MR navigator‐echo monitoring of temporal changes in diaphragm position: Implications for MR coronary angiography

Taylor, Andrew M.; Jhooti, Permi; Wiesmann, Frank; Keegan, Jennifer; Firmin, David N.; Pennell, Dudley J.

doi:10.1002/jmri.1880070404

Cited by 185 publications

(140 citation statements)

References 10 publications

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“…Imaging during free (unrestricted) breathing offers obvious advantages over breathholding. A novel technique for minimizing respiratory-related motion is with the use of real-time navigator echoes 25,27,[212][213][214][215][216][217] that interrogate an interface such as the diaphragm-lung or heart-lung. 25 Positional changes of this interface along the axis of the navigator can then be followed through the normal respiratory cycle.…”

Section: Yucel Et Al Magnetic Resonance Angiographymentioning

confidence: 99%

Magnetic Resonance Angiography

Yucel¹,

Anderson²,

Edelman³

et al. 1999

Circulation

126

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Section: Yucel Et Al Magnetic Resonance Angiographymentioning

confidence: 99%

Magnetic Resonance Angiography

Yucel¹,

Anderson²,

Edelman³

et al. 1999

Circulation

126

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“…However, during prolonged studies drifting of the respiratory pattern leads to a corresponding fall in efficiency (2), resulting in registration errors between scans and a frequent need to reposition the acceptance window. Real-time slice-following (3) has the potential to increase the scan efficiency and reduce the sensitivity to respiratory drift by allowing the implementation of a larger navigator acceptance window.…”

mentioning

confidence: 99%

Coronary artery motion with the respiratory cycle during breath‐holding and free‐breathing: Implications for slice‐followed coronary artery imaging

Keegan¹,

Gatehouse²,

Yang

et al. 2002

Magnetic Resonance in Med

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The displacement of the right coronary artery (RCA) origin with respiratory position was determined relative to the dome of the right hemidiaphragm in three orthogonal directions in eight healthy subjects. Both multiple breath-hold and free-breathing acquisitions were used, and motion correction factors for slicefollowing applications were determined. The correction factors for all three directions showed considerable intersubject variability. The mean superior-inferior factor was slightly less in free-breathing than in breath-holding (0.26 vs. 0.29, P ‫؍‬ ns), and much less than the fixed value of 0.6 frequently implemented with slice-following. The anterior-posterior correction factors were uniformly low in free-breathing, and significantly less than those obtained from breath-holding (0.04 vs. 0.14, P < .05), while the mean left-right correction factors were approximately 0.1 for both. It is concluded that subject variability in correction factors, together with within-subject differences between breath-holding and free-breathing, is such that slice-following should be performed with subject-specific factors determined from free-breathing acquisitions. Key words: respiratory motion; slice-following; coronary artery; breath-holding; free-breathing Navigator-echo controlled free-breathing coronary artery studies (1) typically use a navigator positioned through the dome of the right hemidiaphragm, and an acceptance window of 5 mm to give a reasonable compromise between scan efficiency and image quality. However, during prolonged studies drifting of the respiratory pattern leads to a corresponding fall in efficiency (2), resulting in registration errors between scans and a frequent need to reposition the acceptance window. Real-time slice-following (3) has the potential to increase the scan efficiency and reduce the sensitivity to respiratory drift by allowing the implementation of a larger navigator acceptance window.The efficacy of real-time slice-following is critically dependent on the accuracy with which the motion of the heart can be predicted from the navigator echo data. In 1995, Wang and colleagues (4) used multiple 2D breathhold acquisitions to show a linear relationship between the superior-inferior (SI) motion of the heart and that of the diaphragm in healthy volunteers. In this subject group, the mean correction factor relating the SI motion of the right coronary artery (RCA) origin to that of the diaphragm was 0.57 (Ϯ0.26), and the anterior-posterior (AP) motion was approximately 20% of that in the SI direction (or 12% of that of the diaphragm). Some implementations of slicefollowing consequently use a fixed SI correction factor of 0.6, with or without a fixed AP factor of 0.12 (5,6). This approach has been shown to improve the quality of images acquired with 5-mm and 7-mm navigator acceptance windows, but has failed to produce good quality images when the acceptance window is increased to cover the entire range of respiratory positions (3). This may be due to a failure of the linear model, or to in...

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“…The navigator echo procedure appears to have more application in clinical practice, as the breath hold method is not generally possible for patients with congestive heart failure, CAD, and chronic obstructive pulmonary disease [79,80]. Nonetheless, in those cases the nature of images might be debased because of conflicting breathing patterns and patient developments [82]. The other option systems incorporate magnetic resonance subtraction techniques, which incorporate particular labeling of blood in the aortic root and suppression of the foundation tissue.…”

Section: Respiratory Motionmentioning

confidence: 99%

Comparison of Diagnostic Performance of Multi Detector CT Angiography with Conventional Coronary Angiography for Assessment of Coronary Artery Disease

Bayar¹,

Feng²

2017

J Pain Relief

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Aim: The point of this study was to reflectively assess the analytic exactness of multi detector angiography as a different option for conventional coronary angiography in evaluating coronary artery disease. Materials and Methods:This review study selected 57 patients, who experienced both conventional coronary angiography (CCA), and additionally multi-detector computed coronary angiography (MDCT). Aggregate of 931 open segments were studied. Of which 95 portions indicated shifted level of stenosis, with 34 segments <50% stenosis, 43 segments 50-70% stenosis and 18 segments >70% stenosis. Results:The affectability and specificity of 64 slice MDCT for identifying stenosis in <50%, 50-70% and >70% are 78.57% and 99.34%; 81.08% and 99.33%; 87.5% and 99.78%. The positive predictive value (PPV) and negative predictive value (NPV) are 78.57% and 99.34%; 83.33% and 99.22%; 87.5% and 99.78% individually. Over all exact nesses are 88.95%, 90.2% and 93.64% separately. There was no critical contrast in analytic exactness between conventional coronary angiography and 64 slice computed tomography in moderate (50-70%) and additionally severe (>70%) stenosis (p>0.05). Be that as it may, critical contrast was found in gentle (<50%) stenosis (p<0.05). Conclusion:Indicative exactness of multi detector coronary angiography (MDCT) was found to be higher in moderate and extreme stenosis and can be utilized as a substitute to conventional coronary angiography (CCA).

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MR navigator‐echo monitoring of temporal changes in diaphragm position: Implications for MR coronary angiography

Cited by 185 publications

References 10 publications

Magnetic Resonance Angiography

Magnetic Resonance Angiography

Coronary artery motion with the respiratory cycle during breath‐holding and free‐breathing: Implications for slice‐followed coronary artery imaging

Comparison of Diagnostic Performance of Multi Detector CT Angiography with Conventional Coronary Angiography for Assessment of Coronary Artery Disease

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