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Real-Time FNIRS Investigation of Discrete and Continuous Cognitive Demands During Dual-Task Walking

Younger adults who are walking and doing additional tasks at the same time may not
realize if their performance suffers, putting some at greater risk for injury and impairment during
certain tasks. This thesis has addressed this confound by developing a divided attention paradigm
focusing on discrete and continuous demand manipulations. The work assessed in motorcognitive processing changes with cerebral and behavioral monitoring of over-ground walking
with or without cognitive tasks. Participants (n = 19, 18-35 years, 13 females) were asked to
walk at their usual pace [usual walking condition (SM)], walk at their usual pace while
performing a cognitive task [dual-task condition (DT)] as well as conduct a cognitive task while
standing [single cognitive condition (SC)]. All participants conducted two discrete [simple
response time (SRT) & go-no-go (GNG)] and two continuous cognitive tasks [N-back (NBK) &
double number sequence (DNS)] of increasing demand.
The study revealed significant brain and behavior interactions during the most demanding
continuous cognitive task, the DNS. The findings demonstrated lower accuracy rates, slower
walk speeds as well as greater cerebral oxygenation in DNS DT in comparison to single task
conditions. With increasing cognitive demands and tasks, there were longer response times, as
well as lower accuracy rates. The behavioral findings were qualified by marginally significant
interactions in a 2 x 4 RM ANOVA between SC-DT task and demand for accuracy rate [F (3,
54) = 2.66, p = 0.06, η2 =.13], significant interactions in response time [F (2, 36) = 4.1, p =
0.026, η2 =.18] as well as significant SM-DT task and demand findings for walk speed [F (3, 54)
=5.3, p = 0.003, η2 =.23]. The 2 x 2 x 4 RM ANOVA revealed significant HbO2 interactions
between walking tasks (single and dual), hemisphere and demand [F (3, 54) = 5.730, p = 0.002,
η2 =.24] in the DNS only.
The data suggests that greater demand manipulations with continuous cognitive tasks
may be sensitive to both prefrontal cortex (PFC) and behavioral assessments in younger adults
(YA). Further validation of the discrete-continuous demand paradigm in motor studies may
provide a basis for cognitive assessment with applications in motor learning, cognitive training,
aging and more.

Identiferoai:union.ndltd.org:uottawa.ca/oai:ruor.uottawa.ca:10393/39620
Date13 September 2019
CreatorsRahman, Tabassum Tahmina
ContributorsFraser, Sarah
PublisherUniversité d'Ottawa / University of Ottawa
Source SetsUniversité d’Ottawa
LanguageEnglish
Detected LanguageEnglish
TypeThesis
Formatapplication/pdf

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