Mild traumatic brain injury (mTBI) accounts for the majority of all brain injuries and affected individuals typically experience some extent of cognitive and/or neuropsychiatric deficits. Given that repeated mTBIs often result in worsened prognosis, the cumulative effect of repeated mTBIs is an area of clinical concern and on-going pre-clinical research. Animal models are critical in elucidating the underlying mechanisms of single and repeated mTBI-associated deficits, but the neurobehavioral sequelae produced by these models have not been well characterized. Thus, we sought to evaluate the behavioral changes incurred after single and repeated mTBIs in mice utilizing a modified impact-acceleration model. Mice in the mTBI group received 1 impact while the repeated mTBI group received 3 impacts with an inter-injury interval of 24h. Classic behavior evaluations included the Morris water maze (MWM) to assess learning and memory, elevated plus maze (EPM) for anxiety, and forced swim test (FST) for depression/helplessness. Additionally, species-typical behaviors were evaluated with the marble-burying and nestlet shredding tests to determine motivation and apathy. Non-invasive vibration platforms were used to examine sleep patterns post-mTBI. We found that the repeated mTBI mice demonstrated deficits in MWM testing and poorer performance on species-typical behaviors. While neither single nor repeated mTBI affected behavior in the EPM or FST, sleep disturbances were observed after both single and repeated mTBI. Here, we conclude that behavioral alterations shown after repeated mTBI resemble several of the deficits or disturbances reported by patients, thus demonstrating the relevance of this murine model to study repeated mTBIs.
ID:
Title:
Marble burying reflects a repetitive and perseverative behavior more than novelty-induced anxiety.
An increasing number of investigators utilize the marble-burying assay despite the paucity of information available regarding what underlies the behavior.We tested the possibility that a genetic component underlies marble burying in mice and if there is a genetic correlation with other anxiety-like traits. Since findings reported in the literature indicate that marble-burying behavior reflects an anxiety-like response, we explored the assumption that the novel nature of a marble induces this anxiety. Finally, we investigated how the natural response of a mouse to dig relates to the marble-burying phenomenon.We examined ten different inbred mouse strains to determine if marble-burying behavior is genetically regulated and correlated with anxiety-like traits in two other assays. We employed multiple variants of the "traditional" marble-burying assay to address how issues such as the novelty of marbles and digging behavior contribute to marble burying.Marble-burying behavior varied across strain and did not correlate with anxiety measures in other assays. Multiple tests conducted to reduce the novelty of marbles failed to alter burying behavior. Additionally, digging behavior correlated with marble burying, and the presence of marbles did not significantly impact the digging response.Our results indicate that mouse marble burying is genetically regulated, not correlated with other anxiety-like traits, not stimulated by novelty, and is a repetitive behavior that persists/perseveres with little change across multiple exposures. Marble burying is related to digging behavior and may in fact be more appropriately considered as an indicative measure of repetitive digging.
ID:
Title:
Neuropsychiatric Symptom Modeling in Male and Female C57BL/6J Mice after Experimental Traumatic Brain Injury.
Psychiatric symptoms such as anxiety and depression are frequent and persistent complaints following traumatic brain injury (TBI). Modeling these symptoms in animal models of TBI affords the opportunity to determine mechanisms underlying behavioral pathologies and to test potential therapeutic agents. However, testing these symptoms in animal models of TBI has yielded inconsistent results. The goal of the current study was to employ a battery of tests to measure multiple anxiety- and depressive-like symptoms following TBI in C57BL/6J mice, and to determine if male and female mice are differentially affected by the injury. Following controlled cortical impact (CCI) at a parietal location, neither male nor female mice showed depressive-like symptoms as measured by the Porsolt forced-swim test and sucrose preference test. Conclusions regarding anxiety-like behaviors were dependent upon the assay employed; CCI-induced thigmotaxis in the open field suggested an anxiogenic effect of the injury; however, results from the elevated zero maze, light-dark box, and marble-burying tests indicated that CCI reduced anxiety-like behaviors. Fewer anxiety-like behaviors were also associated with the female sex. Increased levels of activity were also measured in female mice and injured mice in these tests, and conclusions regarding anxiety should be taken with caution when experimental manipulations induce changes in baseline activity. These results underscore the irreconcilability of results from studies attempting to model TBI-induced neuropsychiatric symptoms. Changes in injury models or better attempts to replicate the clinical syndrome may improve the translational applicability of rodent models of TBI-induced anxiety and depression.
