Mechanisms of migraine aura revealed by functional MRI in human visual cortex

Cortical spreading depression (CSD) has been suggested to underlie migraine visual aura. However, it has been challenging to test this hypothesis in human cerebral cortex. Using high-field functional MRI with near-continuous recording during visual aura in three subjects, we observed blood oxygenation level-dependent (BOLD) signal changes that demonstrated at least eight characteristics of CSD, time-locked to percept/onset of the aura. Initially, a focal increase in BOLD signal (possibly reflecting vasodilation), developed within extrastriate cortex (area V3A). This BOLD change progressed contiguously and slowly (3.5 ± 1.1 mm/min) over occipital cortex, congruent with the retinotopy of the visual percept. Following the same retinotopic progression, the BOLD signal then diminished (possibly reflecting vasoconstriction after the initial vasodilation), as did the BOLD response to visual activation. During periods with no visual stimulation, but while the subject was experiencing scintillations, BOLD signal followed the retinotopic progression of the visual percept. These data strongly suggest that an electrophysiological event such as CSD generates the aura in human visual cortex.

Illusory contours activate specific regions in human visual cortex: evidence from functional magnetic resonance imaging.

The neural basis for perceptual grouping operations in the human visual system, including the processes which generate illusory contours, is fundamental to understanding human vision. We have employed functional magnetic resonance imaging to investigate these processes noninvasively. Images were acquired on a GE Signa 1.5T scanner equipped for echo planar imaging with an in-plane resolution of 1.5 x 1.5 mm and slice thicknesses of 3.0 or 5.0 mm. Visual stimuli included nonaligned inducers (pacmen) that created no perceptual contours, similar inducers at the corners of a Kanizsa square that created illusory contours, and a real square formed by continuous contours. Multiple contiguous axial slices were acquired during baseline, visual stimulation, and poststimulation periods. Activated regions were identified by a multistage statistical analysis of the activation for each volume element sampled and were compared across conditions. Specific brain regions were activated in extrastriate cortex when the illusory contours were perceived but not during conditions when the illusory contours were absent. These unique regions were found primarily in the right hemisphere for all four subjects and demonstrate that specific brain regions are activated during the kind of perceptual grouping operations involved in illusory contour perception.

Spreading and synchronization of intrinsic signals in visual cortex of macaque monkey evoked by a localized visual stimulus

Spatio-temporal maps of the occipital cortex of macaque monkeys were analyzed using optical imaging of intrinsic signals. The images obtained during localized visual stimulation (IS) were compared with the images obtained on presentation of a blank screen (IB). We first investigated spontaneous variations of the intrinsic signals by analyzing the 100 IBs for each of the three cortical areas. Slow periodical activation was observed in alternation over the cortical areas. Cross-correlation analysis indicated that synchronization of spontaneous activation only took place within each cortical area, but not between them. When a small, drifting grating (2degreesX2degrees) was presented on the fovea. a dark spot appeared in the optical image at the cortical representation of this retinal location. It spread bilaterally along the border between V1 and V2, continuing as a number of parallel dark bands covering a large area of the lateral surface of V1. Cross-correlation analysis showed that during visual stimulation the intrinsic signals over all of the three cortical areas were synchronized, with in-phase activation of V1 and V2 and anti-phase activation of V4 and V1/V2. The significance of these extensive synergistic and antagonistic interactions between different cortical areas is discussed. (C) 2003 Elsevier B.V. All rights reserved.

