Brain irradiation improves focal cerebral ischemia recovery in aged rats.

BACKGROUND: Studies have shown that aging is a significant factor in worsening stroke outcomes. While many mechanisms may aggravate brain injury in the elderly, one such potential system may involve increased glial proliferation in the aged stroke patient that could result in increased scar formation. We hypothesized that in aged rats a single brain-only exposure to a low radiation dose prior to focal brain ischemia would reduce glial proliferation and confer a long-term neuroprotective effect. METHODS: Brain-only proton irradiation (8 Gy) was performed ten days prior to middle cerebral artery occlusion (MCAO) in aged male rats. Magnetic resonance imaging (MRI) was undertaken in naive, radiation-only (Rad), MCAO, and MCAO+Rad groups at 2, 14 and 28 days post-stroke followed by immunohistochemistry (day 28). RESULTS: Ischemic lesion volume in MCAO+Rad group was decreased by 50.7% with an accelerated temporal reduction in peri-lesional brain edema and increased water mobility within the ischemic core (39.8%) compared to MCAO-only rats. In the peri-lesional brain region of MCAO+Rad rats there was a decreased scar formation (49%, glial fibrillary acidic protein), brain tissue sclerosis (30%, aquaporin-4) and necrosis/apoptosis (58%, TUNEL positive cells) compared to those in MCAO animals. CONCLUSION: In aged animals a single exposure to brain-only radiation prior to focal cerebral ischemia is neuroprotective as it prevents glial hyperproliferation, progressive brain tissue sclerosis and reduces the apoptosis/necrosis in the peri-lesional region. Decreased lesion volume is in agreement with accelerated reduction of brain edema in these animals.

Rodent neonatal bilateral carotid artery occlusion with hypoxia mimics human hypoxic-ischemic injury.

We report a new clinically relevant model of neonatal hypoxic-ischemic injury in a 10-day-old rat pup. Bilateral carotid artery occlusion and 8% hypoxia (1 to 15 mins, BCAO-H) was induced with varying degrees of injury (mild, moderate, severe), which was quantified using magnetic resonance imaging including diffusion-weighted and T2-weighted imaging at 24 h and 21/28 days. We developed a magnetic resonance imaging-based rat pup severity score and compared 3D ischemic injury volumes/rat pup severity score with histology and behavioral testing. At 24 h, hypoxic-ischemic injury was observed in 17/27 animals; long-term survival was 81%. Magnetic resonance imaging lesion volumes did not correlate with hypoxia duration but correlated with rat pup severity score, which was used to classify animals into mild (n=21), moderate (n=6), and severe (n=10) groups with average brain lesion volumes of 0.9%, 33.2%, and 56.3%, respectively. Histology confirmed lesion location and histologic scoring correlated with the rat pup severity score. We also found excellent correlation between injury severity and multiple behavioral tasks. Bilateral carotid artery occlusion and hypoxia in the P10 rat pup is an excellent model of neonatal hypoxic-ischemic injury because it induces diffuse global injury similar to the term infant. This model can produce graded injury severity, similar to that seen in human neonates, but manipulation with hypoxia duration is unpredictable.