Abstract
Purpose
Multidrug resistant tuberculosis is an emerging problem in many parts of the world. The aim of this study was to determine the drug resistance pattern of Mycobacterium tuberculosis complex in Oromia Region of Ethiopia.
Patients and Methods
A cross-sectional study was conducted from Jan 2017 to June 2018 on 450 pulmonary tuberculosis patients who visited health facilities in nine administrative zones of Oromia Region. Socio-demographic characteristics and relevant clinical information were obtained using a structured questionnaire. Line Probe Assay for first and second line drugs was used to assess the pattern of drug resistance. SPSS version 20 was used for statistical analysis.
Results
Median age was 26 years and 240 (53.3%) patients were males. About 24% of them were previously treated for tuberculosis. Thirty-four (7.6%) were HIV co-infected. Line Probe Assay interpretable results were obtained for 387 isolates. Thirty (7.8%) were resistant to rifampicin and isoniazid and thus were multidrug resistant isolates. Among the multidrug resistant samples, three were found to be extensively drug resistant and one was pre-extensively drug resistant. Previous treatment history (AOR 9.94 (95% CI 3.73–26.51), P < 0.001) and nutritional status below normal (AOR 3.15 (95% CI 1.13–8.81), P < 0.029) were found to be associated with multidrug resistance. The chi-square tests have shown that there was a significant difference between the BCG vaccinated and the non-vaccinated in developing multidrug resistant tuberculosis at P = 0.027.
Conclusion
The proportion of multidrug resistance is above the WHO estimate for the country, Ethiopia, and the fact that some zones were at risk of transmission of extensively drug resistant tuberculosis warrant great attention of the control program holders even though it has to be verified through the conventional method.
Keywords: line probe assay, multidrug resistant tuberculosis, extensively drug resistant tuberculosis, Oromia
Introduction
Tuberculosis (TB) is a worldwide problem. Ethiopia is one of the 30 high TB burden countries with the best estimate of incidence of 165,000 cases with HIV positive TB incidence of 7600 and HIV prevalence in incident TB cases of 4.6% in 2018. The emergence of resistant strains of Mycobacterium tuberculosis (MTB) has created a major threat to the control of TB.1,2 Ethiopia is now one of the 30 high multidrug resistant/Rifampicin resistant-TB (MDR/RR-TB) burden countries as well and the level of MDR/RR-TB in Ethiopia shows an increasing trend which still calls for serious intervention.2,3
Estimation of the actual prevalence of extensively drug resistant TB (XDR-TB) or pre-XDR cases in Ethiopia is not yet well known;3 therefore, 0.71% of new TB cases and 16% previously treated MDR/RR-TB cases notified in the reporting year of 2018 are used as estimated burden of resistance to anti TB drugs.2 Moreover, due to the lack of national capacity to perform universal drug sensitivity testing (DST) for all incident TB cases, it is difficult to secure early diagnosis and administration of appropriate therapy in quite significant number of health facilities.4
According to the World Health Organization (WHO) Global TB Report of 2019, estimated TB mortality rate of Human Immune-deficiency Virus (HIV) negative cases in 2018 for Ethiopia was 20–39 per 100,000.2 Though the contribution of HIV infection in TB patients to the development of anti-TB drug resistance is not clear, in recent years, infection with HIV denotes a major risk factor predisposing for opportunistic infections and TB is the most common cause of acquired immune-deficiency syndrome (AIDS) related deaths.5 Drug resistance in TB is a matter of great concern for TB control programs because resistant strains could spread around the world, stressing the need for additional control measures, such as new diagnostic methods, better drugs for treatment, and a more effective vaccine.6–9 The need for additional control measures, on top of the problems related to the prevalence of drug susceptible TB, is one of the health priorities which may compromise the progress of other development agenda of the country.
To contain the spread of drug resistant tuberculosis, early detection of resistance of any kind (RR, MDR, or XDR is crucial when resistance is suspected to decide on the timely management of a TB case and this necessitates the use of newer diagnostic methods for DST.10–12 It is also important to know a drug resistance pattern of a certain area to take appropriate action in the prevention and management of TB for an effective control program.13,14
The purpose of this study was to determine the drug resistance pattern of MTB strains isolated from smear-positive pulmonary TB patients in Oromia, the biggest region of the country, to indicate the importance of appropriate action as a public health measure and to contribute to the effective control of resistant tuberculosis.
