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Bacterial Etiologies of Ear Infection and Their Antimicrobial Susceptibility Pattern at the University of Gondar Comprehensive Specialized Hospital, Gondar, Northwest Ethiopia: A Six-Year Retrospective Study

Authors Getaneh A , Ayalew G , Belete D , Jemal M, Biset S 

Received 2 August 2021

Accepted for publication 9 October 2021

Published 20 October 2021 Volume 2021:14 Pages 4313—4322

DOI https://doi.org/10.2147/IDR.S332348

Checked for plagiarism Yes

Review by Single anonymous peer review

Peer reviewer comments 3

Editor who approved publication: Prof. Dr. Héctor Mora-Montes



Alem Getaneh, Getnet Ayalew, Debaka Belete, Mohabaw Jemal, Sirak Biset

Department of Medical Microbiology, School of Biomedical and Laboratory Sciences, University of Gondar, Gondar, Ethiopia

Correspondence: Sirak Biset 196 Tel +251-911-598-568
Email [email protected]

Background: An ear infection is responsible for up to 40% of preventable hearing impairment; one of the reasons for frequent and unwise antibiotic usage, especially in the developing world. Since the incidence of antibiotic resistance is increasing, especially in resource-limited countries, up-to-date knowledge on the susceptibility of ear-discharge isolates to antibiotic is important for better patient treatment. Therefore, this study aimed at determining the bacterial etiologies and their antibiotic susceptibility profiles among patients suspected with ear infections.
Methods: We collected retrospective data from bacteriological results of ear discharge samples from 2013 to 2018. Sample collection, culture preparation, and bacterial identification were performed using standard microbiological techniques. Antimicrobial susceptibility testing was performed following Clinical and Laboratory Standard Institute (CLSI) guidelines. We extracted and inputted the data using Epi-info version 7 and exported it to SPSS version 20 for analysis.
Results: The overall ear-discharge culture positivity rate was 283/369 (76.7%) (95% CI = 72.4– 81.3), with 14/283 (4.95%) mixed infections. Staphylococcus aureus (27.9%), Proteus spps (20.8%), Streptococcus spps (10%), and Pseudomonas spps (8.92%) were the main isolates. High-level resistance rates for tetracycline (77.6%), penicillins (67.2%), erythromycin (52.6%), and co-trimoxazole (52%), and low-level resistance rates for fluoroquinolones (23.3%), aminoglycosides (23.7%), and cephalosporins (29.8%) were observed. More than 45% of isolates, with 50.9% of Gram-negative and 37.3% of Gram-positive, were multidrug-resistant.
Conclusion: Staphylococcus aureus, Proteus mirabilis, Proteus vulgaris, Escherichia coli, and Pseudomonas aeruginosa were the leading cause of ear infections. The presence of high number of multidrug-resistant strains calls for the need for periodic and continuous follow-up of antibiotic usage in the study area. Further studies are recommended to explore the types of ear infections, with their etiologic agents and possible risk factors.

Keywords: ear infection, bacterial etiologies, antibiotic susceptibility, Gondar, Ethiopia

Background

Worldwide, there are more than 360 million people with disabling hearing loss. Over 60% of this hearing loss could be preventable, and infection is responsible for up to 40% of this preventable hearing loss.1–6 Ear infection can occur in the outer (Otitis Externa (OE)), middle (Otitis Media (OM)), or inner (Otitis Interna (OI)) parts of the ear.7–9 Otitis media or inflammation of the middle ear is the most common and significant disease in the world; it can be suppurative, acute OM (AOM) and chronic OM (COM), or non-suppurative, OM with effusion (OME).10–12 Acute otitis media (AOM), COM, and OME are common problems affecting many peoples, especially young children.13–15 Acute otitis media (AOM) is the presence of fluid along with a rapid onset of signs and symptoms of inflammation in the middle ear.13,16 Otitis media with effusion (OME) is the presence of ear effusion in the absence of acute infection14 whereas, COM is defined when ear effusion (fluid) remains in the middle ear for a long time.15 The etiologies of ear infections can be bacteria, viruses, or fungi. However, bacteria such as Pseudomonas aeruginosa (P. aeruginosa), Staphylococcus aureus (S. aureus), Streptococcus pneumoniae (S. pneumoniae), Streptococcus pyogenes (S. pyogenes), Haemophilus influenzae (H. influenzae), and Proteus species are predominantly responsible for the infection.8,17,18

Upper respiratory tract infection, previous history of AOM, low social status, passive smoker, poor nutrition, and others can be risk factors for OM.19 Untreated AOM can also be a risk factor for COM, eardrum perforation, facial nerve paralysis, meningitis, or mastoiditis.20