ID:
Title:
Impairment of spatial but not contextual memory in CaMKII mutant mice with a selective loss of hippocampal LTP in the range of the theta frequency.
URI:
https://www.ncbi.nlm.nih.gov/pubmed/?term=7781067
Provider Org:
Language Code:
en-us
Document:
We assessed hippocampal-dependent memory in mice with a Ca(2+)-independent form of CaMKII generated by the introduction of an aspartate at amino acid 286. The CaMKII-Asp-286 mice show normal LTP at high frequency stimulation, but in the 5-10 Hz range, they show a shift in the frequency-response curve favoring LTD. This range of frequencies is similar to the theta rhythm, which is associated with exploration in rodents. Using the Barnes maze to assess spatial memory, we found the transgenic mice could not learn to navigate to a specific location using spatial cues. In contrast, one line of transgenic mice performed normally in contextual fear conditioning, a task that is also hippocampal dependent. This dissociation between spatial and contextual memory suggests that even though both require the hippocampus, they may be mediated by different synaptic mechanisms.
ID:
Title:
Effect of traumatic brain injury on mouse spatial and nonspatial learning in the Barnes circular maze.
URI:
https://www.ncbi.nlm.nih.gov/pubmed/?term=9872460
Provider Org:
Language Code:
en-us
Document:
Controlled cortical impact (CCI) is a relatively new model of traumatic brain injury in the mouse, which, in combination with behavioral and histological methods, has potential for elucidating underlying mechanisms of neurodegeneration using genetically altered animals. Previously, we have demonstrated impaired spatial learning in a water maze task following CCI injury at a moderate level. There are many difficulties associated with this task, however, such as stress, physical demand, and the multiple trials over days required for satisfactory training. As a potential alternative to the water maze, we adapted the Barnes circular maze to our mouse model and assessed spatial/nonspatial learning following injury. Mice were trained to locate a dark tunnel, hidden beneath one of 40 holes positioned around the perimeter of a large, flat, plastic disk, brightly illuminated by four overhead halogen lamps. Sham-operated animals rapidly acquired this task, exhibiting reduced latency to find the tunnel and a more efficient search strategy as compared with injured mice. This difference was not due to visuomotor deficits, as all mice performed equally well in a cued version of the same task. These results demonstrate spatial learning impairment following CCI injury in a task that offers an efficient alternative to the water maze.
ID:
Title:
Adaptation of the circular platform spatial memory task for mice: use in detecting cognitive impairment in the APP(SW) transgenic mouse model for Alzheimer's disease.
A methodology is described for use of a 16-hole circular platform task to test spatial memory in mice. Both bright light and a fan were used to motivate mice to escape the platform surface through a single hole containing an attached escape box. For each daily trial, three correlated measures (escape latency, number of errors, and error rating) comprehensively evaluated cognitive performance. In an initial study, the 'spatial' nature of this task was demonstrated by the much poorer performance of non-transgenic mice when visual cues are removed. Behavioral sensitivity of the circular platform task was then shown through its ability to discern cognitive impairment in 7-month-old transgenic mice, carrying the mutant APP(SW) gene for early-onset Alzheimer's disease in humans, from non-transgenic litter-mates. Since there are currently only a few tasks available to definitively test cognitive performance in mice, the circular platform task offers a versatile, multiple-measure option with numerous advantages. Particularly in view of the increasing number of genetically manipulated mouse models being produced, the circular platform task should be most useful in providing a sensitive evaluation of cognition in mice.
ID:
Title:
Cognitive deficits develop 1month after diffuse brain injury and are exaggerated by microglia-associated reactivity to peripheral immune challenge.
