Effect of TB Therapy on the Health and Nutritional Status of Infants Aged 6 Months to 5 Years Diagnosed with Latent TB ()
1. Introduction
Childhood tuberculosis (CTB) is a very preoccupant public health problem all over the world, and more particularly in developing countries [1] . CTB accounts for about 15% to 40% of all tuberculosis (TB) cases. It is an important sentinel event suggesting a recent infection of infants through a contact with infectious adults in a community [1] [2] [3] [4] [5] . Early detection of CTB in children at high enough risk is useful for initiating preventive chemotherapy to avoid the active TB phase [6] . When screening is done, treatment is recommended for all children and adolescents diagnosed TB positive [7] [8] [9] [10] . This treatment requires strong adherence to prevent drug resistance and ensure good therapeutic results [11] , but other factors such as age, gender, nutrition, and drug-related problems are susceptible to influence the treatment outcome [11] [12] [13] . For nutrition, there is evidence suggesting that malnutrition affects gene expression and immune function and predisposes children to progression of TB; this results in active TB phase and inflammatory response that further worsen nutritional status [12] [13] [14] [15] .
Thus, treatment of latent tuberculosis infection (LTBI) is the most effective strategy to prevent future cases of disease. Most cases of CTB in low-prevalence countries are preventable by screening for risk factors, testing for LTBI, and offering therapy [7] [8] [9] [10] . However, although LTBI therapy has been available and emphasized in rich nations, its use is limited in most resource-limited countries [16] . Various regimens have been used for a decade, but concerns about low completion rates, costs, and increasing rates of drug resistance have prompted research on shorter-course LTBI regimens and the use of combination regimens [17] [18] . The International Union against Tuberculosis and Lung Disease [17] completed a direct comparison of 3-, 6-, and 12-month regimens of INH in 27730 adults with tuberculin skin test (TST) induration > 6 mm and fibrotic pulmonary lesions seen on chest radiograph. During 5 years of follow-up, 1.4% of participants in the placebo group developed TB disease compared with 1.1%, 0.5%, and 0.4% in the 3-, 6-, and 12-month regimen groups, respectively. Among persons taking ≥ 80% of their INH doses, efficacy for the 12-month regimen was higher (0.1% disease progression). Participants receiving the 6-month regimen had a 4-fold higher risk of TB disease than those receiving the 12-month regimen. Similar studies are rare in children. However, Hsu’s observational studies [18] of 2494 children who were treated with INH daily for 1 year and followed on average for 6 years, showed greater than 99% protective efficacy given good adherence. It can be expected that the protective efficacy of INH should be substantially higher in young children because they have higher rates of disease progression without therapy.
A recent study in Kisangani [19] on a cohort of 593 children found a CTB prevalence of 40.3% using Tuberculin Skin Test, chest X-ray, laboratory and clinical investigations. All children diagnosed TB+ received the first line anti-tuberculosis treatment. We designed this paper to describe the symptoms of the disease and the nutritional status of infants aged 6 months to 5 years and measure how preventive chemotherapy for TB can improve health and nutritional status in this group.
2. Methods
2.1. Ethical Issue
The study was conducted according to the guidelines laid down in the Declaration of Helsinki, and all procedures involving patients were approved by the Research Review Committee and Ethical Review Committee of the University of Kisangani N˚05/PED/2013. Written informed consent was obtained from all legal guardians of the children.
2.2. Study Design
The complete protocol has been published elsewhere [19] . In summary (Figure 1), a cross-sectional study was conducted in 2013 to assess the prevalence of TB in children and adolescents 6 months to 17 years of age suspected of being infected with TB, using TST, chest X-ray, and clinical investigation.
