Abstract
The annotation of functional neuroimaging results for data sharing and re-use is particularly challenging, due to the diversity of terminologies of neuroanatomical structures and cortical parcellation schemes. To address this challenge, we extended the Foundational Model of Anatomy Ontology (FMA) to include cytoarchitectural, Brodmann area labels, and a morphological cortical labeling scheme (e.g., the part of Brodmann area 6 in the left precentral gyrus). This representation was also used to augment the neuroanatomical axis of RadLex, the ontology for clinical imaging. The resulting neuroanatomical ontology contains explicit relationships indicating which brain regions are “part of” which other regions, across cytoarchitectural and morphological labeling schemas. We annotated a large functional neuroimaging dataset with terms from the ontology and applied a reasoning engine to analyze this dataset in conjunction with the ontology, and achieved successful inferences from the most specific level (e.g., how many subjects showed activation in a subpart of the middle frontal gyrus) to more general (how many activations were found in areas connected via a known white matter tract?). In summary, we have produced a neuroanatomical ontology that harmonizes several different terminologies of neuroanatomical structures and cortical parcellation schemes. This neuroanatomical ontology is publicly available as a view of FMA at the Bioportal website1. The ontological encoding of anatomic knowledge can be exploited by computer reasoning engines to make inferences about neuroanatomical relationships described in imaging datasets using different terminologies. This approach could ultimately enable knowledge discovery from large, distributed fMRI studies or medical record mining.
Highlights
The use of functional magnetic resonance imaging in the study of both healthy and diseased brain function has resulted in a massive amount of both published literature and raw data
The full details of this work are being presented in another paper; in this particular study, we focus on how we reconciled the Talairach Daemon (TD) terms with the formal representation of corresponding neuroanatomical structures in the Foundational Model of Anatomy Ontology (FMA)
The SLF1 projects from the following areas: Brodmann area 5 of superior parietal lobule, Brodmann area 5 of posterior segment of paracentral lobule, Brodmann area 5 of postcentral gyrus, Table 1 | The distribution of activation clusters across different parts of Brodmann area 6 by diagnostic category. This search of the ontology returns the FMAIDs associated with each subregion of BA 6
Summary
The use of functional magnetic resonance imaging in the study of both healthy and diseased brain function has resulted in a massive amount of both published literature and raw data. Many though not all neuroimaging datasets are currently annotated using one of several available labeling systems, such as the Talairach Atlas (Talairach and Tournoux, 1988), Montreal Neurological Institute (MNI) atlas (as implemented in Tzourio-Mazoyer et al, 2002), or other atlases available in software such as FreeSurfer (Fischl et al, 2004; Desikan et al, 2006). Each of these labeling systems provides a neuroanatomical label drawn from their particular nomenclatures for an arbitrary 3D location in their particular standardized brain space. The ability to map these labels into the same coordinate system and visualize where they overlap, as in the SumsDB system
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