New York [US]: According to Weill Cornell Medicine researchers, people with autism spectrum disorder can be classified into four distinct subtypes based on their brain activity and behaviour. The study, which was published on March 9 in Nature Neuroscience, used machine learning to analyse newly available neuroimaging data from 299 people with autism and 907 people who were not autistic.
They discovered patterns of brain connections associated with behavioural traits such as verbal ability, social affect, and repetitive or stereotypic behaviours in people with autism. They confirmed that the four autism subgroups could be replicated in a separate dataset and demonstrated that differences in regional gene expression and protein-protein interactions account for the brain and behavioural differences.
"Like many neuropsychiatric diagnoses, individuals with autism spectrum disorder experience many different types of difficulties with social interaction, communication and repetitive behaviors. Scientists believe there are probably many different types of autism spectrum disorder that might require different treatments, but there is no consensus on how to define them," said co-senior author Dr. Conor Liston, an associate professor of psychiatry and of neuroscience in the Feil Family Brain and Mind Research Institute at Weill Cornell Medicine. "Our work highlights a new approach to discovering subtypes of autism that might one day lead to new approaches for diagnosis and treatment."
A previous study published by Dr. Liston and colleagues in Nature Medicine in 2017 used similar machine-learning methods to identify four biologically distinct subtypes of depression, and subsequent work has shown that those subgroups respond differently to various depression therapies. "If you put people with depression in the right group, you can assign them the best therapy," said lead author Dr. Amanda Buch, a postdoctoral associate of neuroscience in psychiatry at Weill Cornell Medicine.
Building on that success, the team set out to determine if similar subgroups exist among individuals with autism, and whether different gene pathways underlie them. She explained that autism is a highly heritable condition associated with hundreds of genes that has diverse presentation and limited therapeutic options. To investigate this, Dr. Buch pioneered new analyses for integrating neuroimaging data with gene expression data and proteomics, introducing them to the lab and enabling testing and developing hypotheses about how risk variants interact in the autism subgroups.
"One of the barriers to developing therapies for autism is that the diagnostic criteria are broad, and thus apply to a large and phenotypically diverse group of people with different underlying biological mechanisms," Dr. Buch said. "To personalize therapies for individuals with autism, it will be important to understand and target this biological diversity. It is hard to identify the optimal therapy when everyone is treated as being the same, when they are each unique."
Until recently, there were not large enough collections of functional magnetic resonance imaging data of people with autism to conduct large-scale machine learning studies, Dr. Buch noted. But a large dataset created and shared by Dr. Adriana Di Martino, research director of the Autism Center at the Child Mind Institute, as well as other colleagues across the country, provided the large dataset needed for the study.