1 Perception Chris Rorden Lecture 8 Vision and
![37 Ventral vs Dorsal damage (Goodale et al. [1994] Curr Biol. 4: 604 -610)](https://slidetodoc.com/presentation_image/3e97125b98af4050be5fbd99249b2f4e/image-37.jpg "37 Ventral vs Dorsal damage (Goodale et al. [1994] Curr Biol. 4: 604 -610)")
- Slides: 37
1 Perception • Chris Rorden • Lecture 8: Vision and perception • Low level visual deficits: • Visual field defects • Blindsight • Achromatopsia : : cortical colorblindness (V 4) • Akinetopsia : : motion perception (MT/V 5) • Agnosias : : apperceptive, associative, prosop- (FFA) • ‘How’ versus ‘what’ www. mricro. com
2 Vision l Human vision: Lots of real-estate
3 Visual Pathway l l l Each eye sees both left and right visual field. Ipsilateral information crosses over at optic chiasm. Some connections to superior colliculi. – l Reflexive eye movments Others go to thalamus (lateral geniculate nuclei) and then cortex.
4 Visual Defects l Field defects reveal anatomical injury A. Monocular blindness B. C. D. E. F. G. Bitemporal hemianopia Homonymous hemianopia Upper quadrantanopia Lower quadrantanopia Homonymous hemianopia
5 V 1 Primary visual cortex (V 1) lies in calcarine fissure. l Complete damage leads to Homonymous hemianopia. l Partial damage leads to scotomas l
6 V 1 – retinotopic mapping V 1 is retinotopic: distorted spatial map of visual scene l Fovea has massively over represented. l
7 V 1 damage and blindsight l l l People with damage to V 1 fail to report objects presented in their field defect. However, when forced to guess, they can accurately point to location of unseen visual stimulus! Can also accurately report direction of motion. Weiskrantz et al. , 1974
8 Implications of Blindsight l l V 1 is crucial for conscious awareness. What explains blindsight? Why do only 20% of V 1 patients show blindsight? – – Incomplete damage to V 1? Islands of spared tissue (Gazzaniga, 1994). Typically seen in people who had injury while young – neural plasticity? Small number of indirect connections to later cortical visual centers? Visual connections to colliculi?
9 The visual processing stream l Three major streams of vision: 1. 2. 3. Subcortical Dorsal Ventral Different streams do different things…
10 Cortical visual processing Dorsal system is fast, but color blind. Helps with motor control (Where/How). Parietal MT V 5 M-ganglion cells Magno LGN P-ganglion cells Parvo LGN V 1 V 2 V 3 V 2 V 4 Ventral system is slow, but detailed. Helps with object identification (What). IT cortex
11 Achromatopsia : : V 4 Achromatopsia is usually caused by bilateral damage to V 4 - lingual and fusiform gyri (occipitotemporal junction) and is characterized by an inability to identify or discriminate colour l Still able to perceive form and motion l
12 Akinetopsia (Motion Blindness) l Zilles reported first case of akinetopsia. Pure cases are rare, as requires bilateral injury. – Case LM - akinetopsia l l l 43 yr old. Sinus vein thrombosis V 5 damaged bilaterally - V 1 spared Could not see movement of objects but could see still objects. People would suddenly appear Diagnosed as agoraphobic Can see movements/reach for/catch very slow moving objects (< 10°/s)
13 V 5 timecourse l l Beckers & Zeki (1995) examined brief V 5 disruption using TMS. Motion perception disrupted most with V 5 stimulation up to 30 ms after visual stimulation onset V 1 stimulation also partially disrupts motion perception, but later (60 -70 ms after VS onset). Takes 30 -50 ms for signals to go from V 1 to V 5 – – – Direct route to V 5? Reafference to V 1? May explain motion performance in blindsight?
14 Agnosias l Three reasons why people might fail to recognize objects: – – – Perceptual Deficit: e. g. acuity, field cut, loss of color vision Apperceptive agnosia: unable to perceive full shape of object despite intact low level processing. Associative agnosia: ability to perceive shape, but unable to recognize it.
15 Apperceptive agnosia l Intact low-level perception – – – acuity brightness discrimination color vision Unable to recognize objects l Unable to extract global structure. l
16 Associative agnosia Able to see whole form of shapes l No problem copying figures l However, unable to recognize the objects l
17 Associative agnosia l Theoretical explanations: – Disconnection between visual representation and language? – Damage to visual memory representation? – Slightly impaired perception?
