Figure 1 represents the inclusion and exclusion criteria of the study population.

A total of 1200 respondents participated in the study, with a response rate of 85%. All incomplete questionnaires in which more than 5 responses were missing were excluded. In the final analysis, the data of a total of 1019 respondents were included. A multistage sampling technique was utilized for the collection of the data. Samples were selected from different governmental and private institutions through a cluster sampling technique. Afterwards, cluster lists were made, and seven clusters were randomly selected by the investigators for inclusion in the study. Another round of cluster sampling was performed on the selected cluster, and two clusters of that were then included. The total population of the selected clusters was then divided into different sampling units using the list of participants obtained from each department of the selected institutes. Study respondents were then selected using simple random sampling from each of the selected groups through a computer-generated list. Finally, the eligible subjects among them were recruited in the study. The aforementioned sample population has also been used in previously published studies [23‐25].

Data were collected from the participants using a structured questionnaire. The questionnaire used in this study has been published previously [23, 26]. Information about sociodemographic factors such as age, sex, marital status, and education levels was obtained via the same questionnaire. Anthropometric measurements like body weight (kilograms), height (meters), Body Mass Index (BMI) and waist circumference (centimeters) were taken at the time of the interview by trained nurses. All the procedures were performed based on the standards for anthropometric measurements. In addition to this, a blood sample was drawn for a fasting (10–12 h fast) lipid profile from each respondent.

Hypercholesterolemia (HC) is defined as a blood cholesterol level of > 200 mg/dL or > 5 mmol/L [27]. Non-obese or normal weight is defined as a BMI of < 25 kg/m², and overweight denotes a BMI of ≥ 25 kg/m², while a BMI of ≥ 30 kg/m² falls within the obese category [28].

Data were analyzed using SPSS version 25.0 (SPSS Inc., Chicago, Illinois, USA) for Windows. A simple chi-square test was used to examine the association between HC and different categorical variables. Univariate analysis was conducted using the bivariate correlation coefficient (Pearson’s r), while a multinomial regression model was used to test the relationship (adjusted odds ratio) between HC and all other possible risk factors. The confidence interval was 95%, and a P value of less than 0.05 was set to establish a statistical significance.

Bivariate correlation coefficient (Pearson’s r) was conducted between age of respondents.

(continuous variable) and binary HC status (1 = no HC; 2 = yes.

hypercholesterolemia).

The bivariate correlation coefficient (Pearson’s r) was conducted between the ages of the respondents (continuous variable) and binary HC status (1 = no HC; 2 = yes HC). The results showed that there was a significant moderate positive association between increasing age and the prevalence of HC (r = 0.240, P < 0.0001). Another Pearson’s r correlation coefficient test revealed that a high body mass index (BMI), as a continuous variable, was positively and significantly associated with the presence of HC (r = 0.181, P < 0.0001).

The prevalence of HC as a binary variable (1 = no HC; 2 = yes HC) was contrasted with sociodemographic and other risk factors. Seven (n = 7) cross-tabulation (X²) tests were conducted to assess the relationship between HC status and each of: sex, marital status, educational attainment, job type, diabetes status, smoking status, and body mass index (BMI) class/category.

The results are summarized in Table 1. A higher proportion of males (56.7%) had a significantly higher prevalence of HC compared with their female counterparts (43.3%). The Chi-Squared test was (X²) = 23.093, P ≤ 0.0001. Married individuals were significantly more likely to have HC (67.7%) in comparison to individuals who had never married (32.2%). The Chi-Squared test was (X²) = 68.086, P ≤ 0.0001. When HC status was examined according to educational attainment, it was found that secondary school students (23.6%) and university students (63.8%) had the highest prevalence of HC. The Chi-Squared test was (X²) = 27.177, P ≤ 0.000. In regard to job/employment type, a significant proportion of civilian workers had HC (84.3%) compared with those who were unemployed or were soldiers. The Chi-Squared test was (X²) = 56.683, P ≤ 0.0001.

The relationship between HC and diabetes status showed that individuals with diabetes had a higher prevalence of HC (91.3%) than non-diabetic individuals with HC (8.7%). The Chi-Squared test was (X²) = 6.195, P = 0.013 (Table 1). There was a significant increase in the proportion of current smokers who had high cholesterol levels (15.7%), as opposed to only 5.5% of ex-smokers who had high cholesterol levels. The Chi-Squared test was (X²) = 9.044, P ≤ 0.011. Across the BMI categories, the results revealed that the overweight category showed a significantly higher proportion (33.1%) which had high cholesterol levels, followed by the class I obese category (27.6%), and then the class II/III obese group (18.9%). The Chi-Squared test was (X²) = 41.090, P ≤ 0.0001.

A first multiple logistic regression analysis was conducted by using the dichotomous HC status (outcome variable) with BMI (continuous independent variable) and other sociodemographic and lifestyle risk factors (Table 2). The results showed that BMI was positively and significantly associated with high cholesterol status. The odds ratio (OR) was 1.64 (95% CI = 1.610–1.671; P = 0.008). Marital status showed a significant inverse association with HC, in that married individuals had a significantly lower risk of having high cholesterol levels. The OR was 0.396 (95% CI = 0.236–0.664; P ≤ 0.0001). Moreover, job type/status—whether ‘not working’ (unemployed) or ‘civilian’—was positively and significantly associated with HC. The OR for the ‘not working’ status was 3.988 (95% CI = 2.051–5.139; P = 0.042), while the OR for a ‘civilian’ job status was 3.385 (95% CI = 1.722–6.652; P ≤ 0.0001).

A second multiple logistic regression analysis was further carried out to examine the association between BMI class (categorical variable) and the relative risk of HC, after adjusting for sociodemographic and lifestyle risk factors (Table 3). The results showed that overweight respondents had a significantly higher risk of HC. The odds ratio (OR) was 1.727 (95% CI = 1.58–1.914; P = 0.046). Non-obese (< 25 kg/m²) participants had an inverse significant association with the risk of HC. The OR was 0.411 (95% CI = 0.216–0.783; P = 0.007). Marital status and job type/status were also significantly inversely and positively associated with HC respectively (Table 3).