Whole‐brain amide proton transfer (APT) and nuclear overhauser enhancement (NOE) imaging in glioma patients using low‐power steady‐state pulsed chemical exchange saturation transfer (CEST) imaging at 7T

Heo, Hye Young; Jones, Craig K.; Hua, Jun; Yadav, Nirbhay N.; Agarwal, Shruti; Zhou, Jinyuan; Zijl, Peter van; Pillai, Jay J.

doi:10.1002/jmri.25108

Cited by 101 publications

(130 citation statements)

References 38 publications

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“…Next, two-pool MTC spectra (free bulk water and semisolid) were generated by the EMR technique (36, 37, 42–44). The semi-solid MTC model fitting under a non-steady-state (NS) condition can be described from the modified Bloch equations (45, 46).…”

Section: Methodsmentioning

confidence: 99%

Improving the detection sensitivity of pH‐weighted amide proton transfer MRI in acute stroke patients using extrapolated semisolid magnetization transfer reference signals

Heo

Zhang

Burton

et al. 2017

Magnetic Resonance in Med

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138

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Purpose To quantify APT effects in acidic ischemic lesions and assess the spatial-temporal relationship between diffusion, perfusion, and pH deficits in acute stroke patients. Methods Thirty acute stroke patients were scanned at 3 T. Quantitative APT (APT#) effects in acidic ischemic lesions were measured using an extrapolated semisolid magnetization transfer reference signal (EMR) technique and compared with commonly used MTRasym(3.5ppm) or APT-weighted parameters. Results APT# images showed clear pH deficits in the ischemic lesion, whereas MTRasym(3.5ppm) signals were slightly hypointense. The APT# contrast between acidic ischemic lesions and normal tissue in acute stroke patients was more than 3 times larger than MTRasym(3.5ppm) contrast (−1.45 ± 0.40 % for APT# vs. −0.39 ± 0.52 % for MTRasym(3.5ppm), p < 4.6 × 10-4). Hypoperfused and acidic areas without an apparent diffusion coefficient abnormality were observed and assigned to an ischemic acidosis penumbra. Hypoperfused areas at normal pH were also observed and assigned to benign oligemia. Hyperintense APT signals were observed in a hemorrhage area in one case. Conclusion The quantitative APT study using the EMR approach enhances APT MRI sensitivity to pH compared to conventional APT-weighted MRI, allowing more reliable delineation of an ischemic acidosis in the penumbra.

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Section: Methodsmentioning

confidence: 99%

Improving the detection sensitivity of pH‐weighted amide proton transfer MRI in acute stroke patients using extrapolated semisolid magnetization transfer reference signals

Heo

Zhang

Burton

et al. 2017

Magnetic Resonance in Med

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138

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“…The direct saturation (DS), CEST, and nuclear Overhauser effect (NOE) pools were modeled using Lorentzian lineshapes, described as a function of the saturation frequency, ω by:

L_{i} ((),,,, ω, ω_{0 i}, {normalΓ}_{i}, A_{i}) = A_{i} \frac{1}{2 π} \frac{{normalΓ}_{i}}{{(ω - ω_{0 i})}^{2} + {(0.5 {normalΓ}_{i})}^{2}}

…”

Section: Methodsmentioning

confidence: 99%

Optimization and repeatability of multipool chemical exchange saturation transfer MRI of the prostate at 3.0 T

