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Bioinformatics of the Brain
Wang and coworkers performed NGS using whole blood samples from
ADHD patients and their healthy counterparts [93]. 13 miRNAs were dis-
covered as possible indicators for ADHD. In another study, Mccaffrey and
associates performed whole blood RNA sequencing on ADHD patients under
case-control [94]. They identified putative functions for a number of genes with
differential expression, including ABCB5, RGS2, GAK, and GIT1, which have
been linked mechanistically to molecular pathways associated with behavioral
control and ADHD in the past.
8.6
Integration of Brain Transcriptomics and Imaging
Data
There comes a time where data from only one source is not enough to un-
derstand the big picture anymore and integration of several types of data is
necessary to move forward. Integrating brain transcriptomics with neuroimag-
ing data advanced with the public unveiling of the Allen Human Brain Atlas
(AHBA) dataset in 2012. This dataset contained histology data, structural
MRI (sMRI), and whole-brain microarray transcriptome data collected from
healthy mature human subjects [95]. Since then, attempts were made to inte-
grate imaging with transcriptomics to shed more light into the etiology and
progression of these brain diseases and disorders as well as diagnostic and ther-
apeutic studies. For instance, Adewale and coworkers proposed a spatiotem-
poral brain model that takes into consideration the direct interaction between
numerous RNA transcripts and macroscale imaging techniques like MRI and
PET [96]. In another study, Wu and coworkers worked on a so-called federated
model in detection of genomic and transcriptomic factors associated with AD
using sMRI, GWAS (genome-wide association studies), and transcriptomics
data [97]. It is important to interpret the interplay of biological factors at var-
ious spatial resolutions. This area is also called imaging genetics, which is the
application of neuroimaging tools to examine how genetic differences affect
brain structure or function in order to gain an insight into how these varia-
tions affect behavior and disease phenotypes [98]. Research in this field has
been gaining momentum in recent years [99–107]. There are also online tools
specialized in this area. One example of such tools is the Neuroimaging Infor-
matics Tools and Resources Clearinghouse (www.nitrc.org), often known as
NITRC-R. It is a collection of resources for neuroimaging, including data sets,
software for analysis, and computer power. The research focus of NITRC com-
prises software tools, data, and computational resources for MR, PET/SPECT
(Single-photon emission computed tomography), CT (computerized tomogra-
phy), EEG (electroencephalogram)/MEG (Magnetoencephalography), optical
imaging, clinical neuroimaging, computational neuroscience, and imaging ge-
nomics.