Antibiotics can help treat bilateral AOM and both AOM and discharging ear among children aged < 2 years of age. Even though health care practitioners use antibiotics to treat children with AOM, they are not usually the answer to treat the condition.21,22 In addition, in low-income countries, most antibiotics are not ordered based on results from culture and antibiotic susceptibility testing (AST). As a result, misuse or overuse of antimicrobial agents, which facilitates the emergence of antimicrobial resistance, is prevalent in these areas.23,24 Furthermore, most health practitioners in these areas are not aware of the antibiotic-resistant pattern in their health facilities.25 Thus, ensuring proper patient care is impossible if clinicians do not practice appropriate antibiotic use based on the AST results and halt the continuous emergence of resistant bacteria due to antibiotic misuse or overuse.26

In Ethiopia, prospective and retrospective studies on the bacterial etiologies of ear infection and their antibiotic susceptibility pattern (ASP) are present.27–31 Those studies reported that S. aureus, P. aeruginosa, Proteus species, and other lactose fermenter Gram-negative bacteria (GNB) are the predominant ear discharge isolates. Moreover, a significant number of isolates reported by these studies were multidrug resistant (MDR), which is defined as acquired non-susceptibility to at least one antibiotic in three or more antimicrobial classes.32 Despite these studies in different parts of Ethiopia, there is still limited published data on the epidemiology of bacterial ear infections and their ASP in the study area.

Materials and Methods

Study Design, Area, and Period

A hospital-based retrospective study was conducted from 1st Jan 2013 to 30th Dec 2018 at the University of Gondar Comprehensive Specialized Hospital (UoGCSH), Northwest Ethiopia. This hospital is the only specialized hospitals in Gondar town and one of the biggest teaching hospitals in the Amhara region. It provides inpatient and outpatient services for more than 5 million populations.

Study Participants

The study participants were all patients suspected of ear infections and whose ear-discharge samples were provided and analyzed in the bacteriology laboratory of the UoGCSH during the study period.

Data Collection

We did a retrospective review of six-year laboratory records of all ear swabs taken from patients suspected of having ear infections from all departments and units of the UoGCSH. We collected demographic characteristics of patients (age and sex), type of patient, diagnosis year, isolated organisms, and AST results from the laboratory record books using data abstraction form.

Laboratory Method

Ear discharge was collected under a strict aseptic technique using a sterile cotton swab from each patient. Within 2 hrs of collection, swabs were transported to the microbiology laboratory of UoGCSH for culture and AST. The specimens were directly inoculated on Blood agar, Chocolate agar, and MacConkey agar (OXOID, UK). MacConkey and Blood agar plates were incubated in aerobic conditions and Chocolate agar plates in a candle jar. All the inoculated media were incubated at 37°C for 18–24 hr. The identification of bacterial isolates by Gram staining, colony morphology, pigment production, or type of haemolysis on Blood agar follows a standard procedure.33 Moreover, the UoGCSH bacteriology laboratory used Catalase production, Coagulase production, Optochin sensitivity, and Bacitracin sensitivity tests for GPB and Oxidase production, Triple Sugar Iron utilization, Citrate utilization, Urease production, Motility, and Indole production tests for GNB. Antibiotic susceptibility testing was carried out using Kirby-Bauer Disc-diffusion technique34 on Muller Hinton agar (OXOID, UK) following the CLSI guidelines (2012–2017). The bacterial suspension was standardized using 0.5 McFarland standard and inoculated on Mueller–Hinton agar. The antibiotic discs were dispensed after drying the plate for 3–5 min and incubated at 37°C for 24 hrs. Penicillin G (10IU), Cefoxitin (30μg), Ampicillin (10μg), Amoxicillin (10μg), Erythromycin (15μg), Clindamycin (2μg), Cotrimoxazole (25μg), Oxacillin (1μg), Co-amoxiclav (20/10μg), Cefuroxime (30μg), Ceftriaxone (30μg), Gentamicin (10μg), Tobramycin (10μg), Ciprofloxacin (5μg), Norfloxacin (10μg), Meropenem (10μg), Tetracycline (30μg), Nalidixic acid (30μg), Vancomycin (30μg), Amikacin (30μg), and Chloramphenicol (30μg) were used to test the susceptibility of bacterial isolates. The control strains S. aureus (ATCC 25923), E. coli (ATCC 25922), and P. aeruginosa (ATCC 27853) were used for quality control.35

Data Analysis and Interpretation

Data were entered and analyzed using SPSS version 20 software, and results were presented using tables. The Chi-square test was applied to compare the proportions of ear-discharge isolates with patient characteristics. A p-value < 0.05 was considered as a statistically significant association.

