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Research Article | | Peer-Reviewed

The Prevalence and Predictors of MetS Among Commercial Long Distance Bus Drivers (CLDBDs) in Cape Coast, Ghana

Heckel Amoabeng Abban Jacob Setorglo* Christiana Nsiah-Asamoah Samuel Acquah Matilda Steiner-Asiedu
Published in World Journal of Public Health (Volume 9, Issue 4)
Received: 10 October 2024     Accepted: 22 November 2024     Published: 19 December 2024
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Abstract

Background: Metabolic syndrome (MetS) is a foremost risk consideration for the development of cardiovascular disease which is a major cause of mortality around the globe. Objective: This study determined the prevalence and predictors of MetS amongst Commercial Long Distance Bus Drivers (CLDBDs) in Cape Coast, Ghana. Methods: A cross sectional study design that conveniently enrolled 170 registered male CLDBDs from five bus Unions. We included in the study long distance bus drivers registered at the unions, with a valid drivers’ license C. Obesity was determined using the WHO cut-offs. We determined blood pressure among the drivers through diastolic and systolic readings of arterial blood pressures and categorized based on the WHO cut offs. Fasting blood glucose level was reached through laboratory analysis. The MetS was determined based on ATP III NCEP criteria. Percentages were presented for socio-demographic and lifestyle variables. Chi-square statistics was performed on socio-demographic, occupational and lifestyle factors associated with MetS. Multinomial logistic regression was used to determine the factors that predicted the likelihood of developing metabolic syndrome at 95% confidence interval (95%CI). Results: The average age and duration of commercial long-distance driving were 41± 8 years and 18± 8 hours respectively. About 14.2% were obese. A total of 22.4% had diastolic blood pressure 90 mmHg or higher and 21.2% had systolic blood pressure 140 mmHg or higher. About 2.2% of respondents had high levels of LDL-c and 8.8% had high HDL-c levels. Whilst 2.2% had high levels of triglyceride, 4.4% had high levels of total cholesterol (TC). About 82.6% had fasting blood glucose level > 6.1 mmol/L. The prevalence of MetS was 44% alcohol intake was statistically associated with metabolic syndrome (p< 0.01). Alcohol intake predicted MetS [OR=5.17; 95% CI: 1.75-15.2; P=0.03]. Conclusion: The prevalence of metabolic syndrome was high among this group. Out of the five symptoms used for MetS classification, fasting blood glucose proportion was highest and alcohol intake placed drivers at about five times at risk of development of MetS compared with drivers who do not.

Published in World Journal of Public Health (Volume 9, Issue 4)
DOI 10.11648/j.wjph.20240904.19
Page(s) 396-405
Creative Commons

This is an Open Access article, distributed under the terms of the Creative Commons Attribution 4.0 International License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution and reproduction in any medium or format, provided the original work is properly cited.

Copyright

Copyright © The Author(s), 2024. Published by Science Publishing Group
Previous article
Keywords

