View clinical trials related to Healthy Aging.
Filter by:Impaired working memory (WM) plays a crucial role in normal aging, in mild cognitive impairment (MCI) and cognitive decline associated with dementia, such as Alzheimer's disease (AD). The aging-related differences in WM are hypothesized to be based on various neurobiological origins, for example alterations in the dynamic interplay between the large-scale brain networks have proven an important role. Recent studies have shown that non-invasive brain stimulation (NIBS) methods can modulate neuronal activity, plasticity and large-scale brain network interactions. The investigators hypothesize that multifocal NIBS can improve WM. By successive and concurrent stimulation of multiple brain regions of the WM network by transcranial alternating current stimulation (tACS) and/or repetitive transcranial magnetic stimulation (rTMS) the investigators will study dynamic interactions between distinct cortico-cortical and subcortico-cortical brain areas. By leveraging multimodal systems neuroscience information during multifocal stimulation, the investigators expect to acquire better mechanistic understand through which NIBS acts on the brain and improves cognitive functions, such as WM.
Open labelled, virtual home based study to assess the test repeatability and the failure/rejection rate of the samples collected at home by participants.
The number of older Americans will double in the next 4 decades to nearly 90 million, placing an unprecedented financial and resource burden on the health care system. Exercise has clear and demonstrable physical benefits, but a more precise understanding of how exercise supports cognitive function is essential. Demonstrating definitively that exercise as recommended by public health entities has benefits for cognition would have enormous public health implications, encourage the public to adapt more active lifestyles, and stimulate the development of effective exercise delivery programs.
T-cell adaptive immunity is known to be required to sustain a long term immunoglobulin production and a long term memory against several infections. Previous results suggest a lack in the generation of T-cell responses against CoV-N, M and S proteins among cancer patients exposed to SARS-CoV-2 virus highlighting that cancer patients failed to mount a protective T-cell immunity. Given this context, our hypothesis is that COVID-19 vaccine candidates are not immunogenic in some cancer patients. Thus, the monitoring of CD4 and CD8 T-cell responses before and after vaccination might provide information related to the correlation between induction of CD4 T-cells (including helper follicular T-cells) by the vaccine and long-term IgG production (serological index). Additionally, the failure of COVID-19 vaccines in some patients should be monitor carefully in order to provide specific recommendations to avoid COVID-19 infections. The main objective is to assess humoral immune responses following COVID-19 vaccination in a population of cancer patients.
The study seeks to investigate whether 24 weeks of power training has neuroprotective effects in older PwMS. Additional purposes are to examine the effects of 24 weeks power training on physical function, cognitive function and neuromuscular function. Further, it is investigated whether the potential effects of power training are maintained after 24 weeks of follow-up.
This is a pilot RCT with equal arms: experimental arm and (wait list) control arm. All participants will be in the early stage of Alzheimer's disease and on stable medication. They will all continue with this medication for their 6 months participation. Experimental group will add weekly training on the experimental device, 5 days a week for 8 weeks. Training will involve therapeutic games aimed primarily at the memory cognitive domain. All participants will receive weekly calls from clinical coordinator and report on medication and overall health. Caregivers will also be enrolled so they support the trials.
To study the correlation between the iron load in brain, measured in MRI, and the age of healthy subjects Secondary objectives are to study the correlations between the iron load in cortical brain regions and (i) the cognitive performances, (ii) markers of aging (MRI, EEG, OCT, biology),and (iii) demographical factors involved in iron load.
