Browsing by Author "Laukkanen, Heidi"

The aim of the study. Working memory (WM) is a cognitive function that relies on the neurotransmitter dopamine. WM has multiple subfunctions: maintaining relevant information, ignoring distractors, and updating the information when needed. Information maintenance and ignoring irrelevant stimuli are associated with brain activity in the prefrontal cortex and updating information with the striatum. A connection between polymorphisms within the dopaminergic genes COMT (COMT Val158Met polymorphism) and DRD2/ANKK1 (Taq1A polymorphism), and WM performance has been established in previous studies, and these genes seem to impact dopamine signaling in the prefrontal cortex and striatum, respectively. The present study investigates associations between dopaminergic gene polymorphisms and WM performance. The main research questions include the main effects and interactions that the genes have to WM on performance overall and WM stability and flexibility in particular. The study investigates also whether obesity, diet, and age affect WM performance, as there are indications for these from previous studies. Methods. Data from three separate cross-sectional studies with a total of 244 participants was used. A computer-based visual working memory task was used to assess the WM performance measures accuracy and reaction time. Other measurements included blood measures, Body Mass Index (BMI), and the Dietary Fat and free Sugar Questionnaire (DFS). Results and conclusion. In WM accuracy analyses, there was a significant main effect for the task condition as well as interactions between the COMT*task condition and COMT*Taq1A*task condition. In the three-way interaction analysis for WM accuracy, the most beneficial combination was Met/Met & A1- in the task condition measuring the stability, and Val/Met & A1+ in the task condition measuring the flexibility. This result gives support for established knowledge about how Met/Met combined with A1- is beneficial especially for WM stability and maintenance. Also, the inverted-U shape theory and previous studies' results of A1+ being beneficial in executive functions updating tasks, give support to the result regarding WM flexibility. In the three-way interaction reaction time analysis, the combination of Val/Met & A1+ was the fastest in every task condition. However, the significant differences were mainly between A1- and A1+ genotypes when combined with Val/Met and between Met/Met and Val/Met genotypes when combined with A1-. The two-way interaction between COMT Val158Met and task condition did not remain significant in pairwise comparisons. In reaction time analyses, COMT Val158Met and Taq1A had a significant main effect where reaction times followed the order: Met/Met < Val/Val < Val/Met, with Val/Met being significantly slower than the others and in Taq1A A1+ < A1-, with a significant difference. Adding age, BMI, and DFS to the analyses did not affect the significant/non- significant main effects or interactions in the analyses. The results of this thesis converge with the previous knowledge about these genotypes having an interacting effect on working memory stability and flexibility. However, these effects are complex to interpret as the results and their directions differed between the task conditions and outcome measurements. In the main outcome variable (accuracy), the result regarding the WM stability is well in line with previous literature about the Met/Met & A1- combination being beneficial to WM performance, and the result about Val/Met & A1+ being beneficial for WM flexibility gets preliminary support from executive function studies, but also opens new research avenues regarding the WM flexibility subfunction.