Kinetics and distribution of [Fe–I]transferrin injected into the ventricular system of the rat

We examined the kinetics and distribution of ⁵⁹Fe–¹²⁵I] rat Tf and unlabelled human Tf injected into a lateral cerebral ventricle (i.c.v. injection) in the rat. ⁵⁶Fe–¹³¹I]Tf injected intravenously served as a control of blood–brain barrier (BBB) integrity. In CSF of adult rats, ⁵⁹Fe and ¹²⁵I]Tf decreased to only 2.5% of the dose injected after 4 h. In brain parenchyma, ¹²⁵I]Tf had disappeared after 24 h, whereas approximately 18% of i.c.v.-injected ⁵⁹Fe was retained even after 72 h. The elimination pattern of ¹²⁵I]Tf from the CSF corresponded to that of ¹³¹I]albumin injected i.c.v., suggesting a nonselective washout of CSF proteins. ¹³¹I]Tf was hardly detectable in the brain, reflecting an unimpaired BBB during the experiments. Morphologically, ⁵⁹Fe and i.c.v. injected human Tf were confined to the ventricular surface and meningeal areas, whereas grey matter regions at distances more than 2–3 mm from the ventricles and the subarachnoid space were unlabelled. However, accumulation of ⁵⁹Fe was observed in the anterior thalamic and the medial habenular nuclei, and in brain regions with synaptic communications to these areas. In the newborn rats aged 7 days (P7) injected i.c.v. with ⁵⁹Fe–¹²⁵I]Tf and examined after 24 h, the amounts of ¹²⁵I]Tf in CSF were approximately 3.5 times higher than in adult rats collected after the same time interval, whereas the amounts of ⁵⁹Fe in CSF were at the same level in P7 and adult rats. In the brain tissue of the i.c.v. injected P7 rats, both ¹²⁵I]Tf and ⁵⁹Fe were retained to a significantly higher degree compared to that seen in adult brains. The rapid washout and lack of capability for i.c.v. injected ¹²⁵I]Tf to penetrate deeply into the brain parenchyma of the adult brain question the importance of Tf of the CSF, and choroid plexus-derived Tf, for Fe neutralization and delivery of Fe–Tf to TfR-containing neurons and other cells in the CNS. However, it may serve these functions in young animals due to a lower rate of turnover of CSF.