Factors affecting the accommodative response to sustained visual tasks

In the absence of adequate visual stimulation accommodation adopts an intermediate resting position, appropriately termed tonic accommodation (TA). A period of sustained fixation can modify the tonic resting position, and indicate the adaptation properties of TA. This thesis investigates various factors contributing to the accommodative response during sustained visual tasks, in particular the adaptation of TA. Objective infra-red optometry was chosen as the most effective method of measurement of accommodation. This technique was compared with other methods of measuring TA and the results found to be well correlated. The inhibitory sympathetic input to the ciliary muscle provides the facility to attenuate the magnitude and duration of adaptive changes in TA. This facility is, however, restricted to those individuals having relatively high levels of pre-task TA. Furthermore, the facility is augmented by substantial levels of concurrent parasympathetic activity. The imposition of mental effort can induce concurrent changes in TA which are predominantly positive and largely the result of an increase in parasympathetic innervation of the ciliary muscle although there is some evidence for sympathetic attentuation at higher levels of TA. In emmetropes sympathetic inhibition can modify the effect of mental effort on the steady-state accommodative response at near. Late-onset myopes (onset after the age of 15 years) have significantlylower values of TA then emmetropes. Similarly, late-onset myopes show lower values of steady-state accommodative response for nearstimuli. The imposition of mental effort induces concurrent increases in TA and steady-state accommodative response in the myopic group which are significantly greater than those for emmetropes. Estimates of TA made under bright empty-field conditions are well correlated with those made under darkroom conditions. The method by which the accommodative loop is opened has no significant effect on the magnitude and duration of post-task shifts in TA induced by a near vision task. Significant differences in the post-task shifts in TA induced by a near vision task exist between emmetropes and late-onset myopes, the post-task shifts being more sustained for the myopic group.

Effects of Altered Prenatal Sensory Stimulation on Postnatal Contingency Learning in Bobwhite Quail Neonates (Colinus Virginianus)

Preterm infants are exposed to high levels of modified early sensory experience in the Neonatal Intensive Care Unit (NICU). Reports that preterm infants show deficits in contingency detection and learning when compared to full-term infants (Gekoski, Fagen, & Pearlman, 1984; Haley, Weinberg, & Grunau, 2006) suggest that their exposure to atypical amounts or types of sensory stimulation might contribute to deficits in these critical skills. Experimental modifications of sensory experience are severely limited with human fetuses and preterm infants, and previous studies with precocial bird embryos that develop in ovo have proven useful to assess the effects of modified perinatal sensory experience on subsequent perceptual and cognitive development. In the current study, I assessed whether increasing amounts of prenatal auditory or visual stimulation can interfere with quail neonates’ contingency detection and contingency learning in the days following hatching. Results revealed that augmented prenatal visual stimulation prior to hatching does not disrupt the ability of bobwhite chicks to recognize and prefer information learned in a contingent fashion, whereas augmented prenatal auditory stimulation disrupted the ability of chicks to benefit from contingently presented information. These results suggest that specific types of augmented prenatal stimulation that embryos receive during late prenatal period can impair the ability to learn and remember contingently presented information. These results provide testable developmental hypotheses, with the goal of improving the developmental care and management of preterm neonates in the NICU setting.

Visual results with the use of prismatic lenses in the treatment of congenital nystagmus: a clinical case

Purpose: It is important to establish a differential diagnosis between the different types of nystagmus, in order to give the appropriate clinical approach to every situation and to improve visual acuity. The nystagmus is normally blocked when the eyes are positioned in a particular way. This makes the child adopt a posture of ocular torticollis that reduces the nistagmiformes movements, improving the vision in this position. A way to promote the blocking of the nystagmic movements is by using prismatic lenses with opposite bases, to block or minimize the oscillatory movements. This results in a vision improvement and it reduces the anomalous head position. There is limited research on the visual results in children with nystagmus after using prisms with opposing bases. Our aim is to describe the impact on the visual acuity (VA ) of theprescription prism lenses in a nystagmus patient starting at 3 months of age. Methods: Case report on thirty month old caucasian male infant, with normal growth and development for their age, with an early onset of horizontal nystagmus at 3 months of age. Ophthalmic examination included slit lamp examination, fundus, refractive study, electrophysiological and magnetic resonance tests, measurement of VA over time with the Teller Acuity Cards (TAC ) in the distance agreed for the age. At age ten months, the mother noted a persistent turn to the right of the child’s head, which became increasingly more severe along the months. There’s no oscillopcia. At 24 months, an atropine refraction showed the following refractive error: 0D.: -1,50, OS: -0,50 and prismatic lens adapting OD 8 Δ nasal base and OE 8 Δ temporal base. Results: Thirty month old child, with adequate development for their age, with onset of idiopatic horizontal nystagmus, at 3 months of age. Normal ocular fundus and magnetic ressoance without alterations, sub-normal results in electrophysiological tests and VA with values below normal for age. At 6 months OD 20/300; OE 20/400; OU 20/300. At 9 months OD 20/250; OE 20/300; OU 20/150 (TAC a 38 cm). At 18 months OD 20/200; OE 20/100; OU 20/80 (TAC at 38 cm), when the head is turned to the right and the eyes in levoversão, the nystagmus decreases in a “neutral” area. At 24 month, with the prismatic glasses, OD 20/200 OE 20/100, OU20/80 (TAC at 54 cm, reference value is 20/30 – 20/100 para OU e 20/40 – 20/100 monocular), there was an increase in the visual acuity. The child did visual stimulation with multimedia devices and using glasses. After adaptation of prisms: at 30 months VA (with Cambridge cards) OD e OE = 6/18. The child improved the VA and reduced the anomalous head position. There is also improvement in mobility and fine motricity. Conclusion: Prisms with opposing bases., were used in the treatment of idiopathic nystagmus. Said prisms were adapted to reduce the skewed position of the head, and to improve VA and binocular function. Monitoring of visual acuity and visual stimulation was done using electronic devices. Following the use of prismatic, the patient improved significantly VA and the anomalous head position was reduced.

