Trends in Bacterial Blood Culture Isolates and Resistance in Children in Two Microbiologic Eras from a Tertiary Health Facility in North East Nigeria

Elon Warnow Isaac; Iliya Jalo; Mohammed M. Manga; Abubakar Joshua Difa; Mercy Raymond Poksireni; Oyeniyi Christianah; Ibrahim Mohammed; Muhammad Saminu Charanci

doi:10.4236/ojmm.2023.132014

Open Journal of Medical Microbiology > Vol.13 No.2, June 2023

Trends in Bacterial Blood Culture Isolates and Resistance in Children in Two Microbiologic Eras from a Tertiary Health Facility in North East Nigeria

Elon Warnow Isaac^1,2*, Iliya Jalo¹, Mohammed M. Manga^2,3, Abubakar Joshua Difa^2,4, Mercy Raymond Poksireni^1,2, Oyeniyi Christianah², Ibrahim Mohammed³, Muhammad Saminu Charanci⁵
¹Department of Paediatrics, College of Medical Sciences, Gombe State University, Tudun Wada, Nigeria.
²Infectious Disease Training and Research Group Gombe (INDITREGO), Gombe, Nigeria.
³Department of Medical Microbiology, College of Medical Sciences, Gombe State University, Tudun Wada, Nigeria.
⁴Department of Community Medicine, College of Medical Sciences, Gombe State University, Tudun Wada, Nigeria.
⁵Microbiology Laboratory Federal Teaching Hospital Gombe, Gombe, Nigeria.
DOI: 10.4236/ojmm.2023.132014 PDF HTML XML 91 Downloads 442 Views

Abstract

Introduction: Antimicrobial Resistance surveillance is predicated on blood culture as a priority clinical specimen in especially resource limited settings. Establishing trends in blood stream infections and resistance patterns can inform institutional and national policy on antimicrobial stewardship, surveillance, infection prevention and control. Methodology: Blood Culture isolates in children (0 - 18 years) by conventional method from 2008-2012 and Bactec Automated culture system from 2015-2020 were retrieved. Information analyzed included age, sex, month, and year and culture growth/identity of microorganisms and their sensitivity/resistance patterns. Clinical and Laboratory Standards Institute (CLSI) guideline for antibiotic susceptibility testing was used. Results: 20,540 children were admitted: 8964 (44.6%) and 11,630 (55.4%) in the Manual and Bactec blood culture era respectively. Blood cultures were done in 5271 in the manual culture era and 1077 in the Bactec culture era; of these cultures, 514 (9.7%) and 461 (42.8%) were positive for isolates in the respective era (p = 0.01). There were no statistically significant differences in trend between positive and negative blood cultures in males and females. Newborns, followed by children 1 - 5 years had more blood culture performed on them than other age categories. In general, there is no significant relationship in blood culture outcomes between the age categories and sex of the patients. The isolation of Staph aureus, Citrobacter and Alkaligenes increased two-fold with Bactec automated system. Resistance to the quinolones and the penicillin was high. Resistance trend to Genticin, an aminoglycoside was less than 40%. Resistance to Ceftazidime was high. Conclusion: Antimicrobial resistance surveillance is critical to reduce AMR related morbidity and mortality.

Keywords

Trend, Blood Culture Isolates, Children, Manual, Bactec, Resistance

Share and Cite:

Isaac, E. , Jalo, I. , Manga, M. , Difa, A. , Poksireni, M. , Christianah, O. , Mohammed, I. and Charanci, M. (2023) Trends in Bacterial Blood Culture Isolates and Resistance in Children in Two Microbiologic Eras from a Tertiary Health Facility in North East Nigeria. Open Journal of Medical Microbiology, 13, 159-182. doi: 10.4236/ojmm.2023.132014.

1. Introduction

Blood culture is the gold standard for the diagnosis of Blood stream infections [1] . Accurate and reliable diagnosis of blood stream infections is a microbiologic task of utmost clinical significance [2] . Antimicrobial Resistance AMR surveillance is predicated on blood culture as a priority clinical specimen in especially resource limited settings [3] . There were an estimated 4.95 million deaths associated with bacterial AMR in 2019, including 1.27 million deaths attributable to bacterial AMR. At the regional level, it was estimated the all-age death rate attributable to resistance to be highest in western sub-Saharan Africa, at 27.3 deaths per 100,000 [4] . In Nigeria, a situation analysis of antimicrobial use [5] and a National Action Plan for AMR [6] prioritized the use of blood culture in diagnosing BSIs. Low- and middle-income countries especially sub-Saharan Africa face many challenges when implementing blood cultures, due to financial, logistical, and infrastructure-related constraints [7] . In these settings, the conventional/manual culture methods remain the dominant systems while the automated blood culture systems have become the standard in high-income countries (HICs), and are relatively expensive and not universally available for implementation in most LMICs where [7] [8] [9] implementing automated microbiologic systems is feasible [7] [10] . Several reports [11] [12] [13] in LMIC showed that these systems show better performance than manual systems in terms of yield, sensitivity and especially speed of growth and overall turnaround time. Blood cultures are still indispensable for the diagnosis of BSIs however currently available molecular methods based on in situ hybridization-based methods, DNA microarray-based hybridization technology; nucleic acid amplification-based methods and combined methods [14] are a distant prospect for LMICs.

Establishing trends in blood stream infections and resistance patterns can inform health care needs assessment, service provision planning, institutional and national policy on antimicrobial stewardship, surveillance, infection prevention and control [15] . In Nigeria, a nationally representative epidemiologic data on Blood Stream Infections and their antibiotic sensitivity and resistance patterns is lacking [16] . With the triad of Malaria, malnutrition HIV and other prevalent childhood conditions strongly associated with the prevalence of Blood stream infection in the region clinical microbiology laboratories require urgent strengthening in Sub-Saharan Africa [17] . In Nigeria, there is paucity of data on two contrasting microbiologic laboratory periods in transition. We therefore aimed to report blood stream infection and resistance trends in children in our health facility over two microbiologic eras of earlier manual/conventional blood culture and current Bactec automated blood culture methods.

1.1. Method

The Federal Teaching hospital Gombe (FTHG) is currently a 500-bed health facility [18] which started providing health service to the public in the year 2000. The Medical Microbiology Department fully transitioned to automated blood culture system in 2015 from the conventional/manual system which was used at inception.

1.2. Subjects

Blood Culture isolates in children (0 - 18 years) by conventional method from 2008-2012 and Bactec Automated culture system from 2015-2020 were retrieved. Information analyzed included, age, sex, month, and year and culture growth/identity of microorganisms. Blood samples for cultures from consecutive children’s admissions between 2008-2012 and 2015-2020 with suspected blood stream infections or sepsis were obtained using the Hospital standard procedure.

The BD Bactec (R) [19] 9050 instrument which is designed for the rapid detection of microorganisms in clinical cultures of blood was used. The Blood sample to be tested was inoculated into the vial which was entered into the Bactec 9050 for incubation and periodic reading. Each vial contains a sensor which detects increases in carbon dioxide, produced by the growth of microorganisms. The sensor was monitored by the instrument every ten minutes for an increase in its fluorescence, which was proportional to the amount of carbon dioxide present. A positive reading indicates the presumptive presence of viable microorganisms in the vial which are subsequently sub cultured for identification and antibiotic susceptibility testing. Clinical and Laboratory Standards Institute (CLSI) guideline for antibiotic susceptibility testing was used. From 2021 Bactec FX40 was introduced in the microbiology unit to replace the Bactec 9050 equipment and Vitek II automated platform for identification and antimicrobial susceptibility testing (ID/AST) was introduced in 2022. Our laboratory did not participate in any external quality assurance scheme.

1.3. Data Analysis

Data were entered into the EPInfo version 3.5.1 software and analyzed. Automated and manual BC were compared in terms of proportion positive and recovery of different bacteria were calculated using chi and Fischer’s exact test. A p-value below 0.05 was considered as statistically significant. Yearly Blood culture sampling/admission was derived by dividing the number of blood cultures by admissions in the year.

1.4. Ethical Approval

Approval for this study was received from the Ethical Research Committee of the Federal Teaching Hospital Gombe.

