Growth and evolution of category fluency network graphs

Shrestha, Rajeet; Shaw, Barclay; Woyczyński, Wojbor A.; Thomas, Peter J.; Fritsch, Thomas; Lerner, Alan J.

doi:10.15761/jsin.1000103

Cited by 4 publications

(5 citation statements)

References 34 publications

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“…The results from that initial study (Lerner et al, 2009) showed that the number of nodes decreased from normal to mild cognitive impairment to AD, as did the edges, and measures of complexity such as clustering coefficient and mean shortest path length also changed consistently between the groups. Further analysis using this method of graph construction showed that this method produced scale-free networks with small-world properties, thereby providing validation for the methodology (Lenio et al, 2016;Lerner et al, 2009;Shrestha et al, 2015).…”

Section: Simple Associationmentioning

confidence: 86%

“…It is clear from our previous work and the results presented here that group size is an important variable. Using subsets from a study of ∼350 individuals, Shrestha et al (2015) modeled network growth and demonstrated the emergence and change of network parameters with group size. Although our cohort was relatively small, comparisons with Shrestha and colleagues (2015) indicate that network parameters are relatively stable and that our group size appears acceptable for the initial analysis presented here.…”

Section: Discussionmentioning

confidence: 99%

“…Verbal fluency testing is generally tested over a short time interval, most often 60 seconds, although intervals up to 10 minutes have been reported (Rosen et al, 2005). The medical literature has often focused primarily on the animal naming task, which is a large category with an estimated lexicon size of several hundred animals (Shrestha et al, 2015).…”

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confidence: 99%

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Graph Theory Analysis of Semantic Fluency in Russian–English Bilinguals

Sinha

Lissemore

Lerner

2022

Cognitive and Behavioral Neurology

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Background: Semantic category fluency is a widely used task involving language, memory, and executive function. Previous studies of bilingual semantic fluency have shown only small differences between languages. Graph theory analyzes complex relationships in networks, including node and edge number, clustering coefficient, average path length, average number of direct neighbors, and scale-free and small-world properties. Objective: To shed light on whether the underlying neural processes involved in semantic category fluency testing yield substantially different networks in different languages. Method: We compared languages and methods using both network analysis and conventional analysis of word production. We administered the animal naming task to 51 Russian–English bilinguals in each language. We constructed network graphs using three methods: (a) simple association of unique co-occurring neighbors, (b) corrected associations between consecutive words occurring beyond chance, and (c) a network community approach using planar maximally filtered graphs. We compared the resultant network analytics as well as their scale-free and small-world properties. Results: Participants produced more words in Russian than in English. Small-worldness metrics were variable between Russian and English but were consistent across the three graph theory analytical methods. Conclusion: The networks had similar graph theory properties in both languages. The optimal methodology for creating networks from semantic category fluency remains to be determined.

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Section: Simple Associationmentioning

confidence: 86%

Section: Discussionmentioning

confidence: 99%

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Graph Theory Analysis of Semantic Fluency in Russian–English Bilinguals

Sinha

Lissemore

Lerner

2022

Cognitive and Behavioral Neurology

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“…Then, the nodes and edges of each learner are aggregated in a LAG by simply grouping all together. See also Lerner et al ( 2009 ), Shrestha et al ( 2015 ), Lenio et al ( 2016 ) for a similar methodology of graph construction by simple association. Sinha et al ( 2023 ) believe that if scale-free networks with small-world properties are produced with this method, then it is a valid method for graph construction.…”

Section: Vocabulary Production and Lexical Availability In Efl As A F...mentioning

confidence: 99%

Navigating the Mental Lexicon: Network Structures, Lexical Search and Lexical Retrieval

Agustín-Llach,

Rubio

2024

J Psycholinguist Res

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This paper examines the implications of the association patterns in our understanding of the mental lexicon. By applying the principles of graph theory to word association data, we intend to explore which measures tap better into lexical knowledge. To that end, we had different groups of English as Foreign language learners complete a lexical fluency task. Based on these empirical data, a study was undertaken on the corresponding lexical availability graph (LAG). It is observed that the aggregation (mentioned through human coding) of all lexical tokens on a given topic allows the emergence of some lexical-semantic patterns. The most important one is the existence of some key terms, featuring both high centrality in the sense of network theory and high availability in the LAG, which define a hub of related terms. These communities of words, each one organized around an anchor term, or most central word, are nicely apprehended by a well-known network metric called modularity. Interestingly enough, each module seems to describe a conceptual class, showing that the collective lexicon, at least as approximated by LA Graphs, is organised and traversed by semantic mechanisms or associations via hyponymy or hiperonymy, for instance. Another empirical observation is that these conceptual hubs can be appended, resulting in high diameters compared to same-sized random graphs; even so it seems that the small-world hypothesis holds in LA Graphs, as in other social and natural networks.

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“…This threshold is the only parameter in the SemNeT package's implementation of the Naïve Random Walk method and it defaults to 3. The Naïve Random Walk has demonstrated validity by finding exponential growth in the evolution of verbal fluency networks (Shreestha et al, 2015) as well as differences in semantic structure of people with mild cognitive impairments (Lerner et al, 2009).…”

Section: Naïve Random Walkmentioning

confidence: 99%

Semantic Network Analysis (SemNA): A Tutorial on Preprocessing, Estimating, and Analyzing Semantic Networks

Christensen¹,

Kenett²

2019

Preprint

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To date, the application of semantic network methodologies to study cognitive processes in psychological phenomena has been limited in scope. One barrier to broader application is the lack of resources for researchers unfamiliar with the approach. Another barrier, for both the unfamiliar and knowledgeable researcher, is the tedious and laborious preprocessing of semantic data. In this article, we aim to minimize these barriers by offering detailed descriptions of one approach to a semantic network analysis pipeline (preprocessing, estimating, and analyzing networks), and an associated R tutorial that uses a suite of R packages to accommodate this pipeline. Two of these packages, SemNetDictionaries and SemNetCleaner, promote an efficient, reproducible, and transparent approach to preprocessing verbal fluency data. The third package, SemNeT, provides methods and measures for analyzing and statistically comparing semantic networks. Using real-world data, we present a start-to-finish pipeline from raw data to semantic network analysis results. This article aims to provide resources for researchers, both the unfamiliar and knowledgeable, that minimize some of the barriers for conducting semantic network analysis.

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Growth and evolution of category fluency network graphs

Cited by 4 publications

References 34 publications

Graph Theory Analysis of Semantic Fluency in Russian–English Bilinguals

Graph Theory Analysis of Semantic Fluency in Russian–English Bilinguals

Navigating the Mental Lexicon: Network Structures, Lexical Search and Lexical Retrieval

Semantic Network Analysis (SemNA): A Tutorial on Preprocessing, Estimating, and Analyzing Semantic Networks

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