Refine
Document Type
- Article (6)
- Doctoral Thesis (1)
Language
- English (7)
Has Fulltext
- yes (7)
Is part of the Bibliography
- no (7)
Keywords
- - (2)
- clinical trials (2)
- neurology (2)
- Altern (1)
- COVID-19 (1)
- Hirnstimulation (1)
- Kernspintomografie (1)
- Kognition (1)
- aging (1)
- brain plasticity (1)
Institute
Publisher
The combination of repeated behavioral training with transcranial direct current stimulation (tDCS) holds promise to exert beneficial effects on brain function beyond the trained task. However, little is known about the underlying mechanisms. We performed a monocenter, single-blind randomized, placebo-controlled trial comparing cognitive training to concurrent anodal tDCS (target intervention) with cognitive training to concurrent sham tDCS (control intervention), registered at ClinicalTrial.gov (Identifier NCT03838211). The primary outcome (performance in trained task) and secondary behavioral outcomes (performance on transfer tasks) were reported elsewhere. Here, underlying mechanisms were addressed by pre-specified analyses of multimodal magnetic resonance imaging before and after a three-week executive function training with prefrontal anodal tDCS in 48 older adults. Results demonstrate that training combined with active tDCS modulated prefrontal white matter microstructure which predicted individual transfer task performance gain. Training-plus-tDCS also resulted in microstructural grey matter alterations at the stimulation site, and increased prefrontal functional connectivity. We provide insight into the mechanisms underlying neuromodulatory interventions, suggesting tDCS-induced changes in fiber organization and myelin formation, glia-related and synaptic processes in the target region, and synchronization within targeted functional networks. These findings advance the mechanistic understanding of neural tDCS effects, thereby contributing to more targeted neural network modulation in future experimental and translation tDCS applications.
Neural mechanisms of behavioral improvement induced by repeated transcranial direct current stimulation (tDCS) combined with cognitive training are yet unclear. Previously, we reported behavioral effects of a 3-day visuospatial memory training with concurrent anodal tDCS over the right temporoparietal cortex in older adults. To investigate intervention-induced neural alterations we here used functional magnetic resonance imaging (fMRI) and diffusion tensor imaging (DTI) datasets available from 35 participants of this previous study, acquired before and after the intervention. To delineate changes in whole-brain functional network architecture, we employed eigenvector centrality mapping. Gray matter alterations were analyzed using DTI-derived mean diffusivity (MD). Network centrality in the bilateral posterior temporooccipital cortex was reduced after anodal compared to sham stimulation. This focal effect is indicative of decreased functional connectivity of the brain region underneath the anodal electrode and its left-hemispheric homolog with other “relevant” (i.e., highly connected) brain regions, thereby providing evidence for reorganizational processes within the brain's network architecture. Examining local MD changes in these clusters, an interaction between stimulation condition and training success indicated a decrease of MD in the right (stimulated) temporooccipital cluster in individuals who showed superior behavioral training benefits. Using a data-driven whole-brain network approach, we provide evidence for targeted neuromodulatory effects of a combined tDCS-and-training intervention. We show for the first time that gray matter alterations of microstructure (assessed by DTI-derived MD) may be involved in tDCS-enhanced cognitive training. Increased knowledge on how combined interventions modulate neural networks in older adults, will help the development of specific therapeutic interventions against age-associated cognitive decline.
Introduction
Given rapid global population aging, developing interventions against age-associated cognitive decline is an important medical and societal goal. We evaluated a cognitive training protocol combined with transcranial direct current stimulation (tDCS) on trained and non-trained functions in non-demented older adults.
Methods
Fifty-six older adults (65–80 years) were randomly assigned to one of two interventional groups, using age and baseline performance as strata. Both groups performed a nine-session cognitive training over 3 weeks with either concurrent anodal tDCS (atDCS, 1 mA, 20 minutes) over the left dorsolateral prefrontal cortex (target intervention) or sham stimulation (control intervention). Primary outcome was performance on the trained letter updating task immediately after training. Secondary outcomes included performance on other executive and memory (near and far transfer) tasks. All tasks were administered at baseline, post-intervention, and at 1- and 7-month follow-up assessments. Prespecified analyses to investigate treatment effects were conducted using mixed-model analyses.
