Abstract
The brain of neonates is small in comparison to adults. Imaging at typical resolutions such as one cubic mm incurs more partial voluming artifacts in a neonate than in an adult. The interpretation and analysis of MRI of the neonatal brain benefit from a reduction in partial volume averaging that can be achieved with high spatial resolution. Unfortunately, direct acquisition of high spatial resolution MRI is slow, which increases the potential for motion artifact, and suffers from reduced signal-to-noise ratio. The purpose of this study is thus that using super-resolution reconstruction in conjunction with fast imaging protocols to construct neonatal brain MRI images at a suitable signal-to-noise ratio and with higher spatial resolution than can be practically obtained by direct Fourier encoding. We achieved high quality brain MRI at a spatial resolution of isotropic 0.4 mm with 6 min of imaging time, using super-resolution reconstruction from three short duration scans with variable directions of slice selection. Motion compensation was achieved by aligning the three short duration scans together. We applied this technique to 20 newborns and assessed the quality of the images we reconstructed. Experiments show that our approach to super-resolution reconstruction achieved considerable improvement in spatial resolution and signal-to-noise ratio, while, in parallel, substantially reduced scan times, as compared to direct high-resolution acquisitions. The experimental results demonstrate that our approach allowed for fast and high-quality neonatal brain MRI for both scientific research and clinical studies.
Highlights
Magnetic resonance imaging (MRI), as a noninvasive neuroimaging method, has revolutionized our knowledge over the past 20 years in understanding the human brain
The results suggest that the regularization considerably improved the super-resolution reconstruction (SRR) performance on the simulation data set by referring to the results at λ = 0
We have developed a methodology to perform fast and highresolution neonatal brain MRI
Summary
Magnetic resonance imaging (MRI), as a noninvasive neuroimaging method, has revolutionized our knowledge over the past 20 years in understanding the human brain. The interpretation and analysis of MRI of the neonatal brain benefit from a reduction in partial volume effect by increasing spatial resolution (Makropoulos et al, 2018; Dubois et al, 2019). Direct high-resolution (HR) MRI acquisition is time consuming and costly, and suffers from reduced signal-tonoise ratio (SNR). Even in scans where sedation is enabled to avoid subject motion, e.g., in a clinical scan, the long MRI scan for high spatial resolution leads to a substantial reduction in SNR, which in turn, increases the difficulty in distinguishing the signal of interest from noise. The limitations of direct HR acquisition, necessitate the development of the methods that allow for imaging for neonates at high spatial resolution and high SNR, while in parallel, with short scan duration
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