A recently completed study suggested that processing speed and attention (PS/A) oriented cognitive training (VSOP) produced robust effect on PS/A and working memory, but not in cognitive control or episodic memory, and long-term effects were overall modest. The proposed R01 renewal proposes to identify additional attributes to further enhance transferred and long-term effects of PS/A training in older adults with amnestic mild cognitive impairment (MCI) by addressing adaptation capacity that underpins adaptive learning and neuroplasticity. The goal of the stage II double-blinded randomized trial is to test whether adding resonance frequency breathing (RFB) training to VSOP will strengthen multiple contributors to adaptation capacity, particularly the central and peripheral pathways of autonomic nervous system (ANS) flexibility, which will strengthen VSOP training effect on cognitive and brain function and slow the progress of dementia in MCI. The central hypothesis is that strengthening adaptation capacity, via improving autonomic nervous system (ANS) flexibility, will enhance neuroplasticity and slow progress of dementia in MCI, since adaptation capacity is critical for neuroplasticity of VSOP, but compromised in neurodegenerative process. Older adults with MCI (n = 114) will be randomly assigned to an 8-week combined intervention (RFB+VSOP), VSOP with guided imagery relaxation (IR) control, and a waitlist IR control, with periodical booster training sessions at follow-ups. Mechanistic and distal outcomes include ANS flexibility and multiple markers of dementia progress. Data will be collected across a 14-month period. The two primary aims are to examine long-term effects of the combined intervention on ANS flexibility (Aim 1), as well as the cognitive, behavioral, and functional capacity (Aim 2). The exploratory aim will be to determine the preliminary long-term effect of the combined intervention on neurodegeneration. This can be a reasonable renewal plan from the completed study, aiming to identify additional attributes to further enhance transferred and long-term effects of cognitive training in MCI. This will be among the first randomized controlled trials to examine a novel, combined intervention targeting adaptation capacity in MCI, with an ultimate goal for slowing neurodegeneration. In addition, research on how to monitor adherence - the extent to which VSOP training is delivered and followed as intended - has been conceptually and methodologically limited. Robust monitoring of adherence to cognitive training requires valid assessment of effective engagement. Here, we apply our well-supported, novel framework of mental fatigability for measuring effective engagement in cognitive training. Mental fatigability, the failure to remain engaged in tasks requiring sustained mental effort, can be captured via measures of self-reported disengagement, increase in reaction time during tasks, and facial expression of negative valence/low arousal. These markers of disengagement relate to ventromedial prefrontal cortex dysfunction. We will apply this framework to advance understanding of the underpinnings of adherence to VSOP training by monitoring the extent of effective engagement while using the training platform.
In this study, high-definition dual-site transcranial alternating current stimulation (i.e., non-invasive brain stimulation) will be applied to boost the fronto-parietal network during a bimanual coordination task in healthy young and older adults. Previous studies indicated that this network is important in initial motor learning, possibly through its role in spatial working memory. Therefore, stimulation will be applied during both a pure spatial working memory test, and during a bimanual coordination task. It is also shown that healthy older adults do not engage spatial working memory brain regions during motor learning, which is related to worse motor learning. Therefore, the investigators will investigate whether this type of stimulation can improve bimanual motor learning in healthy older adults.
The objective of this pilot study is to evaluate and compare the effect of three different perturbation based training devices on the reactive balance control among healthy young adults, healthy older adults, and neurologically impaired stroke individuals. Furthermore, the project aims to determine the feasibility and tolerability of 30-minutes of perturbation training using the SureFooted Trainer. Overall, the project directs to find out the long term effect of training on fall risk reduction and fall prevention. This study investigates the effects of perturbation training (slip and trip) based on the principles of motor learning. Perturbations in the form of slips and trips induced by the three different types of perturbation devices will displace the center of mass outside the base of support and challenge the stability, thereby inducing a fall and demand compensatory strategies in order to prevent it. Such perturbation training would train the motor system to improve stability control and vertical limb support. The project design aims to examine the ability of the central nervous system to mitigate the interference in stability control (if any) that is induced by opposing types of perturbations. The hypothesis of this study if supported by the results, will provide the difference in motor learning with training on three different perturbation devices. Furthermore, it would help to determine which of the three training devices is the most effective in developing defense mechanisms necessary to reduce fall-risk among community-living older adults and the neurological population.