1. Recovery of photoacoustic images based on accurate ultrasound positioning
- Author
-
Pan Yinhao, Chengbo Liu, Zhiqiang Xu, Ningbo Chen, Liu Liangjian, and Jianhui Zhang
- Subjects
lcsh:NC1-1940 ,Materials science ,Visual Arts and Performing Arts ,Image quality ,Image correction ,Photoacoustic microscopy ,Medicine (miscellaneous) ,Photoacoustic imaging in biomedicine ,lcsh:Computer applications to medicine. Medical informatics ,01 natural sciences ,010309 optics ,03 medical and health sciences ,Ultrasound positioning ,Optics ,lcsh:Drawing. Design. Illustration ,0103 physical sciences ,Computer Science (miscellaneous) ,030304 developmental biology ,Photoacoustic effect ,lcsh:Computer software ,0303 health sciences ,business.industry ,Ultrasound ,Computer Graphics and Computer-Aided Design ,lcsh:QA76.75-76.765 ,Polygon-scanning ,lcsh:R858-859.7 ,Original Article ,Ultrasonic sensor ,Computer Vision and Pattern Recognition ,business ,Software ,Preclinical imaging - Abstract
Photoacoustic microscopy is an in vivo imaging technology based on the photoacoustic effect. It is widely used in various biomedical studies because it can provide high-resolution images while being label-free, safe, and harmless to biological tissue. Polygon-scanning is an effective scanning method in photoacoustic microscopy that can realize fast imaging of biological tissue with a large field of view. However, in polygon-scanning, fluctuations of the rotating motor speed and the geometric error of the rotating mirror cause image distortions, which seriously affect the photoacoustic-microscopy imaging quality. To improve the image quality of photoacoustic microscopy using polygon-scanning, an image correction method is proposed based on accurate ultrasound positioning. In this method, the photoacoustic and ultrasound imaging data of the sample are simultaneously obtained, and the angle information of each mirror used in the polygon-scanning is extracted from the ultrasonic data to correct the photoacoustic images. Experimental results show that the proposed method can significantly reduce image distortions in photoacoustic microscopy, with the image dislocation offset decreasing from 24.774 to 10.365 μm.
- Published
- 2021