Kirsty L. Carrihill-Knoll scite author profile

Exposing young rats to particles of high energy and charge (HZE particles), a ground-based model for exposure to cosmic rays, enhances indices of oxidative stress and inflammation, disrupts the functioning of neuronal communication, and alters cognitive behaviors. Even though exposure to HZE particles occurs at low fluence rates, the cumulative effects of long-term exposure result in molecular changes similar to those seen in aged animals. In the present study, we assessed markers of autophagy, a dynamic process for intracellular degradation and recycling of toxic proteins and organelles, as well as stress and inflammatory responses, in the brains of Sprague-Dawley rats irradiated at 2 months of age with 5 and 50 cGy and 1 Gy of ionizing oxygen particles ((16)O) (1000 MeV/n). Compared to nonirradiated controls, exposure to (16)O particles significantly inhibited autophagy function in the hippocampus as measured by accumulation of ubiquitin inclusion bodies such as P62/SQSTM1, autophagosome marker microtubule-associated protein 1 beta light chain 3 (MAP1B-LC3), beclin1 and proteins such as mammalian target of rapamycin (mTOR). The molecular changes measured at short (36 h) and long (75 days) intervals after (16)O-particle exposure indicate that the loss of autophagy function occurred shortly after exposure but was recovered via inhibition of mTOR. However, HZE-particle radiation caused significant sustained loss of protein kinase C alpha (PKC-α), a key G protein modulator involved in neuronal survival and functions of neuronal trophic factors. Exposure to (16)O particles also caused substantial increases in the levels of nuclear factor kappa B (NF-κB) and glial fibrillary acidic protein (GFAP), indicating glial cell activation 75 days after exposure. This is the first report to show the molecular effects of (16)O-particle radiation on oxidative stress, inflammation and loss of autophagy in the brain of young rats.

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Comparison of the Effects of Partial- or Whole-Body Exposures to¹⁶O Particles on Cognitive Performance in Rats

Rabin

Shukitt‐Hale

Carrihill-Knoll

et al. 2014

Radiation Research

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Studies using a ground-based system (NASA Space Radiation Laboratory) to examine the effects of exposure to high-energy charged particles or HZE particles on cognitive performance have interchangeably used whole-body exposures or exposures restricted to the head of the subject. For this study, we hypothesized that different types of exposure such as whole body vs. head only vs. body only might modulate the impact of irradiation on cognitive performance in different ways with the resulting cognitive performance outcomes being either independent of exposure type or strongly dependent on exposure type with each producing performance outcomes. To test these possibilities, three groups of rats were exposed to ¹⁶O particles (1,000 MeV/n): (1) head only; (2) body only; (3) whole body. Cognitive performance was measured using the elevated plus-maze, novel object recognition, spatial location memory and operant responding on an ascending fixed-ratio schedule. The results indicated that the performance of the rats on the spatial location memory task was markedly different when they received head-only irradiation compared to whole-body exposure. For the operant responding task, irradiation of the whole body resulted in a more severe performance decrement than exposures restricted to the head. The results are discussed in terms of nontargeted effects of HZE particles and the findings suggest that studies that utilize different patterns of exposure may not be directly comparable and that astronauts may be at a greater risk for HZE particle-induced cognitive deficits than previously thought.

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Acute Effects of Exposure to⁵⁶Fe and¹⁶O Particles on Learning and Memory

et al. 2015

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Although it has been shown that exposure to HZE particles disrupts cognitive performance when tested 2-4 weeks after irradiation, it has not been determined whether exposure to HZE particles acutely affects cognitive performance, i.e., within 4-48 h after exposure. The current experiments were designed to determine the acute effects of exposure to HZE particles ((16)O and (56)Fe) on cognitive performance and whether exposure to HZE particles affected learning or memory, as well as to understand the relationship between acute changes in the levels of NOX2 (a measure of oxidative stress) and COX2 (a measure of neuroinflammation) in specific brain regions and cognitive performance. The results of these studies indicate that the acute effects of radiation exposure on cognitive performance are on memory, not learning. Further, the acute effects of exposure to HZE particles on oxidative stress and neuroinflammation and their relationship to cognitive performance indicate that, although the effects of exposure to both (56)Fe and (16)O are widespread, only changes in specific regions of the brain may be related to changes in cognitive function.

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