A Case-Control Study on the Association between Salmonella Bacteriuria and Cystoscopy
Department of Medical Microbiology, The Ottawa Hospital General Campus, The University of Ottawa, Ottawa, ON K1H 8L6, Canada
Infect. Dis. Rep. 2021, 13(1), 205-214; https://doi.org/10.3390/idr13010023
Submission received: 23 November 2020
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Revised: 2 February 2021
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Accepted: 8 February 2021
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Published: 1 March 2021
Abstract
:To date, there is only one published report of an outbreak of urinary tract infections by Salmonella species after cystoscopy. Disinfection procedures for cystoscope have come into question. The current study aimed to determine the odds of developing Salmonella bacteriuria after cystoscopy. A retrospective case-control study was conducted on all patients with Salmonella species in urine (case) and blood (control) from 2017 to 2019 in 16 hospitals in Eastern Ontario, Canada. Eight of the 11 patients had cystoscopy prior to Salmonella bacteriuria; three of the 74 patients had urological procedures prior to Salmonella bacteremia, but none of their procedures were cystoscopy. The odds ratio of urological procedures with Salmonella bacteriuria was 63.1 (95% CI 10.9 to 366.6; p < 0.0001). In the bacteriuria group, the most frequently identified isolates were Salmonella enteritidis (n = 8), followed by Salmonella oranienburg, and Salmonella heidelberg. Seven of the S. enteritidis isolates had identical susceptibilities (ampicillin-sensitive; sulfamethoxazole/trimethoprim-sensitive; ciprofloxacin intermediate). In the bacteremia group, the most frequently identified isolates were S. enteritidis (n = 22), followed by Salmonella typhi, S. heidelberg, S. oranienburg, and Salmonella typhimurium. The result suggested cystoscopy is a risk factor for Salmonella bacteriuria. Identification of Salmonella bacteriuria should prompt public health investigations of linkage between cystoscopy and Salmonella bacteriuria.
1. Introduction
Salmonellosis is a foodborne infectious disease that causes gastroenteritis, bacteremia, and focal metastatic infections. However, Salmonella bacteriuria is a very unusual presentation that accounts for <0.1% of all urinary tract infections [1,2]. A study of 19 patients suggested that urological abnormalities are risk factors for Salmonella bacteriuria [2]. At one hospital in Spain, four patients underwent cystoscopy and were later identified to have Salmonella urinary tract infections between October and November 2014; this unusual presentation suggested the presence of an outbreak [3].
Disinfection procedures for cystoscope have come into question because effective perfusion of disinfectant, rather than immersion alone, is required to reduce microorganism contamination [4]. Outbreaks of cystoscopy infections with Pseudomonas aeruginosa [5,6] and Enterobacter cloacae [7] were reported in the past. In comparison, there were multiple reports of transmission of Salmonella from gastrointestinal endoscopy to hosts [8]. Like other Enterobacteriaceae, Salmonella has adhesion factors that facilitate its attachment in hosts and fomites [9]. Like Pseudomonas species, Salmonella forms a biofilm that facilitates its persistence and resistance in the environment [10]. Furthermore, the Lipid A endotoxin in Gram-negative bacteria make them potential pathogens in human hosts. It is biologically plausible that Salmonella species could enter from cystoscopes to human hosts.
In our Eastern Ontario Regional Laboratory Association (EORLA), affiliated with 16 hospitals, we also noted certain patients with Salmonella bacteriuria had a history of cystoscopy. Using Salmonella bacteremia as a control, the current study aimed to determine the odds of developing Salmonella bacteriuria after cystoscopy.
