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Open Access 01.12.2023 | Research

Antibiotics susceptibility patterns of uropathogenic bacteria: a cross-sectional analytic study at Kanifing General Hospital, The Gambia

verfasst von: Abou Kebbeh, Paul Dsane-Aidoo, Kawsu Sanyang, Sheriffo M. K. Darboe, Nuha Fofana, Donne Ameme, Abdoulie M. Sanyang, Kalifa Sanneh Darboe, Saffiatou Darboe, Bakary Sanneh, Ernest Kenu, Francis Anto

Erschienen in: BMC Infectious Diseases | Ausgabe 1/2023

Abstract

Background

Antimicrobial resistance poses a public health threat for the treatment of community-acquired urinary tract infections. This study determined the susceptibility patterns of uropathogens and associated risk factors among outpatients diagnosed with urinary tract infections at the Kanifing General Hospital in the Gambia.

Methods

A cross-sectional analytic study was conducted among patients with suspected urinary tract infections at Kanifing General Hospital from March to May 2021. Data on socio-demographic and other risk factors were collected from the study participants using a structured pre-tested questionnaire. Mid-stream urine samples were collected, and bacteria identification and antimicrobial susceptibility testing done using standard microbiological methods. Descriptive and inferential statistical analysis were done to determine factors associated with urinary tract infection at 95% confidence level and a p -value < 0.05.

Results

A total of 422 patients were enrolled with 82.5% (348/422) being females. The prevalence of community acquired urinary tract infection was 12.8% (54/422). Escherichia coli was the most prevalent isolate (74.1%, 40/54), followed by Klebsiella spp (8.5%, 10/54). Antimicrobial resistance was highest for Ampicillin (87.0%, 47/54), Trimethoprim/Sulfamethoxazole (77.8%, 42/54) and Tetracycline (75.9%, 41/54). Uropathogens sensitivity was 77.8% (42/54) for Nitrofurantoin and 75.9% (41/54) for Ceftazidime. Being female (aOR 5.90 95% CI = 1.48–23.67), previous history of urinary tract infection (aOR 2.34, 95% CI = 1.06–5.14), use of unprescribed antibiotics (aOR 2.0, 95% CI = 1.05–3.62) and having no formal education (aOR 8.02, 95% CI = 1.04–62.0) were significant factors associated for having uropathogenic bacterial infection.

Conclusion

E. coli was the most prevalent uropathogen isolated. Ciprofloxacin, Nitrofurantoin and Ceftazidime were the most sensitive antibiotics. Routine surveillance of susceptibility of uropathogenic bacteria would be helpful to update clinicians on the choice of antibiotics.

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ATCC

American Type Culture Collection

AMR

Antimicrobial Resistance

CA-UTI

Community acquired Urinary Tract infection

CFU

Colony forming unit

CLSI

Clinical Laboratory and Standard Institute

KGH

Kanifing General Hospital

MDR

Multi-Drug Resistant

OPD

Outpatient Department

UTI

Urinary Tract Infection

WHO

World Health Organization

Background

Urinary Tract Infections (UTIs) are among the most frequent community- and hospital-acquired infections with an increasing antibiotic resistance [1]. The disease is predominantly caused by Gram-negative bacteria including Escherichia coli, Klebsiella spp, Proteus mirabilis, Pseudomonas aeruginosa and Gram-positive bacteria such as Staphylococcus saprophyticus [2]. Globally, about 150 million people are diagnosed with UTIs yearly, resulting in an estimated health care expenditure in excess of six billion dollars [3].

The prevalence of uropathogens is associated with several factors including age, poor economic status, poor hygiene, hospitalization, catheterization, sexual activities, pregnancy and diabetes [4‐7]. The infections are common in young, sexually active women, with incidence exceeding 0.5 episodes per person per year, and about 30% experiencing recurrent infections [8]. Reports from Sub-Saharan Africa show varying prevalence levels among different populations and age-groups; 89.17% among female patients in Nigeria [1], 39.13% among adult outpatients in Uganda [9], 10.1% in Ghana [10], 26.7% among adult patients in Senegal [11] and 21.2% among Gambian children [12].

Antimicrobial misuse in the management of UTIs contributes significantly to the development of antimicrobial resistance (AMR). AMR was estimated to cause about 700,000 deaths per year globally, and if the present trend continues, it might cause over 10 million deaths per year by 2050. In Africa, if action is not taken an estimated 4.1 million people could die as a result of treatment failure by 2050 [13]. This projection has recently been enforced with Western sub-Saharan Africa having the highest burden with 27.3 deaths per 100,000 attributable to AMR and 114.8 deaths per 100,000 associated with AMR in 2019 [14]. High levels of AMR have been reported in West Africa -76.8% in Nigeria [15], including high levels of multidrug resistance (MDR); 80.1% in Ghana [10], 60% in Senegal [11] and 9.0% in The Gambia [16].