Results
No between-group differences emerged in the trained letter updating and Markov decision-making tasks at post-intervention and at follow-up timepoints. Secondary analyses revealed group differences in one near-transfer task: Superior n-back task performance was observed in the tDCS group at post-intervention and at follow-up. No such effects were observed for the other transfer tasks. Improvements in working memory were associated with individually induced electric field strengths.
Discussion
Cognitive training with atDCS did not lead to superior improvement in trained task performance compared to cognitive training with sham stimulation. Thus, our results do not support the immediate benefit of tDCS-assisted multi-session cognitive training on the trained function. As the intervention enhanced performance in a near-transfer working memory task, we provide exploratory evidence for effects on non-trained working memory functions in non-demented older adults that persist over a period of 1 month.
IntroductionWith the worldwide increase of life expectancy leading to a higher proportion of older adults experiencing age-associated deterioration of cognitive abilities, the development of effective and widely accessible prevention and therapeutic measures has become a priority and challenge for modern medicine. Combined interventions of cognitive training and transcranial direct current stimulation (tDCS) have shown promising results for counteracting age-associated cognitive decline. However, access to clinical centres for repeated sessions is challenging, particularly in rural areas and for older adults with reduced mobility, and lack of clinical personnel and hospital space prevents extended interventions in larger cohorts. A home-based and remotely supervised application of tDCS would make the treatment more accessible for participants and relieve clinical resources. So far, studies assessing feasibility of combined interventions with a focus on cognition in a home-based setting are rare. With this study, we aim to provide evidence for the feasibility and the effects of a multisession home-based cognitive training in combination with tDCS on cognitive functions of healthy older adults.Methods and analysisThe TrainStim-Home trial is a monocentric, randomised, double-blind, placebo-controlled study. Thirty healthy participants, aged 60–80 years, will receive 2 weeks of combined cognitive training and anodal tDCS over left dorsolateral prefrontal cortex (target intervention), compared with cognitive training plus sham stimulation. The cognitive training will comprise a letter updating task, and the participants will be stimulated for 20 min with 1.5 mA. The intervention sessions will take place at the participants’ home, and primary outcome will be the feasibility, operationalised by two-thirds successfully completed sessions per participant. Additionally, performance in the training task and an untrained task will be analysed.Ethics and disseminationEthical approval was granted by the ethics committee of the University Medicine Greifswald. Results will be available through publications in peer-reviewed journals and presentations at national and international conferences.Trial registration numberNCT04817124.
IntroductionA substantial number of patients diagnosed with COVID-19 experience long-term persistent symptoms. First evidence suggests that long-term symptoms develop largely independently of disease severity and include, among others, cognitive impairment. For these symptoms, there are currently no validated therapeutic approaches available. Cognitive training interventions are a promising approach to counteract cognitive impairment. Combining training with concurrent transcranial direct current stimulation (tDCS) may further increase and sustain behavioural training effects. Here, we aim to examine the effects of cognitive training alone or in combination with tDCS on cognitive performance, quality of life and mental health in patients with post-COVID-19 subjective or objective cognitive impairments.Methods and analysisThis study protocol describes a prospective randomised open endpoint-blinded trial. Patients with post-COVID-19 cognitive impairment will either participate in a 3-week cognitive training or in a defined muscle relaxation training (open-label interventions). Irrespective of their primary intervention, half of the cognitive training group will additionally receive anodal tDCS, all other patients will receive sham tDCS (double-blinded, secondary intervention). The primary outcome will be improvement of working memory performance, operationalised by an n-back task, at the postintervention assessment. Secondary outcomes will include performance on trained and untrained tasks and measures of health-related quality of life at postassessment and follow-up assessments (1 month after the end of the trainings).Ethics and disseminationEthical approval was granted by the Ethics Committee of the University Medicine Greifswald (number: BB 066/21). Results will be available through publications in peer-reviewed journals and presentations at national and international conferences.Trial registration numberNCT04944147.
Noninvasive Modulation of Cognition in Older Adults – Neural Correlates and Behavioral Outcomes
(2022)
Background: The worldwide population will grow older in the upcoming years. Aging, even in the absence of pathological processes, is associated with decline in cognitive functioning. Age-related cognitive decline is not a uniform process affecting every function in the same way. Research should thus examine specific functions, such as episodic memory or executive functions differentially, especially in older samples. Neural correlates of these functions are well characterized in young adults. However, research on functional and structural neural substrates underlying specific cognitive functions in older adults is scarce, but needed for example to identify targets for noninvasive interventions against cognitive decline. Current advances in this field point towards the effectiveness of combined noninvasive interventions of cognitive training and transcranial direct current stimulation (tDCS). So far, evidence regarding such combined interventions in older adults is inconclusive and neural mechanisms of successful interventions are still unclear. This line of research could advance the development of noninvasive methods to modulate cognitive functions and therefore address the unmet need for treatment options against age-related cognitive decline.