2. Materials and Methods
2.1. Data Set Creation
The current study followed the guidelines and standards given by the Ottawa Health Science Network Research Ethics Board. The Eastern Ontario Regional Laboratory Association (EORLA) microbiology laboratory used the Cerner Millennium software (Version 2013.04.1.34; Kansas City, MO, USA) to store patients’ laboratory data. This software generated reports that included all patients with Salmonella species in urine in a three-year period (1 January 2017 to 31 December 2019). The number of bacteria was quantified using the BD Kiestra™ ReadA Compact imaging acquisition software and established semi-quantitative measurements: <10, 10–100, 100, and >100 × 106 colony-forming unit (CFU)/L [11]. Colony count >100 × 106 CFU/L is generally considered to be significant if patients present with clinical signs and symptoms consistent with urinary tract infection [12]. Patients with Salmonella species in their blood in 2017–2019 were used as a control. The microorganisms were identified using matrix-assisted laser desorption ionization-time of flight mass spectrometry (MALDI-TOF MS). Once the MALD-TOF MS identified a microorganism to be Salmonella species, the identity of the microorganism was further confirmed with Difco Salmonella O Antiserum Poly A-I and Vi (BD Diagnostics, Sparks, MD, USA), and subsequently, serotyping in Public Health Ontario laboratory. Each patient’s electronic health records (EHRs) were retrospectively reviewed using the software Epic Hyperspace (Version November 2018, Verona, MI, USA). Their prior urological procedures, indications for the procedures, age, gender, microorganisms identified, antibiotic susceptibility results (based on Clinical and Laboratory Standards Institute Kirby–Bauer inhibition zone and E-test minimum inhibitory concentration breakpoints) were recorded in a separate spreadsheet. When the history of urological procedures was not recorded, it was assumed that patients had no prior exposure.
2.2. Setting
The EORLA microbiology laboratory, situated at the Ottawa Hospital General campus, Ontario, Canada, is a central laboratory that performed microbiology testing for 16 affiliated hospitals, including the Almonte General Hospital, Arnprior Regional Health, Carleton Place and District Memorial Hospital, Children’s Hospital of Eastern Ontario, Cornwall Community Hospital, Deep River and District Hospital, Glengarry Memorial Hospital in Alexandria, Hawkesbury District General Hospital, Kemptville District Hospital, Montfort Hospital, Pembroke Regional Hospital, Queensway Carleton Hospital, Renfrew Victoria Hospital, St. Francis Memorial Hospital in Barry’s Bay, Ottawa Hospital, and Winchester District Memorial Hospital. Table 1 shows a summary of Salmonella bacteriuria and bacteremia patients identified from the laboratory records.
2.3. Statistical Analyses
Statistical analyses, including odds ratio (OR), standard error of the log odds ratio (SE), and 95% confidence interval (CI), were performed using online MedCalc software (https://www.medcalc.org/calc/odds_ratio.php, accessed on 20 November 2020). The software generated a standard normal deviate (z-value) using the calculation ln(OR)/SE{ln(OR)}; the p value represented the area of the normal distribution outside ± z. For continuous data, such as age, unpaired, two-tailed Student t-test was used (https://www.medcalc.org/calc/comparison_of_means.php, accessed on 20 November 2020). p < 0.05 was determined to be statistically significant a priori. A minimum sample size calculation could not be performed because there was no previous data to suggest the OR of Salmonella bacteriuria. All patients with Salmonella bacteriuria and bacteremia in the study period were included. Only cases in 2017–2019 were included because some of the older records in our laboratory were incomplete.
3. Results
Eleven patients were identified to have Salmonella bacteriuria, but none of them was identified to have Salmonella bacteriuria prior to the study period; eight of these patients had history of cystoscopy prior to the bacteriuria (Table 2). In contrast, 74 patients were identified to have Salmonella bacteremia, but none of them was identified to have Salmonella bacteremia prior to the study period; three of these patients had history of urological procedures prior to the bacteremia, but none of them had cystoscopy (Table 3). The OR of history of urological procedures with the Salmonella bacteriuria group was 63.1 when compared with the Salmonella bacteremia group (95% CI 10.9 to 366.6; z = 4.62; p < 0.0001). The Salmonella bacteriuria patients were significantly older than the bacteremia ones (mean age 71 vs. 42 years, respectively; p = 0.0005). The bacteriuria patients were predominantly male, significantly different from the bacteremia patients (82% vs. 35%, respectively; OR 8.3; 95% CI 1.7 to 41.3; z = 2.59; p = 0.0064). None of the Salmonella bacteriuria patients had concomitant Salmonella species identified in stool culture.
