An indirect method for in vivo T2 mapping of [1‐13C] pyruvate using hyperpolarized 13C CSI

Joe, Eunhae; Lee, Hansol; Lee, Joonsung; Yang, Sanghwa; Choi, Young Kil; Wang, Eun Kyung; Song, Ho Taek; Kim, Dong Hyun

doi:10.1002/nbm.3690

Cited by 7 publications

(12 citation statements)

References 20 publications

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“…Finally, in these initial studies, the total readout time for each slice was 9.9 ms for prostate studies and 16.5 ms for brain studies. Although this resulted in short echo‐spacing and made the acquisitions more robust to B 0 inhomogeneity, we anticipate that the SNR could readily be improved by increasing the total readout duration, given the relatively long T 2 * of 13 C substrates . However, this will place more of a burden on shimming and frequency calibration, as a further increase in echo‐spacing would make the acquisition more susceptible to geometric distortion and bulk shifts in the blip dimension.…”

Section: Discussionmentioning

confidence: 99%

“…Although this resulted in short echo-spacing and made the acquisitions more robust to B 0 inhomogeneity, we anticipate that the SNR could readily be improved by increasing the total readout duration, given the relatively long T 2 * of 13 C substrates. 30 However, this will place more of a burden on shimming and frequency calibration, as a further increase in echo-spacing would make the acquisition more susceptible to geometric distortion and bulk shifts in the blip dimension. In this case, alternating the blip polarity each time frame 31 or using a dual-echo EPI acquisition 32,33 could potentially be used to correct for distortion and signal loss arising from B 0 inhomogeneity.…”

Section: Discussionmentioning

confidence: 99%

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Translation of Carbon‐13 EPI for hyperpolarized MR molecular imaging of prostate and brain cancer patients

Gordon

Chen

Autry

et al. 2018

Magnetic Resonance in Med

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Purpose To develop and translate a metabolite‐specific imaging sequence using a symmetric echo planar readout for clinical hyperpolarized (HP) Carbon‐13 (13C) applications. Methods Initial data were acquired from patients with prostate cancer (N = 3) and high‐grade brain tumors (N = 3) on a 3T scanner. Samples of [1‐13C]pyruvate were polarized for at least 2 h using a 5T SPINlab system operating at 0.8 K. Following injection of the HP substrate, pyruvate, lactate, and bicarbonate (for brain studies) were sequentially excited with a singleband spectral‐spatial RF pulse and signal was rapidly encoded with a single‐shot echo planar readout on a slice‐by‐slice basis. Data were acquired dynamically with a temporal resolution of 2 s for prostate studies and 3 s for brain studies. Results High pyruvate signal was seen throughout the prostate and brain, with conversion to lactate being shown across studies, whereas bicarbonate production was also detected in the brain. No Nyquist ghost artifacts or obvious geometric distortion from the echo planar readout were observed. The average error in center frequency was 1.2 ± 17.0 and 4.5 ± 1.4 Hz for prostate and brain studies, respectively, below the threshold for spatial shift because of bulk off‐resonance. Conclusion This study demonstrated the feasibility of symmetric EPI to acquire HP 13C metabolite maps in a clinical setting. As an advance over prior single‐slice dynamic or single time point volumetric spectroscopic imaging approaches, this metabolite‐specific EPI acquisition provided robust whole‐organ coverage for brain and prostate studies while retaining high SNR, spatial resolution, and dynamic temporal resolution.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Translation of Carbon‐13 EPI for hyperpolarized MR molecular imaging of prostate and brain cancer patients

Gordon

Chen

Autry

et al. 2018

Magnetic Resonance in Med

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“…Blurring arising from T2*-related signal decay will ultimately limit the echo train length. Given that the in vivo T2* values are on the order of 20–100 ms at 3 T [27], readout durations on the order of 20–40 ms should be achievable without substantial resolution loss. While T2 has been reported to be substantially longer than T2* for 13 C substrates [28,29], spin echo approaches [30,31] are problematic for hyperpolarized studies because miscalibration of the B 1 power and B1+ inhomogeneity can lead to rapid RF decay from the refocusing pulses due to saturation at the edge of the coil [32].…”

Section: Discussionmentioning

confidence: 99%

3D hyperpolarized C-13 EPI with calibrationless parallel imaging

Gordon

Hansen

Shin

et al. 2018

Journal of Magnetic Resonance

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With the translation of metabolic MRI with hyperpolarized C agents into the clinic, imaging approaches will require large volumetric FOVs to support clinical applications. Parallel imaging techniques will be crucial to increasing volumetric scan coverage while minimizing RF requirements and temporal resolution. Calibrationless parallel imaging approaches are well-suited for this application because they eliminate the need to acquire coil profile maps or auto-calibration data. In this work, we explored the utility of a calibrationless parallel imaging method (SAKE) and corresponding sampling strategies to accelerate and undersample hyperpolarizedC data using 3D blipped EPI acquisitions and multichannel receive coils, and demonstrated its application in a human study of [1-C]pyruvate metabolism.

