ECG-based gating in ultra high field cardiovascular magnetic resonance using an independent component analysis approach

Krug, Johannes; Rose, Georg; Clifford, Gari D.; Oster, Julien

doi:10.1186/1532-429x-15-104

Cited by 31 publications

(35 citation statements)

References 31 publications

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“…However, EBS increases for ECG gated images during relaxation in contrast to DUS where EBS remains considerably flat. That finding may be caused by the magneto‐hydro‐dynamic‐effect because it is more pronounced during the ejection phase, i.e., during systole, when the left ventricular blood flows into the aorta and the pulmonary arteries .…”

Section: Discussionmentioning

confidence: 99%

Doppler ultrasound compared with electrocardiogram and pulse oximetry cardiac triggering: A pilot study

Kording

Schoennagel

Lund

et al. 2014

Magnetic Resonance in Med

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Section: Discussionmentioning

confidence: 99%

Doppler ultrasound compared with electrocardiogram and pulse oximetry cardiac triggering: A pilot study

Kording

Schoennagel

Lund

et al. 2014

Magnetic Resonance in Med

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“…When an artery is exposed to a magnetic field, the blood charged particles are deviated by the Lorentz force thus inducing electrical currents and voltages along the vessel walls and in the neighboring tissues. Such a situation may occur in several biomedical applications: magnetic resonance imaging (MRI) [1]- [5], magnetic drug transport and targeting [6]- [9], tissue engineering [10]- [13]… An optimal modelisation of the magnetohydrodynamic flow of blood should include the pulsatility of flow, the deformability and conductivity of the vessel wall, together with the induced electrostatic and electromagnetic fields. This leads to a complex mathematical problem and analytical solutions may be found only under restrictive hypotheses.…”

Section: Introductionmentioning

confidence: 99%

Stationary Flow of Blood in a Rigid Vessel in the Presence of an External Magnetic Field: Considerations about the Forces and Wall Shear Stresses

Drochon¹,

Robin²,

Fokapu³

et al. 2016

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The magnetohydrodynamics laws govern the motion of a conducting fluid, such as blood, in an externally applied static magnetic field B 0 . When an artery is exposed to a magnetic field, the blood charged particles are deviated by the Lorentz force thus inducing electrical currents and voltages along the vessel walls and in the neighboring tissues. Such a situation may occur in several biomedical applications: magnetic resonance imaging (MRI), magnetic drug transport and targeting, tissue engineering… In this paper, we consider the steady unidirectional blood flow in a straight circular rigid vessel with non-conducting walls, in the presence of an exterior static magnetic field. The exact solution of Gold (1962) (with the induced fields not neglected) is revisited. It is shown that the integration over a cross section of the vessel of the longitudinal projection of the Lorentz force is zero, and that this result is related to the existence of current return paths, whose contributions compensate each other over the section. It is also demonstrated that the classical definition of the shear stresses cannot apply in this situation of magnetohydrodynamic flow, because, due to the existence of the Lorentz force, the axisymmetry is broken.

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“…Reliable trigger information has been demonstrated when using acoustic cardiac triggering and gating for UHF-CMR (Figure 4) [61,68,70]. Further alternatives for cardiac synchronization include post-processing of the ECG signal to reduce MHD induced distortions of the ECG trace [71,72]. Wideband radar, magnetic field probes or optical systems have been proposed for physiological monitoring [73][74][75].…”

Section: Ancillary Devices For Cardiac Synchronizationmentioning

confidence: 99%

Myocardial T2* Mapping with Ultrahigh Field Magnetic Resonance: Physics and Frontier Applications

Huelnhagen

Paul

et al. 2017

Front. Phys.

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Cardiovascular magnetic resonance imaging (CMR) has become an indispensable clinical tool for the assessment of morphology, function and structure of the heart muscle. By exploiting quantification of the effective transverse relaxation time (T 2 * ) CMR also affords myocardial tissue characterization and probing of cardiac physiology, both being in the focus of ongoing research. These developments are fueled by the move to ultrahigh magnetic field strengths, which permits enhanced sensitivity and spatial resolution that help to overcome limitations of current clinical MR systems with the goal to contribute to a better understanding of myocardial (patho)physiology in vivo. In this context, the aim of this report is to introduce myocardial T 2 * mapping at ultrahigh magnetic fields as a promising technique to non-invasively assess myocardial (patho)physiology. For this purpose the basic principles of T 2 * assessment, the biophysical mechanisms determining T 2 * and (pre)clinical applications of myocardial T 2 * mapping are presented.Technological challenges and solutions for T 2 * sensitized CMR at ultrahigh magnetic field strengths are discussed followed by a review of acquisition techniques and post-processing approaches. Preliminary results derived from myocardial T 2 * mapping in healthy subjects and cardiac patients at 7.0 T are presented. A concluding section discusses remaining questions and challenges and provides an outlook on future developments and potential clinical applications.

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ECG-based gating in ultra high field cardiovascular magnetic resonance using an independent component analysis approach

Cited by 31 publications

References 31 publications

Doppler ultrasound compared with electrocardiogram and pulse oximetry cardiac triggering: A pilot study

Doppler ultrasound compared with electrocardiogram and pulse oximetry cardiac triggering: A pilot study

Stationary Flow of Blood in a Rigid Vessel in the Presence of an External Magnetic Field: Considerations about the Forces and Wall Shear Stresses

Myocardial T2* Mapping with Ultrahigh Field Magnetic Resonance: Physics and Frontier Applications

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