After eliminating the typhoidal Salmonella cases (n = 19; Salmonella typhi and Salmonella paratyphi A and B), there were 11 Salmonella bacteriuria and 55 Salmonella bacteremia patients. The OR of history of urological procedures with the Salmonella bacteriuria group was 46.2 when compared with the Salmonella bacteremia group (95% CI 7.9 to 270.0; z = 4.26; p < 0.0001). The Salmonella bacteriuria patients remained to be significantly older than the bacteremia patients (mean age 71 vs. 47 years, respectively; p = 0.0064). However, the proportion of male patients was no longer significantly different between the two groups (82% vs. 62%, respectively; OR 2.8; 95% CI 0.5 to 14.1; z = 1.23; p = 0.2178).
In the Salmonella bacteriuria group (Table 2), the most frequently identified isolates were Salmonella enteritidis (n = 8), followed by Salmonella oranienburg (n = 2), and Salmonella heidelberg (n = 1). Seven of the eight S. enteritidis isolates had identical susceptibilities (ampicillin-sensitive; sulfamethoxazole/trimethoprim-sensitive; ciprofloxacin-intermediate). The one S. enteritidis isolate with a different susceptibly profile (ampicillin-sensitive; sulfamethoxazole/trimethoprim-sensitive; ciprofloxacin-sensitive) was from a patient who had cystoscopy exposure after development of Salmonella bacteriuria.
In the Salmonella bacteremia group (Table 3), the most frequently identified isolates were S. enteritidis (n = 22), followed by S. typhi (n = 14), S. heidelberg (n = 8), S. oranienburg (n = 7), and S. typhimurium (n = 5). Some of the identified isolates, despite being the same species, have variable susceptibility profiles.
4. Discussion
The current study suggested that history of urological procedures was a possible risk factor for Salmonella bacteriuria (OR of 63.1 between the Salmonella bacteriuria and bacteremia groups). Even after the nontyphoidal Salmonella cases were eliminated, the OR remained to be significant at 46.2. It was long believed that Salmonella bacteriuria is a rare (<1%), extra-intestinal infectious complication of systemic salmonellosis [13]. The current study suggested that Salmonella species could enter the urinary tract through urological manipulation. Although a previous study in Spain reported four patients with Salmonella urinary tract infections who had undergone cystoscopy, the study failed to identify the Salmonella isolates to species level and compare the isolate susceptibility; three of the four patients also had Salmonella species in their stool [3]. It is difficult to determine whether the Salmonella isolates from these four patients came from the same source or separately from each of these patients’ fecal contamination.
The current study showed that seven of the eight Salmonella enteritidis bacteriuria patients had identical antimicrobial susceptibility profiles. However, the current study failed to prove all these eleven patients’ bacteriuria were from the same source, as different Salmonella species were found in four different hospitals.
A study of 19 patients suggested that patients with old age, diabetes mellitus, urologic abnormalities, and immunosuppression were at a higher risk of contracting Salmonella bacteriuria [2]. Similarly, the current study showed that patients with Salmonella bacteriuria were significantly older than the ones with Salmonella bacteremia. Although Salmonella species are generally identified more often from females than males [14,15,16,17], Salmonella bacteriuria occurred more often in males in the current study.
The major strength of this study was capturing of all incidences of Salmonella bacteriuria in 16 affiliated hospitals in Eastern Ontario, Canada, in 2017–2019. This is the largest study to date that investigated the association of Salmonella bacteriuria with cystoscopy and had the Salmonella species susceptibility data available. The major limitation of the current retrospective study was a lack of thorough interview and examination with each patient to determine their signs and symptoms. However, objective review of EHRs reduced the risk of recall bias and overdiagnosis of urinary tract infections, especially among the elderly [18]. It was assumed that patients had no history of cystoscopy when it was not documented in their EHRs; therefore, the incidence of cystoscopy could be underestimated. Despite the underestimation, the current study showed an OR of 63.1 of Salmonella bacteriuria compared with Salmonella bacteremia. The difference in age between the Salmonella bacteriuria and bacteremia groups could be a confounder but could not be easily controlled in a retrospective study. The microbiology reports did not capture patients with probable contamination in urine (bacteriuria with three or more organisms) and could underestimate the incidence of Salmonella bacteriuria. Unfortunately, the current study failed to identify the source of the Salmonella bacteriuria. Based on published literature on infection outbreaks associated with cystoscopy, damages and breaches in reprocessing of cystoscopes were identified as the culprits [5,6,7]. Because of the multi-centered nature of the study, we could not determine whether the disinfection process of cystoscopy in each hospital was consistent with the standard of practice.
