What is the most common nucleus used for MR spectroscopy?

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Multiple Choice

What is the most common nucleus used for MR spectroscopy?

Explanation:
MR spectroscopy relies on detecting signals from nuclei that have an NMR-active spin, and the most practical nucleus for clinical MR spectroscopy is hydrogen-1. Protons are incredibly abundant in the body, especially in water and organic molecules, which gives a strong, readily detectable signal. Hydrogen also has the highest gyromagnetic ratio among common MR-active nuclei, enhancing sensitivity and allowing good signal-to-noise ratios with reasonable scan times. This combination makes it possible to identify and quantify a range of metabolites such as N-acetylaspartate, choline, and creatine in tissues. Other nuclei, like carbon-13, sodium-23, or oxygen-17, have much lower natural abundance or lower gyromagnetic ratios, resulting in much weaker signals and longer acquisition times, which is why they’re not used as routinely as hydrogen in MR spectroscopy.

MR spectroscopy relies on detecting signals from nuclei that have an NMR-active spin, and the most practical nucleus for clinical MR spectroscopy is hydrogen-1. Protons are incredibly abundant in the body, especially in water and organic molecules, which gives a strong, readily detectable signal. Hydrogen also has the highest gyromagnetic ratio among common MR-active nuclei, enhancing sensitivity and allowing good signal-to-noise ratios with reasonable scan times. This combination makes it possible to identify and quantify a range of metabolites such as N-acetylaspartate, choline, and creatine in tissues. Other nuclei, like carbon-13, sodium-23, or oxygen-17, have much lower natural abundance or lower gyromagnetic ratios, resulting in much weaker signals and longer acquisition times, which is why they’re not used as routinely as hydrogen in MR spectroscopy.

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