Computerized Memory Enhancing Treatment in MCI (COMET)

There is currently no efficacious treatment to delay or prevent decline from mild cognitive impairment (MCI) to dementia. Despite major technological advances, from refined animal models, novel molecular approaches, and in vivo biological marker development, discoveries have not translated into effective treatments to prevent decline. A potential alternative approach is cognitive training, however previous studies on memory-focused training have had mixed success in MCI groups, and longer-term improvement has not been observed. A more effective strategy may be to target the deterioration of networks that support memory function, for instance the frontoparietal cortical regions of the cognitive control network (CCN) which are important for higher-order cognitive functions such as planning and switching effectively. These networks become increasingly vital during aging and cognitive decline, as frontal lobe activation acts as a compensatory mechanism for lower-level structural deficits. The present study proposes a novel cognitive enhancement strategy, informed by clinical, behavioral, and neurobiological data suggesting that strengthening these frontal area connections in the CCN may compensate for the deficits in circuitry associated with MCI.

Neuroplasticity-based computerized cognitive remediation (nCCR) is a cognitive enhancement strategy that aims to alter disease-related changes in brain function through the induction of neuroplasticity in clinically relevant networks, subsequently resulting in improved cognitive performance. Neuroplasticity refers to the brain's ability to modify, change, and adapt both structure and function and can be induced through the use of network-specific techniques expressed even in the abnormally aging brain. nCCR involves an intensive, attention-demanding schedule of computerized cognitive training that is both individually adaptive and rewarding to participants. nCCR uses bottom-up and top-down training strategies that have been proven in both preclinical and clinical models to induce neuroplasticity and cognitive enhancement. "Bottom-up" perceptual training in both animal models and older adults has been observed to improve both targeted (perceptual discrimination) and other cognitive functions (working memory). "Top-down" activation of the CCN via nCCR has been shown to improve targeted functions (cognitive flexibility), and also to transfer this improvement to other, untrained skills (episodic memory) in older adults. Prior studies in late-life depression show that nCCR can transfer improvements from targeted to untrained processes, which may lead to a functional improvement in multiple cognitive domains. The researchers propose to test whether in MCI patients, boosting CCN activation may produce enhancement to deficits that are characteristic of the syndrome such as memory and attention.

The proposed study utilizes an nCCR intervention strategy which has successfully shown reductions in executive dysfunction in adults with geriatric depression, and recently been applied by our group to participants suffering from chemotherapy-related cognitive impairment (CRCI) with promising preliminary results showing improvements in both subjective ratings of performance and objective cognitive performance. The proposed study aims to use this nCCR intervention to examine the potential benefits in MCI patients and to obtain pilot data for a larger randomized clinical trial. Before and after the treatment period the researchers will examine self-report and objective measures of performance and utilize EEG to assess physiological changes associated with neuroplasticity induced by nCCR treatment.