In The Gambia, very few reports on the antibiotic susceptibility patterns of uropathogenic bacteria are available [16]. Most health facilities rely on urinalysis and urine microscopy results for treatment without performing antimicrobial susceptibility tests. As a result, clinicians frequently use empirical therapy without knowing the sensitivity of the specific antibiotics being used. With the emergence of antibiotic resistance in the Gambia [12, 17, 18], clinicians need information on locally prevalent uropathogenic bacteria strains and their susceptibility patterns to ensure antimicrobial stewardship. This study determined the antibiotics susceptibility patterns and factors associated with uropathogenic bacterial infection in patients with Community Acquired-Urinary Tract Infections (CA-UTIs) attending the Kanifing General Hospital (KGH) in The Gambia.

Materials and methods

Study design

A cross-sectional analytical study was conducted among clients attending the Out-Patients-Department (OPD) of the Kanifing General Hospital. Patients clinically suspected of community-acquired urinary tract infection (CA-UTI) by attending clinicians at the OPD and referred for laboratory confirmation from March to May 2021 were consecutively recruited. Mid-stream urine samples were received from the patients and culture and sensitivity test performed. Data on demographic characteristics, risk factors for urinary tract infection, including previous UTI, catheterization, and antibiotic use were collected from the patients using a case report form and a structured questionnaire.

Study setting

The Kanifing General Hospital (KGH) is located in Kanifing Municipal Area Council (KMC), which is one of the eight Local Government Areas (LGAs) in The Gambia [19]. The municipality is one of the most densely populated areas and lies in the western part of Banjul, the capital city. The municipality includes Serekunda, which is the largest urban area in the Gambia. According to the Gambia Bureau of Statistics, the population of Kanifing LGA is 382,096 [19]. The hospital is one of the main tertiary care centers in the country that provides health care services to a large section of the population in KMC. The hospital receives patients mainly from the urban area and is the second major point of referral within the urban area. The hospital has a total bed capacity of 340. In addition to general medical services, the hospital provides surgical, laboratory and radiography services.

Study population and sampling techniques

A total of 422 urine samples were estimated for this study using the Cochran formula [20]. Patients who were clinically diagnosed with CA-UTI at the OPD by clinicians and referred to the laboratory for confirmation were consecutively enrolled into the study until the predetermined sample size was obtained. Patients already on antibiotic treatment for any condition and pregnant women mothers in labour were excluded from the study [21].

Data and specimen collection

Data on socio-demographic characteristics (sex, age, employment, education and marital status), risk factors for UTI (history of UTI, pregnancy, urethral catheterization, hospitalization, history of diabetes mellitus), were collected directly from participants using a structured questionnaire and case report forms. Also, information on antibiotic usage (consumption within the last three months, purchase from street vendors, self-medication, adherence to prescription and sharing of left-over antibiotics) were collected.

After detailed instructions, study participants were given a clean, sterile screw-capped labeled container to collect clean-catch midstream urine. A volume of 5–10 ml of urine specimen was requested from each patient. For female patients, they were informed to do handwashing and cleanse the area around the urethral opening with clean water, dry with sterile gauze and collect the urine with the labia held apart. Male patients were instructed to wash hands prior to collection and collect urine in the middle of the urine flow [22]. The collected samples were analyzed within one hour after collection [23]. Children who were too young to follow aseptic instructions, were supported by parents.

Sample processing and identification of isolates

Using calibrated inoculating loop 0.001 ml, each urine sample was inoculated on Cysteine Lactose Electrolytes Deficient (CLED) agar plates and incubated at 37 °C for 18–24 h. After overnight incubation, colonies were counted for the estimation of bacterial load per milliliter of urine sample [24]. A specimen was considered positive for UTI if the isolates cultivated had a concentration of ≥ 10⁵ cfu/ml. After 24 h, the bacterial colonies with pure and significant growth were further confirmed using standard biochemical tests. All positive urine cultures with significant bacteriuria were identified using Analytical Profile Index 20E (API 20E) (bioMerieux) identification system [25].

Antimicrobial susceptibility testing

Antimicrobial Susceptibility Testing (AST) was done using Kirby Bauer’s disc diffusion method following standard guidelines of Clinical and Laboratory Standard Institute (CLSI) [26]. The isolates were tested for their resistance using the following antibiotics that are locally available; Ampicillin (AMP 10 µg), Cefotaxime (CTX 30 µg), Amoxicillin-clavulanic acid, Gentamycin (GEN) (10 µg), Tetracycline (TET 15 µg), Chloramphenicol (CHL 10 µg), Nalidixic acid (NAL 30 µg), Ciprofloxacin (CIP 5 µg), sulfamethoxazole/trimethoprim (SXT 25 µg) and Imipenem (I 10 µg) [17]. ESBL phenotypic was determined based on a ≥ 5 mm increase in a zone diameter for either Cefotaxime or Ceftazidime antibiotics tested in combination with Clavulanate versus the zone of inhibition of the antibiotics when tested alone [26]. Multidrug resistance was defined as bacteria being resistant to three or more antimicrobial classes [27].

Quality control

The laboratory analysis was conducted using Standard Operating Procedures. The culture media were tested for both sterility and performance by inoculating 5% of the batch after preparation [28]. Standard reference strains of Escherichia coli ATCC 25922, Klebsiella pneumoniae ATCC 700603 were used during culture and AST to ensure accuracy of tests done.