Based on the analysis of patient medical records at the Pediatric Village Center of Kisangani University, of 593 children subjected to TST, 187 had a positive result (TST+) and were treated with anti-TB drugs. The 406 children who had a negative TST result were treated with common antibiotics, and of these, 52 did
not respond to antibiotic therapy. All the 187 TST+ and 52 TST− clinically diagnosed as TB+ were subjected to TB therapy with 4 drugs. The four drugs, Rifampicin (R), Isoniazid (H), Pyrazinamide (Z), and Ethambutol (E) were administered as 2(RHZ)7(E)7/7(RH)3: first 2 months (intensive phase) and last 7 months (maintenance phase). To prevent polyneuritis as a treatment-related side effect, vitamin B6 therapy has been consistently associated with anti-TB drugs throughout the course of treatment. For this analysis, the 239 files of children treated for TB were retrieved and only 161 records of children less than 5 years of age, deemed appropriate to provide information on the clinical and nutritional response to treatment, were selected.
2.3. Diagnostic Criteria
Every child or adolescent aged 6 months to 17 years suspected of TB at the health center was eligible. TST was negative when the induration diameter (and not of the erythema) developed at the site of injection was <5 mm. In our case, given that Kisangani is a highly endemic area, there is a high probability of detecting both clinical silent and clinical active infection. A diameter ≥ 10 was considered as active TB while between 5 and 10 was taken roughly as latent form. The criteria for suspicion were promiscuity (more or less than 4 persons sharing a room), contagion (history of living in contagious environment), BCG vaccination (presenting scar or not), chest images (consolidation/opacities, cavitations/cysts, linear opacities/fibrosis, nodules/masses, miliary pattern, lymphadenopathy, pleural abnormalities, trancheobronchial abnormalities, hilar adenopathy and leucocyte formula.
2.4. Nutritional Status
Anthropometry-Body weight and length, or height, are important indications of nutritional status of infants and young children. The nutritional status of children was appreciated by the degree of weight-loss and according to UNICEF-WHO classification which devises stunting by height-for-age index. The ideal weight for each age was estimated by the index (HAZ-score) which was calculated with ENA software for SMART 2011. A child below two standard deviations (−2 SD) from the median of the Child Growth Standards in terms of Weight-for-age was considered bad status [20] .
2.5. Variables
Demographics: Age, sex, residence;
TB infection: TST Sensitivity (TB+/TST+ and TB+/TST−);
Nutritional status: Symptoms: Weight loss;
Health status: Fever, coughs, physical exam, Sedimentation rate (SR): >30 min/h or <30 min/h, asthenia, anorexia, night swears.
2.6. Data Analysis
The data collected was analyzed with Excel Windows and SPSS v20 IBM software. We took underweight as weight 15% below the ideal-weight and fever when body temperature was >37.5˚C. Pearson’s chi-square was used to test the significance of differences at p < 0.05.
3. Results
3.1. Demographic Variables
Table 1 shows demographic variables. The majority came from Makiso health zone (58.39%) followed by Tshopo (18.63%), Kabondo (12.42%), Mangobo (7.45%), Kisangani (2.48%) and Lubunga only (0.62%). In the context of the study, boys and girls are almost equally represented (50.31% vs. 49.69%). The majority of children 73 (45.34%) were less than one year old, followed by 1 - 2 years 49 (30.43%) and 3 - 5 years 39 (24.22%).
3.2. Clinical Diagnosis before Treatment
Table 2 shows clinical investigations before TB chemotherapy. 72% of 161 infants were TST+ and 28% were TST−. About 26.7% were coughing and 64% had high sedimentation rate; the majority (>97%) did not present asthenia, anorexia or night swears. The proportions did not vary significantly by sex or by age. In latent tuberculosis infection (LTBI), clinical warning signs are not well defined.
3.3. Effect of Treatment on Health and Nutritional Status
Table 3 shows the difference in body weight and body temperature before and after treatment. Before treatment, 62.7% had permanent fever (T > 37.5˚C), but after treatment, the score was reduced to 17.4% giving an improvement in 45.3% (p < 0.001). The improvement was not influenced by gender (p = 0.952) or age range (p = 0.121). Similarly, regarding nutritional status, 21.7% were below the ideal weight, and after treatment, the score was reduced to 8.1% giving improvement of 13.6% (p < 0.001). All boys were upper the ideal weight before
Table 1. Demographic characteristics of patients disaggregated by residence, age and sex; N (%).