2. Results

In Table 1, 20,540 children were admitted; 8964 (44.6%) and 11630 (55.4%) in the Manual and Bactec blood culture era respectively. Blood cultures were done in 5271 in first era and 1077 in the second era. Of these cultures, 514 (9.7%) and 461 (42.8%) were positive for isolates respectively. (p = 0.01). Blood culture cost rose from N500 ($1.1) for Manual method to N5000 ($11.1) for Bactec culture and is currently N8500 ($18.8). Of the total children admitted 63% and 9.2% had blood culture in the first and second era respectively. Cumulative Blood sampling for culture was 0.6 per admission in the manual culture era and 0.09 per admission in the Bactec era.

Yearly BC declined sharply when the Bactec 9050BD was introduced in 2015 largely because of increased in the cost of blood culture to 10 times above manual era.

Figure 1(a) and Figure 1(b) show the yearly admission, yearly blood cultures and yearly blood culture rate amongst admitted children in the two eras. Yearly blood culture rate among children admitted in the Manual era varied between 86.2% in 2008 and 68.8% in 2012. In the Bactec era this rate was between 10% - 19.4%. Blood culture sampling per patient admission ranged from 0.5 and 0.7 in the manual era and 0.005 to 0.06 in the Bactec era. The cost of one Blood culture

Table 1. Blood culture era, sex and yield.

(a) (b)

Figure 1. (a): Yearly trend in Blood culture rate per yearly patient admission in the two microbiologic eras in FTH Gombe Nigeria. (b): Yearly blood culture per patient admission in two microbiologic eras in FTH Gombe.

for Manual method was $1.1 and $11.1 (equivalent to the Nigerian currency, the Naira) in the Bactec era. The intervening years of 2013-2015 were not included as the numbers did not differ and two equal time intervals were used for this trend analysis.

In Figure 2(a) and Figure 2(b), blood culture positivity rate peaked in 2008 and decreased to a lowest of 3.8% in 2010 in the manual blood culture era. In the Bactec era, peak positivity rate was 50% in 2016 with the lowest of 30.7% isolation rate.

In Figure 3, more males had received a blood culture than females on a yearly basis in both microbiologic eras but this was not statistically significant (x² = 13.173; p = 0.155). In both sexes blood culture declined with the advent of Bactec automated blood culture system, however there was no statistically significant differences in trend between positive and negative blood cultures in males and females (Table 2). In Figure 4, newborns, followed by children 1 - 5 years had more blood culture performed on them than other age categories. Adolescents

(a) (b)

Figure 2. (a): Trend in Yearly blood culture percent positivity in two microbiologic eras in FTH Gombe Nigeria. (b): Trend in yearly blood culture positivity in children in the manual and Bactec era FTH Gombe.

Figure 3. Trend in yearly blood cultures and Sex of Children admitted in the Manual and Bactec Culture eras in FTH Gombe (x² = 13.173; p = 0.155).

had the lowest rate of blood culture of all the ages. In all age categories, the culture rate declined with the use of Bactec automated culture method despite increasing child admissions. However, there was a statistically significant trend in

Figure 4. Trend in age group and yearly blood cultures in manual and Bactec blood culture era in FTH Gombe.

Table 2. Yearly trend of blood culture results and sex in two microbiologic eras in FTG Gombe.

blood culture results from the manual to the automated era (Table 3). In Table 4, there was in general no significant relationship in blood culture outcomes between the age categories and sex of the patients.

In Figure 5, of the priority pathogens, Staphylococcus aureus, Klebsiella and E. coli remain the most dominant especially in the manual era. The isolation of staph aureus increased two-fold with Bactec automated system. Citrobacter and alkaligenes isolation also increased about two-fold with the Bactec culture method.

In Figure 6, resistance to the quinolones and the penicillin in the early years was high ranging from 60% - 100% with sharp decline in 2016 and 2017 for ciprofloxacin, amoxyllin/clavulanate and amoxicillin as result of none testing. This

Table 3. Yearly trend in blood cultures results and age categories in two microbiologic eras in FTH Gombe.

was the year of the introduction of Bactec automated culture system with its tenfold increase in cost of blood culture. By the later years, resistance to these common antibiotics was less than 50% except for amoxycillin which showed a steep rise between 2018 and 2019 and decline in 2020. The difference in the number of bacterial isolates in the two eras may have accounted for the generally low resistance trend in the bactec era. Resistance trend to Genticin an aminoglycoside has remained less than 40% throughout the last ten years in our facility. At the start of the review resistance to Ceftazidime a 3^rd generation cephalosporin was high at about 60% and remained so with substantial decline to 10% in the 2019 and 2020. The percentage of resistant bacterial isolates was arrived at using the multiple antibiotic resistance index [20] which represents number of antibiotics to which the test isolate depicted resistance divided by the number of antibiotics to which the test isolate has been evaluated for susceptibility in each year. The mean antibiotic resistance was derived from percentage resistance of each pathogen tested against each of the antibiotics in that year.

3. Discussion

In this study, there was a steady increase in paediatric admissions over the last decade in our facility. While this may be attributable to increasing child population and referrals [21] , weak and ineffective primary health care especially and secondary health service have had their toll on tertiary healthcare service [22] [23] .

Fever is common in Sub Saharan Africa and febrile illness remains a major cause of illness and death [24] [25] . With invasive bacterial infection contributing 10% - 13% of febrile illnesses [26] [27] blood culture and indeed pathogen

Table 4. Yearly trend in age group, sex and blood culture results in two microbiologic eras in FTH Gombe.

identification become critical elements of patient care and clinical microbiology in resource limited settings like sub-Saharan Africa [7] [28] .

In this study, half to two thirds of children admitted during the Manual Blood culture era received a blood culture sampling indicating a substantial risk for blood stream infection. This is in contrast to the automated culture era where only a fifth of the children had blood culture sampled despite increasing patient admissions and risk for bacterial infection. The tenfold increase in the

Figure 5. AMR priority and non-priority blood culture isolates in children in two microbiologic eras in FTH Gombe.

Figure 6. Trend in mean multiple antibiotic resistance index of priority and non-priority isolates in two microbiologic times in FTH Gombe.

break-even cost of Bactec blood culture had significantly negative impact on blood culture uptake in our facility. Blood culture per patient admission [29] [30] declined substantially during the Bactec era undermining the public health significance of etiologic diagnosis of acute febrile illness in a setting where clinical malaria is over-diagnosed, non-prescription antibiotics are prevalent and empiric prescription antibiotic by physicians is the standard clinical practice [16] . There is paucity of reports on the impact of automated microbiology methods on service uptake in Nigeria and in the sub-region. In Nigeria Health Insurance coverage is abysmally low at < 5% [31] with significant impact on out-of-pocket expenses in our subregion, North East of Nigeria, where Multidimensional poverty level is 90% and in Gombe state where child multidimensional poverty level is 95% [32] . These automated systems are costly, require regular maintenance and are not adapted to tropical, dusty environments, transferring costs to patients impeding the sustainable implementation of this technique in many developing countries [7] [33] . If according to a market forecasting study, manual blood culture systems will make up roughly two-thirds of the global blood culture market by 2025 [9] recommendations for improvement in manual blood culture and clinical laboratory methods in low resource settings require urgency of implementation [7] [34] [35] .

Pathogen detection and identification is at the heart of tackling infectious diseases in general, whether it is for guiding optimal treatment or for detecting and controlling outbreaks of emerging and drug-resistant pathogens and good quality microbiological diagnostics remains the key factor [36] .

Blood culture positivity trend was higher and sustained in the Bactec era compared to the Manual era. Previous reports in Nigeria [11] [37] [38] [39] and elsewhere [12] [13] [40] have shown higher pathogen yield and shorter turnaround time with Bactec culture systems over the conventional/manual method. However, and in general, access to quality-assured laboratory diagnosis has been a challenge in low-income and middle-income countries (LMICs) resulting in delayed or inaccurate diagnosis and ineffective treatment with consequences for patient safety [41] [42] .

More male than female children had received blood culture on a year-by-year basis implying a substantial risk for blood stream infection among male children. But this was not statistically significant (x² = 13.173, 0.155). Similar findings were reported from Nigeria [43] , Ghana [44] , Tanzania [45] and Switzerland [46] . Most epidemiological studies have shown that being a male is a risk factor for infectious diseases and women are at less risk than men when it comes to developing most infectious diseases (x² = 7.112; 0.626) [47] . This sex dimorphism to infection is related to the interplay of age, comorbidities, genetic predispositions, geographical distribution of pathogens, health behaviors, access to healthcare, and hormonal influences [48] [49] .