Data analysis

Data were entered into Microsoft Excel, cleaned, coded, and analyzed using Stata software version 16.1. All statistical tests were performed at a 95% confidence level. Prevalence in UTI and antibiotic susceptibility patterns were described using proportions. Binary logistic regression analysis was carried out, and odds ratios (OR) [crude odds (cOR) and adjusted odds (aOR)] estimated to determine association between each of the independent variables and dependent variable (uropathogenic bacterial infection). Variables with p < 0.05 at 95% confidence level were considered statistically significant.

Results

Background characteristics of study participants

A total of 422 patients participated in the study, most of them female (82.5%, 348/422), married 67.5% (285/422), median age, 30 years (IQR = 30—40 years), and 46.2% (195/422) without formal education (Table 1).

Table 1

Demographic characteristics of the study participants visiting Kanifing General Hospital, 2021

Characteristics	Frequency	Percentage
Sex
Male	74	17.5
Female	348	82.5
Marital status
Single	123	29.2
Married	285	67.5
Divorce	14	3.3
Pregnancy Status
Pregnant	67	19.3
Not pregnant	281	80.8
Level of Education
No formal education	195	46.2
Primary	40	9.5
Secondary	123	29.2
Tertiary	64	15.2
Occupation
Not employed	223	52.8
Self-employed	83	19.7
Civil servant	46	10.9
Student	70	16.6

Prevalence of uropathogenic bacteria infection

A total of 54 samples yielded significant growth of uropathogenic bacteria (≥ 10⁵ cfu/mL); giving an overall prevalence of uropathogenic bacterial infection of 12.8% (54/422), 95% CI [0.098–0.164]. Bacteria belonging to five different Genera were isolated; these were, Escherichia coli, Klebsiella spp. Pseudomonas aeruginosa, Proteus spp. and Citrobacter spp. (Fig. 1). The predominant bacterial isolates were E. coli (74.1%, 40/54), and Klebsiella spp. (18.5% (10/54). A higher proportion of females 14.66% (51/348) than males 4.05% (3/74) had uropathogenic bacterial infection. The difference was statistically significant (p = 0.03). No significant difference was found in the prevalence of infection among the different age-groups (Fig. 2).

Antibiotics susceptibility patterns of uropathogenic bacterial isolates

Among the isolates tested against various antibiotics, 87.0% (47/54) were resistant to Ampicillin. High proportions of the bacteria were also resistant to Tetracycline and Trimethoprim/Sulfamethoxazole (75.9%, 41/54) and (77.8%, 42/54) respectively. In addition, 61.1% (33/54) and 53.9% (29/54) of the isolates were also observed to be resistant to Ciprofloxacin and Nalidixic acid, respectively. However, Nitrofurantoin (77.8%, 42/54), Ceftazidime (75.9%, 41/54), Cefotaxime (72.2%, 39/54), Gentamycin (72.2%, 39/54) and Amoxicillin-clavulanic acid (68.5%, 33/54) were observed to be sensitive against the isolates. All the isolates were 100% sensitive to Imipenem (Table 2).

Table 2

Antimicrobial susceptibility pattern of uropathogenic bacteria isolated from participants with CA-UTI, Kanifing General Hospital, 2021 (N = 54)

Uropathogens		Antibiotics n(%)
Uropathogens		AMC	CTX	AMP	NIT	GEN	CIP	TET	CHL	SXT	NA	I
E. coli ( 40)	S	5(12.5)	31(77.5)	3(7.5)	34(85.0)	31(77.5)	25(62.5)	7(17.5)	32(80.0)	8(20.0)	18(45.0)	40(100)
	I	6(15.0)	1(2.5)	1(2.5)	1(2.5)	0(0.0)	0(0.0)	2(5.0)	3(7.5)	0(0.0)	1(2.5)	0(0.0)
	R	29(72.5)	8(20.0)	36(90.0)	5(12.5)	9(22.5)	15(37.5)	31(77.5)	5(12.5)	32(80.0)	21(52.5)	0(0.0)
Klebsiella spp (10)	S	5(50.0)	4(40.0)	NA	5(50.0)	5(50.0)	5(50.0)	2(20.0)	7(70.0)	3(30.0)	6(60.0)	10(100)
	I	3(30.0)	0(0)	NA	0(0.0)	0(0.0)	0(0.0)	0(0.0)	1(10.0)	0(0.0)	0(0.0)	0(0.0)
	R	2(20.0)	6(60.0)	NA	5(50.0)	5(50.0)	5(50.0)	8(80.0)	2(20.0)	7(70.0)	4(40.0)	0(0.0)
Proteus mirabilis (2)	S	1(50.0)	2(100)	1(50.0)	1(50.0)	1(50.0)	1(50.0)	1(50.0)	1(50.0)	1(50.0)	1(50.0)	2(100)
	I	1(50.0)	0(0.0)	0(0.0)	0(0.0)	0(0.0)	0(0.0)	0(0.0)	0(0.0)	0(0.0)	0(0.0)	0(0.0)
	R	0(0.0)	0(0.0)	1(50.0)	1(50.0)	5(50.0)	1(50.0)	1(50.0)	1(50.0)	1(50.0)	1(50.0)	0(0.0)
Citrobacter spp (1)	S	1(100)	1(100)	0(0.0)	1(100)	1(100)	1(100)	0(0.0)	1(100)	0(0.0)	0(0.0)	1(100)
	I	0(0)	0(0.0)	0(0.0)	0(0.0)	0(0.0)	0(0.0)	1(100)	0(0.0)	0(0.0)	0(0.0)	0(0.0)
	R	0(0)	0(0.0)	1(100)	0(0.0)	0(0.0)	0(0.0)	0(0.0)	0(0.0)	1(100)	1(100)	0(0.0)
Pseudomonas aeruginosa (1)	S	1(100)	1(100.0)	NA	1(100)	1(100)	1(100)	NA	NA	NA	NA	1(100)
	I	0(0)	0(0.0)	NA	0(0.0)	0(0.0)	0(0.0)	NA	NA	NA	NA	0(0.0)
	R	0(0)	0(0.0)	NA	0(0.0)	0(0.0)	0(0.0)	NA	NA	NA	NA	0(0.0)
Total ( N = 54)	S	37(68.5)	39(72.2)	4(7.41)	42(77.8)	39(72.2)	33(61.1)	11(20.4)	42(77.8)	12(22.2)	23(42.6)	54(100)
	I	8(14.8)	1(1.85)	3(5.6)	1(1.85)	0(0.0)	0(0.0)	2(3.7)	4(4.0)	0(0.0)	29(53.7)	0(0.0)
	R	9(16.67)	14(25.9)	47(87.04)	11(20.4)	15(27.78)	21(38.9)	41(75.9)	8(14.81)	42(77.8)	2(3.7)	0(0.0)

