A 1200 ELEMENT DETECTOR SYSTEM FOR SYNCHROTRON-BASED CORONARY ANGIOGRAPHY

被引:10
|
作者
THOMPSON, AC
LAVENDER, WM
CHAPMAN, D
GMUR, N
THOMLINSON, W
ROSSO, V
SCHULZE, C
RUBENSTEIN, E
GIACOMINI, JC
GORDON, HJ
DERVAN, JP
机构
[1] STANFORD UNIV,HANSEN EXPTL PHYS LAB,STANFORD,CA 94305
[2] BROOKHAVEN NATL LAB,NATL SYNCHROTRON LIGHT SOURCE,UPTON,NY 11973
[3] UNIV PISA,DIPARTIMENTO FIS,I-56100 PISA,ITALY
[4] EUROPEAN SYNCHROTRON RADIAT FACIL,GRENOBLE,FRANCE
[5] STANFORD UNIV,DEPT CHEM,STANFORD,CA 94305
[6] SUNY STONY BROOK,DIV CARDIOL,STONY BROOK,NY 11794
来源
NUCLEAR INSTRUMENTS & METHODS IN PHYSICS RESEARCH SECTION A-ACCELERATORS SPECTROMETERS DETECTORS AND ASSOCIATED EQUIPMENT | 1994年 / 347卷 / 1-3期
基金
美国国家卫生研究院;
关键词
D O I
10.1016/0168-9002(94)91945-3
中图分类号
TH7 [仪器、仪表];
学科分类号
0804 ; 080401 ; 081102 ;
摘要
A 1200 channel Si(Li) detector system has been developed for transvenous coronary angiography experiments using synchrotron radiation. It is part of the synchrotron medical imaging facility at the National Synchrotron Light Source. The detector is made from a single crystal of lithium-drifted silicon with an active area 150 mm long x 11 mm high x 5 mm thick. The elements are arranged in two parallel rows of 600 elements with a center-to-center spacing of 0.25 mm. All 1200 elements are read out simultaneously every 4 ms. An Intel 80486 based computer with a high speed digital signal processing interface is used to control the beamline hardware and to acquire a series of images. The signal-to-noise, linearity and resolution of the system have been measured. Human images have been taken with this system.
引用
收藏
页码:545 / 552
页数:8
相关论文
共 50 条
  • [41] Intravenous coronary angiography with synchrotron radiation at HASYLAB
    Dix, W. -R.
    Dill, T.
    Hamm, C. W.
    Jung, M.
    Kupper, W.
    Lohmann, M.
    Reime, B.
    Ventura, R.
    NUCLEAR PHYSICS A, 1999, 654 (01) : 1043C - 1046C
  • [42] Coronary angiography in rats using synchrotron radiation
    Matsushita, S
    Hyodo, K
    Akishima, S
    Sato, F
    Imazuru, T
    Noma, M
    Hiramatsu, Y
    Shigeta, O
    Sakakibara, Y
    NUCLEAR INSTRUMENTS & METHODS IN PHYSICS RESEARCH SECTION A-ACCELERATORS SPECTROMETERS DETECTORS AND ASSOCIATED EQUIPMENT, 2005, 548 (1-2): : 94 - 98
  • [43] TRANSVENOUS CORONARY ANGIOGRAPHY USING SYNCHROTRON RADIATION
    THOMPSON, AC
    HOFSTADTER, R
    OTIS, JN
    ZEMAN, HD
    KERNOFF, RS
    RUBENSTEIN, E
    GIACOMINI, JC
    GORDON, HJ
    BROWN, GS
    THOMLINSON, W
    NUCLEAR INSTRUMENTS & METHODS IN PHYSICS RESEARCH SECTION A-ACCELERATORS SPECTROMETERS DETECTORS AND ASSOCIATED EQUIPMENT, 1988, 266 (1-3): : 252 - 259
  • [44] Coronary angiography with synchrotron radiation: A brief review
    Sanmiguel, RE
    Herrera, G
    MEDICAL PHYSICS, 1998, 440 : 91 - 95
  • [45] Transvenous coronary angiography in humans with synchrotron radiation
    Thomlinson, W
    BIOMEDICAL APPLICATIONS OF SYNCHROTRON RADIATION, 1996, 128 : 127 - 153
  • [46] Quantifying the uncertainty of synchrotron-based lattice strain measurements
    Schuren, J. C.
