Elizabeth Stevens1, Dennis R Dixon2, Marlena N Novack2, Doreen Granpeesheh2, Tristram Smith3, Erik Linstead4. 1. Chapman University, Schmid College of Science and Technology, Orange, CA, United States. 2. Center for Autism and Related Disorders, Woodland Hills, CA, United States. 3. University of Rochester Medical Center, Rochester, NY, United States. 4. Chapman University, Schmid College of Science and Technology, Orange, CA, United States. Electronic address: linstead@chapman.edu.
Abstract
BACKGROUND AND OBJECTIVE: Autism spectrum disorder (ASD) is a heterogeneous disorder. Research has explored potential ASD subgroups with preliminary evidence supporting the existence of behaviorally and genetically distinct subgroups; however, research has yet to leverage machine learning to identify phenotypes on a scale large enough to robustly examine treatment response across such subgroups. The purpose of the present study was to apply Gaussian Mixture Models and Hierarchical Clustering to identify behavioral phenotypes of ASD and examine treatment response across the learned phenotypes. MATERIALS AND METHODS: The present study included a sample of children with ASD (N = 2400), the largest of its kind to date. Unsupervised machine learning was applied to model ASD subgroups as well as their taxonomic relationships. Retrospective treatment data were available for a portion of the sample (n = 1034). Treatment response was examined within each subgroup via regression. RESULTS: The application of a Gaussian Mixture Model revealed 16 subgroups. Further examination of the subgroups through Hierarchical Agglomerative Clustering suggested 2 overlying behavioral phenotypes with unique deficit profiles each composed of subgroups that differed in severity of those deficits. Furthermore, differentiated response to treatment was found across subtypes, with a substantially higher amount of variance accounted for due to the homogenization effect of the clustering. DISCUSSION: The high amount of variance explained by the regression models indicates that clustering provides a basis for homogenization, and thus an opportunity to tailor treatment based on cluster memberships. These findings have significant implications on prognosis and targeted treatment of ASD, and pave the way for personalized intervention based on unsupervised machine learning.
BACKGROUND AND OBJECTIVE:Autism spectrum disorder (ASD) is a heterogeneous disorder. Research has explored potential ASD subgroups with preliminary evidence supporting the existence of behaviorally and genetically distinct subgroups; however, research has yet to leverage machine learning to identify phenotypes on a scale large enough to robustly examine treatment response across such subgroups. The purpose of the present study was to apply Gaussian Mixture Models and Hierarchical Clustering to identify behavioral phenotypes of ASD and examine treatment response across the learned phenotypes. MATERIALS AND METHODS: The present study included a sample of children with ASD (N = 2400), the largest of its kind to date. Unsupervised machine learning was applied to model ASD subgroups as well as their taxonomic relationships. Retrospective treatment data were available for a portion of the sample (n = 1034). Treatment response was examined within each subgroup via regression. RESULTS: The application of a Gaussian Mixture Model revealed 16 subgroups. Further examination of the subgroups through Hierarchical Agglomerative Clustering suggested 2 overlying behavioral phenotypes with unique deficit profiles each composed of subgroups that differed in severity of those deficits. Furthermore, differentiated response to treatment was found across subtypes, with a substantially higher amount of variance accounted for due to the homogenization effect of the clustering. DISCUSSION: The high amount of variance explained by the regression models indicates that clustering provides a basis for homogenization, and thus an opportunity to tailor treatment based on cluster memberships. These findings have significant implications on prognosis and targeted treatment of ASD, and pave the way for personalized intervention based on unsupervised machine learning.
Authors: Isotta Landi; Benjamin S Glicksberg; Hao-Chih Lee; Sarah Cherng; Giulia Landi; Matteo Danieletto; Joel T Dudley; Cesare Furlanello; Riccardo Miotto Journal: NPJ Digit Med Date: 2020-07-17
Authors: Therese M O'Neil-Pirozzi; Shanti M Pinto; Mitch Sevigny; Flora M Hammond; Shannon B Juengst; Charles H Bombardier Journal: Arch Phys Med Rehabil Date: 2022-02-22 Impact factor: 4.060
Authors: Elizabeth Stevens; Dennis Dixon; Erik Linstead; Julie Gardner-Hoag; Marlena Novack; Chelsea Parlett-Pelleriti Journal: JMIR Med Inform Date: 2021-06-02
Authors: Isotta Landi; Benjamin S Glicksberg; Hao-Chih Lee; Sarah Cherng; Giulia Landi; Matteo Danieletto; Joel T Dudley; Cesare Furlanello; Riccardo Miotto Journal: NPJ Digit Med Date: 2020-07-17