S Susceptible, I Intermediate, R Resistance, AMC Amoxicillin-clavulanic acid, CTX Cefotaxime, AMP Ampicillin, NIT Nitrofurantoin, GEN Gentamycin, CIP Ciprofloxacin, TET Tetracycline, CHL Chloramphenicol, SXT Trimethoprim/Sulfamethoxazole, NA Nalidixic acid, I Imipenem, NA Not Applicable

Multi-resistance rates of uropathogenic bacteria by isolates.

Most of the isolates, 88.9% (48/54) were resistant to at least one of the 11 antimicrobial agents tested. Of this, 1.9% (1/54) showed resistance primarily to one antibiotic only, 11.1% (6/54) were resistant to two antibiotics, 13.0% (7/54) were resistant to three antibiotics, 16.7% (9/54) were resistant to four antibiotics and 57.4% (31/54) were resistant to five or more antibiotics. Overall, 87.0% (47/54) of the isolates were multidrug resistant (MDR) as they were resistant to three or more antibiotic classes. The highest frequency of MDR was observed in Klebsiella spp. occurring in nine samples and E. coli (35 isolates). No MDR was observed in Pseudomonas aeruginosa (Table 3).

Table 3

Distribution of multi-resistance uropathogenic bacteria recovered from patients by isolates type, Kanifing General Hospital, 2021

Isolates (N)	Degree of Resistance n(%)					Total MDR (≥ R3)	ESBL Producer (%)
Isolates (N)	R1	R2	R3	R4	≥ R5	Total MDR (≥ R3)	ESBL Producer (%)
E. coli (40)	1(2.5)	4(10.0)	5(12.5)	7(17.5)	23(57.5)	35(87.5)	8(20)
Klebsiella spp (10)	0(0)	1(10.0)	1(10.0)	2(20.0)	6(60.0)	9(90.0)	5(50)
Proteus mirabilis (2)	0(0)	0(0)	1(50.0)	0(0)	1(50.0)	2(100)	0
Citrobacter spp (1)	0(0)	0(0)	0(0)	0(0)	1(100)	1(100)	0
Pseudomonas aeruginosa (1)	0(0)	1(100)	0(0)	0(0)	0(0)	0(0)	0
Total (54)	1(1.9)	6(11.1)	7(13.0)	9(16.67)	31(57.4)	47(87.0)	13(24.1)

R1-5: Resistance to 1, 2, 3, 4 and 5 antibiotics, ≥ R3 resistance to 3 or more antibiotics

Phenotypic Extended-Spectrum Beta-Lactamase (ESBL) producing Organisms

Among the isolates, 24.1% (13/54) were positive for ESBL production with 50% (5/10) and 20% (8/40) isolates being Klebsiella spp and E. coli respectively (Table 3).

Factors associated with uropathogenic bacterial infection

The multivariable analysis revealed that being female (aOR = 5.90(1.48–23.67), having no formal education (OR = 8.02(1.04–62.0)), having a previous history of UTI (aOR = 2.34(1.06–5.14)) and purchasing antibiotics from street vendors (aOR = 2.0(1.05–3.62)) were significantly associated with uropathogenic bacterial infection. However, history of urethral catheterization (aOR = 2.62, 95% CI = 0.90–7.64), having diabetes (OR = 2.43, 95% CI = 0.96–6.09) and taking antibiotics within the last three months (OR = 0.74 95% CI = 0.39–1.41) were not significantly associated with uropathogenic bacterial infection (Tables 4 and 5).

