scholarly journals Neural organization of speech production: A lesion-based study of error patterns in connected speech

2019 ◽  
Author(s):  
Brielle C Stark ◽  
Alexandra Basilakos ◽  
Gregory Hickok ◽  
Chris Rorden ◽  
Leonardo Bonilha ◽  
...  
Keyword(s):  
Left Hemisphere ◽  
Phonological Processing ◽  
Visual Recognition ◽  
Temporal Cortex ◽  
Occipital Cortex ◽  
Neural Substrates ◽  
Word Naming ◽  
Lesion Volume ◽  
Single Word ◽  
Connected Speech

AbstractWhile numerous studies have explored single-word naming, few have evaluated the behavioral and neural correlates of more naturalistic language, like connected speech, which we produce every day. Here, in a retrospective analysis of 120 participants at least six months following left hemisphere stroke, we evaluated the distribution of word errors (paraphasias) and associated brain damage during connected speech (picture description) and object naming. While paraphasias in connected speech and naming shared underlying neural substrates, analysis of the distribution of paraphasias suggested that lexical-semantic load is likely reduced during connected speech. Using voxelwise lesion-symptom mapping (VLSM), we demonstrated that verbal (real word: semantically related and unrelated) and sound (phonemic and neologistic) paraphasias during both connected speech and naming loaded onto the left hemisphere ventral and dorsal streams of language, respectively. Furthermore, for the first time using both connected speech and naming data, we localized semantically related paraphasias to more anterior left hemisphere temporal cortex and unrelated paraphasias to more posterior left temporal and temporoparietal cortex. The connected speech results, in particular, highlight a gradient of specificity as one translates visual recognition from left temporo-occipital cortex to posterior and subsequently anterior temporal cortex. The robustness of VLSM results for sound paraphasias derived during connected speech was notable, in that analyses performed on sound paraphasias from the connected speech task, and not the naming task, demonstrated significant results following removal of lesion volume variance and related apraxia of speech variance. Therefore, connected speech may be a particularly sensitive task on which to evaluate further lexical-phonological processing in the brain. The results presented here demonstrate the related, though different, distribution of paraphasias during connected speech, confirm that paraphasias arising in connected speech and single-word naming likely share neural origins, and endorse the need for continued evaluation of the neural substrates of connected speech processes.

scholarly journals Shared and Distinct Neuroanatomic Regions Critical for Tool-related Action Production and Recognition: Evidence from 131 Left-hemisphere Stroke Patients

2015 ◽  
Vol 27 (12) ◽  
pp. 2491-2511 ◽  
Author(s):  
Leyla Y. Tarhan ◽  
Christine E. Watson ◽  
Laurel J. Buxbaum
Keyword(s):  
Left Hemisphere ◽  
Mirror Neuron System ◽  
Inferior Frontal Gyrus ◽  
Occipital Cortex ◽  
Neural Substrates ◽  
Middle Temporal Gyrus ◽  
Stroke Patients ◽  
Middle Temporal ◽  
Impaired Performance ◽  
Left Hemisphere Stroke

The inferior frontal gyrus and inferior parietal lobe have been characterized as human homologues of the monkey “mirror neuron” system, critical for both action production (AP) and action recognition (AR). However, data from brain lesion patients with selective impairment on only one of these tasks provide evidence of neural and cognitive dissociations. We sought to clarify the relationship between AP and AR, and their critical neural substrates, by directly comparing performance of 131 chronic left-hemisphere stroke patients on both tasks—to our knowledge, the largest lesion-based experimental investigation of action cognition to date. Using voxel-based lesion-symptom mapping, we found that lesions to primary motor and somatosensory cortices and inferior parietal lobule were associated with disproportionately impaired performance on AP, whereas lesions to lateral temporo-occipital cortex were associated with a relatively rare pattern of disproportionately impaired performance on AR. In contrast, damage to posterior middle temporal gyrus was associated with impairment on both AP and AR. The distinction between lateral temporo-occipital cortex, critical for recognition, and posterior middle temporal gyrus, important for both tasks, suggests a rough gradient from modality-specific to abstract representations in posterior temporal cortex, the first lesion-based evidence for this phenomenon. Overall, the results of this large patient study help to bring closure to a long-standing debate by showing that tool-related AP and AR critically depend on both common and distinct left hemisphere neural substrates, most of which are external to putative human mirror regions.

