Abstract
Multimodal medical image fusion (MIF) plays an important role in clinical diagnosis and therapy. Existing MIF methods tend to introduce artifacts, lead to loss of image details or produce low-contrast fused images. To address these problems, a novel spiking cortical model (SCM) based MIF method has been proposed in this paper. The proposed method can generate high-quality fused images using the weighting fusion strategy based on the firing times of the SCM. In the weighting fusion scheme, the weight is determined by combining the entropy information of pulse outputs of the SCM with the Weber local descriptor operating on the firing mapping images produced from the pulse outputs. The extensive experiments on multimodal medical images show that compared with the numerous state-of-the-art MIF methods, the proposed method can preserve image details very well and avoid the introduction of artifacts effectively, and thus it significantly improves the quality of fused images in terms of human vision and objective evaluation criteria such as mutual information, edge preservation index, structural similarity based metric, fusion quality index, fusion similarity metric and standard deviation.
Highlights
With the development of medical imaging technology, various imaging modals such as ultrasound (US) imaging, computed tomography (CT), magnetic resonance imaging (MRI), positron emission tomography (PET) and single-photon emission computed tomography (SPECT) are finding a range of applications in diagnosis and assessment of medical conditions that affect brain, breast, lungs, soft tissues, bones and so on [1]
To address the problem of unwanted image degradation during fusion for the above-mentioned fusion methods, we have proposed a distinctive spiking cortical model (SCM) based weighting fusion method
A novel spiking cortical model based medical image fusion method is presented in this paper
Summary
With the development of medical imaging technology, various imaging modals such as ultrasound (US) imaging, computed tomography (CT), magnetic resonance imaging (MRI), positron emission tomography (PET) and single-photon emission computed tomography (SPECT) are finding a range of applications in diagnosis and assessment of medical conditions that affect brain, breast, lungs, soft tissues, bones and so on [1]. PCNN has been combined with multi-resolution decomposition methods such as the wavelet transform [31], the NSCT [32,33,34,35,36], the shearlet transform [37,38] and the empirical mode decomposition [39] These methods involve such disadvantages as high computational complexity, difficulty in adaptively determining PCNN parameters for various source images and image contrast reduction or loss of image details. Compared with the PCNN based fusion method, the proposed SCM based method using the multi-features of pulse outputs (SCM-M) has such advantages as higher computational efficiency, simpler parameter tuning as well as less contrast reduction and loss of image details. The SCM has been specially designed for image processing applications
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