Patients and Methods
Study Design, Area, Period, and Setting
Health institution-based repeated cross-sectional design was used in order to perform the present study. Oromia region, the study area, is one of the 10 regional states of the Federal Republic of Ethiopia with a population of about 40 million. In 2017, the region is divided into 22 administrative zones, 19 town administrations, and 337 woredas (sub zones). There were 112 hospitals, 1405 health centers, 5930 health posts. Data were collected during the period between January, 2017 and June, 2018.
Study Population and Subjects
Individuals visiting health centers and hospitals located in nine zones of the Oromia Regional State for ill health and were diagnosed with pulmonary TB constitute the study population.
Sampling Method and Sample Size
It was decided to include nine zones, 21 sub zones, and 32 health facilities to recruit 450 study participants. Study participants were selected according to their arrival for clinical consultation until the estimated sample size was obtained. The sample size was determined based on the resource available, accessibility of health facilities, population size of the study area, and sample size of previous studies on drug resistance patterns in the neighboring regions.
Inclusion Criteria
Patients who were considered to be study participants have fulfilled the following requirements: Newly diagnosed pulmonary TB, volunteer to give consent or assent through guardian and permanently residing in the study area.
Exclusion Criteria
Patients with the following characteristics were excluded from the study: Being on anti-TB treatment for more than 2 weeks, admission to hospital (to not expose data collectors to the in-patient environment), and permanent address out of the study area.
Data Collection Instrument and Process
Development and Testing of the Data Collection Instrument
The data collection instrument was developed after reviewing methodologies of several relevant literatures and considering the research questions to be answered. In this regard, structured, prepared in English language and pretested interviewer administered questionnaires were used to collect data on basic socio-demographic characteristics as well as clinically relevant factors after a case is labeled as pulmonary TB by a clinician based on the National TB and Leprosy Control Program Guideline.15
Interview
After informed consent, questionnaires were administered by the trained data collectors in local language. The data collectors were skilled laboratory technicians, nurses, or public health workers.
Sputum Collection
Each eligible client was instructed to bring morning sputum (3–5 mL) in a sterile plastic tube of 50 mL capacity (falcon tubes) prepared for this purpose. Sputum samples were collected by the laboratory staff and were shared between the diagnostic and research teams. Then stored in the health facility's laboratory for a maximum of 2 days in a temperature range of 2–8 °C until transported to Adama Public Health Research Laboratory (APHRL) for culture and DST. Sputa were collected before chemotherapy is started or at least not beyond two weeks of treatment because treatment can reduce the chance of having a positive culture result for tubercle bacilli.
Sample Transportation and Storage
Samples were transported under triple package in ice pack carriers maintaining the cold chain to the APHRL until the required number of samples was obtained. The preparation and packing of the specimen complied with the national standard operating procedures for biological sample transportation.16 The triple packaged samples with participant data were transported to the APHRL through the sample transportation (postal) system within a maximum of three days after the sputa collection.
Staining, Culture, and Identification
Staining of Acid Fast Bacilli (AFB), Ziehl-Neelsen (ZN) staining was done for every sample to be cultured to confirm the sputum smear positivity according to WHO guideline.17
Sputum Culture
Samples that were found to be smear-positive with ZN staining method were cultured on to Lowenstein Jensen (LJ) and Mycobacterial Growth Indicator Tube (MGIT) media according to the WHO guideline.18
The LJ medium culture was incubated at 37 °C and read weekly for eight weeks. Positive results were determined weekly and if there is no growth at the end of 8th week, the result was considered negative. Contaminated cultures were recorded as “contaminated” in the laboratory form.
MGIT was incubated in Middle Brook 7H9 medium on MGIT machine and the result was flagged as negative or positive on the machine. MGIT positive cultures were tested on blood agar and ZN staining to assess if contaminants exist.
Identification of Mycobacterium tuberculosis Complex
An immune-chromatographic assay (CapilaTM TB-Neo version 6.0. Tauns Laboratories, Inc. Japan)19 was used to differentiate MTB complex (MTBC) from non-tubercular mycobacteria (NTM). It can detect the antigens designated as MPB64 in bacterial isolates specifically produced by the MTBC with a high degree of sensitivity, and provides rapid test results (in less than an hour) by a simple operation. H37Rv (ATCC27294) was used as positive control in each set of tests.