Functional imaging of peripheral vision and dorsal stream function in the human cerebral cortex

Visual information processing in brain proceeds in both serial and parallel fashion throughout various functionally distinct hierarchically organised cortical areas. Feedforward signals from retina and hierarchically lower cortical levels are the major activators of visual neurons, but top-down and feedback signals from higher level cortical areas have a modulating effect on neural processing. My work concentrates on visual encoding in hierarchically low level cortical visual areas in human brain and examines neural processing especially in cortical representation of visual field periphery. I use magnetoencephalography and functional magnetic resonance imaging to measure neuromagnetic and hemodynamic responses during visual stimulation and oculomotor and cognitive tasks from healthy volunteers. My thesis comprises six publications. Visual cortex forms a great challenge for modeling of neuromagnetic sources. My work shows that a priori information of source locations are needed for modeling of neuromagnetic sources in visual cortex. In addition, my work examines other potential confounding factors in vision studies such as light scatter inside the eye which may result in erroneous responses in cortex outside the representation of stimulated region, and eye movements and attention. I mapped cortical representations of peripheral visual field and identified a putative human homologue of functional area V6 of the macaque in the posterior bank of parieto-occipital sulcus. My work shows that human V6 activates during eye-movements and that it responds to visual motion at short latencies. These findings suggest that human V6, like its monkey homologue, is related to fast processing of visual stimuli and visually guided movements. I demonstrate that peripheral vision is functionally related to eye-movements and connected to rapid stream of functional areas that process visual motion. In addition, my work shows two different forms of top-down modulation of neural processing in the hierachically lowest cortical levels; one that is related to dorsal stream activation and may reflect motor processing or resetting signals that prepare visual cortex for change in the environment and another local signal enhancement at the attended region that reflects local feed-back signal and may perceptionally increase the stimulus saliency.

Changing the responses of cortical neurons from sub- to suprathreshold using single spikes in vivo.

Action Potential (APs) patterns of sensory cortex neurons encode a variety of stimulus features, but how can a neuron change the feature to which it responds? Here, we show that in vivo a spike-timing-dependent plasticity (STDP) protocol-consisting of pairing a postsynaptic AP with visually driven presynaptic inputs-modifies a neurons' AP-response in a bidirectional way that depends on the relative AP-timing during pairing. Whereas postsynaptic APs repeatedly following presynaptic activation can convert subthreshold into suprathreshold responses, APs repeatedly preceding presynaptic activation reduce AP responses to visual stimulation. These changes were paralleled by restructuring of the neurons response to surround stimulus locations and membrane-potential time-course. Computational simulations could reproduce the observed subthreshold voltage changes only when presynaptic temporal jitter was included. Together this shows that STDP rules can modify output patterns of sensory neurons and the timing of single-APs plays a crucial role in sensory coding and plasticity.DOI:http://dx.doi.org/10.7554/eLife.00012.001.

Metacognition in monkeys during an oculomotor task.