Throughout the review period newborns in particular and children under Five years had more blood cultures performed on yearly basis compared to other child age categories. The incidence of bloodstream infections is highest at extremes of age, in neonates and elderly people [50] and febrile illness is the commonest cause of hospitalization in children < 5 years in sub-Saharan Africa with bacterial bloodstream infections and malaria as major causes of death [24] [51] Several studies have documented risk factors for blood stream infection in the newborn and under 5 children [45] [52] [53] . Co morbidities like undernutrition, Malaria, anaemia and HIV have added to the burden of BSI in sub-Saharan Africa [16] [54] [55] [56] .

In this study a trend towards Staph aureus, Klebsiella and E. coli being the dominant pathogens isolated from blood cultures of children during the manual era with variable frequencies was observed. Staph aureus isolation increased substantially in our centre with Bactec automated system. Similarly, Citrobacter and alkaligenes were isolated with increasing frequency in the automated blood culture system. While there is paucity of comparable reports to ours in the country and subregion early [57] - [63] and recent studies [43] [64] - [69] , in Nigeria and elsewhere [30] [70] [71] [72] [73] have demonstrated the preponderance of staph aureus, E. coli, Klebsiella and or Pseudomonas in blood stream infections in children 0 - 18 years. While Salmonella and Streptococcus pneumonia were infrequently isolated in our study and others in Nigeria [57] [58] [64] [68] [69] [74] [75] , the reports of Obaro et al. [16] and others in the country [76] [77] have demonstrated the significance of these pathogens in blood stream infections in children. Typhoid fever and Invasive Non Typhoidal Salmonella disease are major agents of invasive bloodstream infections in urban and rural locations, affecting children more commonly than adults across sub-Saharan Africa [78] . Streptococcus pneumoniae is capable of causing a spectrum of disease in children, the most severe of which is invasive pneumococcal disease (IPD), which includes bacteraemic pneumonia, meningitis and sepsis [75] Nevertheless, rates of pneumococcal disease are estimated to be highest on the African continent, causing over 4 million cases a year in children under 5 years; Pneumococcal disease also contributes to substantial mortality, driven predominantly by mortality from pneumococcal pneumonia [79] . With increasing pneumococcal vaccine coverage among children in sub-Saharan Africa, the burden of pneumococcal disease and its invasive forms is reducing [80] [81] [82] . The year-on-year isolation of Citrobacter and alkaligenes increased in the Bactec era compared to the manual blood culture period. Citrobacter, a facultative gram-negative anaerobic bacillus belonging to the family Enterobacteriaceae is being increasingly recognized to cause a wide spectrum of infections especially in immunocompromised or patients with comorbidities [83] [84] [85] .

These gram-negative bacilli constituted 1.3% [86] , 1.9% [87] of blood cultures isolates in Nigeria studies; 9.5% in Tanzania [88] ; <1% in Malawi [89] and 2.2% in Rwanda [90] , 2.4% in India [91] , 1.2% in Kenya [92] and 15% in Ghana [72] .

Alcaligenes spp are Gram-negative, obligate aerobic, oxidase-positive, catalase-positive, and nonfermenting bacteria. It is a potentially emerging pathogen and usually causes opportunistic infections in humans. The most commonly reported cases involved bacteremia, and most cases occurred in newborns and infants [93] . They are commonly found in hospital settings, such as in respirators, hemodialysis systems, and intravenous solutions [94] . A systematic review on bacterial isolates in sub-Saharan Africa by Reddy et al. [95] showed a <1% prevalence of Alcaligenes; recent systemic review in Africa and Asia [96] showed similar very low isolation rate. However, rather than a contaminant, Alcaligenes should be regarded as a pathogen, because global cases of life-threatening infections caused by A. faecalis are emerging [97] . The lack of widespread access to automated blood culture and pathogen identification systems in many developing countries may have contributed to the low isolation of some pathogens [16] . These automated platforms have improved time to detection and recovery of both aerobic and anaerobic organisms and made possible the neutralization of several anti-biotics present in blood culture media. They have minimized contamination and bio-hazard risk [10] [11] [16] [98] .

In general, the unregulated [99] and widespread use of prehospital antibiotics [100] [101] , empirical antibiotic prescription [102] [103] glaring gaps and constraints in clinical microbiology laboratory standards in especially sub-Saharan Africa [34] [104] have impacted significantly on pathogen isolation, identification and therefore surveillance. On the other hand, these aforementioned factors should give impetus an d accelerate policy revision, guideline development and update, on antimicrobials and clinical laboratory standards particularly now and within the arm bit of one health in sub Saharan Africa and other LMICs.

Antimicrobial resistance is a global threat and Africa bears disproportionately this burden [105] [106] [107] . Increasing cost of health care and poor patient outcomes are attributable to AMR especially in LMIC [108] . There is paucity of comparable resistance trend report in Nigeria and the subregion, however an earlier systematic review in patients with BSI in West Africa by Barnabe et al. [109] reported a 17.7% resistance to third-generation cephalosporin, 37.2% to Genticin, 68.4% to Ampicillin and 13.2% to ciprofloxacin. While resistance to 3 GC, Genticin and Ampicillin are comparable to the study mean values, ciprofloxacin resistance was threefold higher. This overall moderate level of AMR is likely to undermine typical empirical antibiotic strategy [109] .

WHO recommends a third-generation cephalosporin as second-line antibiotic [110] but many low- and middle-income countries (LMIC) utilize third-generation cephalosporins-ceftriaxone as first-line treatment for severe sepsis at district, regional and tertiary health care facilities owing their widespread availability [77] [111] [112] .

Lester et al. [113] in systematic review in SSA showed a mean estimate of 3 CG resistance to E. coli, Klebsiella and Salmonella of 18.4%, 54.4% and 1.9% respectively establishing significant heterogeneity not explained by differences in African region group of patients recommending that detailed clinical and demographic parameters should be collected to deepen the understanding of drug resistance isolates and the drivers of transmission of AMR pathogens [113] .

Several Systematic reviews in children in Africa and other LMICS have reported varying 3 GC resistance of 19% against ceftazidime [114] , 49% [115] and 33.9% to ceftriaxone [116] . These reviews also reported ciprofloxacin (43.3%, 44%, 12%), aminoglycoside (14%, 33.5%, 37.2%) and ampicillin (85%, 59.7% 68.8%) resistance rates, noting the high variation between antimicrobial groups and rates, high variation in antibiotics tested against the isolates with significant heterogeneity and low comparability of studies [114] [115] [116] . These researchers highlighted a continent-wide increase in AMR reporting and in resistance and substantial challenges in diagnostic microbiological data quality. Priority strengthening of laboratory capacity, standardized testing and surveillance efforts, and reporting of AST results are required to improve AMR [105] [114] [116] .

A recent review showed Escherichia coli, followed by Staphylococcus aureus, Klebsiella pneumoniae, Streptococcus pneumoniae, Acinetobacter baumannii, and Pseudomonas aeruginosa as six leading pathogens for deaths associated with AMR and the following One pathogen-drug combination, methicillin resistant S. aureus, third-generation cephalosporin-resistant E. coli, carbapenem-resistant A. baumannii, fluoroquinolone-resistant E. coli, carbapenem resistant K. pneumoniae, and third-generation cephalosporin-resistant K. pneumoniae related AMR deaths [4] . In conclusion, while Blood sampling for culture has decreased in our facility on account of higher cost of Bactec blood culture, however the isolation of pathogens through this platform has increased significantly overall. Staph aureus was the leading isolate with Alcaligenes and Citrobacter also being grown increasingly with the use of Bactec automated method. Bacterial Resistance to commonly used antibiotics was multiple, and in general moderate to high.

4. Conclusion

Blood sampling for culture per patient admission is low in the Bactec era. The trend in blood culture positivity is higher with Bactec automated culture system with Staph. Aureus the leading pathogen isolated in both microbiologic eras. Citrobacter and Alcaligenes were increasingly isolated with the automated culture system. The trend in Resistance to commonly used antibiotics was high with mild to moderate resistance to aminoglycoside and the third-generation cephalosporin.

Limitation of the Study

As a retrospective study, microbiology quality and standards in laboratory could not always be guaranteed despite presence of highly qualified personnel and significantly the lack of any external quality assurance of these procedures in our laboratory.