Neural Substrates of Perceptual Enhancement by Cross-Modal Spatial Attention

2003 ◽  
Vol 15 (1) ◽  
pp. 10-19 ◽  
Author(s):  
John J. McDonald ◽  
Wolfgang A. Teder-Sälejärvi ◽  
Francesco Di Russo ◽  
Steven A. Hillyard
Keyword(s):  
Spatial Attention ◽  
Brain Activity ◽  
Visual Stimuli ◽  
Temporal Cortex ◽  
Electrode Array ◽  
Event Related Potentials ◽  
Occipital Cortex ◽  
Neural Substrates ◽  
Superior Temporal Cortex ◽  
Related Potentials

Orienting attention involuntarily to the location of a sudden sound improves perception of subsequent visual stimuli that appear nearby. The neural substrates of this cross-modal attention effect were investigated by recording event-related potentials to the visual stimuli using a dense electrode array and localizing their brain sources through inverse dipole modeling. A spatially nonpredictive auditory precue modulated visual-evoked neural activity first in the superior temporal cortex at 120–140 msec and then in the ventral occipital cortex of the fusiform gyrus 15–25 msec later. This spatio-temporal sequence of brain activity suggests that enhanced visual perception produced by the cross-modal orienting of spatial attention results from neural feedback from the multimodal superior temporal cortex to the visual cortex of the ventral processing stream.

scholarly journals Neural Substrates Associated With Fatigue Symptom In Fibromyalgia

2022 ◽  
Author(s):  
Hung-Yu Liu ◽  
Pei-Lin Lee ◽  
Kun-Hsien Chou ◽  
Yen-Feng Wang ◽  
Shih-Pin Chen ◽  
...  
Keyword(s):  
Brain Mri ◽  
Temporal Cortex ◽  
Occipital Cortex ◽  
Neural Substrates ◽  
Inferior Temporal Cortex ◽  
Morphometry Analysis ◽  
Fatigue Severity ◽  
Subcortical Regions ◽  
The Right ◽  
Neural Signatures

Abstract Many patients with fibromyalgia (FM) experience fatigue, but the associated biological mechanisms have not been delineated. We aimed to investigate the neural signatures associated with fatigue severity in patients with FM using MRI. We consecutively recruited 138 patients with FM and collected their clinical profiles and brain-MRI data. We categorized the patients into 3 groups based on their fatigue severity. Using voxel-based morphometry analysis and trend analysis, we first identified neural structures showing volumetric changes associated with fatigue severity, and further explored their seed-to-voxel structural covariance networks (SCNs). Results showed decreased bilateral thalamic volumes were associated with higher severity of fatigue. There was a more widespread distribution of the thalamic SCNs to the frontal, parietal, subcortical, and limbic regions in patients with higher fatigue severity. In addition, increased right inferior temporal cortex volumes were associated with higher severity of fatigue. The right inferior temporal seed showed more SCNs distributions over the temporal cortex and a higher strength of SCNs to the bilateral occipital cortex in patients with higher fatigue severity. The thalamus and the right inferior temporal cortex as well as their altered interactions with cortical and subcortical regions comprise the neural signatures of fatigue in FM.

Word-Retrieval Difficulty and Disfluent Speech in Adult Anomic Speakers

1981 ◽  
Vol 24 (3) ◽  
pp. 358-365 ◽  
Author(s):  
Catherine S. Brown ◽  
Walter L. Cullinan
Keyword(s):  
Word Naming ◽  
Word Retrieval ◽  
Subject Group ◽  
Single Word ◽  
Connected Speech ◽  
Retrieval Latency ◽  
Group B

