Neuroimaging During Motion with Portable, Wearable Diffuse Optical Tomography

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Abstract Submission 

Hannah DeVore¹, Alvin Agato¹, Calamity Svoboda², William Hamic¹, Anthony O'Sullivan², Michelle Hedlund¹, Sean Rafferty², Jason Trobaugh¹, Adam Eggebrecht², Edward Richter¹, Joseph Culver²

¹Washington University in St. Louis, St. Louis, MO, ²Washington University School of Medicine, St. Louis, MO

Hannah DeVore  
Washington University in St. Louis
St. Louis, MO

Alvin Agato  
Washington University in St. Louis
St. Louis, MO

Calamity Svoboda  
Washington University School of Medicine
St. Louis, MO

William Hamic  
Washington University in St. Louis
St. Louis, MO

Anthony O'Sullivan  
Washington University School of Medicine
St. Louis, MO

Michelle Hedlund  
Washington University in St. Louis
St. Louis, MO

Sean Rafferty  
Washington University School of Medicine
St. Louis, MO

Jason Trobaugh  
Washington University in St. Louis
St. Louis, MO

Adam Eggebrecht, PhD  
Washington University School of Medicine
St. Louis, MO

Edward Richter  
Washington University in St. Louis
St. Louis, MO

Joseph Culver, PhD  
Washington University School of Medicine
St. Louis, MO

While neuroimaging technologies have improved and expanded their capabilities, there has long been a gap in traditional neuroimaging technologies for a noninvasive, high-resolution, portable modality that tolerates participant movement. Established technologies like EEG may be used in real-world settings, but suffer from poor resolution, SNR, and motion susceptibility, while MRI has good spatial resolution, but creates a loud, cramped, unnatural scanning environment. MRI and PET are also stationary, and contraindicated in some populations. Wearable diffuse optical tomography (DOT) systems bridge this gap; our new wearable, high-density (WHD) DOT system offers portability and flexibility like EEG, spatial resolution similar to MRI, and improved robustness against motion artifacts versus fiber-based DOT systems.
DOT is an optical technique that uses multiple, overlapping measurements from high-density imaging arrays to generate 3D tomographic reconstruction of cortical blood oxygenation dynamics (Fig 1a). As with MRI, neuronal activity is inferred from blood oxygenation via neurovascular coupling. While fiber-based DOT systems have been extensively validated against MRI over the last decade, full head fiber DOT systems require that the subject's head remains relatively still. New, wearable DOT systems have recently begun to provide similar imaging performance with the added advantage of permitting subject movement.

Our wearable DOT cap houses an array of modules with integrated optoelectronics and mechanics. The fully untethered system communicates with a control computer over Wi-Fi, and power is supplied via a battery in a backpack. Participants can move their head, stand, walk, and perform more complex movements (Fig 1bcd). 98 sources and 98 detectors are arranged in a high-density grid with a field of view covering most of the cortex. Spring-loaded optodes comb through hair to create and maintain scalp coupling. The system was validated both on the bench and in vivo, and compared to a conventional, fiber-based DOT system. In some cases, subjects were scanned while freely walking, which is impossible in MRI or fiber DOT.

In vivo data from varied behavioral tasks replicate the activation patterns expected from fMRI studies, including visual, auditory, motor, and language processing tasks. The SNR is sufficient for single session individual subject maps without group-averaging. In a 3-way visual decoding task, single-trial responses are robust enough for decoding with up to 100% accuracy.
To verify robustness to subject movement, we used instructed motion from our WHD system and a comparable fiber DOT system. Multiple types of motion were compared, as well as the effects of motion artifacts on task maps and decoding performance. With instructed motion as great as 20 cm added to a visual task, the WHD system still output high quality maps with few motion artifacts, while on the fiber system, activations were completely obscured by motion artifacts (Fig 2a). Even during motion, the WHD system demonstrated high accuracy on a 3-way decoding task, while motion decimated the fiber system's decoding performance (Fig 2b). Quantifying motion artifacts with GVTD, akin to MRI's DVARS, shows rigid body motions on the WHD system gave GVTD values 1/3 of the mean and 1/5 of the amplitude of the GVTD on the fiber system.

We developed a WHD DOT system that bridges a gap in neuroimaging technologies, with wearable convenience, high resolution, and resistance to motion artifacts. Bench and in vivo testing demonstrate good performance, and it significantly outperformed fiber DOT systems during instructed motion. The portability and robustness to motion open new worlds of possibilities for scanning during tasks or in settings that were previously intractable; it is compatible with gross motor movement and locomotion, and with non-laboratory environments such as offices. Current work includes expanding the field of view and improving ergonomics.

Activation (eg. BOLD task-fMRI)

Classification and Predictive Modeling

Motor Behavior Other ²

NIRS ¹

Cortex

Motor

Near Infra-Red Spectroscopy (NIRS)

OPTICAL

Other - Motion artifact