An Human-Computer Interactive Augmented Reality System for Coronary Artery Diagnosis Planning and Training

被引：0

作者：

Qiming Li

Chen Huang

Shengqing Lv

Zeyu Li

Yimin Chen

Lizhuang Ma

机构：

[1] Shanghai Jiaotong University,Laboratory of Digital Media and Data Reconstruction

[2] Shanghai Maritime University,Department of Computer Science and Technology

[3] Shanghai University,Department of Computer Science and Technology

[4] Shanghai Jiaotong University School of Medicine,Computer Center, Ruijin Hospital

来源：

Journal of Medical Systems | 2017年 / 41卷

关键词：

Coronary artery; Diagnosis and preoperative planning; Trainning; Augmented reality; Human computer interaction;

D O I：

暂无

中图分类号：

学科分类号：

摘要：

In order to let the doctor carry on the coronary artery diagnosis and preoperative planning in a more intuitive and more natural way, and to improve the training effect for interns, an augmented reality system for coronary artery diagnosis planning and training (ARS-CADPT) is designed and realized in this paper. At first, a 3D reconstruction algorithm based on computed tomographic (CT) images is proposed to model the coronary artery vessels (CAV). Secondly, the algorithms of static gesture recognition and dynamic gesture spotting and recognition are presented to realize the real-time and friendly human-computer interaction (HCI), which is the characteristic of ARS-CADPT. Thirdly, a Sort-First parallel rendering and splicing display subsystem is developed, which greatly expands the capacity of student users. The experimental results show that, with the use of ARS-CADPT, the reconstruction accuracy of CAV model is high, the HCI is natural and fluent, and the visual effect is good. In a word, the system fully meets the application requirement.

引用

共 68 条

[1]

Miller JM(2008)Diagnostic Performance of Coronary Angiography by 64-row CT N. Engl. J. Med. 359 2324-2336

[2]

Rochitte CE(2006)Comparison of Accuracy of 64-slice Cardiovascular Computed Tomography with Coronary Angiography in Patients with Suspected Coronary Artery Disease Am. J. Cardiol. 97 172-174

[3]

Dewey M(1994)Case Study: Observing a Volume Rendered Fetus within a Pregnant Patient Proc. IEEE Vis. 94 364-368

[4]

Fine JJ(1998)Augmented reality systems for medical applications: Improving surgical procedures by enhancing the surgeon's 'view' of the patient IEEE Eng. Med. Biol. Mag. 17 49-58

[5]

Hopkins CB(2014)Real-time advanced spinal surgery via visible patient model and augmented reality system Comput. Methods Prog. Biomed. 113 869-881

[6]

Ruff N(2010)Augmented reality in minimally invasive surgery Adv. Biomed. Sens. Meas. Instrumen. Syst 55 LNEE 305-320

[7]

Newton FC(2011)A New Approach to Haptic Rendering of Guiderwires for Use in Minimally Invasive Surgical Simulation Comput. Animat. Virtual Worlds 22 261-268

[8]

State A(1997)A survey of augmented reality Presence Teleoper. Virtual Environ. 6 355-385

[9]

Chen DT(2014)Multi-dimensional tumor detection in automated whole breast ultrasound using topographic watershed IEEE Trans. Med. Imaging 33 1503-1511

[10]

Tector C(2011)A Comprehensive Interpolation for Medical Slices Based on Combination of Linear and Matching Interpolation Chin. J. Electron. 20 82-84

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