Methods

We conducted a comparative cross-sectional study design based on a retrospective record review in the Tuberculosis and Leprosy Control Unit, Kelantan State Health Department.

The reference populations were all pediatric tuberculosis patients in Kelantan, and the study samples were children and adolescents with tuberculosis and non-tuberculosis in Kelantan registered in the Tuberculosis Information System (TBIS) from 2012 to 2015 who fulfilled study inclusion and exclusion criteria. The inclusion criteria were confirmed cases of tuberculosis who were notified to respective District Health Offices in Kelantan and registered in the TBIS from 1 January 2012 to 31 December 2015. Non-tuberculosis cases were tuberculosis contacts with no symptoms, negative Mantoux test, no chest radiograph abnormality, and registered in the TBIS from 1 January 2012 to 31 December 2015. Both cases and non-tuberculosis cases must be of pediatric age (1–19 years old).

The sample size was calculated for each variable of associated factors for tuberculosis disease among pediatric patients using power and sample size calculation software23 as well to compare two independent proportions. The largest estimated sample for each group was 322 using the proportion of non-tuberculosis children and adolescents by the factor of urban residence (0.61),24 an estimated proportion of 0.49, 5% type 1 error, 80% power, and additional 20% missing data.

Data were collected from Kelantan TBIS. TBIS is an online registry set up by the Ministry of Health for surveillance of tuberculosis disease in Malaysia. The retrieved information includes sociodemographic data (age, ethnicity, gender, location of residence, and education level) and clinical factors (HIV and cigarettes smoking status). Using Kelantan TBIS, we found a total of 15 333 tuberculosis cases and tuberculosis contacts among the pediatric group from 2012 to 2015. These were subdivided into tuberculosis cases and non-tuberculosis case sampling frames. From each sampling frame, we used a simple random sampling method to obtain 322 study samples for each group. The flowchart for this study is shown in Figure 1.

We defined good education level as those who attended school at least up to age 10.25 Urban areas were defined as gazette areas with a combined population of 10 000 or more. Meanwhile, rural areas were defined as gazette areas with a combined population of less than 10 000.26

The study was approved by the Human Research and Ethics Committee, Universiti Sains Malaysia (USM/JEPeM/16120592) and the Medical Review and Ethical Committee from National Institute of Health, Ministry of Health, Malaysia (NMRR-16-2348-33521 IIR).

We used SPSS Statistics (IBM Corp. Released 2013. IBM SPSS Statistics for Windows, Version 22.0. Armonk, NY: IBM Corp) for data entry and analysis. Descriptive statistics with mean and standard deviation (SD), frequency and percentages were calculated. Simple and multiple logistic regression analysis were used to determine factors associated with tuberculosis disease among pediatric patients. All significant variables with a p-value < 0.250 from univariable analysis and clinically important variables were chosen for multiple logistic regression analysis. A p-value < 0.050 was considered statistically significant.

Results

There were 5412 tuberculosis cases, and 36 356 tuberculosis contacts notified and registered in Kelantan TBIS during the four-year study period (2012–2015). The proportion of tuberculosis among pediatric patients in Kelantan was 8.4% (95% confidence interval (CI): 0.08–0.09) or 456 cases out of total 5412 tuberculosis cases. Of these, 356 (78.1%) cases were pulmonary tuberculosis, 68 (14.9%) cases were extrapulmonary tuberculosis, and 32 (7.0%) cases were pulmonary tuberculosis with concomitant extrapulmonary tuberculosis [Figure 2].

The pretreatment sputum AFB smear distribution for all 388 pulmonary tuberculosis (including the pulmonary form with concomitant extrapulmonary tuberculosis) cases was 252 (64.9%) sputum positive cases, and 136 (35.1%) sputum negative cases [Figure 3].

A total of 644 samples were included in this study with 322 samples for each group of tuberculosis and non-tuberculosis cases [Table 1]. The mean age of children and adolescents with tuberculosis was higher compared to those with non-tuberculosis. Children aged 10–19 years old contributed most tuberculosis cases (n = 293, 91.0%). The majority of tuberculosis cases were Malay children and adolescents (n = 292, 90.7%). Females were more prone to contract tuberculosis (n = 177, 55.0%). Tuberculosis cases showed a higher percentage for residents in non-urban areas with 256 cases (79.5%) and among children and adolescents with a good level of education with 295 cases (91.6%). The majority of children and adolescents diagnosed with tuberculosis were non-smokers (n = 275, 85.4%), and had negative HIV status (n = 313, 97.2%).