Recommendations

Establishment of the collaborative multi-site multi-level health facility surveillance microbiology laboratories with effective and coordinated governance structure in Nigeria and other sub-Saharan African countries.

Collaborative partnership to upscale human capacity and automated microbiologic systems for culture and pathogen identification in specifically high patient flow facilities and the country in general which may impact positively on costs.

Advocacy for reduction in the unit price and consumables of automated blood culture and identification systems.

Author Contribution

WEI, MM conceived of the study and study design. WEI developed the first manuscript draft, and critically reviewed all drafts of the manuscript. IJ and IM critically reviewed bacterial isolates and reviewed draft manuscript. AJD and CO conducted quantitative analysis and critically reviewed the final manuscript.

Acknowledgements

Hajiya Fatima, Hafsat Sabo, Monica Shamaki and Dorcas for data extraction from the laboratory register.

Conflicts of Interest

The authors declare no conflicts of interest.

References

[1]	Cohen, J., Vincent, J.L., Adhikari, N.K.J., et al. (2015) Sepsis: A Roadmap for Future Research. The Lancet Infectious Diseases, 15, 581-614. https://doi.org/10.1016/S1473-3099(15)70112-X
[2]	Tjandra, K.C., Ram-Mohan, N., Abe, R., Hashemi, M.M., Lee, J.H. and Chin, S.M. (2022) Diagnosis of Bloodstream Infections: An Evolution of Technologies towards Accurate and Rapid Identification and Antibiotic Susceptibility Testing. Antibiotics, 11, Article 511. https://doi.org/10.3390/antibiotics11040511
[3]	Diekema, D.J., Hsueh, P.R., Mendes, R.E., Pfaller, M.A., Rolston, K.V., Sader, H.S., et al. (2019) The Microbiology of Bloodstream Infection: 20-Year Trends from the Sentry Antimicrobial Surveillance Program. Antimicrobial Agents and Chemotherapy, 63, e00355-19. https://doi.org/10.1128/AAC.00355-19
[4]	Antimicrobial Resistance Collaborators (2022) Global Burden of Bacterial Antimicrobial Resistance in 2019: A Systematic Analysis. The Lancet, 399, 629-655. https://doi.org/10.1016/S0140-6736(21)02724-0
[5]	Federal Ministries of Agriculture and Rural Development, Environment and Health, Abuja Nigeria (2017) Antimicrobial Use and Resistance in Nigeria: Situation Analysis and Recommendations. FMAEH.
[6]	Federal Ministries of Agriculture and Rural Development, Environment and Health, Abuja Nigeria (2017) National Action Plan for Antimicrobial Resistance 2017-2022. FMAEH.
[7]	Ombelet, S., Barbé, B., Afolabi, D., et al. (2019) Best Practices of Blood Cultures in Low- and Middle-Income Countries. Frontiers in Medicine, 6, Article No. 131. https://doi.org/10.3389/fmed.2019.00131
[8]	Lamy, B., Dargière, S., Arendrup, M.C., Parienti, J.J. and Tattevin, P. (2016) How to Optimize the Use of Blood Cultures for the Diagnosis of Bloodstream Infections? A State of the Art. Frontiers in Microbiology, 7, Article No. 697. https://doi.org/10.3389/fmicb.2016.00697
[9]	Grand View Research (2018) Blood Culture Tests: Market Analysis & Segment Forecast from 2014-2025. Grand View Research, San Francisco.
[10]	Isaac, E.W., Jalo, I., Manga, M.M., Difa, A.J., Poksireni, M.R., Christianah, O., Mohammed, I. and Charanci, M.S. (2022) Transitioning to Automated Microbiologic Era: Blood Culture Isolates in Children and Adults in Federal Teaching Hospital in Gombe, North East Nigeria 2016-2020. Open Journal of Medical Microbiology, 12, 184-203. https://doi.org/10.4236/ojmm.2022.124016
[11]	Isaac, E.W., Jalo, I., Difa, A.J., Poksireni, M.R., Christianah, O., Charanci, M.S., Mohammed, I. and Manga, M.M. (2022) Bacterial Blood Isolates in Children: Conventional vs. Bactec Automated Blood Culture System in a Tertiary Health Centre in Gombe, North East Nigeria. Open Journal of Medical Microbiology, 12, 101-116. https://doi.org/10.4236/ojmm.2022.123010
[12]	Elantamilan, D., Lyngdoh, V.W., Khyriem, A., Rajbongshi, J., Bora, I., Devi, S.T., et al. (2016) Comparative Evaluation of the Role of Single and Multiple Blood Specimens in the Outcome of Blood Cultures Using BacT/ALERT 3D (automated) Blood Culture System in a Tertiary Care Hospital. Indian Journal of Critical Care Medicine, 20, 530-533. https://doi.org/10.5005/ijccm-20-9-530
[13]	Ahmad, A., Iram, S., Hussain, S. and Yusuf, N.W. (2017) Diagnosis of Paediatric Sepsis by Automated Blood Culture System and Conventional Blood Culture. Journal of Pakistan Medical Association, 67, 192-195.
[14]	Peker, N., Couto, N., Sinha, B. and Rossen, J.W. (2018) Diagnosis of Bloodstream Infections from Positive Blood Cultures and Directly from Blood Samples: Recent Developments in Molecular Approaches. Clinical Microbiology and Infection, 24, 944-955. https://doi.org/10.1016/j.cmi.2018.05.007
[15]	Iskandar, K., Molinier, L., Hallit, S., Sartelli, M., Hardcastle, T.C., Haque, M., et al. (2021) Surveillance of Antimicrobial Resistance in Low- and Middle-Income Countries: A Scattered Picture. Antimicrobial Resistance and Infection Control, 10, 63. https://doi.org/10.1186/s13756-021-00931-w
[16]	Obaro, S., Lawson, L., Essen, U., Ibrahim, K., Brooks, K., Otuneye, A., et al. (2011) Community Acquired Bacteremia in Young Children from Central Nigeria—A Pilot Study. BMC Infectious Diseases, 11, Article No. 137. https://doi.org/10.1186/1471-2334-11-137
[17]	WHO (2021) Antimicrobial Resistance in the WHO African Region: A Systematic Literature Review. WHO. Regional Office for Africa.
[18]	https://fthgombe.gov.ng
[19]	Product Insert—B.D, T.M BACTEC. (Becton Dickinson). https://www.bd.com
[20]	Krumperman, P.H. (1983) Multiple Antibiotic Resistance Indexing of Escherichia coli to Indentify High-Risk Sources of Fecal Contamination of Foods. Applied and Environmental Microbiology, 46, 165-170. https://doi.org/10.1128/aem.46.1.165-170.1983
[21]	Isaacs-Long, Y., Myer, L. and Zar, H.J. (2017) Trends in Admissions, Morbidity and Outcomes at Red Cross War Memorial Children’s Hospital, Cape Town, 2004-2013. The South African Medical Journal, 107, 219-226. https://doi.org/10.7196/SAMJ.2017.v107i3.11364
[22]	Nnebue, C.C., Ebenebe, U.E., Adogu, P.O., Adinma, E.D., Ifeadike, C.O. and Nwabueze, A.S. (2014) Adequacy of Resources for Provision of Maternal Health Services at the Primary Health Care Level in Nnewi, Nigeria. Nigerian Medical Journal, 55, 235-241. https://doi.org/10.4103/0300-1652.132056
[23]	Oyedeji, R. and Abimbola, S. (2014) How Tertiary Hospitals Can Strengthen Primary Health Care in Nigeria. Nigerian Medical Journal, 55, 519-520. https://doi.org/10.4103/0300-1652.144715
