Cardiorespiratory motion‐tracking via self‐refocused rosette navigators

Rigie, David; Vahle, Thomas; Zhao, Tiejun; Czekella, Björn; Frohwein, Lynn Johann; Schäfers, Klaus P.; Boada, Fernando E.

doi:10.1002/mrm.27609

Cited by 12 publications

(16 citation statements)

References 25 publications

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“…At the moment, the sequence is implemented as a separate scan in the imaging workflow. However, due to the low acquisition time of around 30 ms per image, it is easily conceivable that it can be implemented as a 2D navigator-sequence interlaced between the excitations of the clinical sequences, similar to the approach in [31]. However, one limiting factor could be that clinical sequences have to be modified to incorporate this navigator acquisition.…”

Section: Discussionmentioning

confidence: 99%

Estimation of Physiological Motion Using Highly Accelerated Continuous 2D MRI

Frohwein,

Büther,

Schäfers

2019

Preprint

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Patient motion is well-known for degrading image quality during medical imaging. Especially positron emission tomography (PET) is susceptible to motion due to its usually long scan times. In hybrid PET/MRI (magnetic resonance imaging), simultaneously acquired dynamic MRI data can be used to correct for motion. Usually, MRI model-based motion correction approaches are applied to the PET data. However, these approaches may fail for nonpredictable, irregular motion. We propose a novel approach for the continuous and real-time tracking of motion using highly accelerated, dynamic MRI for an accurate motion estimation. For this purpose, a TurboFLASH sequence is utilized in single-shot mode with additional exploiting GRAPPA acceleration. Sampling frequency for one slice is up to 26 ms and 520 ms for one 3D volume of 20 coronal slices. Principal component analysis and a phase-sensitive resorting of slices is performed to restore temporal consistency of the volumes. Motion is estimated from these volumes using hyper-elastic registration. The approach is validated with the help of a dynamic thorax phantom as well as with eleven healthy volunteers. Phantom ground-truth data demonstrates that the approach produces an accurate motion estimation. Volunteer validation proves that the approach is also valid for different respiratory amplitudes including highly irregular breathing. The approach could be

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Section: Discussionmentioning

confidence: 99%

Estimation of Physiological Motion Using Highly Accelerated Continuous 2D MRI

Frohwein,

Büther,

Schäfers

2019

Preprint

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“…Another type of navigator involves dedicated gradient events introduced within the MR pulse sequence. For example, a “butterfly” navigator 16 provides motion‐tracking information during data acquisition that is well suited to Cartesian sampling, whereas “rosette” navigators 17 sample the motion information prior to acquisition of imaging data and can be incorporated into almost any sampling scheme. Even though these navigators do not significantly impact the scan efficiency, they still require specific pulse sequence modifications.…”

Section: Introductionmentioning

confidence: 99%

Free‐breathing radial imaging using a pilot‐tone radiofrequency transmitter for detection of respiratory motion

Solomon

Rigie

Vahle

et al. 2020

Magnetic Resonance in Med

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To describe an approach for detection of respiratory signals using a transmitted radiofrequency (RF) reference signal called Pilot-Tone (PT) and to use the PT signal for creation of motion-resolved images based on 3D stack-of-stars imaging under free-breathing conditions. Methods: This work explores the use of a reference RF signal generated by a small RF transmitter, placed outside the MR bore. The reference signal is received in parallel to the MR signal during each readout. Because the received PT amplitude is modulated by the subject's breathing pattern, a respiratory signal can be obtained by detecting the strength of the received PT signal over time. The breathing-induced PT signal modulation can then be used for reconstructing motion-resolved images from free-breathing scans. The PT approach was tested in volunteers using a radial stackof-stars 3D gradient echo (GRE) sequence with golden-angle acquisition. Results: Respiratory signals derived from the proposed PT method were compared to signals from a respiratory cushion sensor and k-space-center-based self-navigation under different breathing conditions. Moreover, the accuracy was assessed using a modified acquisition scheme replacing the golden-angle scheme by a zero-angle acquisition. Incorporating the PT signal into eXtra-Dimensional (XD) motion-resolved reconstruction led to improved image quality and clearer anatomical depiction of the lung and liver compared to k-space-center signal and motion-averaged reconstruction, when binned into 6, 8, and 10 motion states. Conclusion: PT is a novel concept for tracking respiratory motion. Its small dimension (8 cm), high sampling rate, and minimal interaction with the imaging scan offers great potential for resolving respiratory motion.

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“…Alternative methods estimate cardiac and respiratory motion from surrogate signals that are derived from the continuous acquisition of the k‐space centre, from a region‐of‐interest in the image domain, or from navigator echoes that are added to the imaging sequence. Some of these methods have sequence design constraints; others are limited to a specific k‐space sampling trajectory.…”

Section: Introductionmentioning

confidence: 99%

“…Other external devices that are independent to the electrical activity of the heart are based on finger plethysmography, Doppler ultrasound, 7 or on heart tones (phonocardiograms). 8 Alternative methods estimate cardiac and respiratory motion from surrogate signals that are derived from the continuous acquisition of the k-space centre, [9][10][11][12][13][14][15][16][17] from a region-of-interest in the image domain, 18,19 or from navigator echoes [20][21][22][23] that are added to the imaging sequence. Some of these methods have sequence design constraints; others are limited to a specific k-space sampling trajectory.…”

Section: Introductionmentioning

confidence: 99%

Scattering matrix imaging pulse design for real‐time respiration and cardiac motion monitoring

Jaeschke

Robson

Hess

2019

Magnetic Resonance in Med

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Purpose The scattering matrix (S‐matrix) of a parallel transmit (pTx) coil is sensitive to physiological motion but requires additional monitoring RF pulses to be measured. In this work, we present and evaluate pTx RF pulse designs that simultaneously excite for imaging and measure the S‐matrix to generate real‐time motion signals without prolonging the image sequence. Theory and Methods Three pTx waveforms for measuring the S‐matrix were identified and superimposed onto the imaging excitation RF pulses: (1) time division multiplexing, (2) frequency division multiplexing, and (3) code division multiplexing. These 3 methods were evaluated in healthy volunteers for scattering sensitivity and image artefacts. The S‐matrix and real‐time motion signals were calculated on the image calculation environment of the MR scanner. Prospective cardiac triggers were identified in early systole as a high rate of change of the cardiac motion signal. Monitoring accuracy was compared against electrocardiogram or the imaged diaphragm position. Results All 3 monitoring approaches measure the S‐matrix during image excitation with quality correlated to input power. No image artefacts were observed for frequency multiplexing, and low energy artefacts were observed in the other methods. The accuracy of the achieved prospective cardiac gating was 15 ± 16 ms for breath hold and 24 ± 17 ms during free breathing. The diaphragm position prediction accuracy was 1.3 ± 0.9 mm. In all volunteers, good quality cine images were acquired for breath hold scans and dual gated CINEs were demonstrated. Conclusion The S‐matrix can be measured during image excitation to generate real‐time cardiac and respiratory motion signals for prospective gating. No artefacts are introduced when frequency division multiplexing is used.

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Cardiorespiratory motion‐tracking via self‐refocused rosette navigators

Cited by 12 publications

References 25 publications

Estimation of Physiological Motion Using Highly Accelerated Continuous 2D MRI

Estimation of Physiological Motion Using Highly Accelerated Continuous 2D MRI

Free‐breathing radial imaging using a pilot‐tone radiofrequency transmitter for detection of respiratory motion

Scattering matrix imaging pulse design for real‐time respiration and cardiac motion monitoring

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