Table 4

Factors associated with urinary ttract infections among respondents, Kanifeng General Hospital

Variables	Uropathogenic Bacteria		cOR (95% CI)	p-value	aOR (95% CI)	p-value
	Negative n (%)	Positive n (%)
Sex
Male	71(96.0)	3(4.0)	1		1
Female	297(85.3)	51(14.7)	4.1(1.23–13.30)	0.021	5.90(1.48–23.67)	0.021
Occupation
Not employed	183(82.1)	40(17.9)	3.1(0.93–10.61)	0.066	NA
Self-employed	77(92.8)	6(7.2)	1.11(0.26–4.70)	0.88	NA
Student	65(92.9)	5(7.1)	1.10 (0.25–4.85)	0.897	NA
Civil servant	43(93.5)	3(6.5)	1		NA
Level of education
No formal education	164(84.1)	31(15.9)	11.91(1.59–89.09)	0.016	8.02(1.04–62.0)	0.046
Primary	37(92.5)	3(7.5)	5.10 (0.51–50.91)]	0.164	5.05(0.48–52.45)	0.174
Secondary	104(84.5)	19(15.5)	11.50 (1.50–88.08)	0.019	9.28(1.18–72.61)	0.034
Tertiary	63(98.4)	1(1.6)	1		1
Marital status
Married	241(84.6)	44(15.4)	2.06(1.00–4.24)	0.049	NA
Single	113(91.9)	10(8.1)	omitted		NA
Divorce	14(100)	0	1		NA
Medical illness (Diabetes)
Diabetic	59(84.3)	11(15.7)	1.34 (0.65–2.74)	0.425
Non-Diabetic	309(87.8)	43(12.2)	1		NA
Prior Hospital stay (last month)
Hospitalized	36(83.7)	7(16.3)	1.37 (0.58–3.26)	0.472	NA
Not hospitalized	332(87.6)	47(12.4)	1		NA
History of catheterization
Catheterized	19(76.0)	6(24.0)	2.29(0.87–6.03)	0.092	NA
Not catheterized	349(87.9)	48(12.1)	1		NA
History of UTI
Ever had UTI	241(84.9)	43(15.1)	2.05(1.03–4.13)	0.042	2.34(1.06–5.14)	0.033
No history of UTI	127(92.0)	11(8.0)	1		1

Table 5

Antibiotic usage factors associated with uropathogenic bacteria resistant isolates, Kanifing General Hospital

Variable	Uropathogenic Bacteria		cOR (95% CI)	p-value	aOR (95% CI)	p-value
	Negative n (%)	Positive n (%)	cOR (95% CI)	p-value	aOR (95% CI)	p-value
Antibiotic consumption during illness
Taken antibiotics	209(85.3)	36(14.7)	1.52 (0.83–2.78)	0.172	NA
Not taken	159(89.8)	18(10.2)	1
Prior (3 months) antibiotic exposure without medical prescription
Without prescription	125(89.3)	15(10.7)	0.74 (0.39–1.41)	0.368	NA
With prescription	243(86.2)	39(13.8)	1
Bought and used antibiotics from local pharmacy/street vendors
Bought and used	133(82.6)	28(17.4)	1.90(1.07–3.38]	0.028	2.0(1.05–3.62)	0.033
Did not	235(90.0)	26(10.0)	1
Usually take antibiotic without medical prescription
Usually take	114(83.8)	22(16.2)	1.53 (0.85–2.75)	0.154	NA
Do not take	254(88.8)	32(11.2)	1
Finished dosage prescribed antibiotics
Finished dosage	210(86.1)	34(13.9)	1.27 (0.71–2.30)	0.413	NA
Did not finish	158(88.8)	20(11.2)	1
Share antibiotic with family members or friends
Do share	64(81.0)	15(19.0)	1.83 (0.95–3.51)	0.064	NA
Do not share	304(88.6)	39(11.27)	1

aOR Adjusted odds ratio, cOR Crude odds ratio, CI Confidence Interval, NA Not applicable

Discussion

This study determined the antibiotic susceptibility patterns of uropathogenic bacterial isolates and associated factors among outpatients attending the Kanifing General Hospital, in The Gambia. Of five Genera of bacteria isolated from urine samples of the study participants, the most predominant were E. coli (74.1%) and Klebsiella spp. (18.5%). Community-acquired UTIs were found to be associated with the level of formal education, history of urinary tract infection (UTI) and use of unprescribed antibiotics. The bacterial isolates were found to have some level of resistance to all the antibiotics studied except for Imipenem.

The overall prevalence of uropathogenic bacterial infection was 12.85%, which is not very different from that reported from some other African countries, including the Gambia (9.0%), Ghana (10%) and Madagascar (12.9%) [10, 16, 29]. This is however, much lower than the levels reported in Senegal (26.7%) and Ethiopia (21.1%)[11, 28]. The relatively low prevalence our study recorded could be due to the differences in sample size, duration of study period and the methods used in the identification of bacterial uropathogens. Prior antibiotic use is known to affect urine culture results as the medication inhibit bacterial growth [28, 30].