[24]	Prasad, N., Sharples, K.J., Murdoch, D.R. and Crump, J.A. (2015) Community Prevalence of Fever and Relationship with Malaria among Infants and Children in Low-Resource Areas. The American Journal of Tropical Medicine and Hygiene, 93, 178-180. https://doi.org/10.4269/ajtmh.14-0646
[25]	Global Burden of Disease Study (2015) Global Burden of Disease Study 2015 (GBD 2015) Results. Insititute for Health Metrics and Evaluation (IHME), Seattle. https://www.healthdata.org
[26]	Maze, M.J., Bassat, Q., Feasey, N.A., Mandomando, I., Musicha, P. and Crump, J.A. (2018) The Epidemiology of Febrile Illness in Sub-Saharan Africa: Implications for Diagnosis and Management. Clinical Microbiology and Infection, 24, 808-814. https://doi.org/10.1016/j.cmi.2018.02.011
[27]	Kaboré, B., Post, A., Lompo, P., Bognini, J.D., Diallo, S., Kam, B.T.D., Rahamat-Langendoen, J., et al. (2021) Aetiology of Acute Febrile Illness in Children in a High Malaria Transmission Area in West Africa. Clinical Microbiology and Infection, 27, 590-596. https://doi.org/10.1016/j.cmi.2020.05.029
[28]	Orekan, J., Barbe, B., Oeng, S., Ronat, J.B., Letchford, J., Jacob, J., Affolabi, D. and Hardy, L. (2021) Culture Media for Clinical Bacteriology in Low- and Middle-Income Countries: Challenges, Best Practices for Preparation and Recommendations for Improved Access. Review. Clinical Microbiology and Infection, 10, 1400-1408. https://doi.org/10.1016/j.cmi.2021.05.016
[29]	Araujo da Silva, A.R., Jaszkowski, E., Schober, T., et al. (2020) Blood Culture Sampling Rate in Hospitalized Children as a Quality Indicator for Diagnostic Stewardship. Infection, 48, 569-575. https://doi.org/10.1007/s15010-020-01439-y
[30]	Dramowski, A., Cotton, M.F., Rabie, H. and Whitelaw, A. (2015) Trends in Paediatric Bloodstream Infections at a South African Referral Hospital. BMC Pediatrics, 15, Article No. 33. https://doi.org/10.1186/s12887-015-0354-3
[31]	Abubakar, I., Dalglish, S.L., Angell, B., Sanuade, O., Abimbola, S., Adamu, A.L., Adetifa, I.M., Colbourn, T., Ogunlesi, A.O., Onwujekwe, O., Owoaje, E.T., et al. (2022) The Lancet Nigeria Commission: Investing in Health and the Future of the Nation. The Lancet, 399, 1155-1200. https://doi.org/10.1016/S0140-6736(21)02488-0
[32]	Nigeria Multidimentional Poverty Index. (2022) https://mppn.org/wp-content/uploads/2022/11/MPI_web_Nov15_FINAL.pdf
[33]	Alizadeh, A.M., Kabiri, M.R. and Mohammadnia, M. (2016) Comparative Evaluation of Conventional and BACTEC Methods for Detection of Bacterial Infection. Tanaffos, 15, 112-116.
[34]	Barbé, B., Yansouni, C.P., Affolabi, D. and Jacobs, J. (2017) Implementation of Quality Management for Clinical Bacteriology in Low-Resource Settings. Clinical Microbiology and Infection, 23, 426-433. https://doi.org/10.1016/j.cmi.2017.05.007
[35]	Ombelet, S., Natale, A., Ronat, J.-B., Vandenberg, O., Jacobs, J. and Hardy, L. (2022) Considerations in Evaluating Equipment-Free Blood Culture Bottles: A Short Protocol for Use in Low-Resource Settings. PLOS ONE, 17, Article ID: e0267491. https://doi.org/10.1371/journal.pone.0267491
[36]	Wertheim, H.F.L., Huong, V.T.L. and Kuijper, E.J. (2021) Clinical Microbiology Laboratories in Low-Resource Settings, It Is Not Only about Equipment and Reagents, but also Good Governance for Sustainability. Clinical Microbiology and Infection, 271, 1389-1390.
[37]	Medugu, N. and Iregbu, K.C. (2017) Trends in Profiles of Bacteria Causing Neonatal Sepsis in Central Nigeria Hospital. African Journal of Clinical and Experimental Microbiology, 18, 49-52. https://doi.org/10.4314/ajcem.v18i1.7
[38]	Uzodinma, C.C., Njokanma, F., Ojo, O., Falase, M. and Ojo, T. (2013) Bacterial Isolates from Blood Cultures of Children with Suspected Sepsis in an Urban Hospital in Lagos: A Prospective Study Using BACTEC Blood Culture System. The Internet Journal of Pediatrics and Neonatology, 16.
[39]	Shobowale, E.O., Ogunsola, F.T., Oduyebo, O.O. and Ezeaka, V.I. (2015) A Study on the Outcome of Neonates with Sepsis at the Lagos University Teaching Hospital. International Journal of Medicine and Biomedical Research, 4, 41-49.
[40]	El-Din, A.-Z.A.K., Mohamed, M.A., Gad, W.H. and Lotfy, G.S. (2010) Prevalence of Microbial Pathogens in Blood Cultures: An Etiological and Histopathological Study. Journal of Taibah University for Science, 3, 23-32. https://doi.org/10.1016/S1658-3655(12)60017-X
[41]	Nkengasong, J.N., Nsubuga, P., Nwanyanwu, O., et al. (2010) Laboratory Systems and Services Are Critical in Global Health. American Journal of Clinical Pathology, 134, 368-373. https://doi.org/10.1309/AJCPMPSINQ9BRMU6
[42]	Nkengasong, J.N., Yao, K. and Onyebujoh, P. (2018) Laboratory Medicine in Low- Income and Middle-Income Countries: Progress and Challenges. The Lancet, 391, 1873-1875. https://doi.org/10.1016/S0140-6736(18)30308-8
[43]	Ogunkunle, T.O., Abdulkadir, M.B., Katibi, O.S., Bello, S.O., Raheem, R.A. and Olaosebikan, R. (2020) Pediatric Blood Culture Isolates and Antibiotic Sensitivity Pattern in a Nigerian Tertiary Hospital. Nigerian Journal of Medicine, 29, 261-264. https://doi.org/10.4103/NJM.NJM_55_20
[44]	Deku, J.G., Dakorah, M.P., Lokpo, S.Y., Orish, V.N., Ussher, F.A., Kpene, G.E., et al. (2019) The Epidemiology of Bloodstream Infections and Antimicrobial Susceptibility Patterns: A Nine-Year Retrospective Study at St. Dominic Hospital, Akwatia, Ghana. Journal of Tropical Medicine, 2019, Article ID: 6750864. https://doi.org/10.1155/2019/6750864
[45]	Seni, J., Mwakyoma, A.A., Mashuda, F., et al. (2019) Deciphering Risk Factors for Blood Stream Infections, Bacteria Species and Antimicrobial Resistance Profiles among Children under Five Years of Age in North-Western Tanzania: A Multicentre Study in a Cascade of Referral Health Care System. BMC Pediatrics, 19, Article No. 32. https://doi.org/10.1186/s12887-019-1411-0
[46]	Agyeman, P.K., Schlapbach, L.J., Giannoni, E., et al. (2017) Epidemiology of Blood Culture-Proven Bacterial Sepsis in Children in Switzerland: A Population-Based Cohort Study. The Lancet Child & Adolescent Health, 1, 124-133. https://doi.org/10.1016/S2352-4642(17)30010-X
[47]	Gay, L., Melenotte, C., Lakbar, I., Mezouar, S., Devaux, C., Raoult, D., et al. (2021) Sexual Dimorphism and Gender in Infectious Diseases. Frontiers in Immunology, 12, Article 698121. https://doi.org/10.3389/fimmu.2021.698121
[48]	Mège, J.-L., Bretelle, F. and Leone, M. (2018) Sex and Bacterial Infectious Diseases. New Microbes and New Infections, 26, S100-S103. https://doi.org/10.1016/j.nmni.2018.05.010
[49]	vom Steeg, L.G. and Klein, S.L. (2016) SeXX Matters in Infectious Disease Pathogenesis. PlOS Pathogens, 12, e1005374. https://doi.org/10.1371/journal.ppat.1005374
[50]	Laupland, K.B. (2013) Incidence of Bloodstream Infection: A Review of Population-Based Studies. Clinical Microbiology and Infection, 19, 492-500. https://doi.org/10.1111/1469-0691.12144