Evans

Torrealdea

Rega

et al. 2019

Magnetic Resonance Imaging

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Background Chemical exchange saturation transfer (CEST) can potentially support cancer imaging with metabolically derived information. Multiparametric prostate MRI has improved diagnosis but may benefit from additional information to reduce the need for biopsies. Purpose To optimize an acquisition and postprocessing protocol for 3.0 T multipool CEST analysis of prostate data and evaluate the repeatability of the technique. Study Type Prospective. Subjects Five healthy volunteers (age range: 24–47 years; median age: 28 years) underwent two sessions (interval range: 7–27 days; median interval: 20 days) and two biopsy‐proven prostate cancer patients were evaluated once. Patient 1 (71 years) had a Gleason 3 + 4 transition zone (TZ) tumor and patient 2 (55 years) had a Gleason 4 + 3 peripheral zone (PZ) tumor. Field Strength 3.0 T. Sequences run: T2‐weighted turbo‐spin‐echo (TSE); diffusion‐weighted imaging; CEST; WASABI (for B0 determination). Assessment Saturation, readout, and fit‐model parameters were optimized to maximize in vivo amide and nuclear Overhauser effect (NOE) signals. Repeatability (intrasession and intersession) was evaluated in healthy volunteers. Subsequently, preliminary evaluation of signal differences was made in patients. Regions of interest were drawn by two post‐FRCR board‐certified readers, both with over 5 years of experience in multiparametric prostate MRI. Statistical Tests Repeatability was assessed using Bland–Altman analysis, coefficient of variation (CV), and 95% limits of agreement (LOA). Statistical significance of CEST contrast was calculated using a nonparametric Mann–Whitney U‐test. Results The optimized saturation scheme was found to be 60 sinc‐Gaussian pulses with 40 msec pulse duration, at 50% duty‐cycle with continuous‐wave pulse equivalent B1 power (B1CWPE) of 0.92 μT. The magnetization transfer (MT) contribution to the fit‐model was centered at –1.27 ppm. Intersession coefficients of variation (CVs) of the amide, NOE, and magnetization transfer (MT) and asymmetric magnetization transfer ratio (MTRasym) signals of 25%, 23%, 18%, and 200%, respectively, were observed. Fit‐metric and MTRasym CVs agreed between readers to within 4 and 10 percentage points, respectively. Data Conclusion Signal differences of 0.03–0.10 (17–43%) detectable depending upon pool, with MT the most repeatable (signal difference of 17–22% detectable). Level of Evidence: 2 Technical Efficacy: Stage 2 J. Magn. Reson. Imaging 2019;50:1238–1250.

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“…The region of interest (ROI) of each patient was defined as the whole tumor region, made up of peritumoral edema (as displayed in T 2 ‐weighted images) and contrast enhancement, as displayed in gadolinium contrast‐enhanced T 1 images but excluding necrotic tumor regions. Following CEST, metrics were calculated and analyzed for location dependence: APT, dns‐APT, and NOE CEST signals based on the AREX approach (mean and maximum [max] APT AREX , dns‐APT AREX , and mean NOE AREX ), and APT and NOE CEST signals based on the linear difference method (APT LD , NOE LD ) . To assess possible influences of B 1 field inhomogeneity on CEST parameters, the signal intensities of the investigated ROIs were also evaluated at B 1 maps.…”

Section: Methodsmentioning

confidence: 99%

Chemical exchange saturation transfer (CEST) signal intensity at 7T MRI of WHO IV° gliomas is dependent on the anatomic location

Dreher

Oberhollenzer

Meißner

et al. 2018

Magnetic Resonance Imaging

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Whole‐brain amide proton transfer (APT) and nuclear overhauser enhancement (NOE) imaging in glioma patients using low‐power steady‐state pulsed chemical exchange saturation transfer (CEST) imaging at 7T

Cited by 101 publications

References 38 publications

Improving the detection sensitivity of pH‐weighted amide proton transfer MRI in acute stroke patients using extrapolated semisolid magnetization transfer reference signals

Improving the detection sensitivity of pH‐weighted amide proton transfer MRI in acute stroke patients using extrapolated semisolid magnetization transfer reference signals

Optimization and repeatability of multipool chemical exchange saturation transfer MRI of the prostate at 3.0 T

Chemical exchange saturation transfer (CEST) signal intensity at 7T MRI of WHO IV° gliomas is dependent on the anatomic location

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