Lifestyle Behaviors and Cognitive Well-Being: A Cross-Sectional Study Exploring the Role of Lifestyle Factors Among Omani University Students

This study was approved by the Medical Research Ethics Committee (MREC) of the College of Medicine and Health Sciences at Sultan Qaboos University (Ref. No. 3447, 25 November 2024). Informed consent was obtained from all study participants.

This study aims to explore the trajectories of three lifestyle behaviors: physical activity, sleep chronotype, and eating attitudes, in relation to cognitive well-being. A cross-sectional study was conducted among undergraduate students at Sultan Qaboos University (SQU), located on the outskirts of Muscat, the capital city of Oman. As of 2024, SQU enrolled approximately 15,852 students from diverse geographical and socioeconomic backgrounds across the country [20,21]. The university offers a broad range of undergraduate programs in the sciences, humanities, and arts, as well as postgraduate programs, including master's and doctoral degrees. Oman provides free universal education through the secondary level, and students seeking tertiary education typically compete for government scholarships to study at SQU.

All full-time undergraduate students enrolled at SQU were invited to participate. The questionnaire was distributed electronically using Google Forms. Previous studies have suggested that this approach is likely to capture a broad representations of the student body at the present setting [21]. The first page of the questionnaire included an informed consent statement outlining the study objectives, emphasizing voluntary participation, and ensuring confidentiality and anonymity. This approach reduces the likelihood of sampling bias. No personally identifiable information was collected. The survey included a statement advising participants to inform the principal investigator or to seek assistance from campus health or counseling services if participation triggered any adverse experience. Data were collected between 21 August 2024 and 1 November 2025.

Inclusion criteria included Omani, Arabic-speaking male and female full-time undergraduate students at SQU aged. Exclusion criteria included non-Arabic speaking students and those younger than 18 or older than 25 years.

Using a 95% confidence level and a 5% error margin, this sampling approach was deemed sufficient to represent the student population in this setting. Power analysis for this study was conducted using the Epi Info version 6.0 software. The sample size was estimated with a Type I error of 5% (alpha = 0.05) and a 95% confidence level to achieve 80% statistical power. Based on these parameters, a minimum of 375 undergraduate students was required to detect a 50% difference in the odds ratio (OR) between groups of interest. A total of 408 students aged 18–25 years participated in this study (females: n = 303; males: n = 105).

Sociodemographic data and risk factors were collected using a self-administered questionnaire that captured age, sex, marital status, academic year, college and major, duration of university enrollment, academic performance, place of residence, type of accommodation, and level of parental education level. (See Table 1 for details).

Health and life background information was collected through self-report, including chronic health conditions, current medication use, family history of mental illness, smoking habits, and alcohol consumption. Participants were also asked whether they had experienced adverse childhood experiences. The adverse childhood experiences assessed in this study were those defined by the Centers for Disease Control and Prevention (CDC) [22].

Disordered eating attitudes and behaviors were assessed using the 26-item Eating Attitudes Test (EAT-26), developed by Garner and Garfinkel (1979) [23]. The EAT-26 has demonstrated robust psychometric properties in Arabic-speaking populations, including Oman [24]. A cutoff score of 20 was used to identify individuals at risk for disordered eating [23].

Physical activity was assessed using the Short Form of the International Physical Activity Questionnaire (IPAQ-SF) [25], a validated self-report instrument. The IPAQ-SF measures physical activity across four domains (vigorous activity, moderate activity, walking, and sitting time) during the preceding seven days. This study used the validated Arabic version of the IPAQ-SF [25,26]. Participants were classified as 'active' or 'inactive' according to the established scoring guidelines [25].

Chronotype was assessed using the 5-item Morningness–Eveningness Questionnaire (MEQ-5) (5 items) [27], a validated instrument for determining an individual's circadian preference. Total scores range from 4 to 26, with higher scores indicating a morning chronotype. Classification followed the criteria of Adan and Almirall (1991) [28]: evening type (<12), neither type (12–17), and morning type (>17). This study used the validated Arabic version of the MEQ-5 reported by Hazmi and Noorwali (2023) [29].

Subjective cognitive well-being was assessed using an adaptation of the Questionnaire of Memory Efficiency (QME) [30]. QME was utilized in cognitive domains such as concentration, orientation, episodic memory, and prospective memory. Since no Arabic version is available, this study also translated QME into Arabic. Two board-certified neuropsychologists fluent in Arabic participated in translation to ensure conceptual and linguistic validity. The final version demonstrated adequate internal consistency (Cronbach's alpha = 0.85).

The psychometric properties of the outcome measures were as follows: Cronbach's alpha for sleep–wake chronotype = 0.71, disordered eating behavior = 0.83.