[51]	Moyo, S.J., Manyahi, J., Blomberg, B., Tellevik, M.G., Masoud, N.S., Aboud, S., Manji, K., Roberts, A.P., Hanevik, K., MØrch, K. and Langeland, N. (2020) Bacteraemia, Malaria, and Case Fatality among Children Hospitalized with Fever in Dar es Salaam, Tanzania. Frontiers in Microbiology, 11, Article 2118. https://doi.org/10.3389/fmicb.2020.02118
[52]	Connor, N.E., Islam, M.S., Mullany, L.C., et al. (2022) Risk Factors for Community-Acquired Bacterial Infection among Young Infants in South Asia: A Longitudinal Cohort Study with Nested Case–Control Analysis. BMJ Global Health, 7, e009706. https://doi.org/10.1136/bmjgh-2022-009706
[53]	Chukwumeze, F., Lenglet, A., Olubiyo, R., Lawal, A.M., Oluyide, B., Oloruntuyi, G., Ariti, C., Gomez, D., Roggeveen, H., Nwankwo, C., Augustine, N.A., Egwuenu, A., Maloba, G., Sherlock, M., Muhammad, S., Wertheim, H., Hopman, J. and Clezy, K. (2021) Multi-Drug Resistance and High Mortality Associated with Community- Acquired Bloodstream Infections in Children in Conflict-Affected Northwest Nigeria. Scientific Reports, 11, Article No. 20814. https://doi.org/10.1038/s41598-021-00149-1
[54]	Kibuuka, A., Byakika-Kibwika, P., Achan, J., Yeka, A., Nalyazi, J.N., Mpimbaza, A., Rosenthal, P.J. and Kamya, M.R. (2015) Bacteremia among Febrile Ugandan Children Treated with Antimalarials Despite a Negative Malaria Test. The American Journal of Tropical Medicine and Hygiene, 93, 276-280. https://doi.org/10.4269/ajtmh.14-0494
[55]	Crump, J.A., Ramadhani, H.O., Morrissey, A.B., Msuya, L.J., Yang, L.Y., Chow, S.C., Morpeth, S.C., Reyburn, H., Njau, B.N., Shaw, A.V., et al. (2011) Invasive Bacterial and Fungal Infections among Hospitalized HIV-Infected and HIV-Uninfected Children and Infants in Northern Tanzania. Tropical Medicine & International Health, 16, 830-837. https://doi.org/10.1111/j.1365-3156.2011.02774.x
[56]	Ahmed, M., Mirambo, M.M., Mushi, M.F., Hokororo, A. and Mshana, S.E. (2017) Bacteremia Caused by Multidrug-Resistant Bacteria among Hospitalized Malnourished Children in Mwanza, Tanzania: A Cross Sectional Study. BMC Research Notes, 10, Article No. 62. https://doi.org/10.1186/s13104-017-2389-z
[57]	Meremikwu, M.M., Nwachukwu, C.E., Asuquo, A.E., Okebe, J.U. and Utsalo, S.J. (2005) Bacterial Isolates from Blood Cultures of Children with Suspected Septicaemia in Calabar, Nigeria. BMC Infectious Diseases, 5, Article No. 110. https://doi.org/10.1186/s13104-017-2389-z
[58]	Nwadioha, S.I., Nwokedi, E.O., Kashibu, E., Odimayo, M.S. and Okwori, E.E. (2010) A Review of Bacterial Isolates in Blood Cultures of Children with Suspected Septicemia in a Nigerian Tertiary Hospital. African Journal of Microbiology Research, 4, 222-225.
[59]	Samuel, S.O., Fadeyi, A., Akanbi, A.A., Ameen, N.B., Nwabuisi, C. and Onile, B.A. (2006) Bacterial Isolates of Blood Cultures in Patients with Suspected Septicaemia in Ilorin, Nigeria. African Journal of Medicine and Medical Sciences, 35, 137-141.
[60]	Onipede, A.O., Onayade, A.A., Elusanya, J.B.E., Obiajunwa, P.O., Ogundare, E.O.O., Olaniran, O.O., et al. (2009) Invasive Bacterial Isolates from Children with Severe Infections in a Nigerian Hospital. The Journal of Infection in Developing Countries, 3, 429-436, https://doi.org/10.3855/jidc.413
[61]	Motayo, B.O., Akinduti, P., Ogiogwa, J.I., Akingbade, O.A. Aboderin, W.B., Adeyakinu, O. and Akinbo, J.A. (2011) Bacteriological Profile of Blood Cultures from Children with Presumedsepticaemia in a Tertiary Hospital in Abeokuta, Nigeria. Nature and Science, 9, 141-144.
[62]	Ogunlesi, T.A., Ogunfowora, O.B., Osinupebi, O. and Olanrewaju, D.M. (2011) Changing Trends in Newborn Sepsis in Sagamu, Nigeria: Bacterial Aetiology, Risk Factors and Antibiotic Susceptibility. Journal of Paediatrics and Child Health, 47, 5-11. https://doi.org/10.1111/j.1440-1754.2010.01882.x
[63]	Kashibu, E., Ihesiulor, G.U. and Tasabeeh, M.H. (2012) Bacteria Associated with Septicemia in Children and Their Antimicrobial Sensitivity Pattern, Kano, Nigeria. Asian Journal of Biological and Life Sciences, 1, 174-177.
[64]	Kingsley, O.C., Ifeanyi, A.O., Edet, A.E. and Smart, O.C. (2013) Bacteriologic Profile and Antibiotic Susceptibility Pattern of Suspected Septicaemic Patients in Uyo, Nigeria. Research Journal of Medical Sciences, 7, 35-39.
[65]	Onubogu, U.C., Anochie, I.C. and Akani, N.A. (2015) Prevalence of Bacteraemia in Febrile, Under-Five Children in the Children’s Outpatient Clinic of University of Port Harcourt Teaching Hospital, Port Harcourt, Nigeria. Nigerian Journal of Paediatrics, 42, 93-97. https://doi.org/10.4314/njp.v42i2.4
[66]	Peterside, O., Pondei, K. and Adeyemi, O.O. (2017) Bacteriological Profile of Childhood Sepsis at a Tertiary Health Centre in Southern Nigeria. Journal of Medical and Dental Science Research, 4, 11-15.
[67]	Adedokun, A.A., Onosakponome, E.O. and Nyenke, C.U. (2020) Incidence of Septicemia in Children Attending University of Port Harcourt Teaching Hospital, Port Harcourt, Nigeria. Journal of Advances in Medicine and Medical Research, 32, 26-35. https://doi.org/10.9734/jammr/2020/v32i830463
[68]	Chukwu, E.E., Awoderu, O.B., Enwuru, C.A., et al. (2022) High Prevalence of Resistance to Third-Generation Cephalosporins Detected among Clinical Isolates from Sentinel Healthcare Facilities in Lagos, Nigeria. Antimicrobial Resistance & Infection Control, 11, Article No. 134. https://doi.org/10.1186/s13756-022-01171-2
[69]	Oyekale, O.T., Ojo, B.O., Olajide, A.T. and Oyekale, O.I. (2022) Bacteriological Profile and Antibiogram of Blood Culture Isolates from Bloodstream Infections in a Rural Tertiary Hospital in Nigeria. African Journal of Laboratory Medicine, 11, a1807. https://doi.org/10.4102/ajlm.v11i1.1807
[70]	Hill, P.C., Onyeama, C.O., Ikumapayi, U.N., Secka, O., Ameyaw, S., Simmonds N., Donkor, S.A., Howie, S.R., Tapgun, M., Corrah, T. and Adegbola, R.A. (2007) Bacteraemia in Patients Admitted to an Urban Hospital in West Africa. BMC Infectious Diseases, 7, Article No. 2. https://doi.org/10.1186/1471-2334-7-2
[71]	Kitila, K.T., Taddese, B.D., Hailu, T., Sori, L. and Geleto, S. (2018) Assessment of Bacterial Profile and Antimicrobial Resistance Pattern of Bacterial Isolates from Blood Culture in Addis Ababa Regional Laboratory, Addis Ababa, Ethiopia. Journal of Clinical Microbiology, 7, Article ID: 1000312.
[72]	Acquah, S.E., Quaye, L., Sagoe, K., Ziem, J.B., Bromberger, P.I. and Amponsem, A.A. (2013) Susceptibility of Bacterial Etiological Agents to Commonly-Used Antimicrobial Agents in Children with Sepsis at the Tamale Teaching Hospital. BMC Infectious Diseases, 13, Article No. 89. https://doi.org/10.1186/1471-2334-13-89
