Abstract
The ability to produce high-quality images of human brain function in any environment and during unconstrained movement of the subject has long been a goal of neuroimaging research. Diffuse optical tomography, which uses the intensity of back-scattered near-infrared light from multiple source-detector pairs to image changes in haemoglobin concentrations in the brain, is uniquely placed to achieve this goal. Here, we describe a new generation of modular, fibre-less, high-density diffuse optical tomography technology that provides exceptional sensitivity, a large dynamic range, a field-of-view sufficient to cover approximately one-third of the adult scalp, and also incorporates dedicated motion sensing into each module. Using in-vivo measures, we demonstrate a noise-equivalent power of 318 fW, and an effective dynamic range of 142 dB. We describe the application of this system to a novel somatomotor neuroimaging paradigm that involves subjects walking and texting on a smartphone. Our results demonstrate that wearable high-density diffuse optical tomography permits three-dimensional imaging of the human brain function during overt movement of the subject; images of somatomotor cortical activation can be obtained while subjects move in a relatively unconstrained manner, and these images are in good agreement with those obtained while the subjects remain stationary. The scalable nature of the technology we described here paves the way for the routine acquisition of high-quality, three-dimensional, whole-cortex diffuse optical tomography images of cerebral haemodynamics, both inside and outside of the laboratory environment, which has profound implications for neuroscience.
Highlights
Over the last 25 years, the application of functional neuroimaging technologies, functional magnetic resonance imaging, has yielded extensive and detailed insights into the relationships between brain structure, brain function and our interactions with the external world [1,2,3]
We describe the application of this technology to a novel motor neuroimaging paradigm that was designed to test the capabilities of our system, and its capacity for imaging human brain function during overt movement of the subject
By taking the standard-deviation of dark measurements over time for each detector and each experiment, it is possible to quantify the sensitivity of the system in terms of the measured noise-equivalent power (NEP) [30]
Summary
Over the last 25 years, the application of functional neuroimaging technologies, functional magnetic resonance imaging (fMRI), has yielded extensive and detailed insights into the relationships between brain structure, brain function and our interactions with the external world [1,2,3]. The ability to reliably image human brain function outside of the laboratory, using naturalistic stimuli and while subjects move freely, would allow neuroscientists to investigate the effects of experimental environment and examine whole new aspects of human cognition. Optical neuroimaging approaches such as functional near-infrared spectroscopy lend themselves to applications that are either extremely challenging or impossible with traditional neuroimaging technologies like fMRI [4,5,6]. Most fNIRS systems provide somewhere in the range of 1 to 50 measurement channels [7], which yield data that can be analysed channel-by-channel or converted into rudimentary two-dimensional maps with a resolution of around 30 mm [10,11]
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