Evaluation of automated segmentation algorithms for neurons in macaque cerebral microscopic images

You, Zhenzhen; Jiang, Ming; Shi, Zhongchao; Ning, Xiaojuan; Cheng, Shijie; Du, Shuangli; Hérard, Anne‐Sophie; Jan, Caroline; Souedet, Nicolas; Delzescaux, Thierry

doi:10.1002/jemt.23786

Cited by 1 publication

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“…However, for some practical problems, the above-mentioned classical deep learning methods have limited performance. In order to further improve the segmentation results, several techniques can be used such as providing more manual annotations, increasing the number of training samples, enhancing the quality of images to process, improving classical or constructing new network architectures, designing new loss functions (You et al, 2021).…”

Section: Introductionmentioning

confidence: 99%

Multiscale segmentation‐ and error‐guided iterative convolutional neural network for cerebral neuron segmentation in microscopic images

You

Jiang

Shi

et al. 2022

Microscopy Res & Technique

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This article uses microscopy images obtained from diverse anatomical regions of macaque brain for neuron semantic segmentation. The complex structure of brain, the large intra‐class staining intensity difference within neuron class, the small inter‐class staining intensity difference between neuron and tissue class, and the unbalanced dataset increase the difficulty of neuron semantic segmentation. To address this problem, we propose a multiscale segmentation‐ and error‐guided iterative convolutional neural network (MSEG‐iCNN) to improve the semantic segmentation performance in major anatomical regions of the macaque brain. After evaluating microscopic images from 17 anatomical regions, the semantic segmentation performance of neurons is improved by 10.6%, 4.0%, 1.5%, and 1.2% compared with Random Forest, FCN‐8s, U‐Net, and UNet++, respectively. Especially for neurons with brighter staining intensity in the anatomical regions such as lateral geniculate, globus pallidus and hypothalamus, the performance is improved by 66.1%, 23.9%, 11.2%, and 6.7%, respectively. Experiments show that our proposed method can efficiently segment neurons with a wide range of staining intensities. The semantic segmentation results are of great significance and can be further used for neuron instance segmentation, morphological analysis and disease diagnosis. Cell segmentation plays a critical role in extracting cerebral information, such as cell counting, cell morphometry and distribution analysis. Accurate automated neuron segmentation is challenging due to the complex structure of brain, the large intra‐class staining intensity difference within neuron class, the small inter‐class staining intensity difference between neuron and tissue class, and the unbalanced dataset. The proposed multiscale segmentation‐ and error‐guided iterative convolutional neural network (MSEG‐iCNN) improve the segmentation performance in 17 major anatomical regions of the macaque brain. Highlights Cell segmentation plays a critical role in extracting cerebral information, such as cell counting, cell morphometry and distribution analysis. Accurate automated neuron segmentation is challenging due to the complex structure of brain, the large intra‐class staining intensity difference within neuron class, the small inter‐class staining intensity difference between neuron and tissue class, and the unbalanced dataset. The proposed multiscale segmentation‐ and error‐guided iterative convolutional neural network (MSEG‐iCNN) improve the segmentation performance in 17 major anatomical regions of the macaque brain.

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Section: Introductionmentioning

confidence: 99%