[73]	Crichton, H., O’Connell, N., Rabie, H., Whitelaw, A.C. and Dramowski, A. (2018) Neonatal and Paediatric Bloodstream Infections: Pathogens, Antimicrobial Resistance Patterns and Prescribing Practice at Khayelitsha District Hospital, Cape Town, South Africa. The South African Medical Journal, 108, 99-104. https://doi.org/10.7196/SAMJ.2018.v108i2.12601
[74]	Adedoyin, O.T., Ibrahim, M., Johnson, W.B.R., Ojuawo, A.I., Mokuolu, O.A., Ernest, S.K., et al. (2013) Bacterial Isolates of Blood in Children with Suspected Septicaemia in a Nigerian Tertiary Hospital. The Tropical Journal of Health Sciences, 20.
[75]	Iroh Tam, P.-Y., Hernandez-Alvarado, N., Schleiss, M.R., Hassan-Hanga, F., Onuchukwu, C., Umoru, D., et al. (2016) Molecular Detection of Streptococcus pneumoniae on Dried Blood Spots from Febrile Nigerian Children Compared to Culture. PlOS ONE, 11, e0152253. https://doi.org/10.1371/journal.pone.0152253
[76]	Popoola, O., Kehinde, A., Ogunleye, V., Adewusi, O.J., Toy, T., Mogeni, O.D., et al. (2019) Bacteremia Among Febrile Patients Attending Selected Healthcare Facilities in Ibadan, Nigeria. Clinical Infectious Diseases, 69, S466-S473. https://doi.org/10.1093/cid/ciz516
[77]	Obaro, S.K., Hassan-Hanga, F., Olateju, E.K., Umoru, D., Lawson, L., Olanipekun, G., et al. (2015) Salmonella Bacteremia among Children in Central and Northwest Nigeria, 2008-2015. Clinical Infectious Diseases, 61, S325-S331. https://doi.org/10.1093/cid/civ745
[78]	Marks, F., von Kalckreuth, V., Aaby, P., Adu-Sarkodie, Y., El Tayeb, M.A., Ali, M., et al. (2017) Incidence of Invasive Salmonella Disease in Sub-Saharan Africa: A Multicentre Population-Based Surveillance Study. The Lancet Global Health, 5, e310-e323. https://doi.org/10.1016/S2214-109X(17)30022-0
[79]	Iroh-Tam, P.Y., Thielen, B.K., Obaro, S.K., Brearley, A.M., Kaizer, A.M., Chu, H., et al. (2017) Childhood Pneumococcal Disease in Africa—A Systematic Review and Meta-Analysis of Incidence, Serotype Distribution, and Antimicrobial Susceptibility. Vaccine, 35, 1817-1827. https://doi.org/10.1016/j.vaccine.2017.02.045
[80]	Iliya, J., Shatima, D.R., Tagbo, B.N., Ayede, A.I., Fagbohun, A.O., Rasaq, A., et al. (2023) Pneumonia Hospitalizations and Mortality in Children 3 - 24-Month-Old in Nigeria from 2013 to 2020: Impact of Pneumococcal Conjugate Vaccine Ten Valent (PHiD-CV-10). Human Vaccines & Immunotherapeutics, 19, Article ID: 2162289. https://doi.org/10.1080/21645515.2022.2162289
[81]	Bar-Zeev, N., Swarthout, T.D., Everett, D.B., Alaerts, M., Msefula, J., Brown, C., Bilima, S., Mallewa, J., King, C., von Gottberg, A., Verani, J.R., et al. (2021) Impact and Effectiveness of 13-Valent Pneumococcal Conjugate Vaccine on Population Incidence of Vaccine and Non-Vaccine Serotype Invasive Pneumococcal Disease in Blantyre, Malawi, 2006–18: Prospective Observational Time-Series and Case-Control Studies. The Lancet Global Health, 9, e989-e998. https://doi.org/10.1016/S2214-109X(21)00165-0
[82]	Hammitt, L.L., Etyang, A.O., Morpeth, S.C., Ojal, J., Mutuku, A., Mturi, N., Moisi, J.C., Adetifa, I.M., Karani, A., Akech, D.O., Otiende, M., et al. (2019) Effect of Ten- Valent Pneumococcal Conjugate Vaccine on Invasive Pneumococcal Disease and Nasopharyngeal Carriage in Kenya: A Longitudinal Surveillance Study. The Lancet, 393, 2146-2154. https://doi.org/10.1016/S0140-6736(18)33005-8
[83]	John, M.S., Munilakshmi, P. and Deepa, T. (2015) Significance of Citrobacter as an Emerging Nosocomial Pathogen with Special Reference to It S Antibiotic Susceptibility Pattern in a tertiary Care Hospital, Nellore, AP. India. International Journal of Current Microbiology and Applied Sciences, 4, 841-847.
[84]	Nayar, R., Shukla, I. and Sultan, A. (2014) Epidemiology, Prevalence and Identification of Citrobacter Species in Clinical Specimens in a Tertiary Care Hospital in India. International Journal of Scientific and Research Publications, 4, 1-6.
[85]	Liu, L.H., Wang, N.Y., Wu, A.Y., Lin, C.C., Lee, C.M. and Liu C.P. (2018) Citrobacter freundii Bacteremia: Risk Factors of Mortality and Prevalence of Resistance Genes. Journal of Microbiology, Immunology and Infection, 51, 565-572. https://doi.org/10.1016/j.jmii.2016.08.016
[86]	Ibrahim, H.A., Yakubu, Y.M., Farouk, A.G., Ambe, P. and Gadzama, G.B. (2021) Profile of Bacterial Pathogens Causing Infections in Children with Sickle Cell Anaemia in Maiduguri. Nigerian Postgraduate Medical Journal, 28, 218-224. https://doi.org/10.4103/npmj.npmj_531_21
[87]	Iregbu, K.C., Zubair, K.O., Modibbo, I.F., Aigbe, A.I., Sonibare, S.A. and Ayoola, O.M. (2013) Neonatal Infections Caused by Escherichia coli at the National Hospital, Abuja: A Three-Year Retrospective Study. African Journal of Clinical and Experimental Microbiology, 14, 95-100. https://doi.org/10.4314/ajcem.v14i2.9
[88]	Christopher, A., Mshana, S.E., Kidenya, B.R., Hokororo, A. and Morona, D. (2013) Bacteremia and Resistant Gram-Negative Pathogens among Under-Fives in Tanzania. Italian Journal of Pediatrics, 39, Article No. 27. https://doi.org/10.1186/1824-7288-39-27
[89]	Musicha, P., Cornick, J.E., Bar-Zeev, N., French, N., Masesa, C., Denis, B., Kennedy, N., Mallewa, J., Gordon,, M.A., Msefula, C.L., Heyderman, R.S., et al. (2017) Trends in Antimicrobial Resistance in Bloodstream Infection Isolates at a Large Urban Hospital in Malawi (1998–2016): A Surveillance Study. The Lancet Infectious Diseases, 17, 1042-1052. https://doi.org/10.1016/S1473-3099(17)30394-8
[90]	Habyarimana, T., Murenzi, D., Musoni, E., Yadufashije, C. and Niyonzima, N.F. (2021) Bacteriological Profile and Antimicrobial Susceptibility Patterns of Bloodstream infection at Kigali University Teaching Hospital. Infection and Drug Resistance, 23, 699-707. https://doi.org/10.2147/IDR.S299520
[91]	Bhat, Y.R., Lewis, L.E. and Ke, V. (2011) Bacterial Isolates of Early-Onset Neonatal Sepsis and Their Antibiotic Susceptibility Pattern between 1998 and 2004: An Audit from a Center in India. Italian Journal of Pediatrics, 37, Article No. 32. https://doi.org/10.1186/1824-7288-37-32
[92]	Sora, G.H., Gachara, G., Ichinose, Y., Ngayo, M.O., Odoyo, E. and Karama, M. (2020) Epidemiology of Bacterial Septicemia among Children under Five in Mbita Subcounty, South Nyanza, Kenya. Epidemiology, 10, 40-49.
[93]	Huang, C. (2020) Extensively Drug-Resistant Alcaligenes faecalis Infection. BMC Infectious Diseases, 20, Article No. 833. https://doi.org/10.1186/s12879-020-05557-8
[94]	Mordi, R.M., Burke, M.E., Odjadjare, E.E., Enabulelen, S.A. and Umeh, O.J. (2015) Prevalence of Urinary Tract Infections among Pregnant Women in University of Benin Teaching Hospital (UBTH) Benin City, Nigeria. Journal of Asian Scientific Research, 5, 198-204. https://doi.org/10.18488/journal.2/2015.5.4/2.4.198.204