The relationships existing between measures of disfluency and measures of word-retrieval ability in adult anomic aphasic and adult non-brain-damaged subjects were investigated. Subjects produced single-word naming responses for pictured stimuli consisting of objects, colors, and actions. The obtained number of correct naming responses and word-retrieval latency measurements were related to the number and types of disfluencies present in the subjects' connected speech samples. The major findings of the investigation include the following: (a) the anomic subject group presented significantly more disfluencies than did the nonaphasic group; (b) the number of disfluencies increased as word-retrieval difficulty increased for the anomic subjects; (c) when word-retrieval difficulty was measured by the number of correct responses those anomic subjects who tended to be most disfluent and to have the greatest word-retrieval difficulty also tended to have the highest proportions of those disfluencies most likely to be considered "stutterings" (part-word repetitions, vocal segregate repetitions, and prolongations) and the lowest proportions of hesitations; and (d) the proportion of stutterings increased as the total number of disfluencies increased for anomic and tot nonaphasic subjects. Implications of results for testing of aphasic patients are discussed.

scholarly journals Brain Activation During Reading in Deep Dyslexia: An MEG Study

2000 ◽  
Vol 12 (4) ◽  
pp. 622-634 ◽  
Author(s):  
Matti Laine ◽  
Riitta Salmelin ◽  
Päivi Helenius ◽  
Reijo Marttila
Keyword(s):  
Semantic Processing ◽  
Semantic Analysis ◽  
Right Hemisphere ◽  
Word Reading ◽  
Brain Activity ◽  
Temporal Cortex ◽  
Single Word ◽  
Lexical Semantic ◽  
Deep Dyslexia ◽  
Single Word Reading

Magnetoencephalographic (MEG) changes in cortical activity were studied in a chronic Finnish-speaking deep dyslexic patient during single-word and sentence reading. It has been hypothesized that in deep dyslexia, written word recognition and its lexical-semantic analysis are subserved by the intact right hemisphere. However, in our patient, as well as in most nonimpaired readers, lexical-semantic processing as measured by sentence-final semantic-incongruency detection was related to the left superior-temporal cortex activation. Activations around this same cortical area could be identified in single-word reading as well. Another factor relevant to deep dyslexic reading, the morphological complexity of the presented words, was also studied. The effect of morphology was observed only during the preparation for oral output. By performing repeated recordings 1 year apart, we were able to document significant variability in both the spontaneous activity and the evoked responses in the lesioned left hemisphere even though at the behavioural level, the patient's performance was stable. The observed variability emphasizes the importance of estimating consistency of brain activity both within and between measurements in brain-damaged individuals.

scholarly journals Left posterior temporal cortex is sensitive to syntax within conceptually matched Arabic expressions

2021 ◽  
Vol 11 (1) ◽  
Author(s):  
Suhail Matar ◽  
Julien Dirani ◽  
Alec Marantz ◽  
Liina Pylkkänen
Keyword(s):  
Temporal Lobe ◽  
Temporal Cortex ◽  
Syntactic Complexity ◽  
Conceptual Combination ◽  
Single Word ◽  
Grammatical Structure ◽  
Neural Basis ◽  
Word Meanings ◽  
Left Posterior ◽  
Vary Structure

AbstractDuring language comprehension, the brain processes not only word meanings, but also the grammatical structure—the “syntax”—that strings words into phrases and sentences. Yet the neural basis of syntax remains contentious, partly due to the elusiveness of experimental designs that vary structure independently of meaning-related variables. Here, we exploit Arabic’s grammatical properties, which enable such a design. We collected magnetoencephalography (MEG) data while participants read the same noun-adjective expressions with zero, one, or two contiguously-written definite articles (e.g., ‘chair purple’; ‘the-chair purple’; ‘the-chair the-purple’), representing equivalent concepts, but with different levels of syntactic complexity (respectively, indefinite phrases: ‘a purple chair’; sentences: ‘The chair is purple.’; definite phrases: ‘the purple chair’). We expected regions processing syntax to respond differently to simple versus complex structures. Single-word controls (‘chair’/‘purple’) addressed definiteness-based accounts. In noun-adjective expressions, syntactic complexity only modulated activity in the left posterior temporal lobe (LPTL), ~ 300 ms after each word’s onset: indefinite phrases induced more MEG-measured positive activity. The effects disappeared in single-word tokens, ruling out non-syntactic interpretations. In contrast, left anterior temporal lobe (LATL) activation was driven by meaning. Overall, the results support models implicating the LPTL in structure building and the LATL in early stages of conceptual combination.

