A harmonized vendor-agnostic environment for multi-site functional MRI studies
University Of Michigan At Ann Arbor, Ann Arbor MI
Investigators
Linked publications & trials
Abstract
Since its invention in the early 90s, functional magnetic resonance imaging (fMRI) has revolutionized our un- derstanding of the human brain. Functional MRI may be used to observe brain function during a speciï¬c motor or cognitive task, or at ârestâ (resting-state fMRI). The latter produces so-called âfunctional connectivityâ maps that may provide a new window into human cognition. There is currently a large, world-wide effort underway to discover potential research and clinical uses of such connectivity maps. A signiï¬cant practical barrier in this effort, however, is the difï¬culty in ensuring that fMRI experiments are conducted in a consistent and reproducible manner across different centers. In particular, it is generally not possible to ensure identical execution of MR measurements (pulse sequences) across sites operating different MR scanners. Furthermore, even the image reconstruction and data processing methods can be difï¬cult to harmonize, particularly across different MR ven- dors. This makes it challenging to directly compare results between sites, or âpoolâ data from multiple sites to increase statistical power and gain access to rare clinical conditions. We will assemble and disseminate a truly harmonized, cross-vendor, and ï¬exible environment for fMRI re- search that ensures consistent data acquisition and image reconstruction across sites. Our framework is based on an open-source MR sequence development platform that allows any arbitrary MR pulse sequence to be de- signed âoff-lineâ in Matlab or Python and exported to a vendor-independent ï¬le format, that can be ported directly to scanners from different manufacturers (at present, General Electric and Siemens are supported, but others may follow in the future). Due to this open pulse sequence structure it will also be possible to compose a uniï¬ed image reconstruction environment based on current open-source libraries. Based on this technology, we will provide the fMRI research community with a complete and portable workï¬ow for fMRI data acquisition and image reconstruction, backed up by integrated quality control procedures.
View original record on NIH RePORTER →