Like bacteremia, Salmonella isolates in stools could be used as a control. However, nontyphoidal Salmonella in stool does not always require antimicrobial treatment [19]; therefore, antimicrobial susceptibility testing of nontyphoidal Salmonella isolates in stools were not performed in our laboratory unless requested by clinicians. Using stool isolates as a control would limit the antimicrobial susceptibility data of the isolates identified in the current study. Moreover, cystoscopy would be an unlikely portal of entry in gastrointestinal infection; in contrast, cases of bacteremia had been reported after genitourinary tract manipulation [20,21]. Therefore, Salmonella bacteremia was chosen as the control group in the current study.
Salmonellosis is generally a reportable, communicable disease to local public health offices. However, manifestation of Salmonella bacteriuria alone may not meet the definition of salmonellosis, since typical presentations are gastroenteritis, bacteremia, and focal metastatic infections. Due to the association of Salmonella bacteriuria with cystoscopy in the current study, clinicians and laboratorians should promptly contact local public health offices when they encounter such cases. The current study failed to capture incidences of Salmonella bacteriuria identified in the community.
Future quality improvement projects should try to capture community incidences of Salmonella bacteriuria. Molecular studies and genome sequencing should also be considered to confirm whether the Salmonella isolates are from the same source. For instance, when rare microorganisms are identified from urine samples of patients with history of cystoscopy, laboratories may consider storing the isolates for further testing when needed. Pulsed-field gel electrophoresis (PFGE) is considered the “gold standard” of bacterial typing and widely used for infection control investigations [22], including an outbreak of ertapenem-resistant Enterobacter cloacae urinary tract infections due to a contaminated ureteroscope [7]. However, PFGE is a labor-intensive method, and thus, MALDI-TOF MS is being developed as an alternative for bacterial typing [22]. Until a fast, accurate, cheap, and high throughput method is validated for typing, local laboratories may need to send isolates to reference laboratories for further testing.
5. Conclusions
The result suggested cystoscopy is a risk factor for Salmonella bacteriuria. Identification of Salmonella bacteriuria should prompt public health investigations of linkage between cystoscopy and Salmonella bacteriuria.
Author Contributions
Conceptualization, E.Y.H.Y.; methodology, E.Y.H.Y.; software, E.Y.H.Y.; validation, E.Y.H.Y.; formal analysis, E.Y.H.Y.; investigation, E.Y.H.Y.; resources, E.Y.H.Y.; data curation, E.Y.H.Y.; writing—original draft preparation, E.Y.H.Y.; writing—review and editing, E.Y.H.Y.; visualization, E.Y.H.Y.; supervision, E.Y.H.Y.; project administration, E.Y.H.Y. The author has read and agreed to the published version of the manuscript.
Funding
This research received no external funding.
Institutional Review Board Statement
The data collected in the current study was from two quality improvement projects which investigated the indications of urine culture and microbiology susceptibility testing (approved on 30 April 2020 and 3 December 2019, respectively). These projects were deemed to be quality improvement projects and followed the guidelines and standards given by the Ottawa Health Science Network Research Ethics Board.
Informed Consent Statement
Patient consent was waived because the data collected were from retrospective quality improvement projects but not research studies. Patient-identifiable information was anonymized in the current manuscript.
Data Availability Statement
The raw data presented in this study are available on request from the corresponding author. The data are not publicly available due to patient confidentiality.
