Abstract
Photoacoustic (PA) imaging can provide both chemical and micro-architectural information for biological tissues. However, photoacoustic imaging for bone tissue remains a challenging topic due to complicated ultrasonic propagations in the porous bone. In this paper, we proposed a post-processing method based on the convolution neural network (CNN) to improve the image quality of PA bone imaging in a numerical model. To be more adaptive for imaging bone samples with complex structure, an attention block U-net (AB-U-Net) network was designed from the standard U-net by integrating the attention blocks in the feature extraction part. The k-wave toolbox was used for the simulation of photoacoustic wave fields, and then the direct reconstruction algorithm—time reversal was adopted for generating a dataset of deep learning. The performance of the proposed AB-U-Net network on the reconstruction of photoacoustic bone imaging was analyzed. The results show that the AB-U-Net based deep learning method can obtain the image presented as a clear bone micro-structure. Compared with the traditional photoacoustic reconstruction method, the AB-U-Net-based reconstruction algorithm can achieve better performance, which greatly improves image quality on test set with peak signal to noise ratio (PSNR) and structural similarity increased (SSIM) by 3.83 dB and 0.17, respectively. The deep learning method holds great potential in enhancing PA imaging technology for bone disease detection.
Highlights
In recent years, the high incidence of orthopedic diseases like osteoporosis, and the resulting high costs of the treatment make it increasingly essential to monitor bone quality [2]
time reversal (TR)-reconstructed images show that the area of cortical bones is restored
TR tends to compensate for the perturbation caused by inhomogeneous medium to some extent, problems like strong scattering and the variation of sound speed are still unsolved and result in serious artifacts
Summary
The high incidence of orthopedic diseases like osteoporosis Of women and 20% of men over the age of 50 years [1]), and the resulting high costs of the treatment make it increasingly essential to monitor bone quality [2]. Several techniques have been developed for bone assessment non-invasively. Dual-energy X-ray absorptiometry (DXA) is regarded as the gold standard for bone mineral density (BMD) measurement [3,4]. Computerized tomography (CT) can provide bone geometry with relatively high resolution, it is achieved at the cost of delivering a considerable radiation dose [8]. As a newly non-ionizing radiation modality, quantitative ultrasound (QUS) has the advantages of low cost, portability and accessibility [9,10].
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