Results

Over the six years, 369 ear-discharge samples were collected and then tested in the UoGCSH microbiology laboratory. The male to female ratio was 1.71:1, with 233 (63.1%) were male patients. The mean age of the study subjects was 17.46 years (±15.26 SD), with 105 (28.45%) were below the age of 5 years. Most of the ear discharge samples, 282 (76.4%), were from outpatient wards. Most of the samples, 122 (33.1%), were tested in 2013, followed by in 2014 (25.2%) and 2015 (18.2%). Overall, 283 (76.7% (95% CI = 72.4–81.3)) of the samples were culture positive, with 14 (4.95% (95% CI: 2.8–7.7)) were with mixed bacteria (data not shown). The culture positivity rate was slightly higher among patients with age groups of 25–29, females, and inpatients than other respective groups. Higher culture positivity rate was also observed in 2016 (88.2%), followed by 2013 (86.1%), and 2014 (73.1%) (Table 1).

Table 1 The Distribution of Ear Infection in Relation to Age, Sex, Ward, and Diagnosis Year of Patients at the UoGCSH from Jan 2013 to Dec 2018

There were about 269 ear-discharge samples with single bacterial isolates. Gram-negative bacteria 159 (59.1%) were isolated predominantly comprised to GPB 110 (40.9%). The predominant bacterial isolate from ear discharge samples was S. aureus 75 (27.88%), followed by P. mirabilis 28 (10.4%), P. vulgaris 23 (8.55%), E. coli 20 (7.43%), and P. aeruginosa 19 (7.06%) (Table 2).

Table 2 Frequencies of Bacteria Isolated from Patients with Ear Infection at the UoGCSH from Jan 2013 to Dec 2018

Between 2013 and 2018, the UoGCSH microbiology laboratory used ten antibiotic classes and 18 individual antibiotics to identify the ASP of bacteria isolated from ear discharge samples. Tables 3 and 4 show the ASP of GPB and GNB, respectively. The overall resistance rate in GPB was 46.3%, with a range of 5.7% to 65.6%. More than half of Gram-positive isolates were resistant to Tetracycline (65.6%), Co-trimoxazole (54.1%), Erythromycin (52.6%), and Penicillin groups (50%). However, most of them were sensitive to Vancomycin (94.3%), Gentamicin (83.7%), Clindamycin (77.8%), Quinolones (77.1%), Chloramphenicol (74.4%), and Cephalosporins (71.1%) drugs (Table 3).

Table 3 Antimicrobial Susceptibility Pattern of GPB Isolated from Patients with Ear Infection at the UoGCSH from Jan 2013 to Dec 2018

Table 4 Antimicrobial Susceptibility Pattern of GNB Isolated from Patients with Ear Infection at the UoGCSH from Jan 2013 to Dec 2018

The overall resistance rate in GNB was 49.1%, with a range of 12.5% to 90.9%. There was a high level of resistance rate in the Tetracycline group (86.36%), Penicillin group (79%), Clindamycin (70%), Chloramphenicol (64.6%), and Co-trimoxazole (50.8%) among Gram-negative isolates. However, these isolates were relatively sensitive to quinolones (76.5%), Aminoglycosides (73.9%), Cephalosporins (69.7%), and Meropenem (66.7%) drugs (Table 4).

From the total 269 bacterial isolates tested against common antibiotics, 123 (45.72%) were MDR. Gram-negative isolates 81 (50.9%) showed a higher MDR rate than Gram-positive isolates 42 (38.2%). The range of MDR rate among isolates is between 0–72.7%, with 69.57%, 57.9%, 55%, 42.6%, and 41.3% of P. vulgaris, P. aeruginosa, E. coli, P. mirabilis, and S. aureus isolates were MDR, respectively. More than 26%, 23%, 21%, and 19% of the isolates were resistant to at least one antibiotic in three, one, two, and five and more antimicrobial classes, respectively (Table 5).

Table 5 Multidrug Resistance Patterns of Bacteria Isolated from Patients with Ear Infection at the UoGCSH from Jan 2013 to Dec 2018

Discussion

Worldwide, over 430 million people (~ 5% of the world’s population) living with disabling hearing loss, which affects the quality of life of individuals. The prevalence of hearing loss is higher in developing countries, with middle ear disease (one of the common causes of hearing impairment) has the highest incidence.1,36,37 As a result, reporting bacterial etiologies of ear disease and their AST result is vital to prevent the multi-dimensional effect of the ear infection and guide the empirical treatment in the low-resource areas.

