Aging brain

About: Aging brain is a research topic. Over the lifetime, 1255 publications have been published within this topic receiving 66405 citations.

Successful brain aging: plasticity, environmental enrichment, and lifestyle.

Abstract: Aging is a physiological process that can develop without the appearance of concurrent diseases. However, very frequently, older people suffer from memory loss and an accelerated cognitive decline. Studies of the neurobiology of aging are beginning to decipher the mechanisms underlying not only the physiology of aging of the brain but also the mechanisms that make people more vulnerable to cognitive dysfunction and neurodegenerative diseases. Today we know that the aging brain retains a considerable functional plasticity, and that this plasticity is positively promoted by genes activated by different lifestyle factors. In this article some of these lifestyle factors and their mechanisms of action are reviewed, including environmental enrichment and the importance of food intake and some nutrients. Aerobic physical exercise and reduction of chronic stress are also briefly reviewed. It is proposed that lifestyle factors are powerful instruments to promote healthy and successful aging of the brain and delay the appearance of age-related cognitive deficits in elderly people.

Epigenetic Enhancement of BDNF Signaling Rescues Synaptic Plasticity in Aging

Abstract: Aging-related cognitive declines are well documented in humans and animal models. Yet the synaptic and molecular mechanisms responsible for cognitive aging are not well understood. Here we demonstrated age-dependent deficits in long-term synaptic plasticity and loss of dendritic spines in the hippocampus of aged Fisher 344 rats, which were closely associated with reduced histone acetylation, upregulation of histone deacetylase (HDAC) 2, and decreased expression of a histone acetyltransferase. Further analysis showed that one of the key genes affected by such changes was the brain-derived neurotrophic factor (Bdnf) gene. Age-dependent reductions in H3 and H4 acetylation were detected within multiple promoter regions of the Bdnf gene, leading to a significant decrease in BDNF expression and impairment of downstream signaling in the aged hippocampus. These synaptic and signaling deficits could be rescued by enhancing BDNF and trkB expression via HDAC inhibition or by directly activating trkB receptors with 7,8-dihydroxyflavone, a newly identified, selective agonist for trkB. Together, our findings suggest that age-dependent declines in chromatin histone acetylation and the resulting changes in BDNF expression and signaling are key mechanisms underlying the deterioration of synaptic function and structure in the aging brain. Furthermore, epigenetic or pharmacological enhancement of BDNF-trkB signaling could be a promising strategy for reversing cognitive aging.

Challenges of multimorbidity of the aging brain: a critical update

Abstract: A major problem in elderly patients is the high incidence of multiple pathologies, referred to as multimorbidity, in the aging brain. It has been increasingly recognized that co-occurrence of neurodegenerative proteinopathies and other pathologies including cerebrovascular disorders is a frequent event in the brains of both cognitively intact and impaired aged subjects. Although clinical and neuropathological diagnostic criteria of the major neurodegenerative diseases have been improved, major challenges arise from cerebral multimorbidity, and the thresholds to cause clinical overt dementia are ill defined. More than 80 % of aged human brains show neurodegenerative non-Alzheimer type proteinopathies and other pathologies which, however, frequently have been missed clinically and are even difficult to identify at neuropathological examination. Autopsy studies differ in selection criteria and the applied evaluation methods. Therefore, irrespective of the clinical symptoms, the frequency of cerebral pathologies vary considerably: Alzheimer-related pathology is seen in 19–100 %, with “pure” Alzheimer’s disease (AD) in 17–72 %, Lewy pathology in 6–39 % (AD + Lewy disease 9–28 %), vascular pathologies in 28–93 % (10.7–78 % “pure” vascular dementia), TDP-43 proteinopathy in 6–39 %, hippocampal sclerosis in 8–1 %, and mixed pathologies in 10–93 %. These data clearly suggest that pathologically deposited proteins in neurodegenerating diseases mutually interact and are influenced by other factors, in particular cardiovascular and cerebrovascular ones, to promote cognitive decline and other clinical symptoms. It is obvious that cognitive and other neuropsychiatric impairment in the aged result from a multimorbid condition in the CNS rather than from a single disease and that the number of complex pathologies progresses with increasing age. These facts have implications for improvement of the clinical diagnosis and prognosis, the development of specific biomarkers, preventive strategies and better treatment of cerebral multimorbidity.

Functional recovery in aging mice after experimental stroke.

Abstract: Aging is a non-modifiable risk factor for stroke. Since not all strokes can be prevented, a major emerging area of research is the development of effective strategies to enhance functional recovery after stroke. However, in the vast majority of pre-clinical stroke studies, the behavioral tests used to assess functional recovery have only been validated for use in young animals, or are designed for rats. Mice are increasingly utilized in stroke models but well validated behavioral tests designed for rats are not necessarily reproducible in mice. We examined a battery of behavioral tests to evaluate functional recovery in an aging murine model of stroke. We found that the vertical pole, hanging wire and open field can accurately assess acute behavioral impairments after stroke in both young and aging male mice, but animals recover rapidly on these tasks. The corner test can accurately and repeatedly differentiate stroke from sham animals up to 30 days post stroke and can be performed reliably in aging mice. Aging male mice had significantly worse behavioral impairment compared to young male mice in the first two weeks after stroke but eventually recovered to the same degree as young mice. In contrast, chronic infarct size, as measured by ipsilateral cerebral atrophy, was significantly lower in aging male mice compared to young male mice. Reactive gliosis, formation of glial scar, and an enhanced innate immune response was seen in the aging brain and may contribute to the delayed behavioral recovery seen in the aging animals.