*Principal residence is Makiso; Majority age is <1 year (p < 0.001); Majority sex is Male.
Table 2. Frequency (%) of Children presenting with indicated symptoms before treatment.
No significant difference (p > 0.05).
Table 3. Body temperature and Body weight before and after Anti-TB treatment.
(ab): after-before; (mf): male-female; (ag): (age group).
treatment, but 4.9% became underweight at the 5th month of treatment; 43.8% of girls were underweight before treatment, and 11.3% after treatment giving improvement in 32.5%. The difference between boys and girls for weight is statistically significant (p < 0.001). Concerning the age, before treatment 47.9% of infants < 1 year were underweight while no one was underweight in the group > 1 year. After treatment, only 5.5% of infants < 1 year remained underweight giving improvement of 42.4%. However, in the group > 1 year, 8.2% - 12.8% lost weight.
The general physical observation indicated that around 90% of infants were clinically in well health after treatment compared to the situation before treatment. Some patients presented complications and have been transferred to specialized health facilities.
3.4. Limitation
This study was not a highly randomized trial. Also the sample size is limited. However, the finding constitutes interesting starting point for an extended study over all the provinces of the country.
4. Discussion
The high prevalence of infants from Makiso health zone is due to the proximity of this zone with the healthcare facility that received children for screening and also because this HZ is the municipality that offers a lot of commercial activities compared to others; this may drain a lot of people including bacilliferous coughers as source of infection for children.
The distribution of the sample by gender and age showed that the risk of developing TB in infants is the same for both boys and girls even though slightly biased to males (OR = 1.01). Generally, infectious diseases rarely affect males and females equally and tuberculosis is no exception [21] . Globally in adult persons, far more men than women are significantly at risk of contracting and dying from TB. According to the WHO report 2013, the degree of male bias varies by geographic location and by year [22] . Considering the overall trends in the 20 high-burden countries for which data are available, the median male-to-female ratio is 1.8:1, with only Afghanistan reporting a ratio of <1:1. The consistent global trend for male bias in tuberculosis has been attributed to environment factors as well as to biological or physiological differences [22] [23] [24] . Smoking, alcohol drinking, travelling and place of work expose men to TB while hormonal system may protect women. In children under-5, those risk factors are less likely to apply.
The incidence of TB in this study decreased inversely with age, 45.3% in children < 1 year of age, 30.4% in 1 - 2 years old and 24.2% in 3 - 5 years old; this is consistent with the concept of age pyramid. Many studies have found that the lower is the age, the higher is the risk for a child exposed to have a TB infection [1] [3] [19] . The predominance of children under one year of age confirms the vulnerability of this period of childhood development in relation with the immaturity of cellular immunity [25] . It has been reported that among children under 1 year of age, approximately 30% - 40% may progress from primary infection to active disease; for children aged between 1 and 5 years old, this risk is approximately 24%; the risk of progression declines slowly beyond 5 years and increases again at around 10 years of age [25] [26] [27] . The risk factors for progression from primary infection to disease include duration and burden of exposure, the virulence of the mycobacterial strain, HIV infection or other clinical conditions that impair the immune system, malnutrition, and exposure to tobacco smoke [28] .
