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Background: Intact socio-cognitive abilities, such as theory of mind (ToM), facial emotion recognition (FER), social decision making (SDM) and visual perspective taking (VPT), are essential for human well-being and quality of life. Impairment in social cognition can have major implications for health in affected individuals and society as a whole. Evidence for changes in social cognition in healthy and pathological aging processes, such as subjective cognitive decline (SCD) and mild cognitive impairment (MCI), is currently either sparse or inconclusive. It is important to determine how social cognition changes in healthy and pathological aging and provide grounds for targeted and early assessment and intervention. The aims of this thesis were to investigate social cognition across four domains, in particular, ToM, FER, SDM and VPT, in healthy young and older individuals, as well as in individuals with cognitive deficits, such as SCD and MCI. In the case of a decline, further goals were to investigate the degree of impairment and the domains affected.
Methods: A systematic literature search was conducted in four major academic databases, MEDLINE, Web of Science Core Collection, CENTRAL, and PsycInfo, for studies investigating social cognition in healthy young and old individuals as well as individuals affected by SCD and MCI which met the inclusion criteria. The primary outcome was ToM and secondary outcomes were FER, SDM and VPT. After a systematic review was performed, studies eligible for meta-analysis were divided according to comparison groups and outcomes. Random-effects meta-analyses were conducted using standardized mean differences (SMD). Risk of Bias was assessed using the “Tool to assess risk of bias in cohort studies” modified for the present study design.
Results: After a thorough systematic literature search, 86 studies containing 88 comparisons were included in the systematic review, of which 47 were eligible for quantitative analysis. The meta-analysis revealed a progressive decline in ToM and FER abilities from young adulthood to MCI. Varying effect sizes demonstrated different trajectories of change for specific domains. Due to a lack of research, data investigating SDM and VPT, as well as SCD were insufficient for quantitative analysis.
Conclusion: ToM and FER decline gradually from healthy to pathological aging. Therefore, assessment of social cognition is important and should be incorporated in routine neurocognitive testing, so that targeted interventions can be introduced when needed. With this information in mind, future research should focus on the development of new assessment tools, as well as preventive and treatment strategies. This review also identified research gaps in certain populations (e.g. SCD, middle age, MCI-subtypes) as well as domains (VPT and SDM) that need to be addressed in the future.
The Effect of the Patients Nutritional Status on Immune Alterations Induced by Ischemic Stroke
(2018)
Ischemic stroke is one of the leading causes of death and disability throughout the world.
One important aspect of stroke pathophysiology are immunological changes after stroke, especially a combination of post stroke immunodepression, leading to
infectious complications after stroke and an activation of the immune system, leading to cerebral injury. Adipose tissue has several immunological functions and obesity
leads to immunological complications and is accompanied by a chronic immune activation.
To study the effects of body weight and obesity on the immune system and measure weight and fat tissue changes after ischemic stroke we conducted the LIPS Trial and enrolled 50 stroke patients and 16 control subjects between July 2015 and July 2016. On the day of admission and on the days 1, 2, 3, 4, 5, 7, 30, 90 and 180 after admission stroke patients were weighed with an in-bed scale, body composition was measured with BIA, the triceps-skin fold thickness was measured, the NIHSS scale was obtained and blood was drawn. FACS-analysis was performed and triglycerides,cholesterol, CRP and PCT were measured at the central laboratory facility of the Universitätsmedizin Greifswald. Luminex-multiplex analysis for multiple cyto- and chemokines was performed at the Multiplex Facility at the University Leiden. A cerebral MRI and an abdominal MRI were performed shortly after admission and on days 5-7 for most patients and the infarct volume, abdominal fat and hepatic fat percentage were measured. On days 30, 90 and 180 after stroke Bartel Index and mRS were obtained.