Conflicts of Interest
The author has been paid for working as a medical doctor, but not for writing the manuscript.
References
- Ramos, J.M.; Aguado, J.M.; Garcia-Corbeira, P.; Ales, J.M.; Soriano, F. Clinical spectrum of urinary tract infections due on nontyphoidal Salmonella species. Clin. Infect. Dis. 1996, 23, 388–390. [Google Scholar] [CrossRef] [PubMed]
- Tena, D.; Gonzalez-Praetorius, A.; Bisquert, J. Urinary tract infection due to non-typhoidal Salmonella: Report of 19 cases. J. Infect. 2007, 54, 245–249. [Google Scholar] [CrossRef]
- Jimeno, A.; Alcalde, M.M.; Ortiz, M.; Rodriguez, A.; Alcaraz, B.; Vera, F. Outbreak of urinary tract infections by Salmonella spp. after cystoscopic manipulation. Actas Urol. Esp. 2016, 40, 646–649. [Google Scholar] [CrossRef] [PubMed]
- Rutala, W.A.; Gergen, M.F.; Bringhurst, J.; Weber, D.J. Effective high-level disinfection of cystoscopes: Is perfusion of channels required? Infect. Control Hosp. Epidemiol. 2016, 37, 228–231. [Google Scholar] [CrossRef]
- Wendelboe, A.M.; Baumbach, J.; Blossom, D.B.; Frank, P.; Srinivasan, A.; Sewell, C.M. Outbreak of cystoscopy related infections with Pseudomonas aeruginosa: New Mexico, 2007. J. Urol. 2008, 180, 588–592. [Google Scholar] [CrossRef] [PubMed]
- Sorbets, E.; Evrevin, M.; Jumas-Bilak, E.; Masnou, A.; Lotthe, A.; Thuret, R.; Chaize, P.; Peyremorte, F.; Romano-Bertrand, S.; Parer, S. An outbreak of Pseudomonas aeruginosa urinary tract infections following outpatient flexible cystoscopy. Am. J. Infect. Control 2019, 47, 1510–1512. [Google Scholar] [CrossRef]
- Chang, C.L.; Su, L.H.; Lu, C.M.; Tai, F.T.; Huang, Y.C.; Chang, K.K. Outbreak of ertapenem-resistant Enterobacter cloacae urinary tract infections due to a contaminated ureteroscope. J. Hosp. Infect. 2013, 85, 118–124. [Google Scholar] [CrossRef]
- Kovaleva, J.; Peters, F.T.; van der Mei, H.C.; Degener, J.E. Transmission of infection by flexible gastrointestinal endoscopy and bronchoscopy. Clin. Microbiol. Rev. 2013, 26, 231–254. [Google Scholar] [CrossRef] [PubMed] [Green Version]
- Kanamori, H.; Rutala, W.A.; Weber, D.J. The role of patient care items as a fomite in healthcare-associated outbreaks and infection prevention. Clin. Infect. Dis. 2017, 65, 1412–1419. [Google Scholar] [CrossRef]
- Steenackers, H.; Hermans, K.; Vanderleyden, J.; De Keersmaecker, S.C.J. Salmonella biofilms: An overview on occurrence, structure, regulation and eradication. Food Res. Int. 2012, 45, 502–531. [Google Scholar] [CrossRef]
- Patel, P.; Droske, L.E.; Patel, J.; Barza, R.; Lindgren, R.; McElvania, E. 2152. Detection of uropathogens using BD Kiestra™ total laboratory automation with urine culture application. Open Forum Infect. Dis. 2019, 6, S730. [Google Scholar] [CrossRef] [Green Version]
- Kwon, J.H.; Fausone, M.K.; Du, H.; Robicsek, A.; Peterson, L.R. Impact of laboratory-reported urine culture colony counts on the diagnosis and treatment of urinary tract infection for hospitalized patients. Am. J. Clin. Pathol. 2012, 137, 778–784. [Google Scholar] [CrossRef] [PubMed] [Green Version]