In the study area, ear discharge from patients suspected with ear infections is one of the routinely ordered specimens for microbiological analysis. This retrospective study showed that 76.7% (95% CI = 72.4–81.3) of the ear discharge samples were culture positive, with 4.95% of them had mixed isolates. This result is consistent with results reported in Ethiopia, including 80.4% in Bahir-Dar (2013–2015, 38) and 75.6% in Hawassa (a cross-sectional study).28 However, it was lower than reported from other parts of Ethiopia, such as Gondar (2009–2012) (89.5%),29 Dessie (2001–2011) (83.6%),39 and Mikelle (98.2%).27 Our result was slightly higher than reported from Bangladesh (70.8%).40 The differences in culture positivity rate might be affected by the types of study design and study participants used in the study.

In this retrospective analysis, GNB accounted for 59.1% of bacterial ear infections, and S. aureus (27.88%), Proteus spp. (20.82%), Streptococcus spp. (10.4%), and Pseudomonas spp. (8.92%) were predominant isolates. A previous retrospective study (2009–2012) from the same study area also reported GNB (56.4%) as the leading cause of ear infections, and Proteus species (27.5%), followed by S. aureus (26.5%) were the predominant isolate.29 Similar to our finding, previously reported data from other parts of Ethiopia also reported these isolates as the main etiologies of bacterial ear infections.27,31,39 A review article in Sub-Saharan Africa also reported similar bacterial isolates as the cause of OM.18 Furthermore, a recently published article from a tertiary care hospital in Bangladesh reported both GNB (55%) and GPB (45%) as etiologies of bacterial ear infection, with S. aureus (37%) and Pseudomonas species (31.5%) were the leading isolates.40 Different literatures also mentioned S. aureus, P. aeruginosa, Proteus species as the most common isolates from bacterial ear infection.41–46 Since the natural habitats of most of these bacteria can be skin, environment and soil, ear infection, particularly OE from these isolates42,46 is usually common.

Over the six-year (2013–2018) period, the UoGCSH bacteriology laboratory used more than ten antibiotic classes to test the susceptibility of ear-discharge isolates. We observed a higher overall resistance rate in Tetracycline (77.63%), Penicillins (67.2%), Co-trimoxazole (52.04%), Chloramphenicol (51.7%), and Erythromycin (52.6%). However, there was a lower degree of resistance rate in Fluoroquinolones (23.33%), Aminoglycosides (23.73%), and Cephalosporins (29.78%). Studies from different parts of Ethiopia28,38,39,47,48 also reported that most of the ear-discharge isolates were resistant to drugs in the Penicillin, Tetracycline, and Macrolide class. However, they reported that drugs in the Fluoroquinolones, Aminoglycosides, and Cephalosporins were better in treating ear-discharge bacterial isolates. The acquisition of genetic elements carrying resistance genes, mutations within the drug binding site, chromosomal mutation, production of inactivating enzymes, or efflux pumps contribute to the resistance of antibiotics, including Tetracycline, Penicillins, Co-trimoxazole, and Chloramphenicol.49–51

The most effective antibiotics for GPB were Vancomycin (94.3%), Gentamicin (83.7%), Clindamycin (77.8%), Fluoroquinolones (77%), Chloramphenicol (74.4%), and Cephalosporins (71%), and the most effective antibiotics for GNB were antibiotics in the Fluoroquinolones class (Ciprofloxacin (85.3%) and Norfloxacin (82.7%)), Ceftriaxone (76.8%), Aminoglycosides (73.8%), and Meropenem (66.7%). In this study, S. aureus was more sensitive to Vancomycin (91.5%), Gentamicin (84%), Clindamycin (78.6%), and Fluoroquinolones (76.8%) than other antibiotics used in this study. More than 62% of P. mirabilis and P. vulgaris were sensitive to Fluoroquinolones, Gentamicin, and Cephalosporins. Moreover, the antibiotic sensitivity result of P. aeruginosa showed that Gentamicin (86.7%), Fluoroquinolones (85%), and Cephalosporins (68.7%) were more sensitive than other antibiotics used in this study. These results were supported by reports from different parts of Ethiopia.