Drug Sensitivity Testing
Line Probe Assays (LPA) for First Line Drugs
First line LPA DST was done for all isolates identified as MTBC using Geno Type MTB DR/plus VER 2.0.20 LPA is based on deoxyribonucleic acid (DNA) strip technology and was done in three steps. First, DNA was extracted from MTB isolates. Next polymerase chain reaction (PCR) amplification was carried out using biotinylated primers. Following amplification, DNA was hybridized with specific oligonucleotide probes immobilized on a strip which enables the detection of the presence of MTB, and the presence of wild-type (WT) and mutation probes for resistance to rifampicin and isoniazid simultaneously.
Interpretation
Results were interpreted with the use of reading card. There were three internal controls (CC - conjugation control, HYB; AC - Amplification control MM and amplification program; TUB-MTBC, TB positive or negative) and WT probes. Where all the controls and WT were present, sensitivity declared. Where one or more wild types were missing or one or more wild types were missing with a correlating mutation, resistance was documented.
LPA for Second Line Drugs
Those isolates which were turned out to be MDR (resistant to at least rifampicin and isoniazid) or RR were subjected to second line LPA. Drugs involved were capreomycin, amikacin, kanamycin and viomycin from the injectable, and fluoroquinolones from the oral second line drugs. Molecular genetic assay for identification of the MTBC and its resistance to aminoglycosides/cyclic peptides and fluoroquinolones was performed on cultivated samples according to GenoType MTBDRsl VER 2.0 instruction for use.21 The positive control, DNA obtained from the standard H37RV strain and one negative control was also tested in each batch in order to check the cross-contamination during hybridization.
Evaluation and Interpretation
The test was considered valid, only when the hybridization bands were obtained on MTBC control (TUB), conjugate controls (CC) and the amplification controls (AC) along with the targeted gene loci controls.22 There are also WT reaction zones which comprise regions of the genome with known resistance mutations and the MUT reaction zones corresponding to probes that identify the most common resistance mutations of the gene cross-examined. If a WT band was missing or if a MUT band was present, it was taken as an indication of a resistant strain. The resistance status was determined and noted down in the respective column. However, possibility of mutations (resistance) of the strains outside the regions covered by the test cannot be ruled out.
Statistical Analysis
The statistical analysis was performed using SPSS version 20. Descriptive statistics were used to depict the socio-demographic, clinical history, and nutritional status. Bivariate and multiple logistic regression models as well as Chi- square tests were used to test for possible associations between variables.
Operational Definitions
MDR isolate: Is an isolate that is found to be resistant to at least isoniazid and rifampicin.
New TB case: Smear-positive pulmonary TB patient who has never taken anti-TB drugs or has been on TB drug treatment for less than four weeks in previous episode.
Previously treated TB case: Is a patient who has a history of anti-TB drug treatment for at least four weeks for previous episode.
Pre-XDR isolate: Is an isolate that is MDR plus resistant to at least one of the fluoroquinolones (levofloxacin, moxifloxacin, ofloxacin, ciprofloxacin, gemifloxacin) or at least to one of the second-line injectable agents (kanamycin, amikacin, capreomycin).
RR isolate: Is an isolate that is resistant to rifampicin but not to isoniazid with or without being resistant to any other anti-TB drugs.
XDR isolate: Is an isolate that is MDR plus resistant to at least one of the fluoroquinolones and at least to one of the second-line injectable.
Results
Socio-Demographic Characteristics of the Study Participants
The socio-demographic data of the study patients is presented in Table 1. A total of 450 patients were recruited into the study. The majority of the study participants were within the age group of 18–28 years. The age range and median age were 4–81 years and 26 years respectively. The sex composition was approximately equal. Geographically, more than two-thirds of the study population (68%) were from East-Shewa, Arsi, Bale and Guji zones in decreasing order. Patients who were not able to read and write and those who were farmers living in rural areas dominate the study population. More than a quarter of the patients live in a house with no window and yet the majority of the participants use wood, cow dung, and/or charcoal for cooking. About one third of them have a family size of greater than four and a similar number of them have only one room to live in.
Table 1.
