Abstract
Segmented cardiac acquisitions generally require the use of an electrocardiogram (ECG) in combination with a breathhold or a respiratory navigator placed on the diaphragm. These techniques necessitate patient cooperation and increase the complexity of cardiac imaging. The ECG signal may be distorted inside the magnet by interferences from radiofrequency and gradient action. Breathhold acquisition limits the total scan time, while navigators on the diaphragm might not fully reflect respiratory-induced motion of the heart. To overcome some of these problems, several self-gating (SG) or "wireless" techniques have recently been presented. All of these approaches, however, are based on either cardiac triggering or respiratory gating, or the data are processed retrospectively, reducing the efficiency of data acquisition. In this work a prospective SG approach for free-breathing imaging is presented that requires neither ECG gating nor respiratory navigation. The motion data used for cardiac triggering and respiratory gating are extracted from the repeatedly acquired k-space center. Based on computer simulations and in vivo data of the heart, it is shown that cardiac as well as respiratory motion can be accurately extracted in real time. Using the method proposed, the scan efficiency could be significantly increased while preserving image quality relative to retrospective SG approaches.
Highlights
In cardiac imaging, self-gating principles may be applied for either cardiac triggering [1] or respiratory gating [2]
Image quality obtained with the proposed method was found to be comparable to the ECG triggered breathheld acquisitions while the scan efficiency was significantly increased
Due to the local sensitivities of the coil elements it was found that some elements exhibit stronger cardiac variations while others provided better respiratory signal variations
Summary
Self-gating principles may be applied for either cardiac triggering [1] or respiratory gating [2]. These methods simplify patient setup and scan planning as placement of physiological sensors and dedicated respiratory navigation methods become unnecessary. In this work a prospective self-gating approach for time-efficient free breathing cardiac imaging is presented neither requiring an electrocardiogram (ECG) nor respiratory navigation. The motion data needed for synchronization are extracted and processed in real-time from repeatedly acquired data at k-space center. Image quality obtained with the proposed method was found to be comparable to the ECG triggered breathheld acquisitions while the scan efficiency was significantly increased
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