The antibiotics found to be most sensitive were the carbapenems (imipenem and meropenem) and cephalosporin (cefotaxime). It was observed that Nitrofurantoin, which is among the recommended antibiotics for the treatment of uncomplicated UTI in The Gambia demonstrated only moderate sensitivity. Ciprofloxacin and other fluoroquinolones are also among the recommended and broadly prescribed antibiotics for UTIs [3]. This current study found the bacterial isolates to be moderately susceptible to ciprofloxacin and Nalidixic acid. Therefore, these antibiotics may be reserved and only used after confirmation of sensitivity to specific uropathogens. These findings are consistent with earlier reports from Ethiopia [30], but in contrast with a study from Madagascar [29]. These antibiotics are among the most commonly used antibiotics in the Gambia since they are cheap and easy acquired from drug stores.

The bacterial isolates were found to be highly resistant to ampicillin, tetracycline, and trimethoprim/sulfamethoxazole, with eight out of ten of the isolates showing resistance to ampicillin. The high level of resistance renders these antibiotics unsuitable for empirical treatment of UTIs. Similar studies in Ghana and India have also reported very high levels of resistance to ampicillin and co-trimoxazole [20, 31]. The international clinical practice guidelines suggests that, trimethoprim/sulfamethoxazole should not be used empirically for the treatment of uncomplicated UTI in women if the level of resistance exceeds 20% [32].

Amongst the isolated uropathogens, 87.0% were found to be MDR, similar to a study in Ethiopia [30]. However, this level of MDR is much higher compared to what was reported in a study from Turkey, 53.8% [4]. Mostly, in low resource health facilities, clinicians do not have ready access to culture and sensitivity test results to guide their choice of medication. Therefore, suspected infections are empirically treated with a variety of antibiotics. This practice has the tendency to contribute to MDR. Most of the respondents reported they self-medicate, suggesting unregulated use of these antimicrobial agents. Furthermore, in the study area, there is little or no policy implementation on antibiotic sales, resulting in numerous unregulated antibiotics sales outlets. These factors could contribute to the observed high level of antimicrobial resistance.

This study also confirms ESBL presence within the E. coli and Klebsiella species warranting further surveillance. Given the common antimicrobial empiric management of UTI in The Gambia, due to scarce microbiological capabilities. Therefore, knowledge about the existing resistance patterns is paramount for antimicrobial stewardship.

Our findings show that having no formal education increased the risk of having uropathogenic bacterial infection. These findings are in contrast with a study reported from Ethiopia [6]. Formal education can significantly influence a person’s knowledge and therefore health seeking practices when it comes to exposure to infectious pathogens. Our study also showed that participants who had a previous history of UTI were twice as likely to have culture-positive results as those without a previous history of UTI. This result was consistent with a cross-sectional study conducted in Ethiopia [28] which found that history of UTI was a risk factor for uropathogenic infection. The possible explanation of this association could be due to the presence of resistant strains from earlier infections. Again, persons with previous UTI may still be exposed to the risk for recurrence.

The purchase and use of antibiotics without medical prescription was also found to be significantly associated with the presence of resistant uropathogenic bacterial isolates. This could be because of the presence of numerous drug outlets and lack of control of sales of antibiotics by over-the-counter medicine sellers. This practice could contribute to the development of antimicrobial resistant strains as reported in earlier works [17, 33‐35]. This calls for antibiotic stewardship campaigns within the community to limit the use of unprescribed antibiotics. Similar to earlier reports from Uganda [9] and Sri-Lanka [36] we did not find an association between antibiotic use during the previous three months and the presence of resistant uropathogenic isolates. Also, the history of urethral catheterization was not found to be associated with the presence of uropathogenic bacteria [30].

Conclusion

The current study found uropathogenic bacteria in patients with community-acquired UTI receiving care at a tertiary hospital in The Gambia. Escherichia coli was the predominant bacteria species identified. Having no formal education, history of UTI and the use of unprescribed antibiotics were found to be significant risks for current UTI. Nitrofurantoin, cefotaxime, and imipenem were observed to be the most sensitive antibiotics against the bacterial isolates. The high prevalence of MDR among the uropathogens isolated highlights the need for continuous AMR surveillance to update clinical protocol of UTI management.

Although some bacterial isolates were found to be multidrug resistant, molecular analysis were not done to identify the resistant genes. Most of the study participants were female which could have skewed the data, possible as a result of routine screening of pregnant women during antenatal care. These limitations notwithstanding, the current study provides valuable data on antibiotic susceptibility patterns of uropathogens in the study community to guide case management of UTI.

Acknowledgements

The authors are grateful to the clinicians and study participants for their cooperation. The authors acknowledge the staff of the Microbiology department, KGH, National Public Health Laboratory, and the School of Public Health, University of Ghana for their technical assistance throughout the study period. We thank Baba K Fofana for his support in this study.

Declarations

Ethical approval was obtained from the University of The Gambia Research and Publication Committee (RePublic) and The Gambia Government and Medial Research Council Joint ethical committee (reference number: R021011) prior to data collection. The study was conducted in accordance with the declaration of Helsinki. Permission to conduct the study at KGH was granted by the Chief Executive Officer and Head of laboratory department. The purpose, risks and benefits of the study were clearly explained to all the study participants on individual basis using the local language (Mandinka or Wollof) and written informed consent obtained. For children < 18 years, informed consent was obtained from their parents/guardians. In the case of minors 10–17 years, their assent to participate in the study was obtained in addition to the informed consent of their parents/guardians. Signed or thumb printed copies of the consent forms were given to the participants. For participants who could not read and write, informed consent was obtained from such participants in the presence of their appointed representatives. The culture and sensitivity test results were communicated to the attending clinician to enhance care of patients.