Characteristics | N (%) | |
---|---|---|
Age (years) | <18 | 52(11.6) |
18–28 | 203(45.1) | |
29–39 | 106(23.6) | |
40–45 | 55 (12.2) | |
>50 | 34 (7.6) | |
Sex | Male | 240(53.3) |
Female | 210(46.7) | |
Address (Zones) | North Shewa | 37(8.2) |
South West Shewa | 28(6.2) | |
East Shewa | 92(20.4) | |
Arsi | 88(19.6) | |
West Arsi | 24(5.3) | |
Bale | 64(14.2) | |
Guji | 60(13.3) | |
Borena | 25(5.6) | |
West Harerge | 32(7.1) | |
Education status | Cannot read and write | 169(37.6) |
Read and write | 88 (19.6) | |
Elementary school | 146 (32.4) | |
Secondary school | 31 (6.9) | |
College and above | 16 (3.6) | |
Occupation | Farmer | 160 (35.6) |
Merchant | 17(3.8) | |
Government employee | 10 (2.2) | |
Student | 84 (18.2) | |
Others** | 178(39.6) | |
Residence | Urban | 174(38.7) |
Semi-urban | 21 (4.7) | |
Rural | 255(56.7) | |
Window | Yes | 318 (70.7) |
No | 128 (28.4) | |
Homeless | 4 (0.9) | |
Source of energy | Wood cow-dung charcoal | 435(96.7) |
Kerosene | 4 (0.9) | |
Electricity | 8 (1.8) | |
None | 3 (0.9) | |
Family size | Lives alone | 10 (2.2) |
1–4 | 298 (66.2) | |
>4 | 142 (31.6) | |
Number of rooms | No room | 4(0.9) |
One | 159 (35.3) | |
Two | 232 (51.6) | |
Three | 42 (9.3) | |
Four | 11 (2.4) | |
Five | 2 (0.4) | |
Number of meals per day | Three and above | 380 (84.4) |
Less than three | 13 (2.9) | |
No regular meal | 57 (12.7) |
Notes: Others** indicates housewife, Daily laborer, or jobless.
Information Pertaining to Clinical History of the Patients
According to the clinical information obtained from the patients, a quarter of them were previously treated as pulmonary TB patients for at least 4 weeks but were currently having a similar episode. Of the previously treated cases, more than half of them were not cured of the last previous episode while about three fourths of them had developed the symptoms again within one year. Of the total patients, quite a significant proportion of the patients sought modern treatment after about 4 weeks of symptoms; but some of them tried traditional medicine. History of close contact to known TB cases or chronic coughers and HIV serum positivity were documented in some patients. More than half of all the subjects had fallen within the under-nutrition range of body mass index and very few of them were overweight (Table 2).
Table 2.
Clinical Characteristics | Number (%) | |
---|---|---|
Category of tuberculosis treatment history | New | 343 (76.2) |
Prev treated | 107 (23.8) | |
Duration of adherence to treatment after 4 wks | <6mo | 55(51.4) |
(n = 107) | >or= 6mo | 46 (43.0) |
Unknown | 6 (5.6) | |
Treatment outcome of prev treated | Cured | 42(39.3) |
(n = 107) | Not cured | 59 (55.1) |
Unknown | 6 (5.6) | |
Historyofclosecontactwithchronic cougher | No | 368 (81.8) |
Yes | 82(18.2) | |
Duration of illness before medical treatment | < 1mo | 137 (30.4) |
1−2mo | 225(50.0) | |
>2mo | 88 (19.6) | |
Used traditional medicine | No | 397 (88.2) |
Yes | 53 (11.8) | |
HIV serum status | Negative | 404 (89.8) |
Positive | 34 (7.6) | |
Unknown | 12 (2.6) | |
BCG vaccination status | Not Vaccinated | 322 (71.6) |
Vaccinated | 112 (24.9) | |
Do not remember | 16 (3.6) | |
Nutritional status (BMI*) | Severe UW | 40 (8.9) |
Moderate UW | 52(11.6) | |
Mild UW | 140 (31.1) | |
Normal | 213(47.3) | |
Overweight | 5(1.1) |
Abbreviations: BMI*, body mass index; UW, underweight.