Aims: The main aims of the present thesis were (i) to characterize functional and structural neural network correlates of two cognitive functions with high relevance for daily living, namely working memory updating and value-based decision making, (ii) to map out interventions of combined cognitive training and tDCS to modulate these cognitive functions in healthy older adults and adults with prodromal AD and (iii) to assess behavioral and neural outcomes of combined cognitive training (of either executive functions or visuo-spatial memory) and tDCS interventions.
Methods: In order to address these aims, the present thesis includes five papers. Paper I assessed functional and structural neural correlates of working memory updating and value-based decision-making performance in healthy older adults using functional magnetic resonance imaging and diffusion tensor imaging. Papers II and III comprise study protocols of a three-week cognitive training of working memory updating and value-based decision-making abilities with concurrent tDCS over the left dorsolateral prefrontal cortex in healthy older adults and adults with prodromal AD. Paper IV used mixed-model analysis to compute behavioral outcomes of this combined intervention in healthy older adults, including outcome measures of the trained tasks, measures of transfer to untrained tasks and assessment of long-term effects at four weeks and half a year after the intervention. In paper V neural alterations after cognitive training of visuo-spatial memory and active stimulation compared to the training and sham (placebo) stimulation were assessed in older adults using measures of functional network centrality and diffusion tensor imaging-derived measures of grey matter microstructure.
Results: Analyses revealed distinct functional and structural connectivity correlates of performance on the two cognitive tasks assessing working memory updating and value-based decision-making (paper I). Moreover, results showed a combined contribution of a specific white matter pathway (cingulum bundle) and frontoparietal functional connectivity to working memory updating performance, thereby providing information on possible network targets for modulation of working memory updating and value-based decision-making. The combined modulatory intervention of cognitive training and tDCS (papers II and IV) did not demonstrate group differences between concurrent active tDCS over sham tDCS in the trained tasks. However, analysis of a working memory transfer task revealed a beneficial effect of training and active tDCS over training and sham tDCS at post intervention and follow-up. Findings from paper V showed reduced functional network centrality after visuo-spatial memory training and active tDCS compared to training and sham tDCS in the stimulated brain area and its contralateral homologue. Additionally, after the training, measures of grey matter microstructural plasticity in the stimulated brain area were associated with beneficial training outcomes for the active but not the sham stimulation group.
Conclusion: Taken together, cognitive performance, functional and structural networks as well as the possibility of their modulation through combined cognitive training and tDCS interventions were investigated in older adults with and without cognitive impairment. The present thesis therefore contributes to the field of noninvasive neuromodulation in older adults by characterizing distinct neural correlates of two age-sensitive executive functions, which may be altered through modulatory interventions. Moreover, the present work shows that cognitive training with concurrent tDCS holds the potential to elicit transfer effects to untrained tasks and further may evoke neural plasticity on the functional and microstructural level. This work thus promotes the development of modulatory interventions against age-associated cognitive decline and holds promising implications for translation to clinical application.
Age-related deterioration in white and gray matter is linked to cognitive deficits. Reduced microstructure of the fornix, the major efferent pathway of the hippocampus, and volume of the dentate gyrus (DG), may cause age-associated memory decline. However, the linkage between these anatomical determinants and memory retrieval in healthy aging are poorly understood. In 30 older adults, we acquired diffusion tensor and T1-weighted images for individual deterministic tractography and volume estimation. A memory task, administered outside of the scanner to assess retrieval of learned associations, required discrimination of previously acquired picture-word pairs. The results showed that fornix fractional anisotropy (FA) and left DG volumes were related to successful retrieval. These brain-behavior associations were observed for correct rejections, but not hits, indicating specificity of memory network functioning for detecting false associations. Mediation analyses showed that left DG volume mediated the effect of fornix FA on memory (48%), but not vice versa. These findings suggest that reduced microstructure induces volume loss and thus negatively affects retrieval of learned associations, complementing evidence of a pivotal role of the fornix in healthy aging. Our study offers a neurobehavioral model to explain variability in memory retrieval in older adults, an important prerequisite for the development of interventions to counteract cognitive decline.