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12.11: Magnetic resonance imaging (14.10)

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    Unlike computer tomog­raphy or DXA, magnetic resonance imaging (MRI) does not use ionizing radiation so that the technique can be used on infants, and for long-term follow-up when multiple scans on the same person are required. The MRI technique is mainly used to evaluate the quantity and distribution of adipose tissues and skeletal muscle mass, although it can also detect changes in body compo­sition, even in the presence of small body weight changes (Lemos & Gallagher, 2017). In older equipment, scanning times of 10min were necessary, but in more modern equipment, this has been reduced to under 2min. Never­the­less, the MRI technique requires tech­nical expertise, is expensive, and the equipment is bulky (Prada & Heymsfield, 2014).

    Magnetic resonance imaging uses dif­fer­ences in the nuclear magnetic resonance properties of hydrogen atoms in organic and non-organic environments to distinguish signals origin­ating from fat, fat-free mass, and free water. The hydrogen protons behave slightly dif­fer­ently in adipose versus lean tissues. The dif­fer­ences are in the relaxation time that it takes for the nuclei to release the radio-fre­quency-induced energy and return to a random con­figur­ation. These dif­fer­ences can be used to map the distribution of adipose versus lean tissue in the body (Ross, 1996).

    The imaging process involves placing the subject in a very strong magnetic field. Some of the nuclei in the body attempt to align themselves relative to the applied field. The effect is particularly marked for 1H protons. Only a small fraction of the protons become aligned, but they are suffi­ciently numerous for the effect to be detectable when the field is removed or altered. It is then that the dif­fer­ences between the lean and adipose tissue become apparent.

    This page titled 12.11: Magnetic resonance imaging (14.10) is shared under a CC BY 4.0 license and was authored, remixed, and/or curated by Rosalind S. Gibson via source content that was edited to the style and standards of the LibreTexts platform.