18 Anatomical considerations l Apperceptive agnosia: – l right inferior parietal lobe (Middle Cerebral Artery) Associative agnosia: – left occipitotemporal
19 Prosopagnosia Wigan (1844), Quaglino & Borelli (1867), Hughlings Jackson (1872), Charcot & Bernard (1883), Wilbrand (1892) l Inability to visually recognize faces l Even a spouse’s face does not seem familiar l
20 Prosopagnosia - specificity l Seems specific to faces. Patients can still recognize others by: – Silhouette – Voice – Clothing l Note: not like amnesia
21 Prosopagnosia Is face processing special? l Or, are faces simply the most difficult objects we discriminate? l Most people withprosopagnosia have difficulty recognizing differences within categories: l – – – l types of car porcelain fixtures breed of dog Also, often suffer achromatopsia
22 Faces are difficult l l Most objects are identified by unique components However, faces have the same basic components: nose, eyes, ears, hair
23 Are faces special? l Farah tried to find objects as difficult as faces: – Spectacle frames – Undergrads recognized 87% of faces, 67% of eyeglass frames (faces easier) – LH recognized only 64% of faces, and 63% of eyeglass frames
24 Are faces special?
25 Are faces special?
26 Are faces special? l l l Farah examined inversion effect Sequential matching task Undergrads: – – l Upright: 94% correct Inverted: 82% correct Prosopagnosic LH – – Upright: 58% Inverted: 72%
27 Double dissociations l Assal, Faure & Anderes (1984) report zooagnosic farmer MX – – l Lost ability to recognise cows Still recognises faces Bruyer et al (1983) report reverse – – Fails to recognise faces Intact perception of cows
28 Double Dissociation Faces RB MX If faces are simply difficult, we should not find patients with spared face recognition who are impaired on other tasks. Accuracy l Cows
29 Prosopagnosia l l l Selective to faces in a few patients Unable to recognize faces Able to discriminate equally difficult objects: – – – l Why are ‘pure’ prosopagnosics so rare? – – l cows office furniture spectacle frames Lesions tend to be large? Overlap in processing in most patients? Functional imaging can resolve this question
30 Anatomical considerations l l Fusiform gyrus. Usually bilateral, occasionally right hemisphere only (Landis et al. 1986) Near V 4 (color vision) Functional imaging gives convergent evidence (Sergent & Signoret 1992)
31 Vision in split brain patients l l Commissurotomy is neurosurgical treatment for intractable epilepsy where the Corpus callosum is completely divided. Allows systematic investigation of hemispheric specialization and integration
32 Split brain patients l l By using rapid (tachistoscopic) stimuli we can avoid eye movements. Using chimeric faces, Sperry projected different images to each hemisphere. Most able to return to work within 2 years of surgery. Typically, appear healthy Language ‘man’ Left hand woman
33 Split brain patients l Picture presented in RVF (i. e. to LH) – l Picture presented in LVF (i. e. to RH) – – – l Patient could name or reach for the object correctly with right hand. Patients could not name/describe the object Subjects could reach for the correct object with their left hand Likewise, unable to find a object felt with one hand by using the other hand.
34 Split brain patients l l l Left hemisphere clearly specialized in language. Right hemisphere appears better at copying designs, reading facial expressions, fitting forms in molds Similar effects can be seen in healthy people, e. g. most think A and C look more similar than A and B
35 Cortical visual processing Dorsal system is fast, but color blind. Helps with motor control (Where/How). Parietal MT V 5 M-ganglion cells Magno LGN P-ganglion cells Parvo LGN V 1 V 2 V 3 V 2 V 4 Ventral system is slow, but detailed. Helps with object identification (What). IT cortex
36 Visual Form Agnosia l DF has ventral damage – – Profound agnosia : : can not even tell orientation of object Motor control accurate : : motor system functions accurately. Posting task Patient DF Perceptual matching Posting Controls
37 Ventral vs Dorsal damage (Goodale et al. [1994] Curr Biol. 4: 604 -610) When shown two shapes (left), DF was poor at saying if the shapes were same or different, RV was good at this task. chance 0% DF RV Control 25% DF RV Frequency When asked to grasp an object, DF grasped near the centre (like healthy people), RV was poor at this task. 100% 0% 0 15 30 Distance from centre (mm)
Chris rorden
Chris rorden
Chris rorden
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