Central Region, Metabolic Syndrome, Alcohol, Bus Drivers, Prevalence

1. Introduction
Metabolic Syndrome (MetS), formally known as insulin resistance group of conditions that together increase your risk of cardiovascular disease, Type 2 diabetes and stroke
[1]
. In many African countries MetS is cogitated to be of significant public health importance with pervasiveness varying among genders and ethnicity
[2]
. Although there are challenges in the determination of MetS prevalence as a result of the different classifications, the International Diabetes Federation (IDF) estimates that nearly 537 million people of across the globe suffers from MetS
[3]
. Kaur indicates that the prevalence of MetS varies widely across countries and lies within the range of 10–84% depending on factors such as ethnicity, gender, age, and race of population under consideration
[4]
. Although the underlying cause of MetS is not entirely assumed, insulin resistance and obesity are cogitated to be major players
[5]
. IDF estimates that nearly a quarter of the world’s population suffers from MetS
[6]
. Around 20–30% of the adult population in most countries experience MetS
[7]
. There is also a projection that by 2045 persons between the ages of 20 and 79 living with diabetes will surge from 643 million in 2030 to 783 million
[3]
In the case of the African region, the projected increase is 143%, being the highest on the globe, from 24 million in 2022 to 47 million by 2045
[3]
. In Ghana, there has been a steady increased in the prevalences of chronic diseases among the adult population as reported by various reports of the Ghana Health Data Exchange
[8]
. Individual risk factors of MetS have repeatedly been recounted among Ghanaians and this embraces high blood pressure, obesity and diabetes
[9]
. There are concerns for an escalation of metabolic disorders among Ghanaians
[10]
. We believe that understanding the contribution of economic and lifestyle activities to MetS in the Ghanaian population is key to tailoring case management and preventing or reducing the proportion of individuals that have reduced quality of life as a consequence of the burden of diabetes and hypertension and other related metabolic risk factors. Adu-Asare & Steiner-Asiedu, acknowledged overweight and obesity proportions among short expanse drivers, taxi drivers, in Accra to be 41.6% and 38.8% respectively
[10]
. These data indeed indicate that commercial drivers of short distance are at risk and the need to estimate the long-distance drivers cannot be overstressed. The contribution of long-distance bus driving to MetS such as sitting and driving for long hours has not been investigated. We thus sought to establish the prevalence and predictors of MetS in commercial long-distance bus drivers (CLDBDs) in Cape Coast, Ghana.
2. Methods
Design: We adopted a quantitative cross-sectional approached.
Area and setting: This was in Cape Coast in the Central Region. We collected data from drivers in five transport unions (bus stations). These are: (Tantri number 1, Tantri number 2, Francol Transport Services Ltd, Metro Mass Transit Services and Pedu Union). These unions have buses which ply routes that are further than140 km cogitated to be long distance
[11]
. Cape Coast covers a total land mass of 9,826 square kilometers with an estimated population of 1,805,488
[12]
. Cape Coast is sited within longitude 1° 15'W and latitude 5°06'N and jackets a space of 122 square kilometers. The main business of the people is fishing undoubtedly because the southern portion of the township is delimited by the Gulf of Guinea.
Study participants: These encompassed 170 Commercial Long-Distance Bus Drivers (CLDBDs), in the Cape Coast metropolis.
Sample size determination: This study was snuggled in a study on hypertension and so we used the prevalence of hypertension in the the sample size determination. We estimated the sample size by means of the prevalence of hypertension in West African workforce which was 34.4%
[13]
. We used the formula: n = Z 2 pq/d2. Where n = estimated sample size, Z = confidence level (95% level of confidence - 1.96), p= the probability of having hypertension, (Prevalence = 34.4%) = 0.344, q = 1–p, which is the probability of not having hypertension, in this case: 1 - p = 0.656, d = 0.05 as the acceptable margin of error. The population of CLDBDs was =325. Therefore, n = (1.96) 2 (0.344) (0.656) (0.05) 2 = 347. Correction for finite population n / {1+ (n 1/population)} =165. We rounded the calculated figure up to 170 to upturn the exactness of the estimates.
Sampling method: The list of CLDBDs was gotten from the supervisors of the five transport unions. The number of potential respondents needed from each union to make up the sample size was calculated through weighting. Simple random sampling was used to recruit respondents from each union. Those sampled were given identification tags.
Inclusion and exclusion criteria: We included only long-distance bus drivers with a valid drivers’ license C registered at the unions. Drivers who did not have License C and also those who worked at the locations but were not registered at the unions were excluded.
Anthropometric measurements: Height was measured using stadiometer (model: HM200P Charder USA) following standard protocol
[14]
.
Measurement of blood pressure: A standardized digital Omron automatic blood pressure monitor (HEM–172CN2; Omron, China) was used. Classification was done based on the categories
[15]
. Blood pressure above 140 mmHg and 90 mmHg respectively were used as the reference points.
Fasting blood glucose and lipid measurements:
Commercially available rapid diagnostic test kits were used to measure these parameters (Model HumaSens Human GmbH; Wiesbaden-Germany) through standard protocol and measured to the nearest 0.01 mmol/L. The lipid profile, was measured through (Model CardioChek P A; POCD Australia). The serum cholesterol fractions levels were estimated in 0.01 mmol/L. The WHO (1999) and the ATP III NCEP classifications were used for the categorization
[16].
Training and pretesting of questionnaire: We trained the data collectors for two days at the University of Ghana staff resource Centre on interview skills and anthropometrics. We pretested every aspect of the questionnaire at Madina Lorry Park was the location for pretesting. About 5% of CLDBDs who ply Madina-to-Aflao, Madina-to-Kpando, Madina-to-Ho, and Madina-to-Hohoe were used. Following this, we made modifications to the questionnaire and also identified the best time to conduct the study.
Figure 1. Map of Central Region showing the bus unions.
Classification of Study Variables
BMI classification: Anthropometric measurements were converted into the WHO cut-offs. The values were: Underweight: < 18.50; Normal weight: 18.5–24.99; Overweight: ≥ 25.00; Obese class I: 30.00–34.99; Obese class II: 35.00–39.99 and Obese class III: ≥ 40.00
[14]
.
Hypertension classification: This was done based on the WHO categorization.
[15]
.
Serum lipids classification (mmol/L):
We categorized the Low density lipoprotein fraction as: normal (< 2.59); near normal (2.59- 3.35); borderline high (3.36- 4.12) and high (4.13 – 4.90). For the triglycerides (TG) we have two categories which are: normal (< 1.70) and borderline high (1.70- 2.25). High density lipoprotein (HDL-c) fraction was classified as: Low (<1.04), normal as (>1.04 ≤1.54) and high as (1.55 or more). We categorized Total cholesterol (TC) into: desirable (< 5.18), borderline high (5.18- 6.20) and high (6.21 and above). The ratio of total cholesterol and HDL-c category was: desirable (< = 4.5), and risk for CVD (> 4.5).
Fasting blood glucose (mmol/L)
This was categorized as: below normal (<3.6), normal (3.6-6.1) and high blood glucose level (> 6.1)
Classification of Metabolic Syndrome
This was based on the ATP III NCEP criteria of Triglyceride, High Density Lipoprotein, < 1.04 mmol/L; Low Density Lipoprotein 6.21 mmol/L; BMI, underweight <18.5, normal 18.5-24.99, overweight/obese >25 kg/m2; fasting blood glucose > 6.1 mmol/L; high blood pressure >140/90.
Data analysis:
We encoded data, doubly recorded into IBM SPSS Inc. version 16 (Chicago, Illinois, USA).
Proportions were presented for socio-demographic, occupation and lifestyle features. Descriptive statistics was presented for the five selected categorized metabolic syndrome indicators. Chi-square statistics was performed on socio-demographic, occupational and lifestyle features related with MetS. Multinomial logistic regression was used to estimate the factors that forecasted the likelihood of developing metabolic syndrome at 95% confidence interval (95%CI).
Ethical issues: Consent was sought from each respondent before recruitment. Those who were found to have hypertension were immediately referred to Cape Coast Teaching Hospital for physician attention. Ethical authorization (#004/12-13) was given by Institutional Review Board of Noguchi Memorial Institute for Medical Research, University of Ghana, Legon.
3. Results
Socio-demographic, Lifestyle and Lifestyle Characteristics of CLDBDs
All the respondents in this study were men (Table 1) with mean age of 40.78 ± 8.26 years. About 76.5% had completed JHS/MSLC schooling. The mean years of driving commercial vehicle was 18.46 ± 8.48 with majority 88 (51.8%) of them driving for 18 years or less. They drive for 2.96 ± 0.76 mean hours with utmost of them driving in the range of 2-3 hours 126 (74.1). The top number of voyages made in a day was two with 55.3% making one rounded trip. The turn-around time ranged between 1 – 24 hours with 52.9% having a turn-around stint of 1 hour.
Table 1. Socio-demographic, occupational and lifestyle characteristics of CLDBDs (N = 170).