- Huang, D.B.; DuPont, H.L. Problem pathogens: Extra-intestinal complications of Salmonella enterica serotype Typhi infection. Lancet Infect. Dis. 2005, 5, 341–348. [Google Scholar] [CrossRef]
- Reller, M.E.; Tauxe, R.V.; Kalish, L.A.; Molbak, K. Excess Salmonellosis in women in the United States: 1968–2000. Epidemiol. Infect. 2008, 136, 1109–1117. [Google Scholar] [CrossRef] [PubMed]
- Marami, D.; Hailu, K.; Tolera, M. Prevalence and antimicrobial susceptibility pattern of Salmonella and Shigella species among asymptomatic food handlers working in Haramaya University cafeterias, Eastern Ethiopia. BMC Res. Notes 2018, 11. [Google Scholar] [CrossRef] [Green Version]
- Sivapalasingam, S.; Hoekstra, R.M.; McQuiston, J.R.; Fields, P.I.; Tauxe, R.V. Salmonella bacteriuria: An increasing entity in elderly women in the United States. Epidemiol. Infect. 2004, 132, 897–902. [Google Scholar] [CrossRef]
- Levine, M.M.; Black, R.E.; Lanata, C. Precise estimation of the numbers of chronic carriers of Salmonella typhi in Santiago, Chile, an endemic area. J. Infect. Dis. 1982, 146, 724–726. [Google Scholar] [CrossRef] [PubMed]
- Woodford, H.J.; George, J. Diagnosis and management of urinary tract infection in hospitalized older people. J. Am. Geriatr. Soc. 2009, 57, 107–114. [Google Scholar] [CrossRef]
- Onwuezobe, I.A.; Oshun, P.O.; Odigwe, C.C. Antimicrobials for treating symptomatic non-typhoidal Salmonella infection. Cochrane Database Syst. Rev. 2012, 11, CD001167. [Google Scholar] [CrossRef]
- Sullivan, N.M.; Sutter, V.L.; Carter, W.T.; Attebery, H.R.; Finegold, S.M. Bacteremia after genitourinary tract manipulation: Bacteriological aspects and evaluation of various blood culture systems. Appl. Microbiol. 1972, 23, 1101–1106. [Google Scholar] [CrossRef]
- Bavetta, S.; Olsha, O.; Fenely, J. Spreading sepsis by cystoscopy. Postgrad. Med. J. 1990, 66, 734–735. [Google Scholar] [CrossRef] [PubMed] [Green Version]
- Neoh, H.M.; Tan, X.E.; Sapri, H.F.; Tan, T.L. Pulsed-field gel electrophoresis (PFGE): A review of the “gold standard” for bacteria typing and current alternatives. Infect. Genet. Evol. 2019, 74, 103935. [Google Scholar] [CrossRef]
Table 1.
Demographics of patients identified to have Salmonella bacteriuria and bacteremia in 2017–2019.
Table 1.
Demographics of patients identified to have Salmonella bacteriuria and bacteremia in 2017–2019.
| Salmonella Bacteriuria Group | |
|---|---|
| • Total number of patients | 11 |
| • Mean age (year) | 71 |
| • Number of males | 9 |
| • Number of patients with prior urological procedures | 8 |
| • Number of patients with typhoidal Salmonella bacteriuria | 0 |
| • Number of hospitals identified to have Salmonella bacteriuria | 4 |
| Salmonella bacteremia group | |
| • Total number of patients | 74 |
| • Mean age (year) | 42 |
| • Number of males | 26 |
| • Number of patients with prior urological procedures | 3 |
| • Number of patients with typhoidal Salmonella bacteremia | 19 |
| • Number of hospitals identified to have Salmonella bacteremia | 13 |
Table 2.
Patients identified to have Salmonella bacteriuria in 2017–2019, sorted by names of the microorganisms.
Table 2.
