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Vision in 1 Lecture Prof. Jack Pettigrew Vision Touch and Hearing Research Centre, University of Queensland 4072 Australia.

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Presentation on theme: "Vision in 1 Lecture Prof. Jack Pettigrew Vision Touch and Hearing Research Centre, University of Queensland 4072 Australia."— Presentation transcript:

1 Vision in 1 Lecture Prof. Jack Pettigrew Vision Touch and Hearing Research Centre, University of Queensland 4072 Australia.

2 Vision: 1.Parallel Visual Pathways: Diversity of retinal ganglion cells and their destinations E.g. Melanopsin and the circadian clock system: SCN, jet lag etc 2. “Ventral” (conscious) vs. “dorsal” (unconscious) visual streams Blindsight: Veridical vs. Non-veridical

3 (Blind spot)

4 Melanopsin-containing light sensitive retinal ganglion cell M M MM M P P DS P LS

5 Parallel Visual Paths: >9 Separate Destinations of Retinal Ganglion Cells 1.SCN of hypothalamus…melanopsin system.CIRCADIAN CLOCK 2.dLGN (4 P & 2M layers)..geniculostriate. CONSCIOUS VISION ………ventral (&dorsal) stream OBJECT ID 3.Pulvinar-LP complex……MT…dorsal stream…..VISUOMOTOR 4.Pretectal complex…………….NEAR REFLEX TRIAD 5.Midbrain superior colliculus………VISUAL ORIENTATION 6.Accessory optic system…………….VISUAL STABILISATION Dorsal TN, lateral TN, medial TN (pitch, roll & yaw) 7. Habenula, raphe etc ……………..

6 III IV

7 III IV Forebrain Midbrain Hindbrain

8 Anterograde Transport of ocular label

9 1.SCN circadian clock Input from melanopsin ganglion cells 24 hr periodic expression of “Clock” genes Interhemispheric oscillator Characterised only in last decade

10 Labelling in Suprachiasmatic Nucleus (SCN): lac-Z-melanopsin construct

11

12 1. SCN circadian clock 2. dLGN geniculo-striate path Huge in primates Binocular vision emphasised: 3 layers for each eye Conscious vision Developmentally plastic V1 Striate cortex

13 1. SCN circadian clock 2. DLGN geniculostriate 3.Pulvinar-LP complex Old tectal system: primary system in most vertebrates Dominated by striate input in primates MT

14 1. SCN 2. dLGN 3.Pulvinar- LP complex 4. Pretectum Near triad, focus, miosis, vergence

15 1. SCN circadian clock 2. DLGN geniculostriate 3.Pulvinar- LP complex Old tectal system 5. Midbrain-Sup.Colliculus: orientation “visual grasp reflex” “hard wired: lateral visual field 4. Pretectum

16 1. SCN 2. dLGN 3.Pulvinar- LP complex 6. Accessory Optic DS ganglion cells Stabilisation Cerebellum Vestibular interaction 4. Pretectum 5. Midbrain- Sup. colliculus

17 1. SCN 2. dLGN 3.Pulvinar- LP complex 6. Accessory Optic 4. Pretectum 5. Midbrain- Sup. colliculus 7. Habenula, Raphe ?? Function Colour spectrum mood Visual input to “switch”

18 V1 P 1. SCN 2. dLGN 3.Pulvinar- LP complex 6. Accessory Optic 4. Pretectum 5. Midbrain- Sup. colliculus 7. Habenula, Raphe

19 V1 MT M M 1. SCN 2. dLGN 3.Pulvinar- LP complex 6. Accessory Optic 4. Pretectum 5. Midbrain- Sup. colliculus 7. Habenula, Raphe M M M

20 V1 MT DM P M M 2. dLGN 3.Pulvinar- LP complex 5. Midbrain- Sup. colliculus Dorsal Stream M M MM

21 V1 MT DM P M M 2. dLGN 3.Pulvinar- LP complex 5. Midbrain- Sup. colliculus Ventral Stream M M MM

22 V1 MT DM P M M 2. dLGN 3.Pulvinar- LP complex 5. Midbrain- Sup. colliculus Ventral Stream M M MM

23 V1 MT DM P M M 2. dLGN 3.Pulvinar- LP complex 5. Midbrain- Sup. colliculus Ventral Stream M M MM

24 V1 MT DM P M M Ventral Stream IT IT visual Cortex in temporal pole: Complex object recognition, including faces (FF area) Highly plastic (lesions here affect visual memory) Major output projection to limbic system, hippocampus

25 Hierarchical; V1 V2 etc IT Multiply interconnected “Apex” of hierarchy is hippocampal cortex Each has complete representation of visual field Functional specialisation (colour, motion,depth etc) Dorsal Stream V1, MT, DM, P Precision place “Where?” M system Unconscious Veridical No illusions V1 V2 MT V5 V3 Faces Places IT 26 DM S1 S2 etc P A1 Ventral Stream V1,V2,V3,…..IT Object identification “What?” P system Conscious Abstract Illusions Multiple visual cortical areas

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