Characteristics

n (%)

Age (years)

< 35

45 (26.5)

35-40

39 (22.9)

41-45

42 (24.7)

≥46

44 (25.9)

Educational Level

None/ Primary

13 (7.6)

1JHS/MSLC/

130 (76.5)

2SHS/GCE (OL)/Tech/Voc

26 (15.3)

Tertiary

1 (0.6)

Years of commercial driving

≤ 18

88 (51.8)

≥ 19

82 (48.2)

Hours driven to destination

2-3

126 (74.1)

>3

44 (25.9)

Number of round trips in a day

1

94 (55.3)

2

76 (44.7)

Turn- around time back to Cape Coast (hours)

1

90 (52.9)

2

61 (35.9)

3

18 (10.6)

24

1 (0.6)

Lifestyle Practices

Alcohol intake

Yes

78 (45.9)

No

92 (54.1)

Type of alcohol

Spirit

42 (53.8)

Beer

35 (44.9)

Wine

1 (1.3)

Tobacco use

Yes

3 (1.8)

No

167 (98.2)
1JHS/MSLC denotes Junior High School/Middle School Leavers Certificate 2SHS/GCE (OL/AL)/Tech/Voc denotes Senior High School/ General Certificate Examination (Ordinary level/Advance Level)/ Technical School level/Vocational Education CLDBDs denotes commercial long distance bus drivers.
Metabolic Syndrome Indicators Among the CLDBDs
Table 2 shows the categorized metabolic indicators of the drivers. The mean BMI (kgm2) was 25.4 ± 4.2 and 14.2% were obese. A total of 21.2% had systolic blood pressure 140 mmHg or higher and 22.4% had diastolic blood pressure 90 mmHg or more (Table 2). The mean concentration of low-density lipoprotein (LDL-c) was 1.3 ± 0.7 mmol/L and 2.2% of respondents had high levels of LDL. The mean concentration of high-density lipoprotein (HDL-c) level was 1.5 ± 0.7 mmol/L and 8.8% had high HDL levels. Whilst the mean triglyceride (TG) level was 1.0 ± 0.1 mmol/L, 2.2% had high levels. About 4.4% had high levels of total cholesterol (TC) and the mean for the respondents was 1.1 ± 0.4 (mmol/L). The mean fasting glucose level was 6.5 ± 1.9 mmol/L.
Table 2. Descriptive statistics of metabolic syndrome indicators among the CLDBDs.

Measurements

n (%)

Body Mass Index (BMI)

25.39 ± 4.22

Underweight

5 (2.9)

Normal

79 (46.5)

Overweight

62 (36.5)

Obese

24 (14.1)

Systolic blood pressure (mmHg)

130.51 ± 18.1

Normal

134 (78.8)

High

36 (21.2)

Diastolic blood pressure (mmHg)

81.03 ± 13.72

Normal

132 (77.7

High

38 (22.3)

Fasting blood glucose (mmol/L) (n=109)

6.50 ± 1.86

Low

1 (0.9)

Normal

18 (16.5)

High

64 (58.7)

Very high

26 (23.9)

Triglycerides (mmol/L) (n=91)

0.77 ± 0.34

Normal

89 (97.8)

High

2 (2.2)

Low density lipoprotein (mmol/L) (n=91)

2.01 ± 0.75

Low

74 (81.3)

High

17 (18.7)

High density lipoprotein (mmol/L) (HDL) (n=91)

1.03 ± 0.39

Low

54 (59.3)

High

37 (40.7)

Total cholesterol (TC) (mmol/L) (n=91)

3.45 ± 0.81

Normal

86 (94.5)

High

5 (5.5)

TC: HDL ratio (n=91)

3.75 ± 1.40

Normal

57 (62.6)

High

34 (37.4)

Metabolic syndrome (n=91)

Absent

51 (56.0)