Drug Sensitivity Testing
Sensitivity Pattern to Isoniazid and Rifampicin
Of all the 450 smear positive samples collected from the study sites and cultured on both LJ and MGIT media 402 (89.3%) were successfully grown while 48 (10.7%) were either contaminated or culture negative. All the culture positive isolates were examined by Tauns Capilia tuberculosis-Neo Test for species identification and 6 were found to be NTM and excluded. In the first round, the remaining 396 samples were tested using LPA to the two main first line drugs, isoniazid and rifampicin. Of these 396 isolates tested using LPA, invalid test results were obtained for nine while interpretable results were obtained for 387 isolates; 350 of them were susceptible to both drugs, seven (1.8%) were resistant to either rifampicin (3 isolates) or isoniazid (4 isolates) while the remaining 30 (7.8%) were resistant to both drugs and thus were MDR isolates. Highest percentage of MDR-TB was observed among the age group of 18 to 39. Over 60% of the MDR was observed in four of the nine zones. These include East Shewa, West Arsi, Bale and West Harerge (Table 3). Among the previously treated and those who were not cured and whose DST results were available, 17/44 (38.6%) were found to be MDR cases. It was only 4 out of 35 (11.4%) in the cured ones. Only 47 patients reported the use of traditional medicine of any kind and 2 of them became MDR cases on DST.
Table 3.
Non-MDR-TB Number | MDR-TB Number (%) |
Total | |
---|---|---|---|
Total | 357 | 30(7.8) | 387 |
Age group (years) | |||
<18 | 45 | 0 (0) | 45 |
18–28 | 157 | 15 (8.7) | 172 |
29–39 | 82 | 10(10.9) | 92 |
40–50 | 48 | 3 (5.9) | 51 |
>50 | 25 | 2 (7.4) | 27 |
Sex | |||
Male | 195 | 17 (8.0) | 212 |
Female | 162 | 13 (7.4) | 175 |
Zone | |||
North Shewa | 29 | 2 (6.4) | 31 |
South-West Shewa | 25 | 1 (3.8) | 26 |
East Shewa | 63 | 5 (7.3) | 68 |
Arsi | 80 | 3 (3.6) | 83 |
West-Arsi | 17 | 5 (22.7) | 22 |
Bale | 41 | 5 (10.9) | 46 |
Guji | 54 | 4 (6.9) | 58 |
Borena | 23 | 0 (0) | 23 |
West-Harerge | 25 | 5 (16.7) | 30 |
Residence | |||
Urban | 124 | 14 (10.1) | 138 |
Semi-urban | 16 | 0 (0) | 16 |
Rural | 217 | 16 (6.9) | 233 |
Nutritional status | |||
Severe under nutrition | 31 | 3 (8.8) | 34 |
Moderate under nutrition | 41 | 6 (12.8) | 47 |
Mild under nutrition | 96 | 14 (12.7) | 110 |
Normal | 186 | 7 (3.6) | 193 |
Over weight | 3 | 0 (0) | 3 |
HIV status | |||
Negative | 320 | 27(7.8) | 347 |
Positive | 27 | 3 (10) | 30 |
Unknown | 10 | 0 (0) | 10 |
Treatment history | |||
New | 298 | 8 (2.6) | 306 |
Previously treated | 59 | 22 (27.1) | 81 |
Sensitivity Pattern of MDR/RR-TB Cases to Second Line Anti-TB Drugs
The cases found to be MDR-TB with LPA (Geno-Type MTBDRplus Version 2.0) and the three RR cases were further tested for the second line drugs using LPA (Geno-Type MTBDRsl Version 2.0). As a result, among the 30 MDR isolates, three of them were found to be extensively drug resistant (XDR) and one was pre-XDR. Out of the 33 cases (MDR and RR) tested for second line drugs, 23 (69.7%) were sensitive to all the second line drugs tested. One of the three RR but sensitive to isoniazid was resistant to all second line drugs (poly-resistant), the second one was sensitive to all (mono-resistant), and the third one was sensitive only to fluoroquinolones (poly-resistant). Some of the characteristics of patients with XDR-TB are described in Table 4.
Table 4.