This study investigated whether rhesus monkeys show evidence of metacognition in a reduced, visual oculomotor task that is particularly suitable for use in fMRI and electrophysiology. The 2-stage task involved punctate visual stimulation and saccadic eye movement responses. In each trial, monkeys made a decision and then made a bet. To earn maximum reward, they had to monitor their decision and use that information to bet advantageously. Two monkeys learned to base their bets on their decisions within a few weeks. We implemented an operational definition of metacognitive behavior that relied on trial-by-trial analyses and signal detection theory. Both monkeys exhibited metacognition according to these quantitative criteria. Neither external visual cues nor potential reaction time cues explained the betting behavior; the animals seemed to rely exclusively on internal traces of their decisions. We documented the learning process of one monkey. During a 10-session transition phase, betting switched from random to a decision-based strategy. The results reinforce previous findings of metacognitive ability in monkeys and may facilitate the neurophysiological investigation of metacognitive functions.

Towards high-quality simultaneous EEG-fMRI at 7T: Detection and reduction of EEG artifacts due to head motion.

The enhanced functional sensitivity offered by ultra-high field imaging may significantly benefit simultaneous EEG-fMRI studies, but the concurrent increases in artifact contamination can strongly compromise EEG data quality. In the present study, we focus on EEG artifacts created by head motion in the static B0 field. A novel approach for motion artifact detection is proposed, based on a simple modification of a commercial EEG cap, in which four electrodes are non-permanently adapted to record only magnetic induction effects. Simultaneous EEG-fMRI data were acquired with this setup, at 7T, from healthy volunteers undergoing a reversing-checkerboard visual stimulation paradigm. Data analysis assisted by the motion sensors revealed that, after gradient artifact correction, EEG signal variance was largely dominated by pulse artifacts (81-93%), but contributions from spontaneous motion (4-13%) were still comparable to or even larger than those of actual neuronal activity (3-9%). Multiple approaches were tested to determine the most effective procedure for denoising EEG data incorporating motion sensor information. Optimal results were obtained by applying an initial pulse artifact correction step (AAS-based), followed by motion artifact correction (based on the motion sensors) and ICA denoising. On average, motion artifact correction (after AAS) yielded a 61% reduction in signal power and a 62% increase in VEP trial-by-trial consistency. Combined with ICA, these improvements rose to a 74% power reduction and an 86% increase in trial consistency. Overall, the improvements achieved were well appreciable at single-subject and single-trial levels, and set an encouraging quality mark for simultaneous EEG-fMRI at ultra-high field.

Effet de la transmission cholinergique sur la cartographie fonctionnelle du cortex visuel du rongeur

La transmission cholinergique, et notamment muscarinique, joue un rôle déterminant dans le système nerveux central au niveau de la modulation de la plasticité neuronale. La libération d'ACh dans le cortex visuel est concomitante à la présentation de stimuli visuels. Par son action sur la transmission neuronale corticale, l'ACh module à long terme les réponses à de nouveaux stimuli sensoriels. Dans la présente étude, l'implication du système cholinergique au niveau du développement cortical et de la plasticité inductible chez l'adulte a été étudiée par les techniques d'imagerie optique des signaux intrinsèques et d'immunohistochimie chez le rongeur. Ces deux techniques de cartographie de l'activité corticale nous ont permis d'évaluer, d'une part, l'impact modulatoire de l'acétylcholine (ACh) et de ses récepteurs muscariniques (mAChRs, M1 à M5) sur l'organisation fonctionnelle du cortex visuel chez des souris déficitaires pour les mAChRs et, d'autre part, l'impact de la libération d'ACh lors d'un entraînement visuel, sur le nombre, la nature neurochimique et la localisation au niveau des couches corticales des neurones corticaux activés. L'implication du système cholinergique sur la cartographie du cortex visuel primaire a été étudiée sur les souris génétiquement modifiées délétères (knock out : KO) pour différentes combinaisons de sous-types de mAChRs. L'imagerie des signaux intrinsèques, basée sur les changements de réflectance corticale de la lumière survenant lors de la consommation d'oxygène par les neurones activés, a permis de déterminer, lors de stimulations visuelles, les différentes composantes des propriétés des neurones du cortex visuel. La taille des champs récepteurs des neurones est diminuée lors de l'absence du récepteur M1 ou de la combinaison M1/M3. Le champ visuel apparent est augmenté chez les souris M2/M4-KO mais diminué chez les M1-KO. La finesse des connectivités neuronales (évaluée par la mesure du scatter du signal) est réduite lors de l'absence des récepteurs M2/M4. Finalement, chez les animaux M1/M3-KO, une diminution de l'acuité visuelle est observée. L'effet à long-terme d'un entraînement visuel couplé à une stimulation des neurones cholinergiques sur la distribution et la nature des neurones immunoréactifs au c-Fos, c'est-à-dire les neurones activés, a été évalué. Puisque cette stimulation combinée est en mesure de produire des modifications comportementales, notamment au niveau de l'acuité visuelle, il devenait intéressant de s'attarder aux modifications neuroanatomiques et de déterminer quels éléments de l'équilibre excitateur/inhibiteur sont compromis chez ces animaux. Les résultats obtenus démontrent que les animaux ayant reçu une combinaison de l'entraînement cholinergique et visuel présentent une augmentation du marquage c-Fos comparativement aux animaux n'ayant reçu que la stimulation cholinergique. D'autre part, chez ces animaux, il est possible d'observer des modifications de l'équilibre excitateur/inhibiteur qui correspond au potentiel plastique de la région. En conclusion, ces études démontrent un rôle important du système cholinergique dans le développement, la maturation et la plasticité du système visuel cérébral.