The general functional signs found in adults TB patients are fever (38˚C), profuse nocturnal sweating, anorexia, asthenia, chronic cough with sputum, chest pain and/or dyspnea [1] [2] . Among the functional or physical signs found in this study, more than 98% had no asthenia, anorexia, perspiration; only the prevalence of fever, loss of weight and elevation of sedimentation rate were significantly indicative signs of the disease. It is known that the diagnosis of TB in children is difficult because it presents poor and almost atypical symptomatology and also because of its paucibacillary character [19] . In latent tuberculosis infection (LTBI), the presence of TB disease symptoms is almost absent and the mycobacterium may also be absent in well-contained media such as cervical adenitis. In this case only the TST or calcified lymph node on chest radiograph (CXR) may be the only evidence of prior TB infection [29] [30] [31] . In clinical practice, the diagnosis requires a systematic approach that comprises 3 fundamental steps: 1) clinical history and detailed physical examination; 2) imaging evaluation and 3) identification of the pathogen [32] . New diagnostic methods are promising such interferon-gamma assay [32] [33] .
For the treatment, there are 2 main options for chemotherapy: 9 or 6 month regimen [34] [35] [36] [37] . The 9-month regimen is preferred because it is more effective. The Centers for Disease Control and Prevention (CDC) has issued updated recommendations regarding the use of 3HP (once-weekly isoniazid-rifapentine for 12 weeks). The CDC expanded its recommendation for the 3HP regimen for the treatment of LTBI to include patients aged 2 to 11 years old; patients with comorbid HIV infection (including AIDS) who are taking antiretrovirals with acceptable drug-drug interactions with rifapentine, and as either DOT or self-administered therapy (SAT) in those ≥ 2 years old. WHO recommends the following dosages of antituberculosis drugs for the treatment of tuberculosis in children [38] : isoniazid (H) −10 mg/kg (range 10 - 15 mg/kg); maximum dose 300 mg/day; rifampicin (R) −15 mg/kg (range 10 - 20 mg/kg); maximum dose 600 mg/day; pyrazinamide (Z) −35 mg/kg (30 - 40 mg/kg); ethambutol (E) −20 mg/kg (15 - 25 mg/kg). The selection of a 3-drug or 4-drug regimen is based on the location of tuberculosis, risk of isoniazid resistance and prevalence of HIV [39] . To treat TB+ children in this study, the standard treatment regimen (first-line anti-tuberculosis drugs) which included rifampicin, isoniazid, pyrazinamide and ethambutol for the first 2 months and only rifampicin and isoniazid at the continuation phase was applied. This scheme is recommended when resistance to the usual isoniazid is suspected [40] . We have used this scheme as at priory we could not discriminate sensitive and resistant cases. We also systematically added Vitamin B6 to prevent isoniazid peripheral neuropathy side effect that occurs especially in malnourished children and in slow acetylors [40] [41] [42] .
Globally, the clinical treatment outcome was good in more than 90% of cases. This result demonstrates that the success of chemotherapy for antitubercular prophylaxis is maximal in children [12] . This success is explained by a good adherence to treatment, which is due to the rarity of side effects in children [40] . The intervention reduced the prevalence of fever as well as that of underweight. The proportions of children with temperature > 37˚C decreased from 62.7% before to 17.4% after treatment. The underweight varied almost in the same order from 21.7% to 8.1%. The good outcome was noted in both TST+ and TST-children. The good response noted in children TST negative demonstrates that some children with TB have not been diagnosed with TST probably because of their state of skin anergy. This is common in cases of malnutrition or HIV infection and may be due to immunodeficiency12. However, 100% of males were upper ideal weight before treatment but 4.9% went underweight during treatment; 47.9% of children < 1 year were underweight while no one was underweight among older before treatment. Finally, 4.9 to 12.8% could have lost weight during treatment; the reason was not defined, but perhaps they were not responding to the treatment [43] .
5. Conclusion
There is a significant statistical difference between pre-treatment and post-treatment values. Girls under one year of age are at higher risk of fever and malnutrition during the pre-phase of active tuberculosis. The study highlights that TST remains the most useful tool for quickly diagnosing TB in children. Children under 5 years of age are most at risk of developing active TB in an endemic environment. The first-line anti-tuberculosis drugs still work for the management of childhood tuberculosis. Since the metabolic rate of isoniazid may be slow leading to peripheral polynevritis, vitamin B6 may be combined to the treatment regimen.