The NIRS Brain AnalyzIR Toolbox.
Hendrik SantosaXuetong ZhaiFrank A FishburnTheodore HuppertPublished in: Algorithms (2018)
Functional near-infrared spectroscopy (fNIRS) is a noninvasive neuroimaging technique that uses low-levels of light (650-900 nm) to measure changes in cerebral blood volume and oxygenation. Over the last several decades, this technique has been utilized in a growing number of functional and resting-state brain studies. The lower operation cost, portability, and versatility of this method make it an alternative to methods such as functional magnetic resonance imaging for studies in pediatric and special populations and for studies without the confining limitations of a supine and motionless acquisition setup. However, the analysis of fNIRS data poses several challenges stemming from the unique physics of the technique, the unique statistical properties of data, and the growing diversity of non-traditional experimental designs being utilized in studies due to the flexibility of this technology. For these reasons, specific analysis methods for this technology must be developed. In this paper, we introduce the NIRS Brain AnalyzIR toolbox as an open-source Matlab-based analysis package for fNIRS data management, pre-processing, and first- and second-level (i.e., single subject and group-level) statistical analysis. Here, we describe the basic architectural format of this toolbox, which is based on the object-oriented programming paradigm. We also detail the algorithms for several of the major components of the toolbox including statistical analysis, probe registration, image reconstruction, and region-of-interest based statistics.
Keyphrases
- resting state
- functional connectivity
- magnetic resonance imaging
- case control
- electronic health record
- white matter
- big data
- deep learning
- cerebral ischemia
- machine learning
- data analysis
- working memory
- photodynamic therapy
- subarachnoid hemorrhage
- artificial intelligence
- blood flow
- quantum dots
- diffusion weighted imaging
- single molecule
- cerebral blood flow