In this study, frequently isolated bacteria, including S. aureus, P. mirabilis, P. vulgaris, and P. aeruginosa showed a high level of resistance to Penicillins (58.4%, 80.8%, 67.6%, and 95.65%, respectively) and Tetracyclines (64.4%, 91.7%, 84.6%, and 91.7%, respectively). These results suggest that the UoGCSH should avoid using antibiotics in the Penicillins and Tetracyclines class unless they are supported with evidence that they are sensitive to the ear-discharge bacterial isolates. Ear-discharge isolates resistant to beta-lactam antibiotics, including Penicillins and Tetracyclines was also reported in other parts of Ethiopia.27,38,39

In this study, the overall MDR rate among ear-discharge bacterial isolates was 45.72% (123/269) (95% CI = 40.5–51.4%). This was consistent with the study conducted in Bahir Dar, where MDR prevalence was reported as 43%.52 In this study, 50.9% and 38.2% of Gram-negative and Gram-positive isolates were MDR, respectively. Worldwide, there is an increasing population of MDR bacteria, which is becoming a serious concern for healthcare professionals and the population at large. Due to different economic and social-related factors, the burden of AMR is greater in the developing countries, where lack of antimicrobial stewardship program, limited diagnostic facilities, inadequate patient educations, or non-human use of antimicrobials are prevalent.53–55 The higher MDR rate in GNB might be due to extended-spectrum β-lactamase (ESβL) and carbapenemase enzyme in isolates. This claim was supported by a previous report, where 54.2% and 12.5% of the Gram-negative isolates from the UoGCSH were ESβL and carbapenemase producers.56 According to a recent meta-analysis report, an estimated 48.9% of Gram-negative (Enterobacteriaceae) clinical isolates in Ethiopia are ESβL producers, most of them are classified as MDR because they usually carry genes encoding resistance to antibiotics other than beta-lactams.57

Limitation

Because of the limited patient details recorded on the laboratory logbook, it was impossible to include data related to clinical and other diagnosis information. Since, the types of ear infection (OM, OE, OI, or others) were not indicated in the laboratory logbook, we could not compare the association between bacterial isolates with the types of ear infection.

Conclusion and Recommendations

This retrospective study revealed that about two-thirds of the ear discharge samples were bacterial culture positive, which implies that bacterial ear infection is one of the health problems in the study area. S. aureus, P. mirabilis, P. vulgaris, E. coli, and P. aeruginosa were the predominant bacteria isolated from patients suspected of ear infections in the study area. Fluoroquinolones, Aminoglycosides, and Cephalosporins were effective against most of the ear-discharge isolates. However, more than half of the isolates had a high resistance level against Tetracycline, Penicillins, Co-trimoxazole, Chloramphenicol, and Erythromycin. This study also indicated that more than 45% of ear-discharge isolates were MDR. Therefore, periodic and continuous follow-up of antibiotic usage at the UoGCSH is necessary. For successful patient management and prevention of the emergence of MDR bacteria, treating bacterial ear infections based on culture and AST results in the study area is advisable.

Abbreviations

AOM, Acute Otitis Media; AMP, Antimicrobial Susceptibility Pattern; AST, Antimicrobial Susceptibility Testing; ASP, Antimicrobial Susceptibility pattern; CLSI, Clinical and Laboratory Standard Institute; GNB, Gram-negative bacteria; GPB, Gram-positive bacteria; MDR, Multidrug resistant; OI, Otitis Interna; OM, Otitis Media; COM, Chronic Otitis Media; OME, Otitis Media with Effusion; UoG, University of Gondar; UoGCSH, University of Gondar Comprehensive Specialized Hospital.

Data Sharing Statement

All data generated or analyzed during this study were included in this article. Data that support the findings of this study are also available from the corresponding author upon reasonable request.

Ethics Approval and Informed Consent

Before the commencement of the study, we obtained ethical clearance (Ref. No/SBMLS/2123/2019; 22 Feb 2019) from the UoG, School of Biomedical and Laboratory Sciences ethical review committee, and an official letter of co-operations was provided to UoGCSH. Before data collection, we explained the study objective to the heads of the hospital director and bacteriology laboratory personnel. Since we used secondary data for this study, we didn’t require the patient’s informed consent. We conducted the study following the Declaration of Helsinki.58 To ensure confidentiality of information from participant’s record, we didn’t record any personal identifiers on the data collection sheet, and secured data from participant records were not available to anyone except for the investigators.

Acknowledgments

The authors thank all the Medical Microbiology staff working at the UoG, School of Biomedical and Laboratory Science, College of Medicine and Health Sciences for their unreserved support. We like to thank the UoGCSH, and its Microbiology laboratory staff for their support during the data collection period.

