Takuya Hino1, Akinori Tsunomori2, Takenori Fukumoto2, Akinori Hata1, Masako Ueyama3, Atsuko Kurosaki4, Tsutomu Yoneyama2, Sumiya Nagatsuka2, Shoji Kudoh5, Hiroto Hatabu1. 1. Center for Pulmonary Functional Imaging, Department of Radiology, Brigham and Women's Hospital, Harvard Medical School, Boston, MA, USA. 2. R&D Promotion Division, Healthcare Business Headquarters, Konica Minolta, Hachioji-shi, Tokyo, Japan. 3. Department of Health Care, Fukujuji Hospital, Japan Anti-Tuberculosis Association, Kiyose, Tokyo, Japan. 4. Department of Diagnostic Radiology, Fukujuji Hospital, Japan Anti-Tuberculosis Association, Kiyose, Tokyo, Japan. 5. Japan Anti-Tuberculosis Association, Chiyoda-ku, Tokyo, Japan.
Abstract
OBJECTIVES: To explore the feasibility of Vector-Field DXR (VF-DXR) using optical flow method (OFM). METHODS: Five healthy volunteers and five COPD patients were studied. DXR was performed in the standing position using a prototype X-ray system (Konica Minolta Inc., Tokyo, Japan). During the examination, participants took several tidal breaths and one forced breath. DXR image file was converted to the videos with different frames per second (fps): 15 fps, 7.5 fps, five fps, three fps, and 1.5 fps. Pixel-value gradient was calculated by the serial change of pixel value, which was subsequently converted mathematically to motion vector using OFM. Color-coding map and vector projection into horizontal and vertical components were also tested. RESULTS: Dynamic motion of lung and thorax was clearly visualized using VF-DXR with an optimal frame rate of 5 fps. Color-coding map and vector projection into horizontal and vertical components were also presented. VF-DXR technique was also applied in COPD patients. CONCLUSION: The feasibility of VF-DXR was demonstrated with small number of healthy subjects and COPD patients. ADVANCES IN KNOWLEDGE: A new Vector-Field Dynamic X-ray (VF-DXR) technique is feasible for dynamic visualization of lung, diaphragms, thoracic cage, and cardiac contour.
OBJECTIVES: To explore the feasibility of Vector-Field DXR (VF-DXR) using optical flow method (OFM). METHODS: Five healthy volunteers and five COPD patients were studied. DXR was performed in the standing position using a prototype X-ray system (Konica Minolta Inc., Tokyo, Japan). During the examination, participants took several tidal breaths and one forced breath. DXR image file was converted to the videos with different frames per second (fps): 15 fps, 7.5 fps, five fps, three fps, and 1.5 fps. Pixel-value gradient was calculated by the serial change of pixel value, which was subsequently converted mathematically to motion vector using OFM. Color-coding map and vector projection into horizontal and vertical components were also tested. RESULTS: Dynamic motion of lung and thorax was clearly visualized using VF-DXR with an optimal frame rate of 5 fps. Color-coding map and vector projection into horizontal and vertical components were also presented. VF-DXR technique was also applied in COPD patients. CONCLUSION: The feasibility of VF-DXR was demonstrated with small number of healthy subjects and COPD patients. ADVANCES IN KNOWLEDGE: A new Vector-Field Dynamic X-ray (VF-DXR) technique is feasible for dynamic visualization of lung, diaphragms, thoracic cage, and cardiac contour.
Authors: Andreas Fouras; Beth J Allison; Marcus J Kitchen; Stephen Dubsky; Jayne Nguyen; Kerry Hourigan; Karen K W Siu; Rob A Lewis; Megan J Wallace; Stuart B Hooper Journal: Ann Biomed Eng Date: 2011-12-22 Impact factor: 3.934