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Subtle Prosodic Differences in Latent Post-Stroke Aphasia Reveal Underlying Language Deficits


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Individuals with latent post-stroke aphasia, despite performing within normal limits on clinical tests, exhibit subtle differences in prosodic features of speech production compared to neurotypical controls, which can be leveraged to build reliable automated classification tools.
Resumen

This study explored prosodic production in latent aphasia, a mild form of aphasia associated with left-hemisphere brain damage (e.g., stroke). Unlike prior research on moderate to severe aphasia, the researchers investigated latent aphasia, which can seem to have very similar speech production with neurotypical speech.

The researchers analyzed the fundamental frequency (f0), intensity, and duration of utterance-initial and utterance-final words of ten speakers with latent aphasia and ten matching controls. Regression models revealed varying degrees of differences in all three prosodic measures between the groups. The latent aphasia group showed longer word durations and used f0 and intensity differently in utterance-initial and utterance-final positions compared to the control group.

The researchers also investigated the diagnostic classification of latent aphasia versus neurotypical control using random forest models. The models achieved high accuracy in distinguishing the two groups, with prosodic features playing a crucial role. The results suggest that subtle prosodic differences can be leveraged to build reliable automated tools to assist with the identification of latent aphasia, which often goes undetected on standard clinical assessments.

The findings highlight the merits of prosodic research in identifying subtle pathological differences in language and cognition, even in cases where standard clinical tests do not reveal any overt deficits. The study paves the way for future research on subclinical and hidden cognitive-linguistic problems using advanced speech analysis techniques.

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Estadísticas
The latent aphasia group had significantly longer mean word durations compared to the control group. The control group produced utterance-final words with significantly higher mean f0 values than utterance-initial words, while the latent aphasia group used significantly higher f0 in utterance-initial words than in utterance-final words. The control group produced utterance-final words with significantly higher mean intensity than utterance-initial words, while the latent aphasia group showed the opposite pattern.
Citas
"The longer word durations in the latent group could reflect slower speaking rates or processing speed limitations." "The combination of features extracted with Praat and openSMILE, along with the demographic features, were found to be effective and representative of all the features needed for an automatic classification tool."

Ideas clave extraídas de

by Cong Zhang, ... a las arxiv.org 09-25-2024

https://arxiv.org/pdf/2408.11882.pdf
Prosody of speech production in latent post-stroke aphasia

Consultas más profundas

How do the prosodic differences in latent aphasia relate to specific cognitive-linguistic processes, such as speech planning, lexical access, and discourse organization?

The prosodic differences observed in individuals with latent aphasia provide valuable insights into the underlying cognitive-linguistic processes, particularly in areas such as speech planning, lexical access, and discourse organization. The study highlights that individuals with latent aphasia exhibit variations in fundamental frequency (f0), intensity, and duration of utterances, particularly in the context of utterance-initial and utterance-final words. Speech Planning: The differences in prosodic features, such as longer word durations in the latent aphasia group, may indicate slower speech planning or cognitive processing speed limitations. This aligns with the cognitive approach that suggests prosodic markers reflect the execution of speech plans. The ability to effectively plan speech is crucial for fluent communication, and the observed prosodic variations may signal disruptions in this planning process. Lexical Access: Prosodic features can also be indicative of lexical access difficulties. The study found that the latent aphasia group used higher f0 in utterance-initial words compared to utterance-final words, contrasting with the control group. This inconsistency may reflect challenges in retrieving and producing lexical items, as prosody often serves to highlight important information in speech. The variability in prosodic modulation could suggest that individuals with latent aphasia experience delays or errors in accessing the appropriate lexical items during speech production. Discourse Organization: The organization of discourse is another area where prosodic differences manifest. The study's findings suggest that the prosodic features employed by individuals with latent aphasia differ from those of neurotypical controls, particularly in how they structure their narratives. The use of prosody to signal boundaries and emphasize key points in discourse is essential for effective communication. The observed differences may indicate that individuals with latent aphasia struggle with organizing their thoughts and conveying them coherently, which can lead to challenges in maintaining the listener's engagement and understanding. In summary, the prosodic differences in latent aphasia are closely tied to cognitive-linguistic processes, revealing potential deficits in speech planning, lexical access, and discourse organization. These insights underscore the importance of prosodic analysis in understanding the complexities of language production in individuals with latent aphasia.