Author Contributions

All authors made a significant contribution to the work reported, whether that is in the conception, study design, execution, acquisition of data, analysis and interpretation, or in all these areas; took part in drafting, revising or critically reviewing the article; gave final approval of the version to be published; have agreed on the journal to which the article has been submitted; and agree to be accountable for all aspects of the work.

Disclosure

The authors declare that they have no competing interests in this work.

References

1. Brown CS, Emmett SD, Robler SK, Tucci DL. Global hearing loss prevention. Otolaryngol Clin North Am. 2018;51(3):575–592. doi:10.1016/j.otc.2018.01.006

2. Graydon K, Waterworth C, Miller H, Gunasekera H. Global burden of hearing impairment and ear disease. J Laryngol Otol. 2019;133(1):18–25. doi:10.1017/S0022215118001275

3. World Health Organization. Childhood Hearing Loss: Strategies for Prevention and Care. World Health Organization; 2016. Available from: https://apps.who.int/iris/handle/10665/204632. Accessed October 12, 2021.

4. Aarhus L, Tambs K, Kvestad E, Engdahl B. Childhood Otitis media: a cohort study with 30-year follow-up of hearing (The HUNT study). Ear Hear. 2015;36(3):302.

5. Maharjan M, Phuyal S, Shrestha M, Bajracharya R. Chronic otitis media and subsequent hearing loss in children from the Himalayan region residing in Buddhist Monastic schools of Nepal. J Otol. 2020;15(4):144–148.

6. Jensen RG, Koch A, Homøe P. The risk of hearing loss in a population with a high prevalence of chronic suppurative otitis media. Int J Pediatr Otorhinolaryngol. 2013;77(9):1530–1535. doi:10.1016/j.ijporl.2013.06.025

7. CDC. Ear Infection [Internet]; 2021 [cited 2021 Jun 19]. Available from: https://www.cdc.gov/antibiotic-use/ear-infection.html. Accessed October 12, 2021.

8. Szmuilowicz J, Young R. Infections of the Ear. Emerg Med Clin North Am. 2019;37(1):1–9. doi:10.1016/j.emc.2018.09.001

9. McGraw-Hill. Harrison’s Manual of Medicine. 19th ed, Anthony SF, Dennis LK, Stephen LH, Dan LL, Larry J, Joseph JL, editors. In: Harrison’s Manual of Medicine. 19th ed. McGraw Hill Inc; 2017.

10. World Health Organization. World Report on Hearing. World Health Organization; 2021. License: CC BY-NC-SA3.0IGO. Available from: https://apps.who.int/iris/handle/10665/339913. Accessed October 12, 2021.

11. Danisyar A, Ashurst JV. Acute Otitis Media - StatPearls - NCBI Bookshelf. Treasure Island (FL): StatPearls Publishing; 2021.

12. Schilder AGM, Chonmaitree T, Cripps AW, et al. Otitis media. Nat Rev Dis Prim. 2016;2(1):1–8.

13. Atkinson H, Wallis S, Coatesworth AP. Acute otitis media. Postgrad Med. 2015;127:4.

14. Atkinson H, Wallis S, Coatesworth AP. Otitis media with effusion. Postgrad Med. 2015;127(4):1412.

15. Wallis S, Atkinson H, Coatesworth AP. Chronic otitis media. Postgrad Med. 2015;127(4):391–395. doi:10.1080/00325481.2015.1027133

16. Lieberthal AS, Carroll AE, Chonmaitree T, et al. The diagnosis and management of acute otitis media. Pediatrics. 2013;131(3):e964–e999. doi:10.1542/peds.2012-3488

17. Vergison A. Microbiology of otitis media: a moving target. Vaccine. 2008;26:G5–G10. doi:10.1016/j.vaccine.2008.11.006

18. Tesfa T, Mitiku H, Sisay M, et al. Bacterial otitis media in sub-Saharan Africa: a systematic review and meta-analysis. BMC Infect Dis. 2020;20(1). doi:10.1186/s12879-020-4950-y.

19. Zhang Y, Xu M, Zhang J, Zeng L, Wang Y, Zheng QY. Risk factors for chronic and recurrent otitis media–a meta-analysis. PLoS One. 2014;9(1):e86397.