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“…The digital phantom was designed as a replica of the physical phantom and simulated with an 8° tilt along the z‐axis (see Supporting Information Figure ). The following relaxation parameters were used in the simulation: T 1 = 1000 ms; T 2 = 200 ms; and

T_{2}^{*}

= 50 ms (simulating

T_{2}^{*}

properties of pyruvate) . The simulation was performed with a ±15 Hz macroscopic off‐resonance distribution and hard pulse singlet excitation.…”

Section: Methodsmentioning

confidence: 99%

“…The following relaxation parameters were used in the simulation: T 1 = 1000 ms; T 2 = 200 ms; and T * 2 = 50 ms (simulating T * 2 properties of pyruvate). 24 The simulation was performed with a ±15 Hz macroscopic off-resonance distribution and hard pulse singlet excitation. Off-resonance effects of the SPSP excitation were therefore not simulated.…”

Section: Simulationsmentioning

confidence: 99%

Coil profile estimation strategies for parallel imaging with hyperpolarized ¹³C MRI

Hansen

Sánchez‐Heredia

Bøgh

et al. 2019

Magnetic Resonance in Med

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Purpose To investigate auto‐ and pre‐calibration coil profile estimation for parallel imaging reconstruction of hyperpolarized 13C MRI volumetric data. Methods Parallel imaging reconstruction was studied with 3 different approaches for coil profile estimation: auto‐calibration, phantom calibration, and theoretic calibration. Acquisition was performed with a 3D stack‐of‐spirals sequence with spectral–spatial excitation and Cartesian undersampling. Parallel imaging reconstructions were done with conjugate gradient SENSE and 3D gridding with inhomogeneity correction. The approaches were compared in simulations with different SNR, through phantom experiments, and in an in vivo pig study focused on the kidneys. All imaging was done with a rigid home‐built 12‐channel 13C receive coil at 3T. Results The phantom calibrated and theoretic approaches resulted in the best structural similarities in simulations and demonstrated higher image quality in the phantom experiments compared to the auto‐calibrated approach. In vivo mapping of pyruvate uptake and lactate conversion improved for accelerated acquisitions because of a better temporal resolution. From a practical and image quality point of view, use of theoretic coil profiles led to improved results compared to the other approaches. Conclusion The success of the theoretic coil profile estimation demonstrates a negligible effect of load on sensitivity profiles at the carbon frequency at 3T. Through theoretic or phantom calibrated parallel imaging, accelerated 3D volumes could be reconstructed with sufficient sensitivity, temporal, and spatial resolution to map the metabolism of kidneys exemplifying abdominal organs. This approach overcomes a critical step in the clinical translation of parallel imaging in hyperpolarized 13C MR.

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An indirect method for in vivo T₂ mapping of [1‐¹³C] pyruvate using hyperpolarized ¹³C CSI

Cited by 7 publications

References 20 publications

Translation of Carbon‐13 EPI for hyperpolarized MR molecular imaging of prostate and brain cancer patients

Translation of Carbon‐13 EPI for hyperpolarized MR molecular imaging of prostate and brain cancer patients

3D hyperpolarized C-13 EPI with calibrationless parallel imaging

Coil profile estimation strategies for parallel imaging with hyperpolarized ¹³C MRI

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An indirect method for in vivo T2 mapping of [1‐13C] pyruvate using hyperpolarized 13C CSI

Cited by 7 publications

References 20 publications

Translation of Carbon‐13 EPI for hyperpolarized MR molecular imaging of prostate and brain cancer patients

Translation of Carbon‐13 EPI for hyperpolarized MR molecular imaging of prostate and brain cancer patients

3D hyperpolarized C-13 EPI with calibrationless parallel imaging

Coil profile estimation strategies for parallel imaging with hyperpolarized 13C MRI

Contact Info

Product

Resources

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An indirect method for in vivo T₂ mapping of [1‐¹³C] pyruvate using hyperpolarized ¹³C CSI

Coil profile estimation strategies for parallel imaging with hyperpolarized ¹³C MRI