After stroke our patients showed the typical immunological changes described previously as stroke induced immune alterations, namely a post stroke immunodepression as well as signs of an activated immune system and an acute
phase response. Our patients lost weight, but only 1.7 ± 0.5 kg. Skinfold thickness did not change during the course of our trial and abdominal fat measurement did not change in stroke patients. Immunological parameters (leukocytes, neutrophils,CRP, PCT, IL-6) did not differ between BMI subgroups (normal weight: BMI < 25,overweight: BMI ≥ 25, < 30, obese: BMI ≥ 30) and in this trial we could not detect a
difference in patients with normal weight, overweight or obesity in the post stroke periode. In an additional analysis we could show that rapid clinical improvement
did result in a rapid improvement of post stroke immune alterations, especially for leukocytes, neutrophils, IL-6 and CRP.
In aged humans, stroke is a major cause of disability for which no neuroprotective measures are available. In animal studies of focal ischemia, short-term hypothermia often reduces infarct size. Nevertheless, efficient neuroprotection requires long-term, regulated lowering of whole-body temperature. Previously, it is reported that post-stroke exposure to hydrogen sulfide (H2S) effectively lowers whole-body temperature and confers neuroprotection in aged animals. Here we report for the first time that the animals exposed to H2S the normal sleep–wake oscillations are replaced by a low-amplitude EEG dominated by a 4-Hz rhythmicactivity, reminiscent of EEG recordings in hibernating animals. In the present study using magnetic resonance imaging, reverse transcriptase polymerase chain reaction, western blotting and immunofluorescence, we characterized the central nervous system response to H2S -induced hypothermia and report, that annexin A1, a major constituent of peripheral leukocytes that is upregulated after stroke, was consistently downregulated in polymorphonuclear cells in the peri-lesional cortex of post-ischemic, aged rat brain after 48 hours of hypothermia induced by exposure to H2S. This might be due to the reduced kinetics of recruitment, adherence and infiltration of PMN cells by H2S -induced hypothermia. Our findings further suggest that, in contrast to monotherapies that have thus far uniformly failed in clinical practice, prolonged hypothermia has pleiotropic effects on brain physiology that may be necessary for effective protection of the brain after stroke.
Multiple sclerosis (MS) and stroke share a number of mechanisms of neuronal damage. In both cases the balance between neurodestruction and neuroprotection appears modulated by the function of the adaptive immune system. MS is a chronic inflammatory disease of the central nervous system (CNS), leading to permanent disability. It seems certain that an autoimmune response directed against the CNS is central to the pathogenesis of the disease. While these CNS-specific T cells are activated in MS patients, they are inactive and naive in healthy. Therefore it is believed that an activation of autoreactive T cells by cross-reactivity with pathogens occurs outside of the CNS. In consequence T cells express adhesion molecules and proteinases which enable them to cross the blood-brain barrier. In stroke, however, the blood-brain barrier is disturbed in its integrity caused by the decreased blood flow. Cells can freely migrate from the periphery into the brain. CNS autoreactive cells from the periphery can be activated within the CNS and thus contribute to further tissue damage. While the local autoimmune response remains temporary in stroked brains, it is chronically destroyed in MS. The differences between the underlying mechanisms are not understood. This thesis investigated T cell responses in Multiple Sclerosis in response to the therapeutics Mitoxantrone and IFN-b. The induction of a TH1 to TH2 cytokine response appears to be a shared mechanism of action between both therapeutic agents. Primarily the post stroke immune response was investigated. Patients developed a stroke induced immune suppression characterized by monocytic dysfunction and lymphocytopenia explaining the high frequency of post stroke infections. Moreover early post stroke predictors of subsequent infections, like the CD4+ T cell count, were identified. The T cell response of stroke patients appeared primed to proinflammation and unsuppressed after mitogen stimulation. A detailed understanding of post stroke immune alterations may offer new avenues of intervention to improve the clinical fate of stroke victims. In addition, such knowledge could also further our understanding of Multiple Sclerosis, because, while increasing the infection risk, the dampening of the immune system could have an important protective function, if it limits autoimmune brain damage triggered by the massive release of brain antigens during stroke. If these two pathways could be modulated separately it would create the opportunity to develop distinct therapeutic approaches that inhibit autoimmunity and strengthen antibacterial defenses. To further delineate these mechanisms it is crucial to investigate the role of the innate immune system as compared to the adaptive immune system in stroke induced immune suppression.