Not applicable.

Competing interests

The authors declare no competing interests.

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Oli AN, Akabueze VB, Ezeudu CE, Eleje GU, Ejiofor OS, Ezebialu IU, et al. Bacteriology and antibiogram of urinary tract infection among female patients in a tertiary health facility in South Eastern Nigeria. Open Microbiol J. 2017;11:292–300.CrossRefPubMedPubMedCentral

Mohammed MA, Alnour TMS, Shakurfo OM, Aburass MM. Prevalence and antimicrobial resistance pattern of bacterial strains isolated from patients with urinary tract infection in Messalata Central Hospital. Libya Asian Pac J Trop Med. 2016;9:771–6.CrossRefPubMed

Ana L. Flores-Mireles, Jennifer N. Walker, Michael Caparon SJH. Urinary tract infections: epidemiology, mechanisms of infection and treatment options. Nat Rev Microbiol. 2015;13:269–84.

Guclu E, Halis F, Kose E, Ogutlu A, Karabay O. Risk factors of multidrug-resistant bacteria in community-acquired urinary tract infections. Afr Health Sci. 2021;21:214–9.CrossRefPubMedPubMedCentral

Choe HS, Lee SJ, Cho YH, Çek M, Tandoğdu Z, Wagenlehner F, et al. Aspects of urinary tract infections and antimicrobial resistance in hospitalized urology patients in Asia: 10-Year results of the Global Prevalence Study of Infections in Urology (GPIU). J Infect Chemother. 2018;24:278–83.CrossRefPubMed

Emiru T, Beyene G, Tsegaye W. Melaku S Associated risk factors of urinary tract infection among pregnant women at Felege Hiwot Referral. BMC Res Notes. 2013;6:1–6.CrossRef

Foxman B. Epidemiology of urinary tract infections: incidence, morbidity, and economic costs. Dis Mon. 2003;49:53–70.CrossRefPubMed

Dibua UME, Onyemerela IS, Nweze EI. Frequency, urinalysis and susceptibility profile of pathogens causing urinary tract infections in Enugu State, Southeast Nigeria. Rev Inst Med Trop Sao Paulo. 2014;56:55–9.CrossRefPubMedPubMedCentral

Kabugo D, Kizito S, Ashok DD, Graham KA, Ronald N, Sandra N, et al. Factors associated with community-acquired urinary tract infections among adults attending assessment centre, Mulago Hospital Uganda. Afr Health Sci. 2016;16:1131–42.CrossRefPubMedPubMedCentral

10.

Donkor ES, Horlortu PZ, Dayie NTKD, Obeng-Nkrumah N, Labi AK. Community acquired urinary tract infections among adults in Accra. Ghana Infect Drug Resist. 2019;12:2059–67.CrossRefPubMed

11.

Barry MS, Diallo BA, Kanté D, Diallo IS. Antimicrobial susceptibility profile of community-acquired urinary tract infection in adults : a seven months prospective cross-sectional study in Dakar Town, Senegal. Afr J Urol. 2017;23:166–71.CrossRef

12.

Okomo UA, Garba D, Fombah AE, Secka O, Ikumapayi UNA, Udo J, et al. Bacterial isolates and antibiotic sensitivity among Gambian children with severe acute malnutrition. Int J Pediatr. 2011;2011:1–8.CrossRef

13.

Africa CDC. Africa CDC framework for Antimicrobial Resistance-Regional guide for governments in Africa. Policy Review and development framework. Africa CDC Centres for Disease Control and Prevention. 2018.

14.

Murray CJ, Ikuta KS, Sharara F, Swetschinski L, Robles Aguilar G, Gray A, et al. Global burden of bacterial antimicrobial resistance in 2019: a systematic analysis. The Lancet. 2022;399:629–55.CrossRef

15.

Uwaezuoke J, Ogbulie J. Antibiotic sensitivity pattern of urinary tract pathogens in Port – Harcourt, Nigeria. J Appl Sci Environ Manage. 2006;10(3):103–7.

16.

Sumareh N. Aetiologies of Urinary Tract Infection from Patients seen at Medical Research Counci- lUnit, Fajara, The Gambia in 2013. 2014.

17.

Sanneh B, Kebbeh A, Jallow HS, Camara Y, Mwamakamba LW, Ceesay IF, et al. Prevalence and risk factors for faecal carriage of Extended Spectrum β-lactamase producing Enterobacteriaceae among food handlers in lower basic schools in West coast region of the Gambia. PLoS One. 2018;13(8).

18.

Kwambana-adams B, Nabwera H, Foster-nyarko E, Ikumapayi UN, Secka O, Betts M, et al. Salmonella infections in The Gambia, 2005–2015. Clin Infect Dis. 2015;61(Suppl):4.

19.

The Gambia Bureau of Statistics. The Gambia 2013 Population and Housing Census. The Gambia Bureau of Statistics. 2013.

20.

Kasiulevičius V, Šapoka V, Filipavičiūtė R. Sample size calculation in epidemiological studies. Gerontologija. 2006;7:225–31.

21.