20. Bourgeois T, Griffith C, Johnson E-C, Leblanc B, Melancon B. Barriers to current guidelines in the management of pediatric acute otitis media. J Pediatr Pediatr Med. 2019;3(3):7–24. doi:10.29245/2578-2940/2019/3.1146

21. Venekamp RP, Sanders SL, Glasziou PP, Del Mar CB, Rovers MM. Antibiotics for acute otitis media in children. Cochrane Database Syst Rev. 2015. doi:10.1002/14651858.CD000219.pub4

22. Holm NH, Rusan M, Ovesen T. Acute otitis media and antibiotics - a systematic review. Dan Med J. 2020;67:11.

23. Holmes AH, Moore LSP, Sundsfjord A, et al. Understanding the mechanisms and drivers of antimicrobial resistance. Lancet. 2016;387(10014):176–187. doi:10.1016/S0140-6736(15)00473-0

24. Castro-Sánchez E, Moore LSP, Husson F, Holmes AH. What are the factors driving antimicrobial resistance? Perspectives from a public event in London, England. BMC Infect Dis. 2016;16(1). doi:10.1186/s12879-016-1810-x

25. Chaw PS, Höpner J, Mikolajczyk R. The knowledge, attitude and practice of health practitioners towards antibiotic prescribing and resistance in developing countries—a systematic review. J Clin Pharm Ther. 2018;43(5):606–613. doi:10.1111/jcpt.12730

26. Cunningham M, Guardiani E, Kim HJ, Brook I. Otitis media. Future Microbiol. 2012;7(6):733–753. doi:10.2217/fmb.12.38

27. Wasihun AG, Zemene Y. Bacterial profile and antimicrobial susceptibility patterns of otitis media in Ayder Teaching and Referral Hospital, Mekelle University, Northern Ethiopia. Springerplus. 2015;4(1):1–9.

28. Tadesse B, Shimelis T, Worku M. Bacterial profile and antibacterial susceptibility of otitis media among pediatric patients in Hawassa, Southern Ethiopia: cross-sectional study. BMC Pediatr. 2019;19(1). doi:10.1186/s12887-019-1781-3

29. Muluye D, Wondimeneh Y, Ferede G, Moges F, Nega T. Bacterial isolates and drug susceptibility patterns of ear discharge from patients with ear infection at Gondar University Hospital, Northwest Ethiopia. BMC Ear Nose Throat Disord. 2013;13(1). doi:10.1186/1472-6815-13-10

30. Molla R, Tiruneh M, Abebe W, Moges F. Bacterial profile and antimicrobial susceptibility patterns in chronic suppurative otitis media at the University of Gondar Comprehensive Specialized Hospital, Northwest Ethiopia. BMC Res Notes. 2019;12(1). doi:10.1186/s13104-019-4452-4

31. Hailegiyorgis TT, Sarhie WD, Workie HM. Isolation and antimicrobial drug susceptibility pattern of bacterial pathogens from pediatric patients with otitis media in selected health institutions, Addis Ababa, Ethiopia: a prospective cross-sectional study. BMC Ear Nose Throat Disord. 2018;18(1). doi:10.1186/s12901-018-0056-1

32. Magiorakos A-P, Srinivasan A, Carey RB, Carmeli Y, Falagas ME, Giske CG. et al. Multidrug-resistant, extensively drug-resistant and pandrug-resistant bacteria: an international expert proposal for interim standard definitions for acquired resistance. Clin Microbiol Infect. 2012;18(3):268–281. doi:10.1111/j.1469-0691.2011.03570.x

33. Cheesbrough M. District Laboratory Practice in Tropical Countries. Vol. 2. 2nd ed. Cambridge University Press; 2006.

34. Biemer JJ. Antimicrobial susceptibility testing by the Kirby-Bauer disc diffusion method. Ann Clin Lab Sci. 1973;3(2):135–140.

35. Clinical and Laboratory Standards Institute (CLSI). Performance Standards for Antimicrobial Susceptibility Testing; 23rd Informational Supplement M100-S23. Wayne: CLSI; 2013.

36. WHO. Deafness and hearing loss [Internet]; 2021 [cited 2021 Jun 25]. Available from: https://www.who.int/news-room/fact-sheets/detail/deafness-and-hearing-loss. Accessed October 12, 2021.

37. Mulwafu W, Kuper H, Ensink RJH. Prevalence and causes of hearing impairment in Africa. Trop Med Int Heal. 2016;21(2):158–166.

38. Hailu D, Mekonnen D, Derbie A, Mulu W, Abera B. Pathogenic bacteria profile and antimicrobial susceptibility patterns of ear infection at Bahir Dar Regional Health Research Laboratory Center, Ethiopia. Springerplus. 2016;5(1). doi:10.1186/s40064-016-2123-7

39. Argaw-Denboba A, Abejew AA, Mekonnen AG. Antibiotic-resistant bacteria are major threats of Otitis media in Wollo Area, Northeastern Ethiopia: a ten-year retrospective analysis. Int J Microbiol. 2016;2016(2016):1–9. doi:10.1155/2016/8724671

40. Khatun MR, Alam KMF, Naznin M, Salam MA. Microbiology of chronic suppurative Otitis Media: an update from a Tertiary Care Hospital in Bangladesh. Pakistan J Med Sci. 37(3):821.