1 | 2 | 3 | 4 | |
---|---|---|---|---|
Sam. code | BH170 | BH302 | BH486 | BH303 |
Age (yrs) | 22 | 35 | 34 | 24 |
Sex | Male | Female | Male | Male |
Zone | W/Harerge/Oda Bultum 31 | W/Harerge/Chiro | East Shewa/Bushoftu | Arsi/Robe Dide’a |
Residence | Rural | Rural | Urban | Rural |
Education | Elementary | Cannot read and write | Elementary | Cannot read and write |
Occupation | Farmer | Farmer | Daily laborer | Farmer |
Contact history | None | None | None | None |
Previous treatment | New | Previously treated | Previously treated | New |
Nutritional status | Mildmalnutrition (UW) | Moderate malnutrition (UW) | Moderate malnutrition (UW) | Normal |
HIV status | Negative | Negative | Negative | Negative |
Resistance | XDR | XDR | XDR | Pre-XDR |
Bivariate logistic regression model analysis depicts no statistical association at p-value <0.25 between multidrug resistance and age, sex, education, occupation, residence, and HIV serum status. On the other hand, being previously treated, having a history of close contact with a chronic cougher, staying more than two months after onset of illness without getting medical treatment, and nutritional status of under-nutrition were tested for association using multiple logistic regression following bivariate analysis and previous treatment history (AOR 9.94 (95% CI 3.73–26.51), P < 0.001) and nutritional status below normal (AOR 3.15 (95% CI 1.13–8.81), P < 0.029) were found to be associated with multidrug resistance (Table 5).
Table 5.
Characteristics | Total | MDR | COR | 95% CI | P-value | AOR | 95% CI | P-value | |
---|---|---|---|---|---|---|---|---|---|
Age G | <18 | 45 | 0 | – | |||||
18–28 | 157 | 15 | 0.78 | 0.33–1.8 | 0.571 | ||||
29–39 | 82 | 10 | 1 | ||||||
40–50 | 48 | 3 | 0.51 | 0.13–1.93 | 0.328 | ||||
>50 | 25 | 2 | 0.66 | 0.14–3.20 | 0.602 | ||||
Sex | Male | 195 | 17 | 1.09 | 0.51–2.30 | 0.829 | |||
Female | 162 | 13 | 1 | ||||||
Education | Illiterate | 148 | 16 | 1.4 | 0.30–6.47 | 0.672 | |||
Read & write | 74 | 4 | 0.66 | 0.11–3.83 | 0.640 | ||||
Elementary | 125 | 8 | 0.79 | 0.16–3.94 | 0.770 | ||||
Secondary | 25 | 2 | 1 | ||||||
College, above | 15 | 0 | – | ||||||
Occupatn | Farmer | 131 | 12 | 0.73 | 0.08–6.36 | 0.531 | |||
Gov. employee | 10 | 0 | – | ||||||
Merchant | 8 | 1 | 1 | ||||||
Others* | 138 | 13 | 0.75 | 0.09–6.50 | 0.797 | ||||
Residence | Urban | 124 | 14 | 1 | |||||
Semi urban | 16 | 0 | – | ||||||
Rural | 217 | 16 | 1.53 | 0.72– 3.24 | 0.266 | ||||
Treatment | New | 298 | 8 | 1 | |||||
Prev treated | 59 | 22 | 0.72 | 0.03–0.17 | 0.000 | 9.94 | 3.73–26.51 | <0.001 | |
Contact | No | 284 | 29 | 1 | |||||
Yes | 73 | 1 | 7.45 | 0.99–55.63 | 0.05 | 0.18 | 0.22–1.43 | 0.103 | |
DoI* | <1mo | 122 | 3 | 1 | |||||
1–2mo | 180 | 12 | 0.09 | 0.025–0.32 | 0.000 | 1.89 | 0.48–7.38 | 0.362 | |
>2mo | 55 | 15 | 0.24 | 0.11–0.55 | 0.001 | 2.42 | 0.55–10.60 | 0.241 | |
NS* | Severely UN | 34 | 3 | 2.57 | 0.63–10.48 | 0.188 | 2.95 | 0.61–14.20 | 0.176 |
Moderately | 47 | 6 | 3.89 | 1.24–12.18 | 0.020 | 3.41 | 0.98–11.92 | 0.550 | |
Mildly | 110 | 14 | 3.88 | 1.51–9.92 | 0.005 | 3.15 | 1.13–8.81 | 0.029 | |
Normal | 193 | 7 | 1 | ||||||
Overweight | 3 | 0 | – | ||||||
HIV status | Negative | 374 | 27 | 1 | |||||
Positive | 30 | 3 | 0.76 | 0.22–2.66 | 0.667 |
Abbreviations: DoI*, duration of illness before medical treatment; NS*, nutritional status.
The chi-square tests have shown that there was an association between being MDR and no history of BCG vaccination at P = 0.027 where the proportion of those who were not vaccinated and had MDR TB (10%) was significantly greater than those who had a history of vaccination and had no MDR TB (2.1%) (Table 6).