What other speech and language features, beyond prosody, could be leveraged to further improve the accuracy and reliability of automated classification tools for latent aphasia?

To enhance the accuracy and reliability of automated classification tools for latent aphasia, it is essential to consider a broader range of speech and language features beyond prosody. The following features could be particularly beneficial: Lexical Diversity and Complexity: Measures of lexical diversity, such as the type-token ratio, and lexical complexity, including the use of advanced vocabulary, can provide insights into the speaker's language proficiency. Analyzing these features can help identify subtle differences in language use between individuals with latent aphasia and neurotypical controls. Speech Rate and Fluency: Quantifying speech rate (words per minute) and fluency (the presence of disfluencies such as fillers and repetitions) can offer additional context regarding the speaker's cognitive-linguistic abilities. Individuals with latent aphasia may exhibit slower speech rates and increased disfluencies, which can be critical indicators for classification. Syntactic Complexity: Analyzing the syntactic structures used in speech, such as the length and complexity of sentences, can reveal differences in cognitive processing and language organization. Tools that assess syntactic complexity can help differentiate between latent aphasia and neurotypical speech patterns. Error Patterns: Identifying and categorizing errors in speech production, such as phonological, semantic, or syntactic errors, can provide valuable diagnostic information. Automated systems could be trained to recognize specific error patterns associated with latent aphasia, improving classification accuracy. Prosodic Features from Multiple Contexts: While the current study focused on specific utterance positions, incorporating prosodic features from various speech contexts (e.g., spontaneous conversation, narrative retelling) could yield a more comprehensive understanding of prosodic variations in latent aphasia. Cognitive Metrics: Integrating cognitive assessment data, such as working memory and attention measures, could enhance the classification models. These metrics may correlate with language performance and provide a more holistic view of the individual's cognitive-linguistic profile. By leveraging these additional speech and language features, automated classification tools for latent aphasia can achieve greater sensitivity and specificity, ultimately leading to improved diagnostic accuracy and better-targeted interventions.

Could the insights from this study on latent aphasia be extended to other mild cognitive-linguistic disorders, such as mild traumatic brain injury or early-stage neurodegenerative diseases?

The insights gained from the study on latent aphasia have significant implications for understanding other mild cognitive-linguistic disorders, including mild traumatic brain injury (mTBI) and early-stage neurodegenerative diseases. The following points illustrate how these insights can be extended: Shared Cognitive-Linguistic Deficits: Individuals with mTBI and early-stage neurodegenerative diseases often experience cognitive-linguistic deficits similar to those observed in latent aphasia, such as difficulties in speech planning, lexical access, and discourse organization. The prosodic features identified in latent aphasia, such as variations in f0, intensity, and duration, may also manifest in these populations, providing a basis for comparative analysis. Prosodic Markers as Diagnostic Tools: The study's findings suggest that prosodic features can serve as sensitive markers for identifying subtle language impairments. This approach could be applied to mTBI and neurodegenerative diseases, where traditional assessments may not capture the full extent of cognitive-linguistic challenges. Prosodic analysis could enhance diagnostic accuracy and facilitate early intervention. Machine Learning Applications: The use of machine learning techniques, as demonstrated in the study, can be adapted to classify other mild cognitive-linguistic disorders. By incorporating relevant speech and language features from individuals with mTBI or neurodegenerative diseases, researchers can develop robust classification models that account for the unique characteristics of these populations. Holistic Understanding of Cognitive-Linguistic Profiles: The insights from latent aphasia research can contribute to a more comprehensive understanding of cognitive-linguistic profiles across various disorders. By examining how prosodic features relate to cognitive processes in different contexts, clinicians can better tailor interventions to address specific deficits. Intervention Strategies: Understanding the prosodic differences in latent aphasia can inform intervention strategies for other disorders. For instance, speech therapy techniques that focus on enhancing prosodic features may be beneficial for individuals with mTBI or early-stage neurodegenerative diseases, helping to improve their communication skills. In conclusion, the insights from the study on latent aphasia can indeed be extended to other mild cognitive-linguistic disorders, providing valuable information for diagnosis, intervention, and understanding the complexities of cognitive-linguistic impairments across different populations.
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