Your search keyword '"Searleman, Adam C."' showing total 5 results

1. Inversion recovery UTE based volumetric myelin imaging in human brain using interleaved hybrid encoding.

Author

Jang, Hyungseok, Jang, Hyungseok, Ma, Yajun, Searleman, Adam C, Carl, Michael, Corey-Bloom, Jody, Chang, Eric Y, Du, Jiang, Jang, Hyungseok, Jang, Hyungseok, Ma, Yajun, Searleman, Adam C, Carl, Michael, Corey-Bloom, Jody, Chang, Eric Y, and Du, Jiang

Abstract

PurposeDirect myelin imaging can improve the characterization of myelin-related diseases such as multiple sclerosis. In this study, we explore a novel method to directly image myelin using inversion recovery-prepared hybrid encoding (IR-HE) UTE MRI.MethodsThe IR-HE sequence uses an adiabatic inversion pulse to suppress the long T2 white matter signal, followed by 3D dual-echo HE utilizing both single point imaging and radial frequency encoding, for which the subtraction image between 2 echoes reveals the myelin signal with high contrast. To reduce scan time, it is common to obtain multiple spokes per IR. Here, we invented a novel method to improve the HE, adapted for the multi-spoke IR imaging-termed interleaved HE-for which single point imaging encoding is interleaved between radial frequency encodings near nulling point to allow more efficient IR-signal suppression. To evaluate the proposed approach, a computer simulation, myelin phantom experiment, an ex vivo experiment with a cadaveric multiple sclerosis brain, and an in vivo experiment with 8 healthy volunteers and 13 multiple sclerosis patients were performed.ResultsThe computer simulation showed that IR-interleaved HE allows for improved contrast of myelin signal with reduced imaging artifacts. The myelin phantom experiment showed IR-interleaved HE allows direct imaging of myelin lipid with excellent suppression of water signal. In the ex vivo and in vivo experiments, the proposed method demonstrated highly specific imaging of myelin in white matter of the brain.ConclusionIR-interleaved HE allows for time-efficient, high-contrast direct myelin imaging and can detect demyelinated lesions in multiple sclerosis patients.

Published

2020

2. True phase quantitative susceptibility mapping using continuous single-point imaging: a feasibility study.

Author

Jang, Hyungseok, Jang, Hyungseok, Lu, Xing, Carl, Michael, Searleman, Adam C, Jerban, Saeed, Ma, Yajun, von Drygalski, Annette, Chang, Eric Y, Du, Jiang, Jang, Hyungseok, Jang, Hyungseok, Lu, Xing, Carl, Michael, Searleman, Adam C, Jerban, Saeed, Ma, Yajun, von Drygalski, Annette, Chang, Eric Y, and Du, Jiang

Abstract

PurposeIn this study, we explore the feasibility of a new imaging scheme for quantitative susceptibility mapping (QSM): continuous single-point imaging (CSPI), which uses a pure phase encoding strategy to achieve true phase imaging and improve QSM accuracy.MethodsThe proposed CSPI is a modification of conventional SPI to allow acquisition of multiple echoes in a single scan. Immediately following a phase encoding gradient, the free induction decay is continuously sampled with extremely high temporal resolution to obtain k-space data at a fixed spatial frequency (i.e., at a fixed k-space coordinate). By having near-0 readout duration, CSPI results in a true snapshot of the transverse magnetization at each TE. Additionally, parallel imaging with autocalibration is utilized to reduce scan time, and an optional temporal averaging strategy is presented to improve signal-to-noise ratio for objects with low proton density or short T2* decay. The reconstructed CSPI images were input to a QSM framework based on morphology enabled dipole inversion.ResultIn an experiment performed using iron phantoms, susceptibility estimated using CSPI showed high linearity (R2 = 0.9948) with iron concentration. Additionally, reconstructed CSPI phase images showed much reduced ringing artifact compared with phase images obtained using a frequency encoding strategy. In an ex vivo experiment performed using human tibia samples, estimated susceptibilities ranged from -1.6 to -2.1 ppm, in agreement with values reported in the literature (ranging from -1.2 to -2.2 ppm).ConclusionWe have demonstrated the feasibility of using CSPI to obtain true phase images for QSM.

