OBJECTIVE: This study investigates the application of a modified reversed gradient algorithm to the Propeller-EPI imaging method (periodically rotated overlapping parallel lines with enhanced reconstruction based on echo-planar imaging readout) for corrections of geometric distortions due to the EPI readout. MATERIALS AND METHODS: Propeller-EPI acquisition was executed with 360-degree rotational coverage of the k-space, from which the image pairs with opposite phase-encoding gradient polarities were extracted for reversed gradient geometric and intensity corrections. The spatial displacements obtained on a pixel-by-pixel basis were fitted using a two-dimensional polynomial followed by low-pass filtering to assure correction reliability in low-signal regions. Single-shot EPI images were obtained on a phantom, whereas high spatial resolution T2-weighted and diffusion tensor Propeller-EPI data were acquired in vivo from healthy subjects at 3.0 Tesla, to demonstrate the effectiveness of the proposed algorithm. RESULTS: Phantom images show success of the smoothed displacement map concept in providing improvements of the geometric corrections at low-signal regions. Human brain images demonstrate prominently superior reconstruction quality of Propeller-EPI images with modified reversed gradient corrections as compared with those obtained without corrections, as evidenced from verification against the distortion-free fast spin-echo images at the same level. CONCLUSIONS: The modified reversed gradient method is an effective approach to obtain high-resolution Propeller-EPI images with substantially reduced artifacts.
OBJECTIVE: This study investigates the application of a modified reversed gradient algorithm to the Propeller-EPI imaging method (periodically rotated overlapping parallel lines with enhanced reconstruction based on echo-planar imaging readout) for corrections of geometric distortions due to the EPI readout. MATERIALS AND METHODS: Propeller-EPI acquisition was executed with 360-degree rotational coverage of the k-space, from which the image pairs with opposite phase-encoding gradient polarities were extracted for reversed gradient geometric and intensity corrections. The spatial displacements obtained on a pixel-by-pixel basis were fitted using a two-dimensional polynomial followed by low-pass filtering to assure correction reliability in low-signal regions. Single-shot EPI images were obtained on a phantom, whereas high spatial resolution T2-weighted and diffusion tensor Propeller-EPI data were acquired in vivo from healthy subjects at 3.0 Tesla, to demonstrate the effectiveness of the proposed algorithm. RESULTS: Phantom images show success of the smoothed displacement map concept in providing improvements of the geometric corrections at low-signal regions. Human brain images demonstrate prominently superior reconstruction quality of Propeller-EPI images with modified reversed gradient corrections as compared with those obtained without corrections, as evidenced from verification against the distortion-free fast spin-echo images at the same level. CONCLUSIONS: The modified reversed gradient method is an effective approach to obtain high-resolution Propeller-EPI images with substantially reduced artifacts.
Authors: Ulrike I Attenberger; Val M Runge; Alto Stemmer; Kenneth D Williams; L Gill Naul; Henrik J Michaely; Stefan O Schoenberg; Maximilian F Reiser; Bernd J Wintersperger Journal: Invest Radiol Date: 2009-10 Impact factor: 6.016
Authors: Gil-Sun Hong; Choong Wook Lee; Mi-Hyun Kim; Seung Won Jang; Sae Rom Chung; Ga Young Yoon; Jeong Kon Kim Journal: Eur Radiol Date: 2016-05-10 Impact factor: 5.315
Authors: Inge Compter; Jurgen Peerlings; Daniëlle B P Eekers; Alida A Postma; Dimo Ivanov; Christopher J Wiggins; Pieter Kubben; Benno Küsters; Pieter Wesseling; Linda Ackermans; Olaf E M G Schijns; Philippe Lambin; Aswin L Hoffmann Journal: MAGMA Date: 2016-03-30 Impact factor: 2.310
Authors: Kurt G Schilling; Justin Blaber; Yuankai Huo; Allen Newton; Colin Hansen; Vishwesh Nath; Andrea T Shafer; Owen Williams; Susan M Resnick; Baxter Rogers; Adam W Anderson; Bennett A Landman Journal: Magn Reson Imaging Date: 2019-05-07 Impact factor: 2.546