Age-related brain injuries including stroke, are a major cause of physical and mental disabilities. Therefore studying the basic mechanism underlying functional recovery after brain stroke in middle aged subjected it is of considerable clinical interest. Data from our lab and elsewhere indicate that, behaviorally, middle aged rats were more severely impaired by stroke than were young rats, and they also showed diminished functional recovery. Infarct volume did not differ significantly in young and middle aged animals, but critical differences were apparent in the cytological response to stroke, most notably an age-related acceleration of the establishment of the glial scar. The early infarct in older rats is associated with a premature accumulation of BrdU-positive microglia and astrocytes, persistence of activated oligodendrocytes, a high incidence of neuronal degeneration, and accelerated apoptosis. In middle aged rats, neuroepithelial-positive cells were rapidly incorporated into the glial scar, but these neuroepithelial-like cells did not make a significant contribution to neurogenesis in the infarcted cortex in young or middle aged animals. Stroke is accompanied by a strong inflammatory reaction in the brain. We hypothesized that a mild systemic inflammatory reaction as caused by periodontal disease prior to stroke onset, may exert a neuroprotective effect in a rat model of focal ischemia. To test this hypothesis, marginal periodontitis was induced in BB/LL Wistar rats for 3 weeks. Two weeks after periodontitis initiation, focal cerebral ischemia was produced by reversible occlusion of the right middle cerebral artery. After a survival time of 7 days after ischemia, rat brains were analyzed. In addition, markers of systemic inflammation were determined in a different group of laboratory animals at 14 days after the onset of periodontitis. We found that rats with a mild systemic inflammation had a significantly reduced infarct volume and a significant reduction in the number of brain macrophages in the infarcted area. Conclusions: The available evidence indicates that the middle aged brain has the capability to mount a cytoproliferative response to injury, but the timing of the cellular and genetic response to cerebral insult is deregulated in middle aged animals, thereby further compromising functional recovery. In addition we found that that mild systemic inflammation elicited prior to stroke onset may have a neuroprotective effect in rats by reducing the infarct volume and tissue destruction by brain macrophages.
Abstract: Ischemic stroke is an aging disease and causes high mortality or long-term disability. The reduced neurological recovery in aging is possibly associated with impairment of angiogenesis and non-specific enhancement of inflammatory reaction. To check this hypotheses, those events were compared within young and elder animals brain at day 14 following focal ischemic stroke. Moreover, it is of importance to investigate also the potential therapies of indomethacin for prolonging the therapeutic window using aged animal models. The focus of present study was on neurobiological and neurological differences between young and old rats modulated by indomethacin daily treatment beginning at four hours post-ischemic episode. The effectiveness of indomethacin treatment in young and elder rats was probed using immunohistochemistry, oligonucleotide microarray, Real Time PCR and neurological evaluation. Our results provide insight of several age-independent positive consequences of Cox non-specific inhibition by indomethacin including increased NeuN positive surviving neurons, reduced infarct volume and enhanced neuroprotective response of innate immune system evidenced by increased Iba1 and Anx3 immunoreactivities in moderately activated microglia in periinfarction. From gene level we observed in both age groups downregulation of Mdk and Cxcl1 chemokines, and Id3 transcription factor which might modulate inflammatory response and facilitate repair. Other several findings showed age-dependent drug effect. Indomethacin had reduced efficacy in aged ischemic brain. From a total of 34 genes differential regulated, we observed 43% in young and only 28% of genes in aged have tendency toward age-matched sham expression level. In aged rats, indomethacin is ineffective in inhibiting phagocytic activity which is probably due to no expression changes of several cytokines like Tnfá and Cxcl4. Also, at protein level we observed no change of lysosomal ED1 immunoreactivity under treatment. On the other hand aging is characterized by no expression changes of Plau, Timp1, Timp2 and Col18a1 after treatment resulting in no improvement of angiogenesis. In young rats, conversely, drug administration decreased phagocytic activity by downregulating several cytotoxic cytokines such as Tnfá and Cxcl4. Moreover, the observable decrease of proteases like MMP10, Plau and MMP inhibitor Timp2 employed in matrix remodeling together with downregulation of Col18a1 expression after treatment might sustain angiogenesis in young rat ischemic brain. Indomethacin improves the motor-sensory performance in ischemic stroke rats as compared with age-matched untreated animals. Young rats fully recovered while aged showed important recuperation but did not achieve the preoperative level. In view of all this, indomethacin treatment might be consider as adjuvant therapy following ischemic stroke, even if aging blunts the positive effect of indomethacin on altered angiogenic-related gene expression. Because of the small number of rats, the results obtained from this study show only a tendency to significance and that further studies with more animals need to be statistically validated before firmly conclusions can be drawn. KEY WORDS: indomethacin; aging; microglia; angiogenesis; gene expression; microarray; neurological recovery; reversible middle cerebral artery occlusion.