Published

2019

3. Fast quantitative 3D ultrashort echo time MRI of cortical bone using extended cones sampling.

Author

Wan, Lidi, Wan, Lidi, Zhao, Wei, Ma, Yajun, Jerban, Saeed, Searleman, Adam C, Carl, Michael, Chang, Eric Y, Tang, Guangyu, Du, Jiang, Wan, Lidi, Wan, Lidi, Zhao, Wei, Ma, Yajun, Jerban, Saeed, Searleman, Adam C, Carl, Michael, Chang, Eric Y, Tang, Guangyu, and Du, Jiang

Abstract

PurposeTo investigate the effect of stretching sampling window on quantitative 3D ultrashort TE (UTE) imaging of cortical bone at 3 T.MethodsTen bovine cortical bone and 17 human tibial midshaft samples were imaged with a 3T clinical MRI scanner using an 8-channel knee coil. Quantitative 3D UTE imaging biomarkers, including T1 , T2∗ , magnetization transfer ratio and magnetization transfer modeling, were performed using radial or spiral Cones sampling trajectories with various durations. Errors in UTE-MRI biomarkers as a function of sampling time were evaluated using radial sampling as a reference standard.ResultsFor both bovine and human cortical bone samples, no significant differences were observed for all UTE biomarkers (single-component T2∗ , bicomponent T2∗ and relative fractions, T1 , magnetization transfer ratio, and magnetization transfer modeling of macromolecular fraction) for spiral sampling windows of 992 µs to 1600 µs compared with a radial sampling window of 688 µs.ConclusionThe total scan time can be reduced by 76% with quantification errors less than 5%. Quantitative UTE-MRI techniques can be greatly accelerated using longer sampling windows without significant quantification errors.

Published

2019

4. True phase quantitative susceptibility mapping using continuous single-point imaging: a feasibility study.

Author

Jang, Hyungseok, Jang, Hyungseok, Lu, Xing, Carl, Michael, Searleman, Adam C, Jerban, Saeed, Ma, Yajun, von Drygalski, Annette, Chang, Eric Y, Du, Jiang, Jang, Hyungseok, Jang, Hyungseok, Lu, Xing, Carl, Michael, Searleman, Adam C, Jerban, Saeed, Ma, Yajun, von Drygalski, Annette, Chang, Eric Y, and Du, Jiang

Abstract

PurposeIn this study, we explore the feasibility of a new imaging scheme for quantitative susceptibility mapping (QSM): continuous single-point imaging (CSPI), which uses a pure phase encoding strategy to achieve true phase imaging and improve QSM accuracy.MethodsThe proposed CSPI is a modification of conventional SPI to allow acquisition of multiple echoes in a single scan. Immediately following a phase encoding gradient, the free induction decay is continuously sampled with extremely high temporal resolution to obtain k-space data at a fixed spatial frequency (i.e., at a fixed k-space coordinate). By having near-0 readout duration, CSPI results in a true snapshot of the transverse magnetization at each TE. Additionally, parallel imaging with autocalibration is utilized to reduce scan time, and an optional temporal averaging strategy is presented to improve signal-to-noise ratio for objects with low proton density or short T2* decay. The reconstructed CSPI images were input to a QSM framework based on morphology enabled dipole inversion.ResultIn an experiment performed using iron phantoms, susceptibility estimated using CSPI showed high linearity (R2 = 0.9948) with iron concentration. Additionally, reconstructed CSPI phase images showed much reduced ringing artifact compared with phase images obtained using a frequency encoding strategy. In an ex vivo experiment performed using human tibia samples, estimated susceptibilities ranged from -1.6 to -2.1 ppm, in agreement with values reported in the literature (ranging from -1.2 to -2.2 ppm).ConclusionWe have demonstrated the feasibility of using CSPI to obtain true phase images for QSM.

Published

2019

5. Fast quantitative 3D ultrashort echo time MRI of cortical bone using extended cones sampling.

Author

Wan, Lidi, Wan, Lidi, Zhao, Wei, Ma, Yajun, Jerban, Saeed, Searleman, Adam C, Carl, Michael, Chang, Eric Y, Tang, Guangyu, Du, Jiang, Wan, Lidi, Wan, Lidi, Zhao, Wei, Ma, Yajun, Jerban, Saeed, Searleman, Adam C, Carl, Michael, Chang, Eric Y, Tang, Guangyu, and Du, Jiang

Abstract

PurposeTo investigate the effect of stretching sampling window on quantitative 3D ultrashort TE (UTE) imaging of cortical bone at 3 T.MethodsTen bovine cortical bone and 17 human tibial midshaft samples were imaged with a 3T clinical MRI scanner using an 8-channel knee coil. Quantitative 3D UTE imaging biomarkers, including T1 , T2∗ , magnetization transfer ratio and magnetization transfer modeling, were performed using radial or spiral Cones sampling trajectories with various durations. Errors in UTE-MRI biomarkers as a function of sampling time were evaluated using radial sampling as a reference standard.ResultsFor both bovine and human cortical bone samples, no significant differences were observed for all UTE biomarkers (single-component T2∗ , bicomponent T2∗ and relative fractions, T1 , magnetization transfer ratio, and magnetization transfer modeling of macromolecular fraction) for spiral sampling windows of 992 µs to 1600 µs compared with a radial sampling window of 688 µs.ConclusionThe total scan time can be reduced by 76% with quantification errors less than 5%. Quantitative UTE-MRI techniques can be greatly accelerated using longer sampling windows without significant quantification errors.

Published

2019