Spinal cord injury chronically depresses glucose uptake in the rodent model.

The pathophysiology following spinal cord injury (SCI) progresses from its lesion epicenter resulting in cellular and systemic changes acutely, sub-acutely and chronically. The symptoms of the SCI depend upon the severity of the injury and its location in the spinal cord. However, there is lack of studies that have longitudinally assessed acute through chronic in vivo changes following SCI. In this combinatorial study we fill this gap by evaluating acute to chronic effects of moderate SCI in rats. We have used fluorodeoxyglucose (FDG) imaging with positron emission tomography (PET) as a marker to assess glucose metabolism, motor function, and immunohistochemistry to examine changes following moderate SCI. Our results demonstrate decreased FDG uptake at the injury site chronically at days 28 and 90 post injury compared to baseline. This alteration in glucose uptake was not restricted to the lesion site, showing depressed FDG uptake in non-injured areas (cervical spinal cord and cerebellum). The alteration in glucose uptake was correlated with reductions in neuronal cell viability and increases in glial cell activation at 90 days at the lesion site, as well as chronic impairments in motor function. These data demonstrate the chronic effects of SCI on glucose metabolism both within the lesion and distally within the spinal cord and brain.

Role of Insulin in Neurotrauma and Neurodegeneration: A Review.

Insulin is a hormone typically associated with pancreatic release and blood sugar regulation. The brain was long thought to be "insulin-independent," but research has shown that insulin receptors (IR) are expressed on neurons, microglia and astrocytes, among other cells. The effects of insulin on cells within the central nervous system are varied, and can include both metabolic and non-metabolic functions. Emerging data suggests that insulin can improve neuronal survival or recovery after trauma or during neurodegenerative diseases. Further, data suggests a strong anti-inflammatory component of insulin, which may also play a role in both neurotrauma and neurodegeneration. As a result, administration of exogenous insulin, either via systemic or intranasal routes, is an increasing area of focus in research in neurotrauma and neurodegenerative disorders. This review will explore the literature to date on the role of insulin in neurotrauma and neurodegeneration, with a focus on traumatic brain injury (TBI), spinal cord injury (SCI), Alzheimer's disease (AD) and Parkinson's disease (PD).

Ventral pallidal encoding of reward-seeking behavior depends on the underlying associative structure.

Despite its being historically conceptualized as a motor expression site, emerging evidence suggests the ventral pallidum (VP) plays a more active role in integrating information to generate motivation. Here, we investigated whether rat VP cue responses would encode and contribute similarly to the vigor of reward-seeking behaviors trained under Pavlovian versus instrumental contingencies, when these behavioral responses consist of superficially similar locomotor response patterns but may reflect distinct underlying decision-making processes. We find that cue-elicited activity in many VP neurons predicts the latency of instrumental reward seeking, but not of Pavlovian response latency. Further, disruption of VP signaling increases the latency of instrumental but not Pavlovian reward seeking. This suggests that VP encoding of and contributions to response vigor are specific to the ability of incentive cues to invigorate reward-seeking behaviors upon which reward delivery is contingent.