Aphasia Loss or impairment of language comprehension or production
Language Impairments PRODUCTION Spontaneous Speech Fluent versus nonfluent Unintended or “off” words (paraphasias) Word finding difficulties (anomia) Poor articulation Prosody (aprosodia) Repetition Single words Phrases Writing (agraphia) COMPREHENSION Auditory Single words Phrases Commands (Token Test) Syntax Visual (Reading - alexia) Single words Phrases
Broca’s Aphasia Bouillaud (1825): large series of speech loss with frontal lesions Marc Dax (1836): LH damage, right hemiplegia, & aphasia linked Paul Broca (1861) convincing evidence of speech laterality; Tan “Nous parlons avez l’hemispheregauche” Paul Broca ( )
Wernicke’s Aphasia Carl Wernicke (1874) reports that temporal lobe lesion disturbs comprehension. Developed connectionism model of language and predicated conduction aphasia
Aphasias Conduction –Fluent speech –Good comprehension –Poor repetition –Poor naming Possibly lesion in arcuate fasciculus or its connections in inferior parietal lobule Wernicke’s –Fluent speech –Poor comprehension –Poor repetition –Poor naming Posterior superior temporal lobe lesion (first temporal gyrus)
Aphasias Transcortical Sensory –Fluent speech –Poor comprehension –Good repetition –Poor naming Lesion in posterior temporo-parietooccipital junction while sparing Wernicke’s area Anomic –Fluent speech –Good comprehension –Good repetition –Poor naming Temporal or temporo- parietal lesion
Wernicke & TCS Aphasia
Aphasias Broca’s –Non-fluent speech –Good comprehension –Poor repetition –Poor naming Posterior inferior frontal lesion Global –Non-fluent speech –Poor comprehension –Poor repetition –Poor naming Lesion involves frontal, temporal and parietal lobes, Including Broca’s and Wernicke’s area
Aphasias Mixed Transcortical –Non-fluent speech –Poor comprehension –Good repetition –Poor naming Anterior and posterior association cortex lesions while sparing perisylvian language region Transcortical Motor –Non-fluent speech –Good comprehension –Good repetition –Poor naming Lesion involves frontal lobe but spares Broca’s area
Linguistic processes
Turn of the century models for Reading and Speaking
Reading Aloud (Grapheme to Phoneme conversion – GPC)
TOKEN TEST: Point to the large yellow circle Linguistic Competence of the Disconnected RH Vocabulary vs syntactical competence
Lexical Language in the disconnected RH -?+ NG -?+ LB GPCSyntacticalAuditory Compreh. Reading Compreh. Split Brain Patients Token test assesses auditory comprehension but more so syntactical competence
Auditory comprehension GPC (via Rhyme) Reading GPC but may index visual familiarity)
Lexical Language in the disconnected RH NG LB GPCSyntacticalAuditory Compreh. Reading Compreh. Split Brain Patients Token test assesses auditory comprehension but more so syntactical competence
LH RH
Syntactical incompetence of the RH (poor prepositions) but competence for nouns and adjectives, with control for word frequency (i.e., visual familiarity)
Not all nouns are alike RH competence for concrete and imageable Concrete but not imageable Encephalon Matter Welt Imprint Morass plaza Not Concrete but imageable Alone Affectionate Wise Joy Fun blessing
Right Hemisphere Ability
Lexical Language in the disconnected RH - - GPC - - Syntax Concrete only Nouns -+++ NG -+++ LB Aud. Phonetics Aud. Comp. Read Comp. Split Brain Patients
Isolation of grapho-motor module In VJ, writing dissociates from other language abilities. –Writing in RH –All others LH In JW & VP all language abilities are localized in LH. Unusual brain organization - dissociations
Gross functions across split brain series +--++NG -++++PS Writing ++++VP --++RY, AA, DR, VJ +?++LB, JW SemanticsSpeechReading Compreh. Auditory Compreh. Split Brain Patients
Patient O.A.
Linguistic Competence that requires intact interhemispheric language systems Alternative meanings –Narrative processing, inference –Metaphor –Humor –Indirect request Technique suitable for fast, short presentations only – <180 ms
inference
How to test sustained visual attention in one visual field: Z-lens
Ongoing inference in sentential readings The pizza was too hot to cry
Hough (1990) - Narrative Integration
Polysemantic Processing Revising interpretations of non-humorous discourse Sally became too bored to finish the history book. She had already spent five years writing it. (or we saw her duck) Same initial inference generated by controls and RHD, but RHD failed to abandon dominant inference for alternative interpretation consistent with both sentences (Brownell 1996) RHD performance = normals’ for integrating across sentence boundaries. Johnny missed the wild pitch. The windshield was shattered. Related Findings –RH maintains activation over longer prime-target intervals. –RH primed by weakly associated primes (foot, cry, glass for cut) as much as by direct prime (scissors for cut). –LH shows only priming for direct prime Conclusions RH generates extensive (multiple) representational sets for meanings implied or novel LH inhibits alternatives and focuses on dominant reading. –LH excels at selecting & processing one (dominant) interpretation.
Priming for Polysemy Dominant context: The dog played with the ball Subordinate context: She bought a new dress for the ball Associated: ROUND (dominant) or DANCE (subordinate)
By 40 ms LH (RVF) has collapsed all subordinate (alternative) word meanings or never allowed them to emerge (I put my money in the bank)
Deep dyslexia
Deep dyslexia - Reliance on diffuse representational system of RH
New word learning shifts child’s attention from thematic (RH) to categorical (LH)
RH = vocab 13y, syntax 5y
Aphasia with multiple languages Bilingual recovery –Parallel recovery –Differential or nonparallel recovery L1 recovers faster (“Ribot’s law”—old before new) L2 recovers faster (“Pitres’ law”—frequent first) Due to different or overlapping brain areas, or what? Recovery implies that actual language centers weren’t destroyed, only cut off or inhibited.