Participants with missing data were excluded from the analyses. Categorical variables were reported as frequencies (percentages) for EAT-26, IPAQ and chronotype, and continuous variables were reported as means with standard deviations. The Kolmogorov–Smirnov test was used to assess the normality of continuous data. Associations between categorical covariates and disordered eating, physical activity, and chronotype were tested using the chi-square test. Individual linear regression analyses were conducted to examine the association among disordered eating (continues format), sleep–wake chronotype (continues format), and physical activity (categories), as well association between physical activity and subjective cognitive function. Structural equation modeling (SEM) was conducted to test a conceptual model hypothesizing associations between disordered eating, physical activity, and sleep–wake chronotype and subjective cognitive function. Direct, indirect, and total effects were calculated using the bootstrap method (5000 samples; 95% confidence interval). All analyses were performed with SPSS version 29 (IBM Corp., Armonk, NY, USA). SEM analysis was performed using SmartPLS (free trial version). A p-value < 0.05 was considered statistically significant for all analyses.

A total of 408 students participated in this study. As shown in Table 1, the mean age of participants was 20.21 ± 1.566 years. The majority of participants were females (n = 303, 74.3%), while males accounted for n = 105 (25.7%). Most participants were single (n = 397, 97.3%), and only 11 (n = 11, 2.7%) were married.

Regarding parental education, n = 285 (71.1%) fathers had university or institute-level education, while n = 99 (24.7%) had school-level education, and 4.2% were illiterate. Among mothers, n = 201 (49.3%) had a university degree, n = 161 (39.5%) had school-level education, and n = 44 (10.8%) were illiterate. In terms of housing arrangements, n = 221 (54.2%) participants resided on campus. Among students living off campus, most lived with their families (n = 116, 63.7%), followed by those in shared accommodation (n = 55, 30.2%). Academically, n = 202 (49.5%) students were rated 'very good', and n = 113 (27.7%) were rated 'good'. Participants were distributed across various colleges, with the highest representation in the College of Medicine and Health Sciences (n = 131, 32.1%), followed by the College of Sciences (n = 62, 15.2%), and the College of Education (n = 43, 10.5%).

Most respondents did not report chronic disease, whereas n = 31 (7.6%) did. A small proportion of the participants (n = 39, 9.6%) had sought unified help for issues such as psychological problems. Similarly, n = 32 students (7.8%) reported having a history of adverse childhood experiences. Behavioral risk factors were minimal: only three students (0.7%) reported smoking, and none reported alcohol consumption, indicating a complete abstinence rate (100%) from alcohol in this group.

As shown in Table 2, n = 292 (71.6%) participants had eating attitude (EAT-26) score below 20, indicating no disordered eating attitudes, whereas n = 116 (28.4%) scored above 20, suggesting possible concerns about eating behavior. Regarding physical activity levels, n = 212 (52.3%) participants were classified as active, and n = 193 (47.7%) were classified as inactive. In terms of chronotype, n = 92 (22.5%) participants were identified as morning type, n = 139 (34.1%) as evening type, and n = 177 (43.4%) as neither type.

In this section, we conducted an exploratory analysis to investigate the associations between participant characteristics and the three study domains (Table 3). The result showed significant association between disordered eating behavior and seeking unified help for psychological or socioeconomic problems (p = 0.002), as well as a history of adverse childhood experiences (p = 0.023). Participants with chronic diseases requiring medical follow-up showed a significant association with disordered eating behavior (p = 0.039). However, no significant associations were obsereved for age, sex, marital status, accommodation, or smoking status (Table 3).

Additionally, there was a significant association between physical activity levels and participants' sex (p = 0.009) and accommodation status (p = 0.017), with more females classified as physically inactive, 51.5% (155/301), compared with males, 36.5% (38/104). Students residing on campus were also more likely to be inactive (53.2%) than those living off campus (41.1%). For the sleep–wake chronotype, a significant association with academic level (p = 0.044) (Table 3).

The results of the regression analyses are shown in Table 4. In the first equation model, eating attitudes and chronotype were treated as independent variables, and physical activity was the dependent variable. In the second equation model, physical activity was the independent variable, and cognitive well-being was the dependent variable.

The first equation model showed that chronotype was positively associated with physical activity (β = 0.06, p = 0.004). However, disordered eating behavior was not significantly associated with physical activity (β = 0.1, p = 0.16). The second equation model showed that physical activity was positively associated with cognitive function (β = 0.11, p = 0.039). However, the effect sizes in both equations indicated small effect (β < 0.2) between the variables and the dependent variables.

SEM was implemented to examine potential chain-mediating effects among disordered eating behavior, chronotypes, physical activity, and subjective cognitive well-being among college students. We evaluated a range of possible models to identify the best and most appropriate model for assessing how physical activity, sleep–wake chronotypes, and disordered eating behaviors are associated with subjective cognitive well-being (Supplementary Figure S1). As shown in Supplementary Figure S1 and Table S1, chronotypes (β = 0.179, p = 0.001) and disordered eating behavior (β = 0.10, p = 0.047) were positively associated with physical activity, and physical activity was significantly associated with subjective cognitive well-being (β = 0.151, p = 0.005). However, the standardized βs were below 0.2, indicating small effect sizes. In addition, the total effect indicated that disordered eating behavior was not associated with subjective cognitive well-being (β = 0.015, p = 0.115). Chronotypes were significantly associated with subjective cognitive well-being (β = 0.027, p = 0.046) (Supplementary Table S1). The goodness-of-fit indices for the SEM model were as follows: standardized root mean squared residual (SRMR) = 0.29, normed fit index (NFI) = 0.65. This suboptimal fit could be due to the non-normal data distribution, or it may reflect potential involvement of additional unmeasured factors that warrant further investigation.

