Abstract

.Significance: Neonates are a highly vulnerable population. The risk of brain injury is greater during the first days and weeks after birth than at any other time of life. Functional neuroimaging that can be performed longitudinally and at the cot-side has the potential to improve our understanding of the evolution of multiple forms of neurological injury over the perinatal period. However, existing technologies make it very difficult to perform repeated and/or long-duration functional neuroimaging experiments at the cot-side.Aim: We aimed to create a modular, high-density diffuse optical tomography (HD-DOT) technology specifically for neonatal applications that is ultra-lightweight, low profile and provides high mechanical flexibility. We then sought to validate this technology using an anatomically accurate dynamic phantom.Approach: An advanced 10-layer rigid-flexible printed circuit board technology was adopted as the basis for the DOT modules, which allows for a compact module design that also provides the flexibility needed to conform to the curved infant scalp. Two module layouts were implemented: dual-hexagon and triple-hexagon. Using in-built board-to-board connectors, the system can be configured to provide a vast range of possible layouts. Using epoxy resin, thermochromic dyes, and MRI-derived 3D-printed moulds, we constructed an electrically switchable, anatomically accurate dynamic phantom. This phantom was used to quantify the imaging performance of our flexible, modular HD-DOT system.Results: Using one particular module configuration designed to cover the infant sensorimotor system, the device provided 36 source and 48 detector positions, and over 700 viable DOT channels per wavelength, ranging from 10 to over an area of approximately . The total weight of this system is only 70 g. The signal changes from the dynamic phantom, while slow, closely simulated real hemodynamic response functions. Using difference images obtained from the phantom, the measured 3D localization error provided by the system at the depth of the cortex was in the of range 3 to 6 mm, and the lateral image resolution at the depth of the neonatal cortex is estimated to be as good as 10 to 12 mm.Conclusions: The HD-DOT system described is ultra-low weight, low profile, can conform to the infant scalp, and provides excellent imaging performance. It is expected that this device will make functional neuroimaging of the neonatal brain at the cot-side significantly more practical and effective.

Highlights

  • Functional near-infrared spectroscopy is a form of neuroimaging that is non-invasive and non-ionizing

  • While functional magnetic resonance imaging (fMRI) is primarily sensitive to changes in the concentration of HbR, Functional near-infrared spectroscopy (fNIRS) has the ability to differentiate between HbO and HbR, providing more complete information on hemodynamics and cerebral oxygenation

  • The light-emitting diode (LED) are controlled by an LED driver and each photodiode is connected to 1 of 4 channels of an analog-to-digital converter (ADC) which records the data in real time

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Summary

Introduction

Functional near-infrared spectroscopy (fNIRS) is a form of neuroimaging that is non-invasive and non-ionizing. Because fNIRS measurements are obtained by applying sources and detectors of NIR light to the scalp, the technique allows functional neuroimaging of the human cortex to be cheap, accessible, easy to use, and available at the bedside or in almost any other environment. Due to these advantages, fNIRS technologies have been successfully applied across multiple neuroscience domains (including studies of social cognition, autism, sleep, multi-person interaction, and language development)[1,2,3,4,5] and in the clinic (e.g., in the study of epilepsy, stroke, and traumatic brain injury).[6,7,8]

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