scholarly journals Word comprehension in temporal cortex and Wernicke area

Neurology ◽  
2018 ◽  
Vol 92 (3) ◽  
pp. e224-e233 ◽  
Author(s):  
M.-Marsel Mesulam ◽  
Benjamin M. Rader ◽  
Jaiashre Sridhar ◽  
Matthew J. Nelson ◽  
Jungmoon Hyun ◽  
...  
Keyword(s):  
Temporal Lobe ◽  
Sentence Comprehension ◽  
Single Case ◽  
Temporal Cortex ◽  
Primary Progressive Aphasia ◽  
Single Word ◽  
Word Comprehension ◽  
Cerebrovascular Lesions ◽  
Core Components

ObjectiveTo explore atrophy–deficit correlations of word comprehension and repetition in temporoparietal cortices encompassing the Wernicke area, based on patients with primary progressive aphasia (PPA).MethodsCortical thickness in regions within and outside the classical Wernicke area, measured by FreeSurfer, was correlated with repetition and single word comprehension scores in 73 right-handed patients at mild to moderate stages of PPA.ResultsAtrophy in the Wernicke area was correlated with repetition (r = 0.42, p = 0.001) but not single word comprehension (r = −0.072, p = 0.553). Correlations with word comprehension were confined to more anterior parts of the temporal lobe, especially its anterior third (r = 0.60, p < 0.001). A single case with postmortem autopsy illustrated preservation of word comprehension but not repetition 6 months prior to death despite nearly 50% loss of cortical volume and severe neurofibrillary degeneration in core components of the Wernicke area.ConclusionsTemporoparietal cortices containing the Wernicke area are critical for language repetition. Contrary to the formulations of classic aphasiology, their role in word and sentence comprehension is ancillary rather than critical. Thus, the Wernicke area is not sufficient to sustain word comprehension if the anterior temporal lobe is damaged. Traditional models of the role of the Wernicke area in comprehension are based almost entirely on patients with cerebrovascular lesions. Such lesions also cause deep white matter destruction and acute network diaschisis, whereas progressive neurodegenerative diseases associated with PPA do not. Conceptualizations of the Wernicke area that appear to conflict, therefore, can be reconciled by considering the hodologic and physiologic differences of the underlying lesions.

Neural correlates of motion processing through echolocation, source hearing, and vision in blind echolocation experts and sighted echolocation novices

2014 ◽  
Vol 111 (1) ◽  
pp. 112-127 ◽  
Author(s):  
L. Thaler ◽  
J. L. Milne ◽  
S. R. Arnott ◽  
D. Kish ◽  
M. A. Goodale
Keyword(s):  
Visual Motion ◽  
Brain Activity ◽  
Region Of Interest ◽  
Occipital Cortex ◽  
Neural Substrates ◽  
Motion Processing ◽  
Planum Temporale ◽  
Show Evidence ◽  
Visual Cortical ◽  
Source Motion

We have shown in previous research (Thaler L, Arnott SR, Goodale MA. PLoS One 6: e20162, 2011) that motion processing through echolocation activates temporal-occipital cortex in blind echolocation experts. Here we investigated how neural substrates of echo-motion are related to neural substrates of auditory source-motion and visual-motion. Three blind echolocation experts and twelve sighted echolocation novices underwent functional MRI scanning while they listened to binaural recordings of moving or stationary echolocation or auditory source sounds located either in left or right space. Sighted participants' brain activity was also measured while they viewed moving or stationary visual stimuli. For each of the three modalities separately (echo, source, vision), we then identified motion-sensitive areas in temporal-occipital cortex and in the planum temporale. We then used a region of interest (ROI) analysis to investigate cross-modal responses, as well as laterality effects. In both sighted novices and blind experts, we found that temporal-occipital source-motion ROIs did not respond to echo-motion, and echo-motion ROIs did not respond to source-motion. This double-dissociation was absent in planum temporale ROIs. Furthermore, temporal-occipital echo-motion ROIs in blind, but not sighted, participants showed evidence for contralateral motion preference. Temporal-occipital source-motion ROIs did not show evidence for contralateral preference in either blind or sighted participants. Our data suggest a functional segregation of processing of auditory source-motion and echo-motion in human temporal-occipital cortex. Furthermore, the data suggest that the echo-motion response in blind experts may represent a reorganization rather than exaggeration of response observed in sighted novices. There is the possibility that this reorganization involves the recruitment of “visual” cortical areas.

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