| Mechanism of action |
Based on the behavior of protons when placed in a strong magnetic
field, which is interpreted and transformed into images by magnetic
resonance (MR) instruments. Paramagnetic agents have unpaired electrons
that generate a magnetic field about 700 times larger than the proton's
field, thus disturbing the proton's local magnetic field. When the local
magnetic field around a proton is disturbed, its relaxation process is
altered. MR images are based on proton density and proton relaxation
dynamics. MR instruments can record 2 different relaxation processes,
the T1 (spin-lattice or longitudinal relaxation time) and the T2
(spin-spin or transverse relaxation time). In magnetic resonance imaging
(MRI), visualization of normal and pathological brain tissue depends in
part on variations in the radiofrequency signal intensity that occur
with changes in proton density, alteration of the T1, and variation in
the T2. When placed in a magnetic field, gadodiamide shortens both the
T1 and the T2 relaxation times in tissues where it accumulates. At
clinical doses, gadodiamide primarily affects the T1 relaxation time,
thus producing an increase in signal intensity. Gadodiamide does not
cross the intact blood-brain barrier; therefore, it does not accumulate
in normal brain tissue or in central nervous system (CNS) lesions that
have not caused an abnormal blood-brain barrier (e.g., cysts, mature
post-operative scars). Abnormal vascularity or disruption of the
blood-brain barrier allows accumulation of gadodiamide in lesions such
as neoplasms, abscesses, and subacute infarcts. |
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