Abstract
Accurately extracting brain tissue is a critical and primary step in brain neuroimaging research. Due to the differences in brain size and structure between humans and nonhuman primates, the performance of the existing tools for brain tissue extraction, working on macaque brain MRI, is constrained. A new transfer learning training strategy was utilized to address the limitations, such as insufficient training data and unsatisfactory model generalization ability, when deep neural networks processing the limited samples of macaque magnetic resonance imaging(MRI). First, the project combines two human brain MRI data modes to pre-train the neural network, in order to achieve faster training and more accurate brain extraction. Then, a residual network structure in the U-Net model was added, in order to propose a ResTLU-Net model that aims to improve the generalization ability of multiple research sites data. The results demonstrated that the ResTLU-Net, combined with the proposed transfer learning strategy, achieved comparable accuracy for the macaque brain MRI extraction tasks on different macaque brain MRI volumes that were produced by various medical centers. The mean Dice of the ResTLU-Net was 95.81% (no need for denoise and recorrect), and the method required only approximately 30–60 s for one extraction task on an NVIDIA 1660S GPU.
Highlights
Due to the restrictions on direct research of the living human brain, the research team took a different approach, in order to derive the working principles of the human brain, through the study of various animal brains [1,2]
Brain tissue extraction is a fundamental step in studying brain structure and function through brain medical images [8,9,10,11]
The Dice of the models using our transfer learning strategy show much higher coefficients, and the performance tended to be more stable, which means our transfer learning strategy could improve the network performance in the extraction of macaque brain tissue
Summary
Due to the restrictions on direct research of the living human brain, the research team took a different approach, in order to derive the working principles of the human brain, through the study of various animal brains [1,2]. For use on the human brain for skull stripping, have been developed, such as the Brain Extraction Tool (BET) in FSL [15,16], 3dSkullStrip in AFNI [17,18,19], and the hybrid watershed algorithm (HWA) in FreeSurfer [20,21] These tools can perform well, when applied to the human brain, their performance is lacking when used on the macaque brain, mainly due to the image differences between the macaque and human brains [22]. In addition to the significant differences in size and shape, macaques show the eyes as more prominent than those of humans in MRI images; there is more fatty tissue and a thicker skull around the brain, and the frontal lobe of macaques is very narrow and prominent [23]
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
