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

Slides:

Advertisements

Similar presentations

Sensory systems in the brain The visual system. Organization of sensory systems PS 103 Peripheral sensory receptors [ Spinal cord ] Sensory thalamus Primary.

Advertisements

Light Cornea Sclera Optic nerve Lens Vitreus humor Pigment epithelium Fovea Retina Light entering the eye is focused by the cornea and the lens. Then it.

2002/02/05PSYC , Term 2, Copyright Jason Harrison, Visual pathways from here to there to everywhere.

Why Brains Are Ugly. Let’s face it... brains are ugly and complicated looking.

Higher Processing of Visual Information: Lecture III

Blue= rods Green = Cones Pathways from the Retina In the brain, retinal ganglion axons travel to… –the hypothalamus: control bodily rhythms.

1 Biological Neural Networks Example: The Visual System.

COGNITIVE SCIENCE 17 The Visual System: Color Vision Part 2 Jaime A. Pineda, Ph.D.

The Retina has layers of cells

Chapter 10 The Central Visual System. Introduction Neurons in the visual system –Neural processing results in perception Parallel pathway serving conscious.

Bruce Draper Department of Computer Science Colorado State University

Visual Pathways visual hemifields project contralaterally –exception: bilateral representation of fovea! Optic nerve splits at optic chiasm about 90 %

Color vision Different cone photoreceptors have opsin molecules which are differentially sensitive to certain wavelengths of light – these are the physical.

Chapter 10 The Central Visual System. Introduction Neurons in the visual system –Neural processing results in perception Parallel pathway serving conscious.

The visual system Lecture 1: Structure of the eye

Ganglion cells project to the brain via the optic nerve information is projected to contralateral cortex! Visual Pathways.

Visual Learning Instructor: Arnold Glass. Visual Processing Millions of computations are performed on the light patterns that fall on the retina before.

Retina  takes the information from its 100 million photoreceptors about 1 million optic nerve axons.  Interposed between the photoreceptor.

Copyright © 2007 Wolters Kluwer Health | Lippincott Williams & Wilkins Neuroscience: Exploring the Brain, 3e Chapter 10: The Central Visual System.

Vision. Light is electromagnetic energy. One nm = one billionth of a meter The Visible Spectrum.

Higher Visual Processing

Higher Processing of Visual Information Lecture I --- April 2, 2007 by Mu-ming Poo 1.Overview of the Mammalian Visual System 2.Retinotopic Maps and Cortical.

Vision Biology/Psychology Some introductory thoughts Sensory world in general is basically a representation of the real world So, we have a rich.

Mammalian Nervous System

OCEAN MEDICAL CENTER STROKE SERIES. AWARENESS OF VISUAL SEQUELLA OF STROKES.

Lateral Geniculate Nucleus (LGN) 1.Overview of central visual pathway 2.Projection from retina to LGN 3.LGN layers: P and M pathways 4.LGN receptive fields.

1 Computational Vision CSCI 363, Fall 2012 Lecture 3 Neurons Central Visual Pathways See Reading Assignment on "Assignments page"

THE VISUAL SYSTEM: EYE TO CORTEX Outline 1. The Eyes a. Structure b. Accommodation c. Binocular Disparity 2. The Retina a. Structure b. Completion c. Cone.

Unit Ten: The Nervous System: B. Special Senses

The Visual Cortex: Anatomy

Slide 1 Neuroscience: Exploring the Brain, 3rd Ed, Bear, Connors, and Paradiso Copyright © 2007 Lippincott Williams & Wilkins Bear: Neuroscience: Exploring.

Occipital Lobe Videos: –Brain modules 8,9,10, 11 –Consciousness- Blindsight.

Central nervous system (CNS) Brain + Spinal Cord

Understanding sensory-motor integration. ORGANIZATION OF SENSORY SYSTEMS: General perspectives Sensori-motor integration External senses Localize/Detect.

Vision Psychology Some introductory thoughts Sensory world in general is basically a representation of the real world Sensory world in general is.

Visual Neuroscience Visual pathways Retina Photoreceptors Rods Cones Spacing and density ON and OFF pathways Ganglion cells Retinal projections SCN Pretectum.

VISUAL SYSTEM Key points

Maps Plasticity of maps Retinotopic map Last Lecture.

Figure 2.7. Number of neural impulses in selected single cells of the monkey brain when shown differing pictures. These neurons fire the most when a face.

Chapter 1 Vision from a Biological Viewpoint  What is the function of vision?

Exam Written exam will take place on Wednesday June 11, 2014, at 1 – 3 PM, in the room 131 (SDT). After written exam one should sign up for an oral exam,

VS131 Visual Neuroscience

VS131 Visual Neuroscience Lateral Geniculate Nucleus (LGN)

The Eye: III. Central Neurophysiology of Vision L12

Ascending Visual Pathways

Innervation of the Eye and Orbit Part 1: The Optic Nerve and

Human Eye. Structures of the Human Eye Anatomy of the Retina.

1 Copyright © 2014 Elsevier Inc. All rights reserved. Chapter 19 Visual Network Moran Furman.

The visual system Chapter 10. The physical stimulus Light is a wave… …and a particle.

Sensory Neural Systems 5 February 2008 Rachel L. León

LAB #7 VISION, EYEBALL MOVEMENT AND BALANCE SYSTEMS II.

Neuroanatomy. Brain Organization Spinal Cord Anatomy Dorsal Ventral Dorsal Horn: Sensory information in Ventral Horn: Motor information out.

1 Psychology 304: Brain and Behaviour Lecture 31.

1 Perception and VR MONT 104S, Spring 2008 Lecture 3 Central Visual Pathways.

Processing visual information - pathways

Central visual pathways

Vision III: Cortical mechanisms of vision

Neuroscience: Exploring the Brain, 3e

VS142 Visual Neuroscience

The Visual System.

CORTICAL MECHANISMS OF VISION

Visual Cortex Vision Science Lectures in Ophthalmology Curtis Baker.

Optic Nerve Projections

The Visual System: Higher Cortical Mechanisms

Visual Perceptions: Motion, Depth, Form

VS142 Visual Neuroscience

Innervation of the Eye and Orbit Part 1: The Optic Nerve and

Central Visual Pathways

Central visual processing

Week 14: Neurobiology of Vision Part 2

Presentation transcript:

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

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

(Blind spot)

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

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 ……………..

III IV

III IV Forebrain Midbrain Hindbrain

Anterograde Transport of ocular label

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

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

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

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

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

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

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

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”

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

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

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

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

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

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

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

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