[95]	Reddy, E.A., Shaw, A.V. and Crump, J.A. (2010) Community-Acquired Bloodstream Infections in Africa: A Systematic Review and Meta-Analysis. The Lancet Infectious Diseases, 10, 417-432. https://doi.org/10.1016/S1473-3099(10)70072-4
[96]	Marchello, C.S., Dale, A.P., Pisharody, S., Rubach, M.P. and Crump, J.A. (2019) A Systematic Review and Meta-Analysis of the Prevalence of Community-Onset Bloodstream Infections among Hospitalized Patients in Africa and Asia. Antimicrobial Agents and Chemotherapy, 64, e01974-19. https://doi.org/10.1128/AAC.01974-19
[97]	Al-Zakhari, R., Suhail, M., Ataallah, B., Aljammali, S. and Grigos, A. (2020) Rare But Fetal Case of Cavitary Pneumonia Caused by Alcaligenes faecalis. Cureus, 12, e8934. https://doi.org/10.7759/cureus.8934
[98]	Chowdhury, R.N., Akter, N., Ahmed, S. and Chowdhury, A.H. (2021) Comparison of Conventional and Automated Blood Culture Methods for the Diagnosis of Neonatal Septicemia. Bangladesh Journal of Medical Microbiology, 15, 12-18. https://doi.org/10.3329/bjmm.v15i2.57815
[99]	Fuller, W.L., Aboderin, A.O., Yahaya, A., Adeyemo, A.T., Gahimbare, L., Kapona, O., Hamzat, O.T. and Bassoum, O. (2022) Gaps in the Implementation of National Core Elements for Sustainable Antimicrobial Use in the WHO-African Region. Frontiers in Antibiotics, 1, Article 1047565. https://doi.org/10.3389/frabi.2022.1047565
[100]	Nyeko, R., Otim, F., Obiya, E.M. and Abala, C. (2022) Pre-Hospital Exposures to Antibiotics among Children Presenting with Fever in Northern Uganda: A Facility-Based Cross-Sectional Study. BMC Pediatrics, 22, Article No. 322. https://doi.org/10.1186/s12887-022-03375-2
[101]	Valia, D., Ingelbeen, B., Kaboré, B., et al. (2022) Use of WATCH Antibiotics Prior to Presentation to the Hospital in Rural Burkina Faso. Antimicrobial Resistance & Infection Control, 11, Article No. 59. https://doi.org/10.1186/s13756-022-01098-8
[102]	Sulis, G., Adam, P., Nafade, V., Gore, G., Daniels, B., Daftary, A., Das, J., Gandra, S. and Pai, M. (2020) Antibiotic Prescription Practices in Primary Care in Low-and Middle-Income Countries: A Systematic Review and Meta-Analysis. PLOS Medicine, 17, e1003139. https://doi.org/10.1371/journal.pmed.1003139
[103]	Aboderin, A.O., Adeyemo, A.T., Olayinka, A.A., Oginni, A.S., Adeyemo, A.T., Oni, A.A., Olabisi, O.F., Fayomi, O.D., Anuforo, A.C., Egwuenu, A., Hamzat, O. and Fuller, W. (2021) Antimicrobial Use among Hospitalized Patients: A Multi-Center, Point Prevalence Survey across Public Healthcare Facilities, Osun State, Nigeria. Germs, 11, 523-535. https://doi.org/10.18683/germs.2021.1287
[104]	Vounba, P., Loul, S., Tamadea, L.F. and Siawaya, J.F.D. (2022) Microbiology Laboratories Involved in Disease and Antimicrobial Resistance Surveillance: Strengths and Challenges of the Central African States. African Journal of Laboratory Medicine, 11, a1570. https://doi.org/10.4102/ajlm.v11i1.1570
[105]	Roberts, T., Dahal, P., Shrestha, P., Schilling, W., Shrestha, R., Ngu, R., Huong, V.T., van Doorn, H.R., Phimolsarnnousith, V., Miliya, T. and Crump, J.A. (2022) Antimicrobial Resistance Patterns in Bacteria Causing Febrile Illness in Africa, South Asia and Southeast Asia: A Systematic Review of Published Aetiological Studies from 1980-2015. International Journal of Infectious Diseases, 122, 612-621. https://doi.org/10.1016/j.ijid.2022.07.018
[106]	WHO (2021) Antimicrobial Resistance in the WHO African Region: A Systematic Literature Review. WHO. Regional Office for Africa.
[107]	Williams, P.C., Isaacs, D. and Berkley, J.A. (2018) Antimicrobial Resistance among Children in Sub-Saharan Africa. The Lancet Infectious Diseases, 18, e33-e44. https://doi.org/10.1016/S1473-3099(17)30467-X
[108]	Shrestha, P., Cooper, B.S., Coast, J., Oppong, R., Do Thi Thuy, N., Phoda, T., et al. (2018) Enumerating the Economic Cost of Antimicrobial Resistance Per Antibiotic Consumed to Inform the Evaluation of Interventions Affecting Their Use. Antimicrobial Resistance & Infection Control, 7, Article No. 98. https://doi.org/10.1186/s13756-018-0384-3
[109]	Bernabé, K.J., Langendorf, C., Fordnronat, J.-B. and Murphy, R.A. (2017) Antimicrobial Resistance in West Africa: A Systematic Review and Meta-Analysis. International Journal of Antimicrobial Agents, 50, 629-639. https://doi.org/10.1016/j.ijantimicag.2017.07.002
[110]	WHO (2015) Guideline: Managing Possible Serious Bacterial Infection in Young Infants When Referral Is Not Feasible. World Health Organization.
[111]	Menkem, E.Z., Nanfah, A.L., Takang, T., Awah, L.R., Achua, K.A., Akume, S.E., et al. (2023) Attitudes and Practices of the Use of Third-Generation Cephalosporins among Medical Doctors Practicing in Cameroon. International Journal of Clinical Practice, 2023, Article ID: 8074413. https://doi.org/10.1155/2023/8074413
[112]	Versporten, A., Bielicki, J., Drapier, N., et al. (2016) The Worldwide Antibiotic Resistance and Prescribing in European Children (ARPEC) Point Prevalence Survey: Developing Hospital-Quality Indicators of Antibiotic Prescribing for Children. Journal of Antimicrobial Chemotherapy, 71, 1106-1117. https://doi.org/10.1093/jac/dkv418
[113]	Lester, R., Musicha, P., Van Ginneken, N., Dramowski, A., Hamer, D.H., Garner, P. and Feasey, N.A. (2020) Prevalence and Outcome of Bloodstream Infections Due to Third-Generation Cephalosporin-Resistant Enterobacteriaceae in Sub-Saharan Africa: A Systematic Review. Journal of Antimicrobial Chemotherapy, 75, 492-507.
[114]	Haindongo, E.H., Ndakolo, D., Hedimbi, M., Vainio, O., Hakenen, A. and Vuopio, J. (2023) Antimicrobial Resistance Prevalence of Escherichia coli and Staphylococcus aureus amongst Bacteremic Patients in Africa: A Systematic Review. Journal of Global Antimicrobial Resistance, 32, 35-43. https://doi.org/10.1016/j.jgar.2022.11.016
[115]	Okomo, U., Akpalu, E.N.K., Le Doare, K., Roca, A., Cousens, S., Jarde, A., et al. (2019) Aetiology Invasive Bacterial Infection and Antimicrobial Resistance in Neonates in Sub Saharan AFRICA: A Systematic Review and Meta Analysis in Line with STROBE-IN Guidelines. The Lancet, 19, 1219-1234. https://doi.org/10.1016/S1473-3099(19)30414-1
[116]	Droz, N., Hsia, Y., Ellis, S., Dramowski, A., Sharland, M. and Basmaci, R. (2019) Bacterial Pathogens and Resistance Causing Community Acquired Paediatric Bloodstream Infections in Low- and Middle-Income Countries: A Systematic Review and Meta-Analysis. Antimicrobial Resistance & Infection Control, 8, Article No. 207. https://doi.org/10.1186/s13756-019-0673-5

Journals Menu

Follow SCIRP

	+1 323-425-8868
	customer@scirp.org
	+86 18163351462(WhatsApp)
	1655362766

	Paper Publishing WeChat

Journals Menu

Home

About SCIRP

Service

Policies