Aging is a risk factor for stroke. Animal models of stroke have been widely used to study the pathophysiology of ischemic stroke, which in turn helped to develop numerous therapeutic strategies. Despite the considerable success of therapeutic strategies in animal models of ischemic stroke, almost all of them have been proved to be unsuccessful in the clinical trials. One of explanation is that data obtained from young animals may not fully resemble the effects of ischemic stroke in aged animals or elder patients, causing the discrepancy between animal experiments and clinical trials. To investigate these differences with regard to age, pathway specific gene arrays were used to identify and isolate differentially expressed genes in periinfarct following focal cerebral ischemia. The results from this study showed a persistent up-regulation of pro-apoptotic and inflammatory-related genes up to 14 days post stroke, a 50% reduction in the number of transcriptionally active stem cell-related genes and a decreased expression of genes with anti-oxidative capacity in aged rats. Also, it was observed that at day 3 post-stroke, the contralateral, healthy hemisphere of young rats is much more active at transcriptional level than that of the aged rats, especially at the level of stem cell- and hypoxia signaling associated genes. Next, protein levels between young and aged post-stroke rats in periinfarct were compared using proteomic tools. Among others, AnxA3 was identified as differentially regulated protein, but the expression of AnxA3 has no significant changes in periinfarct between these two age groups at day 3 and 14. Different from periinfarct, a strong upregulation of AnxA3 at day 3 in young rats plus a strengthened increase of AnxA3 at day 14 in aged rats using immunohistochemical quantification indicated a delayed microglial accumulation in infarct core of aged rats, suggesting that quick activation of microglia in infarct core of young rats might be beneficial for recovery. Colocalization with established microglial marker demonstrated that AnxA3 as a novel microglial marker is implicated in the microglial responses to the focal cerebral ischemia. In addition, it was found that AnxA3 positive microglial cells incorporated more proliferating cell marker BrdU. Third, the expression, localization and function of several transport proteins were investigated in young rats following focal ischemic stroke. P-gp staining was detected in endothelial cells of desintegrated capillaries and by day 14 in newly generated blood vessels. There was no significant difference, however, in the Mdr1a mRNA amount in the periinfarct region compared to the contralateral site. For Bcrp, a significant mRNA up-regulation was observed from day 3 to 14. This up-regulation was followed by the protein as confirmed by quantitative immunohistochemistry. Oatp2, located in the vascular endothelium, was also up-regulated at day 14. For Mrp5, an up-regulation was observed in neurons in the periinfarct region (day 14). In conclusion, reduced transcriptional activity in the healthy, contralateral sensorimotor cortex in conjunction with an early up-regulation of proapoptotic genes and a decreased expression of genes with anti-oxidative capacity in the ipsilateral sensorimotor cortex of aged rats, plus the delayed up-regulation of AnxA3 positive microglial cells in infarct core may contribute to diminished recovery in post-stroke old rats. In addition, it was demonstrated in this study that after stroke the transport proteins were up-regulated with a maximum at day 14, a time point that coincides with behavioral recuperation. The study further suggests Bcrp as a pronounced marker for the regenerative process and a possible functional role of Mrp5 in surviving neurons. This study provided several evidences for the different responses of young and aged rats using a focal ischemic stroke model. Understanding the effect of age is crucial for the development of relevant therapeutic drugs.