Recovery from aphasia L1 and L2 may recover independently –implies some differential representation in the brain. Case – L1 recovery only: Dimitrijevic (1940). Woman grew up speaking Bulgarian & Yiddish (both L1), As adult, she learned Serbian (L2) which she spoke daily for 25y. She kept “forgetting” Bulgarian until brain injury at 60y resulted in loss of Serbian in speech (however, she still could understand L2)
Second language recovery 1/3rd of multilinguals do not recover L1, but L2 or L3 Case L2 recovery: Minkowski (1928). Acquisition: –L1=Swiss German –L2 schooled in standard German –L3 became fluent in French, then stroke after 19 y Recovery: –spoke French (L3) for 3 weeks, then German (L2), but incapable of using Swiss German (L1) for 6 months. –Suddenly L1 returned, to detriment of French (L3).
Factors involved in L2 recovery Minkowski: Languages are not spatially separated, but exert mutual inhibition in delicate balance (“Great Powers of Europe metaphor” th c). –Lesion disrupts balance and can suppress any language (including L1). –In support, “lost” languages can be recovered faster than usually required to “learn from scratch” –Little evidence of right hemisphere involvement in L2 But Broca’s area in polyglots is no larger than monolinguals (e.g. Sauerwein spoke 54 languages with a normal-sized Broca’s area, Fabbro 2001)
Experimental inhibition (Ojemann & Whitaker 1978) Dutch inhibited English inhibited Both inhibited Neither inhibited
Recovery of dead languages Case: Grasset (1884). Patient knew only French. After stroke, he could speak only single words in Latin that he learned from Mass. Case: Pötzl (1925). Classics professor suffered a stroke and was only able to express himself in dead languages (Latin & ancient Greek), which he acquired through reading alone.
Bilingual representation –Sometimes only one language returns not always L1 –Production, comprehension and translation separable, even within a language. –Comprehension often spared in all languages –Inconsistent evidence for macroscopic localization differences for multiple languages (VHS Mind # 26)
PET vs Lesion data Why is PET data so much more focal?
Individual Differences in Language Lateralization
Agnosia Greek for “lack of knowledge” –Coined by Sigmund Freud Inability to recognize people or objects even when basic sensory modalities, such as vision, are intact. Modality-specific impairment
“ What & Where” – Ventral and Dorsal Visual Pathways Established with electophysiology, lesion, neuropsychology and neuroimaging data
What-Where Distinction Object task: Same objects? Spatial Task” Same locations?
Three Types of Object in the World Words – Objects – Faces Alexia – Agnosias – Prosopagnosia Recognition involved three (or four) stages of processing: 1.Sensory input 2.Perception (able to form percepts) 3.Categorization (able to associate percept to meaning) 4.Identification (able to identify specific example)
Agnosia Apperceptive –Object recognition failure due to perceptual processing Associative –Perceptual processing intact but subject cannot use information to recognize objects
Apperceptive Agnosia Impaired global structure (gestalt) extraction 1.Diffuse brain injury (CO poisoning) 2.Intact acuity, brightness discrimination, color vision and other elementary capabilities 3.Real images recognized better than illustrations; motion better than static (more cues)
Gestalt Principles
Example of connectedness
Gestalt principles
Case D.F. (Milner & Goodale, 1995) Classic Apperceptive Agnosic Severly impaired FORM perception Damage to V2, V3, V4- - Ventral Stream Intact abilities should reflect operation of dorsal stream
Dissociating What from How Orientation reports: IMPAIRED –verbal –matching Posting behavior SPARED Implication: Orientation & shape representations available for guiding action D.F. Control Perceptual matching Visuomotor posting
Associative Agnosia Impaired matching percept to memory 1.Occipitotemporal damage 2.Draw accurately without recognizing 3.Identify objects through other modalities (touch, verbal description) 4.Not perceptual except copying is slow and sequential
Prosopagnosia or Face Blindness
Prosopagnosia Specific inability to recognize faces Are faces and other objects in the world represented in fundamentally different ways in memory? Does face-memory depend on fundamentally different brain systems?
Are Faces Special?
Objects represented in parts and holistically Faces represented holistically
Prosopagnosia Impairment of identity of familiar faces 1.Posterior artery (medial OT, right sided usually) 2.Perception and categorization is intact. Patient can still determine gender, ethnicity, age, emotions, everything but identity 3.Conscious recognition impaired 4.Nonconscious (implicit) recognition intact in some – GSRs, EPs, forced decision 5.Are faces a unique set of stimuli? Or difficult to discriminate highly similar exemplars from each other (e.g., prosopagnosic farmer who couldn’t recognize faces but could recognize his cows) ISSUE: Are faces and other objects in the world represented in fundamentally different ways in memory?
Single cell recording in IT
Other agnosias Auditory Agnosia inability to recognize specific sounds in the context of intact hearing. –pure word deafness –sound agnosia –receptive amusia (agnosia for music). Somatosensory Agnosia (Astereognosis) difficulty perceiving objects through tactile stimulation though basic tactile sensation intact. Simultanagnosia, Inability to recognize a whole image although individual details are recognized. Color anomia can discriminate colors on tasks but cannot name colors or point to colors named by examiner. (color recognition problem, not color perception which is Central Achromatosia)
Alexia (with or w/o agraphia Impairment in letter recognition and reading 1.OP damage 2.Word blindness – inability to read
Patterns of dissociation support this idea: