The work performed for this project can be broken down into four major parts: (1) Scientific and statistical problem formulation (2) Methods: statistical analysis and software (3) Results. (4) Dissemination.
The overall focus of this project was to develop matching techniques useful for understanding, detecting and informative in suggesting suitable interventions in brain disease using large observational neuroimaging datasets. We used the UK Biobank project as a testbed to develop and implement data-analytic aspects. The UKBiobank data is a cohort study that has been specifically designed “ with the aim of improving the prevention, diagnosis and treatment of a wide range of serious and life-threatening illnesses – including cancer, heart diseases, stroke, diabetes, arthritis, osteoporosis, eye disorders, depression and forms of dementia”.
Our goal was to use the large scale of this dataset to reliably uncover important relationships between key (potentially modifiable) risk factors and outcomes that through previous literature have shown evidence of being implicated in future dementia or risk of dementia. There is strong evidence of a significant statistical relationship between Alzheimers risk and educational attainment, a factor upon which we focussed. Furthermore use of matched sampling in large imaging studies has been hitherto limited. We now give an overview of the methods and results to date.
Methods
The UK Biobank dataset provided us with more than 20000 subjects with full MRI imaging. We describe here just the first step in estimating the full mediation model which was to first assess the relationship between levels of education and brain structure. To this end we used an image processing methods known as Voxel-based morphometry to process each subjects T1-weighted MRI image into a common brain atlas space into which they could be easily compared across education in terms of grey matter density. Computationally this process took around 10-20 minutes per subject, leading to a total compute time per analysis of about 5-6 days on a 40 cpu linux cluster.
Results
We fit an adjusted 1x4 ANOVA across the 16631 subjects, to test if there was a significant difference in means of brain structure between the four educational levels. The subject numbers within each ANOVA level were (1) College or University Degree (9422) (2) A-levels or equivalent (2736) (3) O Levels or equivalent (3866) (4) CSEs or equivalent (607). We first fit a nonparametric adjusted ANOVA model and saw large areas of highly significantly different grey matter density primarily in the cerebellum. To simplify the problem somewhat we modified the groups into just two categories, contrasting those who had a degree (9422) and those who did not (7209). As seen in Figure 1 we also saw large areas of cerebellum and additional areas in the fusiform gyrus, temporal pole, parahippocampus, orbito-frontal areas and striatum.
Dissemination: One manuscript (joint first name) that used a subset of the methods developed in this project submitted to a clinical journal. This work used MR imaging texture analysis for prediction of BRCA-associated genetic risk. One manuscript in preparation reporting the results showing the effects of Education on Brain Structure under proper conditioning of covariates. Another is in preparation detailing the methods used above and extended to the setting where dementia outcomes are also known. One methodological conference planned for presentation in 2020.