Table 6.
Characteristics | Total N (%) |
MDR N (%) |
Non-MDR N (%) |
P-value | |
---|---|---|---|---|---|
Age | <18 | 45(11.6) | 0(0) | 45(12.6) | 0.239 |
18–28 | 172(44.4) | 15(8.7) | 157(91.3) | ||
29–39 | 92(23.8) | 10(10.9) | 82(89.1) | ||
40–45 | 51(13.2) | 3(5.9) | 48(94.1) | ||
>50 | 27(7.0) | 2(7.4) | 25(92.6) | ||
Sex | Male | 212(54.8) | 17(8.0) | 195(92.0) | 0.829 |
Female | 175(45.2) | 13(7.4) | 162(92.6) | ||
Zones | North Shewa | 31(8.0) | 2(6.5) | 29(93.5) | 0.067* |
South-West Shewa | 26(6.7) | 1(3.8) | 25(96.2) | ||
East Shewa | 68(17.6) | 5(7.4) | 63(92.6) | ||
Arsi | 83(21.4) | 3(3.6) | 80(96.4) | ||
West Arsi | 22(5.7) | 5(22.7) | 17(77.3) | ||
Bale | 46(11.9) | 5(10.9) | 41(89.1) | ||
Guji | 58(15.0) | 4(6.9) | 54(93.1) | ||
Borena | 23(5.9) | 0(0) | 23(100) | ||
West Harerge | 30(7.8) | 5(16.7) | 25(83.3) | ||
Residence | Urban | 138(35.7) | 14(10.1) | 124(89.9) | 0.259 |
Semi-urban | 16(4.1) | 0(0) | 16(100) | ||
Rural | 233(60.2) | 16(6.9) | 217(93.1) | ||
BCG | Not Vaccinated | 280(72.4) | 28(10) | 252(90) | 0.027 |
Vaccinated | 95(24.5) | 2(2.1) | 93(97.9) | ||
Unknown | 12(3.1) | 0(0) | 12(100) |
Note: *Fisher’s exact test.
Discussion
As described in the Results section out of 387 isolates for which DST was done using LPA, 350 of them were sensitive to first line drugs tested, rifampicin and isoniazid. Three isolates were resistant to rifampicin but sensitive to isoniazid and another four isolates were resistant to isoniazid but sensitive to rifampicin. The remaining 30 of the isolates were resistant to both rifampicin and isoniazid being labeled as MDR-TB. This was 2.6% in new cases and 27.1% in previously treated ones with the overall MDR prevalence rate of 7.8%.
The 7.8% MDR prevalence rate was not far from the results seen in a study done in Jijiga town, East Ethiopia with a sample size of 105, which had the prevalence of MDR in new cases, in previously treated cases, and overall of 4.5%, 22.6% and 10.2% respectively.23 Another similar study in Jimma town, South West Ethiopia, with sample size of 112 shows an overall prevalence of MDR of 27.7%.24 Differences here might be explained by the fact that almost all (106/112, 94.6%) of the included isolates were having any resistance, patients were referred from health facilities probably after prior TB treatment. A similar study from Arsi zone of Oromia region, central Ethiopia with sample size of 150, shows an MDR prevalence rate of 3.8% in new cases.25 This zone is one of the zones included in the current study and the overall MDR proportion out of 80 isolates examined was 3.6% which is similar to the finding. According to the surveillance of drug resistance based on reference laboratory data to the national level,26 among 329 isolates tested for first line drugs 5.7% were isoniazid resistant, 6.3% were rifampicin resistant, and MDR was documented in 4.3% of new cases and 6.7% of previously treated cases with the overall MDR proportion of 11.6%. Given the difference in sampling technique and level of study between this surveillance and current study the differences observed in the findings is not out of expectation. In contrast to the current study the finding from southern Ethiopia shows an overall MDR-TB prevalence of 0.8 with no MDR-TB in new cases while it is 14.3% in previously treated cases and no XDR or pre-XDR cases.27 Similarly, reports from the Amhara region, North-West Ethiopia show that the overall proportion of MDR-TB was 5% with 3.7% in new and 10.9% in previously treated cases but no report of XDR-TB or pre-XDR-TB.28 One study from coastal Kenya also revealed an MDR-TB prevalence of 2.6% in new cases and 29.4% in previously treated cases.29 An MDR-TB prevalence of 5.3% in new and 14.7% in old cases was also reported from Sudan.30 Differences could be attributed to differences in methods used, sampling, or the innate existence of resistant cases or the combination of these factors. The global proportion of MDR/RR-TB was estimated to be 3.4% in new and 18% in previously treated cases while that of Ethiopia was 0.7% and 16% respectively.2 If we take this WHO report as a reference, though differences in the methods used exists, it is very likely that Oromia region takes the larger share of MDR/RR-TB burden of the country.