    Miller, M. P.
    JOURNAL OF STRAIN ANALYSIS FOR ENGINEERING DESIGN, 2011, 46 (07): : 663 - 681
  • [47] Biomedical applications of the ESRF synchrotron-based microspectroscopy platform
    Bohic, S.
    Cotte, M.
    Salome, M.
    Fayard, B.
    Kuehbacher, M.
    Cloetens, P.
    Martinez-Criado, G.
    Tucoulou, R.
    Susini, J.
    JOURNAL OF STRUCTURAL BIOLOGY, 2012, 177 (02) : 248 - 258
  • [48] SAPT: a synchrotron-based proton therapy facility in Shanghai
    Man-Zhou Zhang
    De-Ming Li
    Li-Ren Shen
    Hai-Rong Zhang
    Zhi-Ling Chen
    Han-Wen Du
    Ming Gu
    Rui Li
    De-Kang Liu
    Yue-Hu Pu
    Jun-Feng Yu
    Jian-Feng Chen
    Chu Chen
    Chun-Long Guo
    Hao Guo
    Ge-Yang Jiang
    Zhi-Qiang Jiang
    Lin Jin
    Wen-Jing Li
    Xiu-Fang Li
    Ye Lin
    Ming Liu
    Yong-Hao Liu
    Ya-Juan Liu
    Ming Lv
    Qing-Ru Mi
    Lian-Hua Ouyang
    Wei-Guo Shi
    Hang Shu
    Qi-Sheng Tang
    Kun Wang
    Zhi-Shan Wang
    Jun Wu
    Xiao-Bing Wu
    Jia-Qiang Xu
    Wen-Zhen Xu
    Chong-Xian Yin
    Cheng Yu
    Ren-Xian Yuan
    Qi-Bing Yuan
    Hai-Qun Zhang
    Miao Zhang
    Wen-Zhi Zhang
    Li-Ying Zhao
    Wei-Min Zhou
    Shou-Xian Fang
    Xi-Dong Sun
    Zhen-Tang Zhao
    Nuclear Science and Techniques, 2023, 34
  • [49] SAPT: a synchrotron-based proton therapy facility in Shanghai
    Zhang, Man-Zhou
    Li, De-Ming
    Shen, Li-Ren
    Zhang, Hai-Rong
    Chen, Zhi-Ling
    Du, Han-Wen
    Gu, Ming
    Li, Rui
    Liu, De-Kang
    Pu, Yue-Hu
    Yu, Jun-Feng
    Chen, Jian-Feng
    Chen, Chu
    Guo, Chun-Long
    Guo, Hao
    Jiang, Ge-Yang
    Jiang, Zhi-Qiang
    Jin, Lin
    Li, Wen-Jing
    Li, Xiu-Fang
    Lin, Ye
    Liu, Ming
    Liu, Yong-Hao
    Liu, Ya-Juan
    Lv, Ming
    Mi, Qing-Ru
    Ouyang, Lian-Hua
    Shi, Wei-Guo
    Shu, Hang
    Tang, Qi-Sheng
    Wang, Kun
    Wang, Zhi-Shan
    Wu, Jun
    Wu, Xiao-Bing
    Xu, Jia-Qiang
    Xu, Wen-Zhen
    Yin, Chong-Xian
    Yu, Cheng
    Yuan, Ren-Xian
    Yuan, Qi-Bing
    Zhang, Hai-Qun
    Zhang, Miao
    Zhang, Wen-Zhi
    Zhao, Li-Ying
    Zhou, Wei-Min
    Fang, Shou-Xian
    Sun, Xi-Dong
    Zhao, Zhen-Tang
    NUCLEAR SCIENCE AND TECHNIQUES, 2023, 34 (10)
  • [50] Applications of synchrotron-based X-ray microprobes
    Bertsch, PM
    Hunter, DB
    CHEMICAL REVIEWS, 2001, 101 (06) : 1809 - 1842
12345