Deuterium Magnetic Resonance Imaging Using Deuterated Water-Induced 2H-Tissue Labeling Allows Monitoring Cancer Treatment at Clinical Field Strength

Asano, Hirofumi; Elhelaly, Abdelazim Elsayed; Hyodo, Fuminori; Iwasaki, Ryota; Noda, Yoshifumi; Kato, Hiroki; Ichihashi, Koki; Tomita, Hiroyuki; Murata, Masaharu; Mori, Takashi; Matsuo, Masayuki

doi:10.1158/1078-0432.ccr-23-1635

Cited by 3 publications

References 33 publications

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Transition-Metal-Catalyzed Deuteration via Hydrogen Isotope Exchange

Jiang,

Gao,

Bai

2024

SynOpen

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Direct hydrogen isotope exchange represents a distinctive strategy for deuterium labelling, where the protium is directly replaced by deuterium. In this graphic review, we summarized the progress in deuteration via transition metal catalyzed hydrogen isotope exchange. The review was organized according to the mechanism of C-H bond activation in the homogeneous catalysis, and the heterogeneous catalysis was also discussed according to the catalyst type. Representative mechanistic processes were depicted, and proven cases for tritiation were also highlighted.

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Transition-Metal-Catalyzed Deuteration via Hydrogen Isotope Exchange

Jiang,

Gao,

Bai

2024

SynOpen

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Deuterium MR spectroscopy: potential applications in oncology research

Bitencourt,

Bhowmik,

Marcal Filho

et al. 2023

BJR|Open

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Metabolic imaging in clinical practice has long relied on positron emission tomography (PET) with fluorodeoxyglucose (FDG), a radioactive tracer. However, this conventional method presents inherent limitations such as exposure to ionizing radiation and potential diagnostic uncertainties, particularly in organs with heightened glucose uptake like the brain. This review underscores the transformative potential of traditional deuterium magnetic resonance spectroscopy (MRS) when integrated with gradient techniques, culminating in an advanced metabolic imaging modality known as deuterium MR imaging (DMRI). While recent advancements in hyperpolarized MRS hold promise for metabolic analysis, their widespread clinical usage is hindered by cost constraints and the availability of hyperpolarizer devices or facilities. DMRI, also denoted as deuterium metabolic imaging (DMI), represents a pioneering, single-shot, and non-invasive paradigm that fuses conventional MRS with non-radioactive deuterium-labeled substrates. Extensively tested in animal models and patient cohorts, particularly in cases of brain tumors, DMI's standout feature lies in its seamless integration into standard clinical MRI scanners, necessitating only minor adjustments such as radiofrequency coil tuning to the deuterium frequency. DMRI emerges as a versatile tool for quantifying crucial metabolites in clinical oncology, including glucose, lactate, glutamate, glutamine, and characterizing IDH mutations. Its potential applications in this domain are broad, spanning diagnostic profiling, treatment response monitoring, and the identification of novel therapeutic targets across diverse cancer subtypes.

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Development and optimization of human deuterium MRSI at 3 T in the abdomen: feasibility in renal tumors following oral heavy water administration

McLean,

Menih,

Wodtke

et al. 2024

Preprint

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Purpose: To establish and optimize abdominal deuterium MRSI in conjunction with orally administered 2H-labelled molecules. Methods: A flexible transmit-receive surface coil was used to image naturally abundant deuterium signal in phantoms and healthy volunteers and after orally administered 2H2O in a patient with a benign renal tumor (oncocytoma). Results: Water and lipid peaks were fitted with high confidence from both unlocalized spectra and from voxels within the liver, kidney, and spleen on spectroscopic imaging. Artifacts were minimal despite the high 2H2O concentration in the stomach immediately after ingestion, which can be problematic with the use of a volume coil. Conclusion: We have shown the feasibility of abdominal deuterium MRSI at 3 T using a flexible surface coil. Water measurements were obtained in healthy volunteers and images were acquired in a patient with a renal tumor after drinking 2H2O. The limited depth penetration of the surface coil may have advantages in characterizing early uptake of orally administered agents in abdominal organs despite the high concentrations in the stomach which can pose challenges with other coil combinations.

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Deuterium Magnetic Resonance Imaging Using Deuterated Water-Induced 2H-Tissue Labeling Allows Monitoring Cancer Treatment at Clinical Field Strength

Cited by 3 publications

References 33 publications

Transition-Metal-Catalyzed Deuteration via Hydrogen Isotope Exchange

Transition-Metal-Catalyzed Deuteration via Hydrogen Isotope Exchange

Deuterium MR spectroscopy: potential applications in oncology research

Development and optimization of human deuterium MRSI at 3 T in the abdomen: feasibility in renal tumors following oral heavy water administration

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