Patients identified to have Salmonella bacteriuria in 2017–2019, sorted by names of the microorganisms.
| Age (years) | Gender | Source of Urine | Prior Urological Procedures | Procedure Indications | Microorganism | Amount (CFU/L) | Ampicillin Susceptibility | SXT Susceptibility | Ciprofloxacin Susceptibility |
|---|---|---|---|---|---|---|---|---|---|
| 52 | M | In and out | Cystoscopy | Hematuria | Salmonella enteritidis | >100 × 106 | S | S | I |
| 52 | M | Midstream | Cystoscopy | Hematuria | S. enteritidis | >100 × 106 | S | S | I |
| 69 | M | Midstream | Cystoscopy | Bladder cancer | S. enteritidis | >100 × 106 | S | S | I |
| 69 | M | Cystoscopic | Cystoscopy | Renal cyst; bladder cancer | S. enteritidis | <10 × 106 | S | S | I |
| 69 | M | In and out | Cystoscopy | Renal cyst; bladder cancer | S. enteritidis | >100 × 106 | S | S | I |
| 79 | M | Midstream | Cystoscopy | Bladder cancer | S. enteritidis | >100 × 106 | S | S | I |
| 86 | M | Midstream | None | S. enteritidis | >100 × 106 | S | S | S | |
| 90 | M | In and out | None | S. enteritidis | >100 × 106 | S | S | I | |
| 44 | F | Midstream | Cystoscopy | Cystocele; stress incontinence | Salmonella heidelberg | >100 × 106 | S | S | S |
| 83 | F | Midstream | Cystoscopy | Urinary incontinence | Salmonealla oranienburg | >100 × 106 | S | S | S |
| 88 | M | Midstream | None | S. oranienburg | >100 × 106 | S | S | S |
Abbreviations: M, male; F, female; CFU, colony-forming unit; SXT, sulfamethoxazole/trimethoprim; S, sensitive; I, intermediate; R, resistant.
Table 3.
Patients identified to have Salmonella bacteremia in 2017–2019, sorted by names of the microorganisms.
Table 3.
Patients identified to have Salmonella bacteremia in 2017–2019, sorted by names of the microorganisms.
| Age (years) | Gender | Prior Urological Procedures | Procedure Indications | Microorganism | Ampicillin Susceptibility | SXT Susceptibility | Ciprofloxacin Susceptibility |
|---|---|---|---|---|---|---|---|
| 2 | M | None | Salmonella chester | S | S | S | |
| 23 | M | None | Salmonella choleraesuis * | R | S | I | |
| 20 | M | None | Salmonella eastbourne | S | S | S | |
| 75 | M | None | Salmonella enterica subsp. enterica | R | R | I | |
| 85 | M | None | S. enterica subsp. enterica | S | S | I | |
| 2 | M | None | S. enterica subsp. enterica | S | S | S | |
| 0 | M | None | S. enterica subsp. enterica | S | S | S | |
| 57 | M | None | S. enteritidis | S | S | S | |
| 76 | F | None | S. enteritidis | S | S | S | |
| 59 | F | None | S. enteritidis | S | S | S | |
| 33 | M | None | S. enteritidis | S | S | S | |
| 66 | F | None | S. enteritidis | S | S | S | |
| 90 | M | None | S. enteritidis | S | S | I | |
| 63 | F | None | S. enteritidis | S | S | I | |
| 70 | M | None | S. enteritidis | S | S | S | |
| 68 | M | None | S. enteritidis | S | S | I | |
| 86 | M | None | S. enteritidis | S | S | S | |
| 43 | M | None | S. enteritidis | S | S | S | |
| 76 | F | Laparoscopic insertion of dialysis catheter | Chronic kidney disease | S. enteritidis | S | S | I |
| 11 | F | None | S. enteritidis | S | S | I | |
| 18 | M | None | S. enteritidis | S | S | S | |
| 70 | M | None | S. enteritidis | S | S | I | |
| 58 | M | None | S. enteritidis | S | S | I | |
| 71 | M | Dorsal slit | Phimosis | S. enteritidis | S | S | S |
| 10 | F | None | S. enteritidis | S | S | S | |
| 75 | F | None | S. enteritidis | S | S | S | |