Réactivité posturale et inconfort subjectif induits par un stimulus visuel

Il est bien connu des professionnels de la vision que l’ajustement des verres progressifs sur un patient presbyte peut induire de l’inconfort et des difficultés posturales (Timmis, Johnson, Elliott, & Buckley, 2010). Ces plaintes sont directement associées à l’information visuelle perçue à travers les verres progressifs. Le principal objectif de cette thèse est d’identifier quels sont les paramètres d’un stimulus visuel (p.ex. fréquence temporelle ou vélocité) à l’origine de la perturbation posturale et de l’inconfort. Les distorsions dynamiques perçues à travers des verres progressifs s’apparentent aux mouvements d’un bateau qui roule de droite à gauche ou qui tangue d’avant en arrière. Ce type de stimulation visuelle a été reproduit dans une voute d’immersion en réalité virtuelle avec un sol à texture de damier noir et blanc qui oscillait périodiquement de droite à gauche et d’avant en arrière à différentes fréquences et amplitudes. Les études qui portent sur ce sujet montrent que la réponse posturale induite visuellement augmente avec la vélocité de stimulation et diminue lorsque la fréquence augmente. Cette information peut paraitre contradictoire, car ces deux variables sont liées entre elles par l’amplitude et covarient dans le même sens. Le premier objectif de cette thèse était de déterminer les causes possibles de cette contradiction. En faisant varier la fréquence temporelle de stimulation visuelle, on retrouve deux domaines de réponse posturale. Le premier domaine correspond aux fréquences inférieures à 0,12 Hz. Dans ce domaine, la réponse posturale est visuodépendante et augmente avec la vélocité du stimulus. Le second domaine postural correspond aux fréquences supérieures à 0,25 Hz. Dans ce domaine, la réponse posturale sature et diminue avec l’augmentation de la fréquence. Cette saturation de la réponse posturale semble causée par des limitations biomécaniques et fréquentielles du système postural. D’autres études ont envisagé d’étudier l’inconfort subjectif induit par des stimuli visuels périodiques. Au sein de la communauté scientifique, deux théories principales se confrontent. La théorie sensorielle repose sur les conflits sensoriels induit par le stimulus visuel tandis que la théorie posturale suggère que l’inconfort est la conséquence de l’instabilité posturale. Nos résultats révèlent que l’inconfort subjectif induit par une stimulation visuelle dynamique dépend de la vélocité du stimulus plutôt que de sa fréquence. L’inconfort peut être prédit par l’instabilité naturelle des individus en l’absence de stimulus visuel comme le suggère la théorie posturale. Par contre, l’instabilité posturale induite par un stimulus visuel dynamique ne semble pas être une condition nécessaire et suffisante pour entrainer de l’inconfort. Ni la théorie sensorielle ni la théorie posturale ne permettent à elles seules d’expliquer tous les mécanismes à l’origine de l’inconfort subjectif. Ces deux théories sont complémentaires, l’une expliquant que l’instabilité intrinsèque est un élément prédictif de l’inconfort et l’autre que l’inconfort induit par un stimulus visuel dynamique résulte d’un conflit entre les entrées sensorielles et les représentations acquises par l’individu.