Present

40 (44.0)
BMI (kg/m2): Underweight (<18.5); Normal (18.5-24.9); Overweight (25-29.9); Obesity (≥30); Systolic blood pressure (mmHg): Normal (≤ 140); High (>140); Diastolic blood pressure (mmHg): Normal (≤ 90); High (> 90); Triglycerides (mmol/L): Normal (< 1.70); Borderline high (1.70- 2.25); Total cholesterol (mmol/L): Desirable (< 5.18) Borderline high (5.18- 6.20) High (6.21 and above); Total cholesterol: HDL: Desirable (< = 4.5) Risk for CVD (> 4.5); High Density Lipoprotein (HDL): Desirable (< 5.18) Borderline high (5.18- 6.20) High (6.21 and above); Fasting blood glucose (mmol/L): Below normal, (<3.6) Normal (3.6-6.1); High glucose level (>6.1)
Chi-square Statistics of Socio-demographic, Lifestyle and Occupational Factors Associated Metabolic Syndrome Among the CLDBDs
Relatively, less proportion of the drivers had family history of diabetes, hypertension and obesity, although these proportions were not statically associated with MetS development. The occupational and lifestyle variables were also not statistically related with the elaboration of metabolic syndrome but for alcohol ingestion, (Table 3; P= 0.01).
Table 3. Chi-square statistics of socio-demographic factors associated Metabolic Syndrome among the CLDBDs (N=170).

Characteristics

Metabolic Syndrome

Absent

Present

Total

p-value

Age (years)

<35

14 (27.5)

7 (17.5)

21 (23.1)

0.35

35-40

15 (29.4)

9 (22.5)

24 (26.4)

41-45

12 (23.5)

10 (25.0)

22 (24.2)

≥46

10 (19.6)

14 (35.0)

24 (26.4)

Educational level

None

0 (0.0)

1 (2.5)

1 (1.1)

0.17

JHS/MSLC

46 (90.2)

31 (34.1)

77 (84.6)

SHS

2 (3.9)

6 (15.0)

8 (8.8)

OTHER

3 (5.9)

2 (5.0)

5 (5.5)

Years of Commercial driving

<14

21 (41.2)

14 (35.0)

35 (38.5)

0.58

14-21

14 (27.5)

9 (22.5)

23 (25.3)

>21

16 (31.4)

17 (42.5)

33 (36.3)

Hours to destination

≤3

36 (70.6)

29 (72.5)

65 (71.4)

0.84

>3

15 (29.4)

11 (27.5)

26 (28.6)

Turn around time

≤4

28 (54.9)

23 (57.5)

51 (56.0)

0.83

>4

23 (45.1)

17 (42.5)

40 (44.0)

Trips in a day

1

27 (52.9)

21 (52.5)

48 (52.7)

0.97

2

24 (47.1)

19 (47.5)

43 (47.3)

Family history

Diabetes

75(86)

16 (9.0)

0.44

Hypertension

89(93.5)

11 (6.5)

Obesity

29(63.5)

62 (36.5)

Alcohol use

Yes

17 (33.3)

25 (62.5)

42 (46.2)

0.01*

No

34 (66.7)

15 (37.5)

49 (53.8)
Predictors of Metabolic Syndrome Among CLDBDs
Multinomial logistics regression was used to estimate the predictors of metabolic syndrome among the population. Drivers who consume alcohol are about five times more likely to develop metabolic syndrome linked with drivers who did not (Table 4; OR= 5.17; %95 CI=1.75-15.26; P< 0.03). The rest of the explanatory factors did not indicate any statistically significant associations withs MetS development.
Table 4. Multinomial logistics regression of predictors of metabolic syndrome among CLDBDs.

