Greater neurodegeneration and behavioral deficits after single closed head traumatic brain injury in adolescent versus adult male mice.

Traumatic brain injury (TBI) is a major public health concern affecting 2.8 million people per year in the United States, of whom about 1 million are children under 19 years old. Animal models of TBI have been developed and used in multiple ages of animals, but direct comparisons of adult and adolescent populations are rare. The current studies were undertaken to directly compare outcomes between adult and adolescent male mice, using a closed head, single-impact model of TBI. Six-week-old adolescent and 9-week-old adult male mice were subjected to mild-moderate TBI. Histological measures for neurodegeneration, gliosis, and microglial neuroinflammation, and behavioral tests of locomotion and memory were performed. Adolescent TBI mice have increased mortality (Χ2  = 20.72, p < 0.001) compared to adults. There is also evidence of hippocampal neurodegeneration in adolescents that is not present in adults. Hippocampal neurodegeneration correlates with histologic activation of microglia, but not with increased astrogliosis. Adults and adolescents have similar locomotion deficits after TBI that recover by 16 days postinjury. Adolescents have memory deficits as evidenced by impaired novel object recognition between 3-4 and 4-16 days postinjury (F1,26  = 5.23, p = 0.031) while adults do not. In conclusion, adults and adolescents within a close age range (6-9 weeks) respond to TBI differently. Adolescents are more severely affected by mortality, neurodegeneration, and inflammation in the hippocampus compared to adults. Adolescents, but not adults, have worse memory performance after TBI that lasts at least 16 days postinjury.

Connecting endoplasmic reticulum and oxidative stress to retinal degeneration, TBI, and traumatic optic neuropathy.

Traumatic optic neuropathy (TON) is commonly associated with head trauma, and thus is a known comorbidity of traumatic brain injury (TBI). TON has not received much attention in basic research despite being associated with permanent vision loss, color blindness, and loss of visual fields. This mini-review discusses the importance of studying TON in the context of TBI and mechanisms that may be involved in the ongoing optic nerve degeneration of TON. We focus particularly on endoplasmic reticulum (ER) and redox stress processes because of the overlapping presence of these degenerative mechanisms in both TBI and various retinopathies, even though these stress pathways have not yet been used to explain retinal degeneration in a model of TON. We propose that future research is needed to uncover whether ER and redox stress function independently or whether one precedes the other. This understanding is necessary in order to understand the time frames of potential treatment and the prognosis of ongoing secondary effects of TBI including optic nerve injury.