La caractérisation neuromagnétique de l'attention sans réflexion chez les méditants zen dans un contexte d'images visuelles négatives.

L’état d’attention sans réflexion, aussi appelé « mindfulness », a démontré des effets positifs en clinique pour les désordres émotionnels associés à diverses conditions. Le nombre d’études portant sur la caractérisation des substrats neuronaux de cet état attentionnel croît, mais il importe d’investiguer davantage à ce chapitre pour éventuellement améliorer les interventions cliniques. La présente étude compte aider à déterminer, par la magnétoencéphalographie, quelles régions cérébrales sont en corrélation avec le mindfulness chez des experts, i.e. des méditants Zen. Ces derniers cultivent un état dans lequel ils s’abstiennent de rechercher ou de rejeter les phénomènes sensoriels, ce qui en fait d’excellents candidats à la présente étude. Dans un contexte de stimulations visuelles émotionnelles, il fut demandé aux méditants tantôt d’observer les images dans un état de mindfulness (condition expérimentale), tantôt dans un état dit normal (condition contrôle) où aucun effort particulier d’attention n’était requis. Les résultats d’analyse suggèrent que les participants expérimentèrent une intensité émotionnelle moins importante en mindfulness : les cotes subjectives ainsi qu’une réponse magnétique cérébrale reliée aux émotions nommée Potentiel Positif Tardif magnétique (PPTm) suggèrent cela. Cependant, le résultat le plus statistiquement probant dépasse la nature affective des stimuli. Il s’agit d’une diminution temporellement soutenue de l’activité de fréquence gamma au niveau des zones visuelles associatives du lobe temporal droit, sans égard à la nature des images. Également, une suppression de l’activité gamma d’une zone du cortex préfrontal latéral gauche fut observée. Ceci pourrait indiquer une diminution de la conceptualisation des stimuli reliée au langage et aux processus réflectifs du soi.

Asymétries fonctionnelles du cortex visuel observées par spectroscopie proche de l’infrarouge fonctionnelle

Les objectifs de ce mémoire sont d’étudier la rétinotopie et les asymétries fonctionnelles du cortex visuel chez l’humain avec la spectroscopie proche de l’infrarouge fonctionnelle (SPIRf), tout en confirmant la fiabilité de cette technique. Tel qu’attendu, les résultats montrent une activation plus forte dans l’hémisphère controlatéral et dans le cortex haut/bas inverse à l’hémichamp stimulé. Nous avons également mesuré une activation significativement plus forte dans le cortex visuel supérieur (lorsque le champ visuel inférieur était stimulé) que l’activation dans le cortex visuel inférieur (lorsque le champ visuel supérieur était stimulé), surtout lorsque ces stimuli étaient présentés dans le champ visuel droit. Il s’agit de la première étude en SPIRf à observer les asymétries horizontale et verticale du cortex visuel et à ainsi confirmer l’existence de ces asymétries. Cette étude témoigne également de la fiabilité de la SPIRf comme technique d’imagerie pour cartographier le cerveau humain.

A psychophysical and computational analysis of the spatio-temporal mechanisms underlying the flash-lag effect

Several accounts put forth to explain the flash-lag effect (FLE) rely mainly on either spatial or temporal mechanisms. Here we investigated the relationship between these mechanisms by psychophysical and theoretical approaches. In a first experiment we assessed the magnitudes of the FLE and temporal-order judgments performed under identical visual stimulation. The results were interpreted by means of simulations of an artificial neural network, that wits also employed to make predictions concerning the F LE. The model predicted that a spatio-temporal mislocalisation would emerge from two, continuous and abrupt-onset, moving stimuli. Additionally, a straightforward prediction of the model revealed that the magnitude of this mislocalisation should be task-dependent, increasing when the use of the abrupt-onset moving stimulus switches from a temporal marker only to both temporal and spatial markers. Our findings confirmed the model`s predictions and point to an indissoluble interplay between spatial facilitation and processing delays in the FLE.