Variables

OR

95 % confidence interval

p-value

Lower

Upper

Age

<35

0.20

0.03

1.26

0.40

35-40

0.40

0.09

1.79

41-45

0.45

0.11

1.89

≥46

1.00

Years of Commercial driving

<14

1.67

0.36

7.65

0.52

14-21

0.75

0.20

2.85

>21

1.00

Hours to destination

≤3

1.40

0.32

6.25

0.66

>3

1.00

Turn around time

≤4

0.85

0.22

3.37

0.82

>4

1.00

Family history

Diabetes

0.76

0.34

0.52

0.55

High blood pressure

0.57

0.35

0.38

Obesity

1.0

Yes

2.06

0.66

6.42

0.21

No

1.00

Alcohol use

Yes

5.17

1.75

15.26

0.003*

No

1.00

Fruit intake

Yes

1.57

0.28

8.78

0.61

No

1.00
*Significant at p-valve< 0.05. Adjusted R2=0.23; OR’s are adjusted for all variables in the table
1.0: reference values
4. Discussion
This cross sectional study was undertaken among 170 Long Distance Commercial Bus Driver (LDCBDs) in Cape Coast to determine the prevalence and determinants of metabolic syndrome (MetS). The combination of anthropometric and biochemical variables permitted MetS diagnosis and provided insight into the individual MetS components and factors that are associated with it.
This study is the first that assess MetS among this cohort in Central region and Ghana. We found the prevalence of Metabolic syndrome (MetS) to be 44% based on the ATPIII NCEP classification. The prevalence of MetS among Ghanaians was estimated by different studies in Ghana to range between 6 – 21.2% depending on the whether you used ATPIII NCEP, WHO, and IDF guidelines. Gyakobo et al. measured MetS among Ghanaian rural residents and stated high prevalence of MetS [15% (ATP III) Gyakobo et al.
[17]
. Their finding was among rural dwellers as compared to ours which was among urban dwellers. The lower prevalence among that cohort may be due to the fact they were rural folks and small industrialist whose occupation lifestyle and dietary intake may have an association with their findings. In order words, the dietary habits among the agrarian society may have been protective compared to our sample which were urban and usually eats away from home and also have different occupation and lifestyle. Their daily shift starts at about 5.00 am daily including weekends and holidays. Lifestyle and occupational practices differ among rural and urban dwellers. The lifestyle among Ghanaians has been noted to contribute to an escalation in MetS development
[7]
– specify the lifestyle for contextual relevance. Poor nutrition, poor sleep quality has been associated with MetS diagnosis, as well as with hyperglycemia, high triglycerides, low HDL cholesterol and obesity
[18, 19]
. The difference in gender of respondents could also be a factor since in Ghana females are more obese than men
[7]
and obesity has been implicated in the development of MetS].
Although a study has linked both short and long sleep interval in MetS risk.
[20]
, sleep was not a significant predictor of MetS in this study. Among the occupation variables, turnaround time, hours driven to destination, number of round trips, some of which were in the night turned out to be potential protective factor for MetS development among our population. The higher prevalence reported in our study could be due to the proportion of respondents with high fasting blood glucose and is in consonance with
[21]
. They reported a higher MetS prevalence of (29.2%) among Nigerians when some of the respondents had type 2 diabetes. Prevalence of high fasting blood (> 6.1 mmol/L) glucose was 82.57% among the drivers. This high fasting blood glucose level can lead to the development of type 2 diabetes, damages to nerves, blood vessels and some organs of the body
[22]
.
Empirical evidence points to an increase in the prevalence of hypertension
[23]
, diabetes mellitus
[24]
, hyperlipidemia, and obesity
[25]
, which are individual components of MetS, is in Ghana and in West Africa
[26]
.
Obesity which is one of the indicators of MetS development is lower in our group (14.2%) compared with the national prevalence of obesity (23.1%) for males 20 years and older
[27]
. Our lower BMI value may be due to lower dietary energy intake among the population as suggested by our data. It has been noted driving is not a sedentary activity and therefore some amount of energy is expended in conveying passengers. Our results are dissimilar to a study in Ghana which establish high prevalence of overweight and obesity among commercial minibus (trotro) drivers and among taxi drivers by Adu-Asare and Steiner-Asiedu
[10]
. The same trend was discovered among qualified bus and truck drivers
[28]
. The socio-demographic and occupational correlates such as in the commercial long distance bus driving would have to be pondered in preventive efforts
[29]
.
This could be due to the fact that alcohol intake is independently related to obesity in men since it is a form of empty calorie
[30]
. Our respondents could have been involved in the habit because intake of alcohol has been shown to increase the risk of hypertension in black men
[31]
. Asiamah et al. found drivers used alcohol because it is thought to have a relaxation effect, removes their inhibitions, upturn their driving confidence level, builds-up acquaintances and, also because of the savor
[32]
. About 50% of the respondents took alcohol and these may have accounted for alcohol intake precipitating development of MetS in this group. The study design is strong in its ability to provide a quick, cost-effective snapshot of long-distance bus drivers in Cape Coast and their characteristics. However, its reliance on non-probability sampling, cross-sectional nature, and inability to establish causality or account for temporal changes pose limitations. Therefore, careful interpretation of results is required, especially regarding generalizability and causation. We believe the cross-sectional nature and the sample size may have reduced the relevance of the findings in terms of generalization. However, we added a margin to the calculated sample size to surge the accuracy of the assessments. The differences in the subset of respondents who presented data on serum and BP could also be a reason.
5. Conclusion
The prevalence of MetS is high from the study. The exposure to occupational long-distance driving did not appear as a factor in MetS manifestation among the group however, alcohol intake predicted MetS. Counselling against alcohol intake should be part of treatment protocols among this group.
Abbreviations

ATP III

Adult Treatment Panel lII

BMI

Body Mass Index

CI

Confidence Interval

CLDBDs

Long Distance Commercial Bus Driver

CVR

Cardiovascular Risk

DSP

Diastolic Blood Pressure

FBS

fasting Blood Glucose

GHDx

Ghana Special Demographic and Health Survey

GSS

Ghana Statistical Services

HDL-c

High Density Lipoprotein

IBM SPSS

Statistical Package for the Social Sciences

IDF

International Diabetic Federation

JHS

Junior High School

LDL-c

LOW Density Lipoprotein

MetS

Metabolic Syndrome

MSLC

Middle School Leavers Certificate

NCEP

National Cholesterol Education Programme

OR

Odds Ratio

SBP

Systolic Blood Pressure

SHS/GCE (OL/AL)/Tech/Voc

Senior High School/ General Certificate Examination (Ordinary Level)