41. Rosenfeld RM, Schwartz SR, Cannon CR, et al. Clinical practice guideline: acute otitis externa. Otolaryngol Neck Surg. 2014;150(1_suppl):161–168. doi:10.1177/0194599813517659

42. Wiegand S, Berner R, Schneider A, Lundershausen E, Otitis Externa: DA. Investigation and evidence-based treatment. Dtsch Aerzteblatt Online. 2019. doi:10.3238/arztebl.2019.0224

43. Lee H, Kim J, Nguyen V. Ear infections: otitis externa and otitis media. Prim Care Clin off Pract. 2013;40(3):671–686. doi:10.1016/j.pop.2013.05.005

44. Osazuwa F, Osazuwa E, Osime C, et al. Etiologic agents of otitis media in Benin city, Nigeria. N Am J Med Sci. 2011;3(2):95.

45. Appiah-Korang L, Asare-Gyasi S, Yawson A, Searyoh K. Aetiological agents of ear discharge: a two year review in a teaching hospital in Ghana. Ghana Med J. 2014;48(2):91. doi:10.4314/gmj.v48i2.6

46. Aboutalebian S, Ahmadikia K, Fakhim H, et al. Direct detection and identification of the most common bacteria and fungi causing otitis externa by a stepwise multiplex PCR. Front Cell Infect Microbiol. 2021;11. doi:10.3389/fcimb.2021.644060

47. Gorems K, Beyene G, Berhane M, Mekonnen Z. Antimicrobial susceptibility patterns of bacteria isolated from patients with ear discharge in Jimma Town, Southwest, Ethiopia. BMC Ear Nose Throat Disord. 2018;18(1). doi:10.1186/s12901-018-0065-0

48. Abera B, Kibret M. Bacteriology and antimicrobial susceptibility of otitis media at dessie regional health research laboratory, Ethiopia. Ethiop J Heal Dev. 2011;25(2):161–167.

49. Grossman TH. Tetracycline Antibiotics and Resistance. Cold Spring Harb Perspect Med. 2016;6(4):a025387. doi:10.1101/cshperspect.a025387

50. Markley JL, Wencewicz TA. Tetracycline-inactivating enzymes. Frontiers Microbiol. 2018;9:1058.

51. Reygaert CW. An overview of the antimicrobial resistance mechanisms of bacteria. AIMS Microbiol. 2018;4(3):482–501. doi:10.3934/microbiol.2018.3.482

52. Endaylalu K, Abera B, Mulu W. Extended spectrum beta lactamase producing bacteria among outpatients with ear infection at FelegeHiwot Referral Hospital, North West Ethiopia. PLoS One. 2020;15(9):e0238891. doi:10.1371/journal.pone.0238891

53. Ayukekbong JA, Ntemgwa M, Atabe AN. The threat of antimicrobial resistance in developing countries: causes and control strategies. Antimicrob Resist Infect Control. 2017;6(1). doi:10.1186/s13756-017-0208-x

54. Founou RC, Founou LL, Essack SY. Clinical and economic impact of antibiotic resistance in developing countries: a systematic review and meta-analysis. PLoS One. 2017;12(12):e0189621. doi:10.1371/journal.pone.0189621

55. Hosain MZ, Kabir SML, Kamal MM. Antimicrobial uses for livestock production in developing countries. Vet World. 2021;14(1):210–221. doi:10.14202/vetworld.2021.210-221

56. Moges F, Gizachew M, Dagnew M, et al. Multidrug resistance and extended-spectrum beta-lactamase producing Gram-negative bacteria from three Referral Hospitals of Amhara region, Ethiopia. Ann Clin Microbiol Antimicrob. 2021;20(1). doi:10.1186/s12941-021-00422-1.

57. Abayneh M, Worku T. Prevalence of multidrug-resistant and extended-spectrum beta-lactamase (ESBL)-producing gram-negative bacilli: a meta-analysis report in Ethiopia. Drug Target Insights. 2020;14(1):16–25. doi:10.33393/dti.2020.2170

58. WMA. World Medical Association Declaration of Helsinki: ethical principles for medical research involving human subjects. JAMA. 2013;310(20):373.

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