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Parameter estimation for connectome generative models: Accuracy, reliability, and a fast parameter fitting method.

Authors :
Liu, Yuanzhe
Seguin, Caio
Mansour, Sina
Oldham, Stuart
Betzel, Richard
Di Biase, Maria A.
Zalesky, Andrew
Source :
NeuroImage. Apr2023, Vol. 270, pN.PAG-N.PAG. 1p.
Publication Year :
2023

Abstract

• We evaluate three parameter estimation methods for connectome generative models. • The three methods show a tradeoff between accuracy, reliability, and computational expense. • We develop a new fast, accurate and reliable estimation method. • We report minimum sample sizes required to detect between-group differences in model parameters. Generative models of the human connectome enable in silico generation of brain networks based on probabilistic wiring rules. These wiring rules are governed by a small number of parameters that are typically fitted to individual connectomes and quantify the extent to which geometry and topology shape the generative process. A significant shortcoming of generative modeling in large cohort studies is that parameter estimation is computationally burdensome, and the accuracy and reliability of current estimation methods remain untested. Here, we propose a fast, reliable, and accurate parameter estimation method for connectome generative models that is scalable to large sample sizes. Our method achieves improved estimation accuracy and reliability and reduces computational cost by orders of magnitude, compared to established methods. We demonstrate an inherent tradeoff between accuracy, reliability, and computational expense in parameter estimation and provide recommendations for leveraging this tradeoff. To enable power analyses in future studies, we empirically approximate the minimum sample size required to detect between-group differences in generative model parameters. While we focus on the classic two-parameter generative model based on connection length and the topological matching index, our method can be generalized to other growth-based generative models. Our work provides a statistical and practical guide to parameter estimation for connectome generative models. [ABSTRACT FROM AUTHOR]

Details

Language :
English
ISSN :
10538119
Volume :
270
Database :
Academic Search Index
Journal :
NeuroImage
Publication Type :
Academic Journal
Accession number :
162477297
Full Text :
https://doi.org/10.1016/j.neuroimage.2023.119962