring prior to saccade triggering. The use of functional brain imaging allows a better understanding of the networks involved specifically in distinct processes of saccade generation. The use of sophisticated visual stimulation paradigms in functional imaging studies suggests that the decision process of where to look when faced with visual alternatives is subserved by a prefrontoparietal network, including the dorsolateral prefrontal cortex.

Prefrontal cortex is involved in internal decision of forthcoming saccades.

Deciding where to look is mandatory to explore the visual world. To study the neural correlates subserving the cognitive phase of self-initiated eye movements in humans, we tested 12 healthy participants, using event-related functional MRI. Changes in the frontal-cortical activity preceding voluntary saccades were studied when the participants freely decided the direction of a forthcoming saccade, compared with a condition in which they had only to prepare an externally cued saccade. Self-initiation of saccades, before their execution, was specifically associated with frontal-lobe activation in the dorsolateral prefrontal cortex, and in the right presupplementary eye field and frontal eye fields, suggesting the roles of these areas in the decision process of where to look when facing two possible visual targets.

Lateralized parietal activity during decision and preparation of saccades.

The posterior parietal cortex is involved in numerous visuospatial tasks, but little is known about the lateralization of these functions. We used functional magnetic resonance imaging to map the posterior parietal areas involved in saccades. Cerebral activation was studied during three different steps of saccadic elaboration: internal Decision of where to direct a horizontal saccade, motor Preparation and saccade Execution. These steps activated distinct areas: Decision and Preparation selectively activated the left posterior parietal cortex (left deep posterior intraparietal sulcus and left medial posterior intraparietal sulcus), whereas Execution activated only the right posterior parietal cortex (right medial posterior intraparietal sulcus). In humans, left but not right posterior parietal cortex might be specifically related to decision making and preparation of forthcoming ocular saccades.