Multiple logistic regression analysis revealed age, gender, education level, location of residence, and smoking status were the significant associated factors for tuberculosis infection among children and adolescents [Table 2].

Discussion

The proportion of tuberculosis cases among pediatric patients in Kelantan was 8.4% (95% CI: 0.08–0.09). Our finding is similar to the finding from a national data study where children and adolescents comprised about 8.5% out of total tuberculosis cases nationwide.3

We found that the majority of cases among pediatric patients in Kelantan were pulmonary tuberculosis (78.1%). This finding is congruent with a report from the WHO, which showed 70–80% of children with tuberculosis had pulmonary form.14
In Malaysia, a high incidence of tuberculosis was seen among 10 to 19 years old.3 The finding was consistent with our study. Since this age group represents adolescents, it explains the reason for the high incidence of sputum smear-positive tuberculosis in our study because adolescents are at particular risk of developing adult-type disease (that is, they are often sputum smear-positive and highly infectious).14
Our study revealed the mean age for tuberculosis among children and adolescents was 15.9 years old. The finding showed slight discrepancy with a matched case-control study from Brazil that analyzed the risk factors for tuberculosis infection among older children where the mean age of the enrolled patients was 14.4 years.8 Another study on the prevalence of tuberculosis among adolescents in Western Kenya reported the mean age as 14.4 years.6

In our study, age was a significant factor associated with tuberculosis infection (aOR = 1.41, 95% CI: 1.29–1.54; p < 0.001). An increase of one year of age has a 1.4-times increase in the odds of contracting tuberculosis. Similar findings were reported from a cohort study in South Africa among adolescent tuberculosis patients.18 A possible explanation is that older age is associated with engaging in multiple health and disease risk behaviors.27 Moreover, this finding may explain the high incidence of sputum smear-positive tuberculosis, which is believed to be attributed to the older age or the adolescent group. Sputum positive patients are capable of transmitting infection. The number of bacilli depends on the extent of the lesion or the presence of lung cavitation in the pulmonary form of tuberculosis. The larger the cavity or lesion, the larger the amount of bacilli present. Thus, the grading of a positive smear reflects the extent of lesion in a patient as well as being directly proportional to the infectiousness of the case.28

We found a significant association between gender and tuberculosis infection. More than half of patients were female (55.0%), and both female children and adolescents were almost twice as likely to get tuberculosis infection. This finding is in line with three different studies conducted among children and adolescents with tuberculosis in Uganda, Pakistan, and South Africa.9,10,18 All these studies showed that female children and adolescents had higher odds of getting tuberculosis infection. Some studies have shown that males with risk factors such as smoking, alcoholism, drug addiction, and HIV infection acquire tuberculosis more than females, so the sex difference in tuberculosis prevalence was attributable to these factors.29,30 However, there is a possible explanation for the shift of notification rate towards female group. It is possible that female adolescents are simply more likely to use health services during their reproductive years. A study from the US reported that different health-seeking behaviors by females would increase their chance of being diagnosed should they have symptoms of tuberculosis.31 It is known that male patients seek help and use health services less frequently than female patients. Adherence to patriarchal masculine characteristics, such as superiority, independence, self-reliance, and dominance may act as a barrier to men accessing and using health services and consequently prevents diseases from being diagnosed and treated.32

We also found a significant association between other sociodemographic determinants such as ethnicity and education level with tuberculosis infection among children and adolescents. Malay ethnic people comprised the majority of the studied patients most probably due to the high Malay population (95.7%) in Kelantan.1 A conclusion that tuberculosis was prevalent among Malay children and adolescents cannot be made because there were few non-Malay patients in this study. Therefore, the variable cannot be used to test the causal hypothesis.