Cognitive well-being is crucial for university students, as it supports their ability to learn and retain information. It also enhances essential academic skills, including attention, memory, and problem-solving. Moreover, adequate cognitive well-being is associated with better time management, adaptability, and decision-making skills, which are vital for independent living and future careers. Overall, cognitive well-being helps enable students to thrive academically, socially, and personally. Against this background, the central aim of this study was to identify lifestyle variables that are associated with cognitive well-being.

A forced-entry regression analysis revealed that chronotype was positively associated with physical activity (β = 0.06, p = 0.004), whereas disordered eating behavior was not significantly associated with physical activity. Moreover, physical activity was positively associated with cognitive function (β = 0.11, p < 0.001).

Although the regression analyses showed small effect sizes (β < 0.2) and the hypothesized SEM model had a suboptimal fit, the observed relationships were statistically significant. This suggests small yet statistically reliable associations between the variables and cognitive well-being. Moreover, the small effect sizes may indicate that additional, unmeasured factors also contribute to these associations. Previous research indicates that behaviors and mental health are multifactorial, shaped by multiple biological, psychological, and environmental influences, and that combined effects should be considered rather than examining each factor in isolation [7,42]. These findings suggest a network of interactions through which lifestyle factors interrelate; some may influence cognitive well-being indirectly by affecting other components of the lifestyle behaviors (physical activity, chronotype, and eating habits), warranting further investigation.

Physical activity levels (directly) and chronotypes (indirectly) may contribute, with small effects, to associations with cognitive well-being; however, when considered alongside additional factors and over longer periods, their collective influence may be greater. The observed association between physical activity and cognitive well-being aligns with a growing body of literature highlighting the role of exercise in reducing chronic stress [43]. In student populations, physical activity has been shown to reduce emotional distress and enhance academic coping. Furthermore, emerging evidence suggests that chronotype, although relatively underexplored, may be significantly associated with cognitive outcomes [44].

This study investigated a novel insight into how the three modifiable risk factors (physical activity, eating habits, and chronotypes) may simultaneously be associated with cognitive well-being. Findings from this study may provide a foundation for future research aimed at refining the proposed hypothetical model by incorporating additional factors. However, given the exploratory nature of this study, further research is needed to confirm and extend these findings and future longitudinal studies investigating the associations of physical activity, chronotypes, and eating habits with cognitive well-being across the undergraduate years may reveal a cumulative or interactive effects over an extended time or when combined with other factors. Similar investigations could also be conducted in non-academic settings or among different age groups.

Furthermore, findings from this study support the development of integrated interventions that promote physical activity and align academic routines with individual chronotypes such as the creation of low-cost pilot activities within school and university environments that encourage healthier lifestyle behaviors. Such approaches are sustainable and may yield both immediate and long-term benefits by reducing healthcare burden and associated costs.

As with any cross-sectional survey, this study has several limitations that may affect the generalizability of its findings. First, the sample was drawn from a single public university, which may limit the applicability of the findings to students in private institutions or those studying abroad. Second, the sample was disproportionately female (74.3%), reflecting national trends, but introducing the possibility of sex-related bias. Third, the distribution of participants was skewed toward specific colleges, reducing the representativeness of the broader student population. Fourth, for QME questionnaire, no validated Arabic version is currently available. Fifth, this study was exploratory and lacked a pre-established theoretical baseline model; therefore, we evaluated a range of SEM models to identify the most appropriate model. Although significant associations were observed, the final model demonstrated suboptimal fit. The small effect size (β < 0.2) and suboptimal model fit may be partly attributed to the (non-normal distribution of the data, which can influence goodness-of-fit indices. These findings may also suggest a possibility of residual confounding factors or additional unmeasured factors that could cumulatively influence cognitive well-being over time, warranting examination in future studies. Furthermore, data collection relied on self-reported questionnaires, which are susceptible to recall bias, social desirability bias, and potential misinterpretation of items. It would have been ideal to determine how the participants defined chronic disease, an issue that warrants future investigation in future studies. Additionally, the use of subjective measures to assess perceived cognitive well-being may not fully capture its complexity when compared to objective neuropsychological assessments. Although the broader literature suggests that physical inactivity, poor sleep patterns, and disordered eating are precursors to students' burnout, this study did not explore the variation in burnout or the presence of chronic stress in the present cohort. Future studies should address this issue. Finally, the cross-sectional design of the study precludes causal inference among the variables examined.