| 44 | M | None | S. enteritidis | S | S | I | |
| 48 | F | None | S. enteritidis | S | S | I | |
| 86 | M | None | S. enteritidis | S | S | S | |
| 72 | M | None | Salmonella hadar | S | S | S | |
| 22 | M | None | S. heidelberg | R | S | S | |
| 36 | M | None | S. heidelberg | S | S | S | |
| 44 | F | None | S. heidelberg | S | S | S | |
| 19 | M | None | S. heidelberg | S | S | S | |
| 13 | F | None | S. heidelberg | S | S | S | |
| 73 | F | None | S. heidelberg | S | S | S | |
| 1 | F | None | S. heidelberg | S | S | S | |
| 7 | M | None | S. heidelberg | S | S | S | |
| 58 | M | None | Salmonella manhatan | S | S | S | |
| 34 | M | None | Salmonella newport | S | S | S | |
| 72 | M | None | S. oranienburg | S | S | S | |
| 37 | F | None | S. oranienburg | S | S | S | |
| 11 | M | None | S. oranienburg | S | S | S | |
| 48 | F | None | S. oranienburg | S | S | S | |
| 78 | F | None | S. oranienburg | S | S | I | |
| 20 | M | None | S. oranienburg | S | S | S | |
| 33 | F | None | S. oranienburg | S | S | S | |
| 22 | F | None | Salmonella paratyphi A | S | S | R | |
| 33 | F | None | S. paratyphi A | S | S | R | |
| 28 | F | None | S. paratyphi A | S | S | I | |
| 2 | M | None | S. paratyphi B | S | S | S | |
| 28 | M | None | S. paratyphi B | S | S | S | |
| 53 | M | None | Salmonella saintpaul | S | S | S | |
| 33 | F | None | Salmonella stanley | S | S | S | |
| 38 | M | None | Salmonella typhi | S | S | I | |
| 28 | M | None | S. typhi | S | S | R | |
| 24 | M | None | S. typhi | S | S | I | |
| 45 | M | None | S. typhi | S | S | I | |
| 9 | M | None | S. typhi | S | S | I | |
| 19 | M | None | S. typhi | S | S | I | |
| 29 | M | None | S. typhi | S | S | I | |
| 16 | F | None | S. typhi | R | R | I | |
| 25 | M | None | S. typhi | S | S | S | |
| 21 | M | None | S. typhi | S | S | I | |
| 6 | M | None | S. typhi | S | S | I | |
| 42 | M | None | S. typhi | S | S | R | |
| 12 | F | None | S. typhi | R | R | R | |
| 60 | M | None | S. typhi | S | S | S | |
| 69 | M | None | Salmonella typhimurium | S | S | S | |
| 42 | M | Renal transplant | End stage renal disease | S. typhimurium | S | S | S |
| 73 | F | None | S. typhimurium | S | S | S | |
| 62 | M | None | S. typhimurium | S | S | S | |
| 80 | F | None | S. typhimurium | R | S | S | |
| 22 | F | None | Salmonella virchow | S | S | S |
Abbreviations: M, male; F, female; SXT, sulfamethoxazole/trimethoprim; S, sensitive; I, intermediate; R, resistant. * Salmonella choleraesuis was later renamed to Salmonella enterica.
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Yeung, E.Y.H. A Case-Control Study on the Association between Salmonella Bacteriuria and Cystoscopy. Infect. Dis. Rep. 2021, 13, 205-214. https://doi.org/10.3390/idr13010023
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Yeung EYH. A Case-Control Study on the Association between Salmonella Bacteriuria and Cystoscopy. Infectious Disease Reports. 2021; 13(1):205-214. https://doi.org/10.3390/idr13010023
Chicago/Turabian StyleYeung, Eugene Y. H. 2021. "A Case-Control Study on the Association between Salmonella Bacteriuria and Cystoscopy" Infectious Disease Reports 13, no. 1: 205-214. https://doi.org/10.3390/idr13010023
APA StyleYeung, E. Y. H. (2021). A Case-Control Study on the Association between Salmonella Bacteriuria and Cystoscopy. Infectious Disease Reports, 13(1), 205-214. https://doi.org/10.3390/idr13010023