Previously treated patients are those who were diagnosed to have TB and took anti-TB drugs for at least one month in the previous episode. These patients might or might not have completed the intended treatment; might have been declared cured or not. The proportion of previously treated patients was found to be significant; about 24%. It is difficult to establish the reason why this is so with the amount of information extracted from the study participants. However, for those who did not complete the treatment, the reason for quitting treatment could be poor socio-economic status as indicated by the fact that 65/107 (62%) of them were under-nourished and may not afford treatment cost even if they get drugs for free. This may force them to quit drug treatment particularly after the intensive phase (the first 2 months of treatment) when major symptoms could subside without being cured. The other possibility is that some, 13/107 (12.6%), of them resort to traditional medicine after starting proper anti-TB drugs for the same reason stated above or other reasons like side-effects of the drugs. There is also a possibility of missing drug resistant TB cases because not all patients undergo DST at the first visit of their medical consultation. Otherwise, there is no evidence of sub-standard treatment regimen in Oromia. The significance of this proportion of previously treated cases could entail addressing problems related to default from treatment. The importance to address different aspects of the diseases encompassing the host and pathogen features, the need for tailored treatment regimens, as well as the needs to further implement an adequate follow-up based on the available resources are important areas to consider.31,32
The association between a nutritional status below normal and development of resistance to anti-TB drugs could be attributed to the fact that under-nutrition weakens the immunity of the patients33 which can negatively affect the synergetic effect of drugs and nutrition to fight against the M. tuberculosis organisms. With the advancement of control programs addressing factors contributing to the development of drug resistance there will be more achievement in prevention and increased treatment success rate for “End TB strategy” to be effective.
The significant difference in developing MDR-TB between those having a history of BCG vaccination and not vaccinated in favor of those vaccinated could be due to the cumulative effect of multiple immune components on the control of mycobacterial growth as a result of vaccine-induced bacterial growth inhibition in combination with drug treatment following historical BCG vaccination.34,35
The new anti-tuberculosis drugs are a real hope for the management of drug resistant TB and other new therapeutic combinations which address psychosocial and economic aspects of the disease may improve treatment success rate.36
Limitations
LPA used for DST does not cover all the anti-TB drugs and of course it has a lower resolution compared to conventional methods.
Conclusion
The findings from DST indicate that the proportion of MDR and the fact that W. Arsi and W. Harerge were at risk of transmission of XDR-TB warrant great attention of the control program holders though it has to be verified through conventional DST.
Acknowledgment
The authors are grateful to Adama Public Health Research Laboratory and Quality Assurance Center not only to allow conducting the laboratory work but also for their support of all the required materials and Madda Walabu University for its financial support to transport samples.
Abbreviations
APHRL, Adama Public Health Research Laboratory; AOR, adjusted odd’s ratio; CI, confidence interval; COR, crude odd’s ratio; DNA, deoxyribonucleic acid; DST, drug sensitivity testing; FDRE, Federal Democratic Republic of Ethiopia; FMOH, Federal Ministry of Health; LJ, Lowenstein Jensen; LPA, line probe assay; MGIT, mycobacterial growth indicator tube; MDR, multidrug resistant; MTB, Mycobacterium tuberculosis; NTM, non-tubercular mycobacteria; PCR, polymerase chain reaction; RR, rifampicin resistance; TB, tuberculosis; WHO, World Health Organization; XDR, extensively drug resistant; ZN, Ziehl-Neelsen.
Data Sharing Statement
The data are available and can be presented by corresponding author on legitimate request.
Ethics Approval
Ethical clearance was obtained from Health Studies Higher Degree Committee of University of South Africa (Ref No: REC-012714-039, HSHDC/454/2015). The purpose of the study was explained to the study participants and written consents were obtained from each. For those aged less than 18 years, assents were obtained from their parents/guardians in accordance with the Declaration of Helsinki.37
Disclosure
The authors report no conflicts of interest in this work.
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