TC

Total Cholesterol

TG

Triglyceride

WHO-ISH

World Health Organization-International Society of Hypertension

WHO

World Health Organization
Acknowledgments
We are grateful to all the drivers that participated in this study. Our appreciation also to the data collectors.
Author Contributions
Heckel Amoabeng Abban: Conceptualization, Data curation, Formal Analysis, Funding acquisition, Investigation, Methodology, Resources, Validation, Visualization, Writing – original draft, Writing – review & editing
Jacob Setorglo: Conceptualization, Data curation, Formal Analysis, Methodology, Software, Supervision, Validation, Visualization, Writing – original draft, Writing – review & editing
Christiana Nsiah-Asamoah: Conceptualization, Data curation, Formal Analysis, Investigation, Methodology, Validation, Writing – original draft, Writing – review & editing
Samuel Acquah: Data curation, Formal Analysis, Methodology, Resources, Software, Validation, Visualization, Writing – original draft, Writing – review & editing
Matilda Steiner-Asiedu: Conceptualization, Data curation, Formal Analysis, Funding acquisition, Investigation, Methodology, Project administration, Resources, Software, Supervision, Validation, Visualization, Writing – original draft, Writing – review & editing
Conflicts of Interest
The authors declare no conflicts of interest.
References
[1] Wang, Q., Chair, S. Y., Wong, E. M., Taylor-Piliae, R. E., Qiu, X., & Li, X. M. (2019). Metabolic syndrome knowledge among adults with cardiometabolic risk factors: A Cross-Sectional Study. International Journal of Environmental Research And Public Health, 16(1), 159.
[2] Kruger, M. J. & Nell, T. A. (2017). The prevalence of the metabolic syndrome in a farm worker community in the Boland district, South Africa. BMC Public Health 17, 61.
[3] International Diabetic Federation (IDF) (2021). Diabetes around the world in 2021. IDF Diabetes Atlas. Available:

https://diabetesatlas.org/atlas/tenth-edition/ retrieved August 2022.

[4] Kaur, J. “A comprehensive review on metabolic syndrome,” Cardiology Research and Practice, vol. 2014, Article ID 943162, 21 pages, 2014.
[5] Adnan, E., Rahman, I. A., & Faridin, H. P. (2019). Relationship between insulin resistance, metabolic syndrome components and serum uric acid. Diabetes & Metabolic Syndrome, 13(3), 2158–2162.
[6] International Diabetes Federation, IDF Worldwide Definition of the Metabolic Syndrome, IDF, 2015.
[7] Ofori-Asenso, R., Agyeman, A. A., & Laar, A. (2017). Metabolic syndrome in apparently “healthy” ghanaian adults: A systematic review and meta-analysis. International Journal of Chronic Diseases, vol. 2017.
[8] GHDx (2018). Ghana Special Demographic and Health Survey 2017. ICF International. United States of America: Fairfax.
[9] Appiah, C. A., Afriyie, E. O., Hayford, F. E. A., Frimpong, E. (2020). Prevalence and lifestyle-associated risk factors of metabolic syndrome among commercial motor vehicle drivers in a metropolitan city in Ghana. Pan African Medical Journal; 36(136).
[10] Adu-Asare, C., Steiner-Asiedu, M. (2008). Nutrition and Lifestyle Behaviours of Taxi Drivers in Accra. Dessertation (BSc) Submitted to the Department of Nutrition and Food Science, University of Ghana; 2008(1): 60-88.
[11] Yobo, E., Kunawotor, M. E., Apau, E. V. (2010) Ernest Victor, et al. Ghana Metro Mass Transit, Transport manual. Int J Economics; 5.
[12] Ghana Statistical services (GSS) (2020). Population & Housing Census; 21-103.
[13] Bosu, W. K., (2010). Epidemic of hypertension in Ghana: a systematic review, BMC Public Health; 10(1): 418.
[14] WHO,(1995). Physical status: the use and interpretation of anthropometry. Report of a WHO Expert Committee. WHO Technical Report Series 854. Geneva: World Health Organization. Retrieved from

http://apps.who.int/bmi/index.jsp?introPage=

[15] WHO-ISH (1999). World Health Organization-International Society of Hypertension guidelines for the management of hypertension. J Hypertension. 17: 151-183.
[16] Expert Panel on Detection, Evaluation, and Treatment of High Blood Cholesterol in Adults: Executive summary of the third report of the national cholesterol education program (NCEP) expert panel on detection, evaluation, and treatment of high blood cholesterol in adults (Adult Treatment Panel III). JAMA. 2001, 285: 2486-2497.

