Sensitivity of cerebellar glutathione system to neonatal ionizing radiation exposure.

Reactive oxygen species (ROS) are relevant components of living organisms that, besides their role in the regulation of different important physiological functions, when present in excess are capable to affect cell oxidative status, leading to damage of cellular molecules and disturbance of normal cell function. ROS accumulation has been associated with a variety of conditions such as neurodegenerative diseases and ionizing radiation exposure. Cell ability to counteract ROS overproduction depends on the capacity of the endogenous antioxidant defenses--which includes the glutathione (GSH) system--to cope with. Since developing central nervous system (CNS) is especially sensitive to ROS-induced damage, the aim of the present work was to evaluate ROS, reduced GSH and oxidized glutathione (GSSG) levels in the cerebellum at different developmental ages after irradiation, in order to test if any changes were induced on these key oxidative stress-related cellular markers that might explain the high cerebellar vulnerability to radiation-induced injury. Since intracellular levels of GSH are maintained by glutathione reductase (GSHr), this enzymatic activity was also evaluated. Newborn Wistar rats were irradiated in their cephalic ends and the different parameters were measured, from 1h to 90 days post-irradiation. Results showed that an early transient increase in ROS levels followed by a decrease in cerebellar weight at 3-5 days post-irradiation were induced. An increase in cerebellar GSH levels was induced at 30 days after irradiation, together with a decrease in GSHr activity. These results support the hypothesis that ROS may represent a marker of damage prior to radiation-induced cell death. In contrast, it would be suggested that GSH system might play a role in the compensatory mechanisms triggered to counteract radiation-induced cerebellar damage.

Motor, cytoarchitectural and biochemical assessment of pharmacological neuroprotection against CNS damage induced by neonatal exposure to ionizing radiation.

Exposure of neonatal rats to a 5 Gy single dose of X-irradiation induces permanent abnormalities in cerebellar cortex cytoarchitecture and neurochemistry and motor function. This rodent model constitutes an useful tool to evaluate morphological, neurochemical and motor changes induced by ionizing radiation and the possible restorative effects of potential or clearly established neuroprotective drugs. After selection and administration of a neuroprotective agent to neonatally irradiated rats, quantitative evaluations of motor behavior (gait), cerebellar cortex cytoarchitecture and cerebellar monoamine levels are performed. Data are compared to those of both saline-injected, X-irradiated, and saline-injected, sham-irradiated controls. Evaluation of data from the different experimental groups is performed at postnatal days 30 and 90. After this postnatal interval, radiation-induced damage of cerebellar function in nonprotected rodents is considered to be permanent. The longitudinal evaluation of various parameters in the different experimental groups through a multidisciplinary approach, allows determination of the variables that are more sensitive to X-irradiation-induced damage and/or neuroprotective agent-induced restoration. Given the well-known correspondence in cerebellar developmental stages between rodents and humans, this model and related studies bring health-related implications, considering the accidental or therapeutic exposure of developing human beings to ionizing radiation.