Traumatic brain injury (TBI) elicits immediate neuroinflammatory events that contribute to acute cognitive, motor, and affective disturbance. Despite resolution of these acute complications, significant neuropsychiatric and cognitive issues can develop and progress after TBI. We and others have provided novel evidence that these complications are potentiated by repeated injuries, immune challenges and stressors. A key component to this may be increased sensitization or priming of glia after TBI. Therefore, our objectives were to determine the degree to which cognitive deterioration occurred after diffuse TBI (moderate midline fluid percussion injury) and ascertain if glial reactivity induced by an acute immune challenge potentiated cognitive decline 30 days post injury (dpi). In post-recovery assessments, hippocampal-dependent learning and memory recall were normal 7 dpi, but anterograde learning was impaired by 30 dpi. Examination of mRNA and morphological profiles of glia 30 dpi indicated a low but persistent level of inflammation with elevated expression of GFAP and IL-1β in astrocytes and MHCII and IL-1β in microglia. Moreover, an acute immune challenge 30 dpi robustly interrupted memory consolidation specifically in TBI mice. These deficits were associated with exaggerated microglia-mediated inflammation with amplified (IL-1β, CCL2, TNFα) and prolonged (TNFα) cytokine/chemokine expression, and a marked reactive morphological profile of microglia in the CA3 of the hippocampus. Collectively, these data indicate that microglia remain sensitized 30 dpi after moderate TBI and a secondary inflammatory challenge elicits robust microglial reactivity that augments cognitive decline.Traumatic brain injury (TBI) is a major risk factor in development of neuropsychiatric problems long after injury, negatively affecting quality of life. Mounting evidence indicates that inflammatory processes worsen with time after a brain injury and are likely mediated by glia. Here, we show that primed microglia and astrocytes developed in mice 1 month following moderate diffuse TBI, coinciding with cognitive deficits that were not initially evident after injury. Additionally, TBI-induced glial priming may adversely affect the ability of glia to appropriately respond to immune challenges, which occur regularly across the lifespan. Indeed, we show that an acute immune challenge augmented microglial reactivity and cognitive deficits. This idea may provide new avenues of clinical assessments and treatments following TBI.
ID:
Title:
Marble-burying is enhanced in 3xTg-AD mice, can be reversed by risperidone and it is modulable by handling.
Translational research on behavioural and psychological symptoms of dementia (BPSD) is relevant to the study the neuropsychiatric symptoms that strongly affect the quality of life of the human Alzheimer's disease (AD) patient and caregivers, frequently leading to early institutionalization. Among the ethological behavioural tests for rodents, marble burying is considered to model the spectrum of anxiety, psychotic and obsessive-compulsive like symptoms. The present work was aimed to study the behavioural interactions of 12 month-old male 3xTg-AD mice with small objects using the marble-burying test, as compared to the response elicited in age-matched non-transgenic (NTg) mice. The distinction of the classical 'number of buried marbles' but also those left 'intact' and those 'changed' of position of marbles or partially buried (the transitional level of interaction) provided new insights into the modelling of BPSD-like alterations in this AD model. The analysis revealed genotype differences in the behavioural patterns and predominant behaviors. In the NTg mice, predominance was shown in the 'changed or partially buried', while interactions with marble were enhanced in 3xTg-AD mice resulting in an increase of marble burying. Besides, genotype-dependent meaningful correlations were found, with the marble test pattern of 3xTg-AD mice being directly related to neophobia in the corner tests. In both genotypes, the increase of burying was reversed by chronic treatment with risperidone (1mg/kg, s.c.). In 3xTg-AD mice, the repetitive handling of animals during the treatment also exerted modulatory effects. These distinct patterns further characterize the modelling of BPSD-like symptoms in the 3xTg-AD mice, and provide another behavioural tool to assess the benefits of preventive and/or therapeutic strategies, as well as the potential action of risk factors for AD, in this animal model.
ID:
Title:
Value of water mazes for assessing spatial and egocentric learning and memory in rodent basic research and regulatory studies.