https://doi.org/10.1001/jama.285.19.2486

[17] Gyakobo, M., Amoah, A. G. B. D., Martey-Marbell, A., & Snow, R. C., (2012). “Prevalence of the metabolic syndrome in a rural population in Ghana,” BMC Endocrine Disorders, vol. 12, article 25.
[18] Pulido-Arjona, L., Correa-Bautista, J. E., Agostinis-Sobrinho, C., Mota, J., Santos, R., Correa-Rodríguez, M., Garcia-Hermoso, A., & Ramírez-Vélez, R. (2018). Role of sleep duration and sleep-related problems in the metabolic syndrome among children and adolescents. Italian Journal of Pediatrics volume 44, (9).
[19] Lemke, M. K., Apostolopoulos, Y., Hege, A., Wideman, L., & Sönmez, S. (2017). Work organization, sleep and metabolic syndrome among long-haul truck drivers. Occupational Medicine, 67(4), 274–281.
[20] Fan, L., Hao, Z., Gao, L., Qi, M., Feng, S., & Zhou, G. (2020). Non-linear relationship between sleep duration and metabolic syndrome: A population-based study. Medicine, 99(2).
[21] Nygren, K., Hammarström, A. & Rolandsson, O. (2017). Binge drinking and total alcohol consumption from 16 to 43 years of age are associated with elevated fasting plasma glucose in women: Results from the northern Swedish cohort study. BMC Public Health 17, 509.
[22] Dwivedi1, M. & Pandey, A. R. (2020). Diabetes mellitus and its treatment: An overview. Journal of Advancement in Pharmacology, 1(1).
[23] Al-Azzam, N., Al-Azzam, S., Elsalem, L., & Karasneh, R. (2020). Hypertension prevalence and associated factors among patients with diabetes: A retrospective cross-sectional study from Jordan. Annals of Medicine And Surgery, 61, 126–131.
[24] Ingelfinger, J. R. & Jarcho, J. A. (2017). Increase in the Incidence of Diabetes and Its Implications. The New England Journal of Medicine. 376, 1473-1474.
[25] Gan, W., Liu, Y., Luo, K., Liang, S., Wang, H., Li, M., Zhang, Y. & Huang, H. (2018). The prevalence change of hyperlipidemia and hyperglycemia and the effectiveness of yearly physical examinations: An eight-year study in Southwest China. Lipids in Health Disease (17), 70.
[26] Ofori-Asenso, R., and Garcia, D. (2016). “Cardiovascular diseases in Ghana within the context of globalization,” Cardiovascular Diagnosis and Therapy, vol. 6, no. 1, pp. 67–77.
[27] WHO, (2011c). Prevalence of insufficient physical activity. Retrieved from:

https://www.who.int/data/gho/data/indicators/indicator-details/GHO/prevalence-of-insufficient-physical-activity-among-adults-aged-18-years-(age-standardized-estimate)-(-)

[28] Saberi, H., Moraveji, A. and Parastouie, K. (2009). Metabolic syndrome among professional bus and truck drivers in Kashan, 2008. ISMJ. 12(20): 126-132.
[29] Anto, E. O., Owiredua W. K. B. A., Adua, E., Obirikoranga, C., Fondjoa, L. A., Annani-Akollora, M. E., Acheamponga, E., Asamoah, E. A., Roberts, P., Wang, W., 35. Donkora, S. (2020). Prevalence and lifestyle-related risk factors of obesity and unrecognized hypertension among bus drivers in Ghana. Science Direct 6(1).
[30] Duvigneaud, N., Wijndaele, K., Matton, L., Philippaerts, R., Lefevre, J., Thomis, M., Delecluse, C. and Duquet, W. (2007). Dietary factors associated with obesity indicators and level of sports participation in Flemish adults: a cross-sectional study. Nutr J. 6: 26.
[31] Minzer, S., Losno, R. A., & Casas, R. (2020). The effect of alcohol on cardiovascular risk factors: Is there new information?. Nutrients, 12(4), 912.
[32] Asiamah, G., Blantari, J. and Mock C. (2002). Understanding the knowledge and attitudes of commercial drivers in Ghana regarding alcohol impaired driving. InjPrev. 8(1): 53-56. cardiovascular_diseases/en/ 4/6/12.
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    Abban, H. A., Setorglo, J., Nsiah-Asamoah, C., Acquah, S., Steiner-Asiedu, M. (2024). The Prevalence and Predictors of MetS Among Commercial Long Distance Bus Drivers (CLDBDs) in Cape Coast, Ghana. World Journal of Public Health, 9(4), 396-405. https://doi.org/10.11648/j.wjph.20240904.19

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    Abban, H. A.; Setorglo, J.; Nsiah-Asamoah, C.; Acquah, S.; Steiner-Asiedu, M. The Prevalence and Predictors of MetS Among Commercial Long Distance Bus Drivers (CLDBDs) in Cape Coast, Ghana. World J. Public Health 2024, 9(4), 396-405. doi: 10.11648/j.wjph.20240904.19

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    AMA Style

    Abban HA, Setorglo J, Nsiah-Asamoah C, Acquah S, Steiner-Asiedu M. The Prevalence and Predictors of MetS Among Commercial Long Distance Bus Drivers (CLDBDs) in Cape Coast, Ghana. World J Public Health. 2024;9(4):396-405. doi: 10.11648/j.wjph.20240904.19

