Leigh B. Rosengren scite author profile

Escherichia coli often carries linked antimicrobial resistance genes on transmissible genetic elements. Through coselection, antimicrobial use may select for unrelated but linked resistance or virulence genes. This study used unconditional statistical associations to investigate the relationships between antimicrobial resistance phenotypes and antimicrobial resistance genes in 151 E. coli isolates from healthy pigs. Phenotypic resistance to each drug was significantly associated with phenotypic resistance to at least one other drug, and every association found that the probability of observing the outcome resistance was increased by the presence of the predictor resistance. With one exception, each statistical association that was identified between a pair of resistance genes had a corresponding significant association identified between the phenotypes mediated by those genes. This suggests that associations between resistance phenotypes might predict coselection. If this hypothesis is confirmed, evaluation of the associations between resistance phenotypes could improve our knowledge of coselection dynamics and provide a cost-effective way to evaluate existing data until large-scale genotypic data collection becomes feasible. This could enable policy makers and users of antimicrobials to consider coselection in antimicrobial use decisions. This study also considered the unconditional relationships between resistance and virulence genes in E. coli from healthy pigs (aidA-1, eae, elt, estA, estB, fedA1, stx1, and stx2). Positive statistical associations would suggest that antimicrobial use may select for virulence in bacteria that may contaminate food or cause diarrhea in pigs. Fortunately, the odds of detecting a virulence gene were rarely increased by the presence of an antimicrobial resistance gene. This suggests that on-farm antimicrobial use did not select for the examined virulence factors in E. coli carried by this population of healthy pigs.Antimicrobial resistance (AMR) is a serious concern in human and veterinary medicine. Resistant bacterial infections are associated with increased morbidity, mortality, and treatment expense compared to their susceptible counterparts (3,4,40). Resistant commensal E. coli, while rarely causing direct disease, is a reservoir of AMR genes. These genes can be transferred to zoonotic pathogens, such as Salmonella, or to other gram-negative bacteria in the gut (42, 43). Pathogenic and commensal strains of E. coli have different rates of resistance and can carry different genes (10, 41). Therefore, describing the AMR genes in commensal E. coli isolates documents the diversity of genes available for dissemination to other bacteria.In a previous paper, we described the frequency and patterns of phenotypic AMR in E. coli from healthy grow-finish pigs in western Canada. Of 1,439 isolates, 21% were susceptible to all of the 16 drugs considered, while 57% were resistant to two or more antimicrobials (33). This paper describes the presence of resistance and virulence genes in a subse...

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Distribution of Salmonella serovars in various pig production categories and risk factors for shedding in ten farrow-to-finish swine farms in western Canada.

Wilkins

Rajić

Waldner

et al. 2009

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Associations Between Feed and Water Antimicrobial Use in Farrow-to-Finish Swine Herds and Antimicrobial Resistance of Fecal Escherichia coli from Grow-Finish Pigs

Rosengren¹,

Waldner²,

Reid‐Smith

et al. 2007

Microbial Drug Resistance

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Escherichia coli (n = 1439), isolated from the feces of apparently healthy grow-finish pigs in 20 herds, were tested for susceptibility to 16 antimicrobials. Logistic regression models were developed for each resistance that was observed in more than 5% of the isolates. Each production phase's (suckling, nursery, grow-finish pigs or sows) antimicrobial exposure rate, through feed or water, was considered as a risk factor. Management variables were evaluated as potential confounders. Six resistance outcomes were associated with an antimicrobial use risk factor and four included exposures of pigs outside the grow-finish phase. In the case of sulfamethoxazole, the odds of resistance increased 2.3 times for every 100,000 pig-days of nursery pig exposure to sulfonamides. Thus, swine producers and veterinarians must be aware that antimicrobial use in pigs distant from market could have food safety repercussions. Five resistance outcomes were associated with exposure to an unrelated antimicrobial class. Most notably, the odds of sulfamethoxazole and chloramphenicol resistance were each six times higher in herds reporting high (more than 500/1,000 pig-days) grow-finish pig, macrolide exposure compared to herds with no macrolide use in grow-finish pigs. Therefore, the potential for co-selection should be considered in antimicrobial use decisions. This study emphasizes the importance of judicious antimicrobial use in pork production.

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Canadian Integrated Program for Antimicrobial Resistance Surveillance (CIPARS) Farm Program: Results from Finisher Pig Surveillance

Deckert

Gow

Rosengren³

et al. 2010

Zoonoses and Public Health

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Impacts• Farm level antimicrobial use (AMU) and antimicrobial resistance (AMR) surveillance data provide information on AMU by the end-user and AMR at the level where antimicrobials are used.• Antimicrobials considered very important to human health were not frequently used in Canadian sentinel grower-finisher swine herds and resistance to these antimicrobials was low.• A Canadian farm level surveillance program utilizing herd veterinarians and sentinel herds is feasible and effective.

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Associations between Antimicrobial Exposure and Resistance in Fecal Campylobacter spp. from Grow-Finish Pigs On-Farm in Alberta and Saskatchewan, Canada

Rosengren

Waldner

Reid‐Smith

et al. 2009

Journal of Food Protection

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Campylobacter spp. (n = 405), isolated from the feces of apparently healthy grow-finish pigs in 20 herds, were tested for susceptibility to 10 antimicrobials representing seven classes. Twelve percent of the isolates were susceptible to all drugs, while 64% were resistant to two or more antimicrobial classes. Resistance was most common to clindamycin, azithromycin, and erythromycin (71% each), and 10% of the isolates were resistant to ciprofloxacin. An antimicrobial use risk-factor analysis and a variance analysis explored the connection between antimicrobial resistance and the herd. The antimicrobial exposure of each production phase of each herd, through feed and water, was evaluated as a potential risk factor for resistance to macrolides and quinolones. Every 100,000 pig days of macrolide exposure in nursery pigs increased the odds of resistance to macrolides by a factor of 1.3. In contrast, the odds of resistance to a quinolone were nine times higher in Campylobacter from herds without beta-lactam exposure in grow-finish pigs compared with those with exposure. The variance analysis identified remarkably high clustering between isolates within herds; the intraclass correlations for resistances ranged from 0.52 to 0.82. Such extreme clustering demonstrates the potential for herd-level interventions to influence antimicrobial resistance in Campylobacter. The three key findings of this study, i.e., the prevalent resistance to macrolides, the association between macrolide exposure and Campylobacter resistance to macrolides, and the high clustering of resistance within herds, illustrate the need for continued study of antimicrobial-resistant Campylobacter on pig farms and the importance of judicious antimicrobial use in pork production.

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