Studies of stroke in experimental animals have demonstrated the neuroprotective efficacy of a variety of interventions; however, most such strategies have failed to show clinical benefits in aged humans. One possible explanation for this discrepancy between animal and clinical studies may be the role that age plays in the recovery of the brain following insult. For example, the poor functional recovery of aged rats after stroke may be caused by a decline in brain plasticity. Although the incidence of ischemic stroke increases dramatically with advancing age, relatively few studies have been conducted on aged animals, which would mimic most closely the context in which stroke occurs in humans. We have shown that, at one week following stroke, there was vigorous expression of MAP1B and its mRNA, as well as MAP2 protein, in the border zone adjacent to the infarct of 3 month- and 20 month-old male Sprague Dawley rats. Hypothesis: The decline in brain plasticity is caused by an age-related decline in the upregulation of factors promoting brain plasticity (MAP1B, ßAPP) and an age-related increase in astroglial scaring and in the expression of neurotoxins such as beta amyloid. Methods: Focal cerebral ischemia was produced by reversible occlusion of the right middle cerebral artery in 3- and 20-month-old male Sprague Dawley rats. The functional outcome was assessed in neurobehavioral tests at 3, 7, 14, and 28 days post-stroke. At these time points, brains were removed and analyzed for markers of (i) brain plasticity (microtubule-associated protein 1B, MAP1B, secreted forms of fi-amyloid precursor protein); (ii) neurogenesis (BrdU-positive cells, doublecortin, nestin); (iii) neurotoxicity (B-amyloid aggregates); (iv) inflammation (microglia, astrocytes, oligodendrocytes, endothelial cells). Results: (1) There was a non-significant tendency for blood pressure to be higher in old than in young rats. By post-stroke day 3 the infarct volume covered about 15% of the cortical neurons in young and 28% in aged rats. By day 7, infarct volumes were roughly equal in the two age groups. (2) Cell counting showed increases in the number of BrdU-positive cells in the infarcted area of old rats at day 3 post-stroke. This increase became even more dramatic at day 7 post-stroke in aged rats. There was no significant contribution of apoptosis to cell death. (3) Behaviorally, young rats recovered gradually and reached a maximum of 90% of baseline performance at day 14, post-stroke while the aged rats recovered only to a maximum of 70% of pre-surgery performance by week 2 post-stroke, and remained at that level. (4) The temporal pattern of recovery correlated well with the expression of growth-associated phenotype of ßAPP as well as with MAP1B accumulation in varicosities along axons (an indicator of growth) in cortical areas affected by stroke and was at maximum between days 14 to 28 in young rats. In contrast, aged rats showed delayed (day 28) and reduced axonal remodelling as well as a delayed (day 28) expression of growth-associated ßAPP. Instead, the neurotoxic carboxy-terminal form of ßAPP steadily accumulated over time and reached a maximum at day 14 in aged rats as compared to 28d for the young rats. Nestin, a marker for immature neurons, overlapped with BrdU-labelled cells at day 7 post-stroke in corpus callosum and at the infarct border in both young and aged rats, suggesting increased stroke-induced neurogenesis. (5) In young rats there was a gradual activation of both microglia and astrocytes that peaked by days 14 to 28 with the formation of a glial scar. In contrast, aged rats showed an accelerated astrocytic and microglial reaction that peaked in week 1 post-stroke. We also noted a strong activation of oligodendrocytes at early stages of infarct development in all rats that persisted in aged rats. Evolution of astrocytic and microglial reactivity closely paralled the time course of scar formation in both young and aged rats and coincided with the stagnation in the recovery rate of aged rats. Conclusions: The time course of functional recovery in young rats correlated well with the expression of plasticity proteins such as MAP1B and ßAPP while an early and persistent expression of the neuro toxic fragment AB in conjunction with a delayed expression of MAP1B and ßAPP may impede functional recovery in aged rats. The results also suggest that a temporally anomalous glial reaction to cerebral ischemia in aged rats leads to the premature formation of scar tissue that impedes functional recovery to stroke.