In contrast with our findings, a study by Liew et al,3 showed that patients without any formal education were 1.94-fold more likely to develop tuberculosis compared to the educated group. Our study revealed that educated children and adolescents were more prone to tuberculosis infection. This finding is supported by a previous study in Brazil, which reported that there is evidence indicating the lack of knowledge and misinformation about tuberculosis among educated group could expose them to the same risk of getting tuberculosis as the uneducated group.33 Possible reasons could be due to lack of tuberculosis awareness or education programs that focus on the educated group. There are many issues that contributed to the lack of tuberculosis awareness or education programs. Among the issues was the community’s reluctance to take ownership of health issues as educated people in some cultures are more reluctant to participate in health activities.34 Alternatively, it may suggest that educated patients have better health-seeking behavior and are well-informed about the need to seek treatment for tuberculosis. This is supported by qualitative research findings on perceptions of tuberculosis and health-seeking behavior in rural Inner Mongolia, China, which reported that less educated people and low-income groups were less likely to seek care, or more likely to seek care at village level where it is cheaper. Both financial and structural barriers were found to stop them from seeking proper health care.35

We also found a significant association between area of residence and tuberculosis infection among children and adolescents. Children and adolescents residing in rural areas had 1.9-times higher odds of getting tuberculosis compared to those in urban areas. The result was in line with a study in Western Kenya, which reported that rural children were more likely to get tuberculosis and accounted for 87% of the total caseload.6 The prevalence of tuberculosis among rural residents are majorly due to lack of knowledge regarding the disease itself. It is reported through a study in a northern rural area of Vietnam that knowledge of causes, transmission routes, symptoms and curability of tuberculosis was low among rural people. They reported that 82% of women and 74% of men residing in rural areas did not know that tuberculosis is caused by bacteria. A large proportion reported that tuberculosis is caused by hard work or it is a hereditary disease.36

The result of this study showed that children and adolescents who smoke cigarettes were three-times more likely to develop tuberculosis infection compared to non-smokers. Findings of this study are in line with another study conducted among older children in Brazil which showed that tobacco smoking has a significant impact on tuberculosis infection.8 In a cross-sectional population survey in South Africa, data on smoking and tuberculin skin test (TST) results of 2401 respondents aged 15 years and above were compared. Out of 1309 current or ex-smokers, 1070 (82%) had a positive TST indicating that cigarette smoking increases the risk of M. tuberculosis infection.37 Another case-control study on the association between tobacco smoke and tuberculosis among children in Thailand revealed that children who were also exposed to tobacco smoke were almost four times more likely to get tuberculosis infection compared to the unexposed group.38 Smokers were more likely to develop tuberculosis due to pathophysiological changes in their respiratory pathway. Smoking not only induces local anatomical disruption, but it also elicits a complex immunological response among smokers.39 A likely explanation is that nicotine turns off the production of TNF-a by the macrophages in the lungs, rendering the patient more susceptible to the development of progressive disease from latent M. tuberculosis infection.40

Multivariable analysis showed no significant association (p = 0.073) between HIV status and tuberculosis infection among children and adolescents, after controlling potential confounding factors. This finding was in agreement with a study in rural Eastern Uganda, which also projected there was no significant association between HIV status and tuberculosis infection among children and adolescents.19 However, it is well-known from previous studies that tuberculosis is among the commonest opportunistic infection in HIV-infected patients.41 HIV-positive people are 20–30 times more likely than HIV-negative people to develop tuberculosis in countries with a generalized HIV epidemic. Tuberculosis is also a major cause of morbidity in HIV-infected children. HIV-infected children have a 20–25-fold higher incidence of contracting tuberculosis than uninfected children, with an overall tuberculosis incidence in South African HIV-infected children of 9.2% (95% CI: 0.14–0.97).42

Among limitations of the study are its small sample size of HIV-positive patients and limited samples from other ethnicities besides Malay. Moreover, the use of a cross-sectional study design may only reveal the association between sociodemographic and clinical factors with tuberculosis rather than a proper sequence of cause and effect.

Conclusion

The most common of tuberculosis disease among pediatric patients in Kelantan was the pulmonary form and sputum smear-positive. The identified risk factors for tuberculosis were older age, female gender, good education level, rural residence, and cigarette smoking. Our study widens the comprehension and understanding of the epidemiology of tuberculosis among pediatric patients and its associated factors. Future cohort studies including a wider range of other factors such as nutritional status, social factors (specifically household condition), and molecular level factors contributing to tuberculosis disease are needed. It is hoped that the findings from this study may assist health authorities to design a better and comprehensive plan for national tuberculosis control, focusing more attention towards the pediatric age group.

Disclosure

The authors declared no conflicts of interest. No funding was received for this study.

Acknowledgements

The authors would like to thank the Director General of Health Malaysia for allowing us to perform data collection from TBIS database for tuberculosis. Ethical approval was obtained from Ministry of Health. Our gratitude also goes to the Kelantan Tuberculosis and Leprosy Control Unit for their assistance during data collection.

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