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  • @article{10.11648/j.wjph.20240904.19,
  author = {Heckel Amoabeng Abban and Jacob Setorglo and Christiana Nsiah-Asamoah and Samuel Acquah and Matilda Steiner-Asiedu},
  title = {The Prevalence and Predictors of MetS Among Commercial Long Distance Bus Drivers (CLDBDs) in Cape Coast, Ghana
},
  journal = {World Journal of Public Health},
  volume = {9},
  number = {4},
  pages = {396-405},
  doi = {10.11648/j.wjph.20240904.19},
  url = {https://doi.org/10.11648/j.wjph.20240904.19},
  eprint = {https://article.sciencepublishinggroup.com/pdf/10.11648.j.wjph.20240904.19},
  abstract = {Background: Metabolic syndrome (MetS) is a foremost risk consideration for the development of cardiovascular disease which is a major cause of mortality around the globe. Objective: This study determined the prevalence and predictors of MetS amongst Commercial Long Distance Bus Drivers (CLDBDs) in Cape Coast, Ghana. Methods: A cross sectional study design that conveniently enrolled 170 registered male CLDBDs from five bus Unions. We included in the study long distance bus drivers registered at the unions, with a valid drivers’ license C. Obesity was determined using the WHO cut-offs. We determined blood pressure among the drivers through diastolic and systolic readings of arterial blood pressures and categorized based on the WHO cut offs. Fasting blood glucose level was reached through laboratory analysis. The MetS was determined based on ATP III NCEP criteria. Percentages were presented for socio-demographic and lifestyle variables. Chi-square statistics was performed on socio-demographic, occupational and lifestyle factors associated with MetS. Multinomial logistic regression was used to determine the factors that predicted the likelihood of developing metabolic syndrome at 95% confidence interval (95%CI). Results: The average age and duration of commercial long-distance driving were 41± 8 years and 18± 8 hours respectively. About 14.2% were obese. A total of 22.4% had diastolic blood pressure 90 mmHg or higher and 21.2% had systolic blood pressure 140 mmHg or higher. About 2.2% of respondents had high levels of LDL-c and 8.8% had high HDL-c levels. Whilst 2.2% had high levels of triglyceride, 4.4% had high levels of total cholesterol (TC). About 82.6% had fasting blood glucose level > 6.1 mmol/L. The prevalence of MetS was 44% alcohol intake was statistically associated with metabolic syndrome (pConclusion: The prevalence of metabolic syndrome was high among this group. Out of the five symptoms used for MetS classification, fasting blood glucose proportion was highest and alcohol intake placed drivers at about five times at risk of development of MetS compared with drivers who do not.
},
 year = {2024}
}

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  • TY  - JOUR
T1  - The Prevalence and Predictors of MetS Among Commercial Long Distance Bus Drivers (CLDBDs) in Cape Coast, Ghana

AU  - Heckel Amoabeng Abban
AU  - Jacob Setorglo
AU  - Christiana Nsiah-Asamoah
AU  - Samuel Acquah
AU  - Matilda Steiner-Asiedu
Y1  - 2024/12/19
PY  - 2024
N1  - https://doi.org/10.11648/j.wjph.20240904.19
DO  - 10.11648/j.wjph.20240904.19
T2  - World Journal of Public Health
JF  - World Journal of Public Health
JO  - World Journal of Public Health
SP  - 396
EP  - 405
PB  - Science Publishing Group
SN  - 2637-6059
UR  - https://doi.org/10.11648/j.wjph.20240904.19
AB  - Background: Metabolic syndrome (MetS) is a foremost risk consideration for the development of cardiovascular disease which is a major cause of mortality around the globe. Objective: This study determined the prevalence and predictors of MetS amongst Commercial Long Distance Bus Drivers (CLDBDs) in Cape Coast, Ghana. Methods: A cross sectional study design that conveniently enrolled 170 registered male CLDBDs from five bus Unions. We included in the study long distance bus drivers registered at the unions, with a valid drivers’ license C. Obesity was determined using the WHO cut-offs. We determined blood pressure among the drivers through diastolic and systolic readings of arterial blood pressures and categorized based on the WHO cut offs. Fasting blood glucose level was reached through laboratory analysis. The MetS was determined based on ATP III NCEP criteria. Percentages were presented for socio-demographic and lifestyle variables. Chi-square statistics was performed on socio-demographic, occupational and lifestyle factors associated with MetS. Multinomial logistic regression was used to determine the factors that predicted the likelihood of developing metabolic syndrome at 95% confidence interval (95%CI). Results: The average age and duration of commercial long-distance driving were 41± 8 years and 18± 8 hours respectively. About 14.2% were obese. A total of 22.4% had diastolic blood pressure 90 mmHg or higher and 21.2% had systolic blood pressure 140 mmHg or higher. About 2.2% of respondents had high levels of LDL-c and 8.8% had high HDL-c levels. Whilst 2.2% had high levels of triglyceride, 4.4% had high levels of total cholesterol (TC). About 82.6% had fasting blood glucose level > 6.1 mmol/L. The prevalence of MetS was 44% alcohol intake was statistically associated with metabolic syndrome (pConclusion: The prevalence of metabolic syndrome was high among this group. Out of the five symptoms used for MetS classification, fasting blood glucose proportion was highest and alcohol intake placed drivers at about five times at risk of development of MetS compared with drivers who do not.

VL  - 9
IS  - 4
ER  -

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Author Information

  • Heckel Amoabeng Abban

    Department of Nutrition and Food Science, University of Ghana, Accra, Ghana

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  • Jacob Setorglo

    Department of Medical Biochemistry, University of Cape Coast, Cape Coast, Ghana

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  • Christiana Nsiah-Asamoah

    Department of Clinical Nutrition and Dietetics, University of Cape Coast, Cape Coast, Ghana

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  • Samuel Acquah

    Department of Medical Biochemistry, University of Cape Coast, Cape Coast, Ghana

    Contact Email

  • Matilda Steiner-Asiedu

    Department of Nutrition and Food Science, University of Ghana, Accra, Ghana

    Contact Email

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