Radiation-induced cognitive impairment-from bench to bedside

Greene-Schloesser, Dana; Robbins, Mike E.

doi:10.1093/neuonc/nos196

Cited by 179 publications

(151 citation statements)

References 83 publications

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“…The capability of dendritic spines to rapidly respond to transmembrane signals, including those associated with behavior, hormonal status, and synaptic activity and various forms of stress, indicate their critical role in learning and memory (32,33). The fact that radiation exposure leads to reduced spine density and, in particular, inhibits the formation of immature filopodia, is consistent with the adverse neurocognitive sequlae documented in brain cancer survivors subjected to cranial radiotherapy (1,34). The persistence of these structural changes coincides with the protracted recovery of the irradiated CNS, and is again consistent with the progressive and irreversible nature of radiation-induced cognitive dysfunction (11,35).…”

Section: Discussionmentioning

confidence: 73%

Cranial irradiation compromises neuronal architecture in the hippocampus

Parihar

Limoli

2013

Proc. Natl. Acad. Sci. U.S.A.

190

199

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Cranial irradiation is used routinely for the treatment of nearly all brain tumors, but may lead to progressive and debilitating impairments of cognitive function. Changes in synaptic plasticity underlie many neurodegenerative conditions that correlate to specific structural alterations in neurons that are believed to be morphologic determinants of learning and memory. To determine whether changes in dendritic architecture might underlie the neurocognitive sequelae found after irradiation, we investigated the impact of cranial irradiation (1 and 10 Gy) on a range of micromorphometric parameters in mice 10 and 30 d following exposure. Our data revealed significant reductions in dendritic complexity, where dendritic branching, length, and area were routinely reduced (>50%) in a dose-dependent manner. At these same doses and times we found significant reductions in the number (20-35%) and density (40-70%) of dendritic spines on hippocampal neurons of the dentate gyrus. Interestingly, immature filopodia showed the greatest sensitivity to irradiation compared with more mature spine morphologies, with reductions of 43% and 73% found 30 d after 1 and 10 Gy, respectively. Analysis of granule-cell neurons spanning the subfields of the dentate gyrus revealed significant reductions in synaptophysin expression at presynaptic sites in the dentate hilus, and significant increases in postsynaptic density protein (PSD-95) were found along dendrites in the granule cell and molecular layers. These findings are unique in demonstrating dose-responsive changes in dendritic complexity, synaptic protein levels, spine density and morphology, alterations induced in hippocampal neurons by irradiation that persist for at least 1 mo, and that resemble similar types of changes found in many neurodegenerative conditions. radiation-induced cognitive dysfunction | radiation injury | structural plasticity

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Section: Discussionmentioning

confidence: 73%

Cranial irradiation compromises neuronal architecture in the hippocampus

Parihar

Limoli

2013

Proc. Natl. Acad. Sci. U.S.A.

190

199

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“…It is characterized by decreased verbal memory, spatial memory, attention, and novel problem-solving ability [9,24]. Cognitive dysfunction progresses to dementia in approximately 2% to 5% of long-term survivors who have received WBI, including memory loss, ataxia, and urinary incontinence.…”

Section: Cognitive Tests To Evaluate Radiation-induced Cognitive Dysfmentioning

confidence: 99%

“…The mechanisms of radiation-induced cognitive dysfunction are not yet fully understood. According to the available knowledge, radiation-induced cognitive dysfunction is hypothesized to result from dynamic interactions between multiple cell types: vascular and glial clonogens, neurogenesis, neural function and neuroinflammation [8][9][10]. Therefore, studies into the mechanisms and preventive measures of radiation-induced cognitive dysfunction are of paramount importance to decrease the side effects of WBI and increase the quality of life of patients.…”

mentioning

confidence: 99%

The Current Utilization of Cognitive Tests in the Research of Radiation-Induced Cognitive Dysfunction in Rodent Models

Li¹,

Chen²,

Zhang³

2017

Brain Disord Ther

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Recent clinical studies suggest that radiation-induced damage to the hippocampus plays a considerable role in the cognitive dysfunction of patients after cranial irradiation. In particular, deficits in learning, memory, and spatial processing observed in patients who received WBI are thought to be related to hippocampal injury [7]. The mechanisms of radiation-induced cognitive dysfunction are not yet fully understood. According to the available knowledge, radiation-induced cognitive dysfunction is hypothesized to result from dynamic interactions between multiple cell types: vascular and glial clonogens, neurogenesis, neural function and neuroinflammation [8][9][10]. Therefore, studies into the mechanisms and preventive measures of radiation-induced cognitive dysfunction are of paramount importance to decrease the side effects of WBI and increase the quality of life of patients. To achieve this goal, widely acknowledged animal models and universally utilized cognitive tests are the prerequisite and foundation. The Establishment of Rodent ModelsRodents, including mice and rats, are the most commonly utilized animal models in medical research given their genetic background, anatomical structure, operability, and relatively low cost of use [11]. Experimental data indicated that rodents showed similar anatomical AbstractWhole brain irradiation using low LET rays has remained the mainstay to treat some primary and metastatic brain tumors. Radiation-induced cognitive dysfunction is a progressive and irreversible late side effect after whole brain irradiation and inevitably decreases the quality of life of cancer survivors. To address this negative issue, many studies have been performed to explore the mechanisms of radiation-induced cognitive dysfunction and to develop efficacious preventive and treating measures. The prerequisite and foundation of implementing a persuasive and profound study to investigate radiation-induced cognitive dysfunction is the utilization of widely acknowledged animal models and universally applied cognitive tests. In this review, articles studying radiation-induced cognitive dysfunction from 2011 to 2016 were collected. The establishment of animal models and detailed utilization of cognitive tests were analyzed and summarized. This review summarized the general range of irradiation doses and time intervals utilized and the effects of these two factors on the results of cognitive tests. changes and physiopathological mechanisms to human beings after cranial irradiation [12]. In addition, the effects of radiation on rodents could be assessed over relatively short time periods-weeks to months rather than years to decades. Anatomical and functional changes of rodents after cranial irradiation are dependent on age, dose, and sex, which are compatible with the risk factors in human patients [13]. Given that these observations are representative of the effects seen in patients, the rodent model would enable the efficient study of mechanisms and treatments.

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“…In addition, functional deficits like progressive impairments in memory, attention, and executive function may also occur. These structural and functional changes have been observed to have profound effects on quality of life (QOL) of cancer survivors [12].…”

Section: Introductionmentioning

confidence: 99%