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, Poster présenté à l'European Conference on Visual Perception à Trieste en 2018 et au GDR Vision de 2018 à Paris. Etude de pupillométrie fondamentale : Effet des réponses pupillaires à la luminance et à l'attention sur la discrimination de fréquences spatiales, vol.77
, Les courbes fines grises représentent la taille de la pupille au cours du temps, la courbe noire épaisse superposée représente la moyenne de ces essais, Les courbes bleues représentent les moyennes et intervalles de confiances à 95% en fonction des conditions de luminances des essais figurés, vol.78
, SC : sujet contrôle ; RP : patient atteint de rétinite pigmentaire ; NOHL : patient atteint de neuropathie optique héréditaire de Leber ; Stargardt : patient atteint de maladie de Stargardt. Les cases noires représentent les participants exclus secondairement, Données OCT utilisées dans les analyses PupDyn, vol.84
, Effet de la couleur sur les variables du PCT chez les populations PupDyn : les contrôles en noir, les MS en vert, les RP en rouge et les NOHL en bleu. (A) Temps d'oscillation pupillaire. (B) Fréquence moyenne d'oscillation pupillaire. (C) Variabilité de la fréquence, Annexe Figure, vol.85
, Etude paramétrique préliminaire au PFT : effet de l'amplitude de l'oscillation lumineuse et de la taille du stimulus sur la puissance dans le spectre de l'oscillation de la pupille à une fréquence haute chez un sujet sain, Annexe Figure, vol.86
, Puissance spectrale du signal pupillaire aux fréquences d'intérêt en fonction de la proportion visible du stimulus calculée à partir de l'isoptère V4 lors du PFT plein champ. (A) pour les patients MS ; (B) pour les patients RP et (C) pour les patients NOHL. Les lignes en pointillés représentent les régressions linéaires et sont accompagnées d'un coefficient de Pearson et sa pValue, Annexe Figure, vol.87
, Puissance spectrale du signal pupillaire aux fréquences d'intérêt en fonction de la proportion visible du stimulus calculée à partir de l'isoptère V1 lors du PFT plein champ. (A) pour les patients MS ; et (B) pour les patients NOHL. Les lignes en pointillés représentent les régressions linéaires et sont accompagnées d'un coefficient de Pearson et sa pValue, Annexe Figure, vol.88
, Puissance spectrale du signal pupillaire aux fréquences d'intérêt en fonction de la proportion visible du stimulus calculée à partir de l'isoptère III1 lors du PFT plein champ. (A) pour les patients MS ; et (B) pour les patients NOHL. Les lignes en pointillés représentent les régressions linéaires et sont accompagnées d'un coefficient de Pearson et sa pValue, Annexe Figure, vol.89
, Annexe Figure 90 : Puissance spectrale du signal pupillaire aux fréquences d'intérêt en fonction de la proportion visible du stimulus calculée à partir de l'isoptère V4 lors du PFT localisé. (A) pour les patients MS
, B) pour les patients RP et (C) pour les patients NOHL. Les lignes en pointillés représentent les régressions linéaires et sont accompagnées d'un coefficient de Pearson et sa pValue
, Annexe Figure 91 : Puissance spectrale du signal pupillaire aux fréquences d'intérêt en fonction de la proportion visible du stimulus calculée à partir de l'isoptère V1 lors du PFT localisé. (A) pour les patients MS
, et (B) pour les patients NOHL. Les lignes en pointillés représentent les régressions linéaires et sont accompagnées d'un coefficient de Pearson et sa pValue
, Annexe Figure 92 : Puissance spectrale du signal pupillaire aux fréquences d'intérêt en fonction de la proportion visible du stimulus calculée à partir de l'isoptère III1 lors du PFT localisé. (A) pour les patients MS
, et (B) pour les patients NOHL. Les lignes en pointillés représentent les régressions linéaires et sont accompagnées d'un coefficient de Pearson et sa pValue
, Stimulus utilisé : 4 anneaux concentriques de 2° d'épaisseurs, de 8, 6, 4 et 2° de diamètre externe dont la luminance oscille à 2.27, 1.34, 1.74 et 1.00 Hz (de l'intérieur vers l'extérieur). (B) Résultats obtenus chez 2 volontaires sains : spectre du signal pupillaire lors de l'observation pendant 60, Annexe Figure 93 : Etude paramétrique du PFT : recherche de la précision minimale. (A)
, les droites verticales rouges représentent les fréquences d'intérêt
,
, Annexe Figure 95 : Poster présenté à l'European Conference on Visual Perception en aout 2017 à Berlin portant sur l'analyse spectrale de la perturbation par marquage fréquentiel des mouvements de fixation