Priyadharshana U, Piyasiri LB, Wijesinghe C. Prevalence, antibiotic sensitivity pattern and genetic analysis of extended spectrum beta lactamase producing Escherichia coli and Klebsiella spp among patients with community acquired urinary tract infection in Galle district, Sri Lanka. Ceylon Med J. 2019;64:140.CrossRefPubMed

22.

Pouladfar G, Basiratnia M, Anvarinejad M, Abbasi P, Amirmoezi F, Zare S. The antibiotic susceptibility patterns of uropathogens among children with urinary tract infection in Shiraz. Medicine (United States). 2017;96:1–6.

23.

Pietrucha-Dilanchian P, Hooton TM. Diagnosis, treatment, and prevention of urinary tract infection. Microbiol Spectr. 2016;4:1–20.CrossRef

24.

Odoki M, Aliero AA, Tibyangye J, Nyabayo Maniga J, Wampande E, Kato CD, et al. Prevalence of Bacterial Urinary Tract Infections and Associated Factors among Patients Attending Hospitals in Bushenyi District, Uganda. Int J Microbiol. 2019;2019:80–8.

25.

Kothari A, Sagar V. Antibiotic resistance in pathogens causing community-acquired urinary tract infections in India: a multicenter study. J Infect Dev Ctries. 2008;2:354–8.CrossRefPubMed

26.

CLSI. Performance Standards for Antimicrobial Susceptibility Testing. 30th ed. Clinical and Laboratory Standards Institute. Wayne: CLSI supplement M100; 2020.

27.

Magiorakos AP, 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;18:268–81.CrossRefPubMed

28.

Gebremariam G, Legese H, Woldu Y, Araya T, Hagos K. Bacteriological profile, risk factors and antimicrobial susceptibility patterns of symptomatic urinary tract infection among students of Mekelle University , northern Ethiopia. BMC Infect Dis. 2019;2:1–11.

29.

Randrianirina F, Soares JL, Carod JF, Ratsima E, Thonnier V, Combe P, et al. Antimicrobial resistance among uropathogens that cause community-acquired urinary tract infections in Antananarivo, Madagascar. J Antimicrob Chemother. 2007;59:309–12.CrossRefPubMed

30.

Tesfa T, Baye Y, Sisay M, Amare F, Gashaw T. Bacterial uropathogens and susceptibility testing among patients diagnosed with urinary tract infections at Hiwot Fana Specialized University Hospital, Eastern Ethiopia. SAGE Open Med. 2021;9:205031212110011.CrossRef

31.

Fofana BK. Isolation of Uropathogenic Bacteria and their Antimicrobial Susceptibility Pattern in Urine Samples of Patients with Suspected Urinary Tract Infection in Eastern Regional Hospital, Koforidua. 2016.

32.

Colgan R, Miller LG, Gupta K, Hooton TM, Naber KG, Moran GJ, et al. International clinical practice guidelines for the treatment of acute uncomplicated cystitis and pyelonephritis in women : A 2010 update by the infectious diseases society of America and the European Society for microbiology and infectious diseases. Clin Infect Dis. 2011;52:103–20.

33.

Chaw PS, Schlinkmann KM, Raupach-rosin H, Karch A, Pletz MW, Huebner J, et al. Antibiotic use on paediatric inpatients in a teaching hospital in the Gambia, a retrospective study. Antimicrob Resist Infect Control. 2018;7:1–9.CrossRef

34.

Kebbeh A, Anderson B, Jallow HS, Sagnia O, Mendy J, Camara Y, et al. Prevalence of highly multi-drug resistant salmonella fecal carriage among food handlers in lower basic schools in The Gambia To cite this article. 2017;6:39–44

35.

Kwambana-Adams B, Darboe S, Nabwera H, Foster-Nyarko E, Ikumapayi UN, Secka O, et al. Salmonella infections in The Gambia, 2005–2015. Clin Infect Dis. 2015;61(Suppl 4):S354–62.CrossRefPubMed

36.

Fernando MMPSC, Luke WANV, Miththinda JKND, Wickramasinghe RDSS, Sebastiampillai BS, Gunathilake MPML, et al. Extended spectrum beta lactamase producing organisms causing urinary tract infections in Sri Lanka and their antibiotic susceptibility pattern -A hospital based cross sectional study. BMC Infect Dis. 2017;17:1–7.CrossRef

Titel: Antibiotics susceptibility patterns of uropathogenic bacteria: a cross-sectional analytic study at Kanifing General Hospital, The Gambia
verfasst von: Abou Kebbeh
Paul Dsane-Aidoo
Kawsu Sanyang
Sheriffo M. K. Darboe
Nuha Fofana
Donne Ameme
Abdoulie M. Sanyang
Kalifa Sanneh Darboe
Saffiatou Darboe
Bakary Sanneh
Ernest Kenu
Francis Anto
Publikationsdatum: 01.12.2023
Verlag: BioMed Central
Erschienen in: BMC Infectious Diseases / Ausgabe 1/2023
Elektronische ISSN: 1471-2334
DOI: https://doi.org/10.1186/s12879-023-08373-y

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Antibiotics susceptibility patterns of uropathogenic bacteria: a cross-sectional analytic study at Kanifing General Hospital, The Gambia