Hostname: page-component-586b7cd67f-t7czq Total loading time: 0 Render date: 2024-11-28T02:22:02.380Z Has data issue: false hasContentIssue false

Risk factors for ceftiofur resistance in Escherichia coli from Belgian broilers

Published online by Cambridge University Press:  29 June 2010

D. PERSOONS*
Affiliation:
Department of Obstetrics, Reproduction and Herd Health, Veterinary Epidemiology Unit, Faculty of Veterinary Medicine, Ghent University, Merelbeke, Belgium Institute for Agricultural and Fisheries Research, Unit Technology and Food Science, Melle, Belgium
F. HAESEBROUCK
Affiliation:
Department of Pathology, Bacteriology and Avian Diseases, Faculty of Veterinary Medicine, Ghent University, Merelbeke, Belgium
A. SMET
Affiliation:
Department of Pathology, Bacteriology and Avian Diseases, Faculty of Veterinary Medicine, Ghent University, Merelbeke, Belgium
L. HERMAN
Affiliation:
Institute for Agricultural and Fisheries Research, Unit Technology and Food Science, Melle, Belgium
M. HEYNDRICKX
Affiliation:
Institute for Agricultural and Fisheries Research, Unit Technology and Food Science, Melle, Belgium
A. MARTEL
Affiliation:
Department of Pathology, Bacteriology and Avian Diseases, Faculty of Veterinary Medicine, Ghent University, Merelbeke, Belgium
B. CATRY
Affiliation:
Epidemiology Unit, Scientific Institute of Public Health, Brussels, Belgium
A. C. BERGE
Affiliation:
Department of Obstetrics, Reproduction and Herd Health, Veterinary Epidemiology Unit, Faculty of Veterinary Medicine, Ghent University, Merelbeke, Belgium
P. BUTAYE
Affiliation:
Department of Pathology, Bacteriology and Avian Diseases, Faculty of Veterinary Medicine, Ghent University, Merelbeke, Belgium Department of Bacteriology and Immunology, CODA-CERVA-VAR, Brussels, Belgium
J. DEWULF
Affiliation:
Department of Obstetrics, Reproduction and Herd Health, Veterinary Epidemiology Unit, Faculty of Veterinary Medicine, Ghent University, Merelbeke, Belgium
*
*Author for correspondence: Mr D. Persoons, Salisburylaan 133, 9820 Merelbeke, Belgium. (Email: [email protected])
Rights & Permissions [Opens in a new window]

Summary

A cross-sectional study on 32 different Belgian broiler farms was performed in 2007 and 2008 to identify risk factors for ceftiofur resistance in Escherichia coli. On each farm, one E. coli colony was isolated from 30 random birds. Following susceptibility testing of 14 antimicrobials, an on-farm questionnaire was used to obtain information on risk factors. Using a multilevel logistic regression model two factors were identified at the animal level: resistance to amoxicillin and to trimethoprim–sulfonamide. On the farm level, besides antimicrobial use, seven management factors were found to be associated with the occurrence of ceftiofur resistance in E. coli from broilers: poor hygienic condition of the medicinal treatment reservoir, no acidification of drinking water, more than three feed changes during the production cycle, hatchery of origin, breed, litter material used, and treatment with amoxicillin. This study confirms that not only on-farm antimicrobial therapy, but also management- and hatchery-related factors influence the occurrence of antimicrobial resistance.

Type
Original Papers
Copyright
Copyright © Cambridge University Press 2010

INTRODUCTION

Ceftiofur is a third-generation cephalosporin antibiotic which is solely used in veterinary medicine and currently only registered for swine and cattle in the European Union. Up to 2000, ceftiofur was also authorized in Belgium as a subcutaneously injectable antimicrobial in 1-day-old chicks. This was subsequently banned because no maximum residue level (MRL) was established for this target animal species. No single compound of the cephalosporin group is currently registered for use in poultry in the European Union [Reference Bertrand1].

In a large-scale Belgian survey in 2007–2008 on faecal E. coli from broiler chickens, a remarkably high average level of 37% ceftiofur resistance was found [Reference Persoons2]. Comparison with older, smaller-scale Belgian studies in E. coli from poultry suggests a gradual but substantial increase in resistance towards this important antimicrobial compound. The reported ceftiofur resistance percentages were 6% and 28% in the period 2001–2003 [Reference Verloo3] and 2006 [Reference Casteleyn4], respectively.

As a consequence of worldwide reports of high and increasing levels of cephalosporin resistance in both veterinary [Reference Briñas5Reference Kojima7] and human [Reference Zahar8Reference Gupta11] medicine, the World Health Organization advisory panel ranked third- and fourth-generation cephalosporins in the top three of most important antimicrobials for treatment in humans. This prioritizes this subgroup of β-lactam antimicrobials as a class for which risk-management strategies are most urgently needed [Reference Collignon12].

The public health concern of cephalosporin resistance in commensal E. coli from animals lies in the fact that this resistance might be transferred to animal-associated pathogenic bacteria [Reference Winokur13] or to human commensal and/or pathogenic strains via the food chain or through direct contact [Reference Bywater14Reference Aarestrup and Wegener16]. Commensal bacteria play a crucial role in the acquisition and transfer of resistance genes because of their high reproduction capacity and large population [Reference Witte17]. Pathogenic E. coli strains are still one of the most common causes of bacterial infection in humans [Reference Wang and Chen18, Reference Kennedy, Roberts and Collignon19].

To stop emerging – and ultimately reduce –resistance levels it is first necessary to identify the factors that influence the presence of this resistance. Therefore the aim of this study was to identify factors, both at animal and flock level that may influence the occurrence of ceftiofur resistance in faecal E. coli in Belgian broilers.

MATERIAL AND METHODS

Thirty-two broiler farms were selected randomly from all commercial Belgian broiler farms with a minimum capacity of 10 000 chickens. All farms were sampled twice leaving one production round in between unsampled. The visits all took place during 2007–2008 and each visit coincided when the birds were in their fifth week of production, i.e. the week prior to slaughter. At each sampling, individual faecal swabs from 30 randomly selected broiler chickens were collected, as well as one questionnaire for each visited farm. In the first five flocks, more samples were taken (89–100) for the additional purpose of later detection of extended spectrum β-lactamases (ESBLs).

For the isolation of E. coli, the swabs were cultured on MacConkey agar plates (Oxoid, France) and incubated aerobically for 24 h at 37°C. From each sample, one random colony matching the morphology consistent with E. coli was purified on MacConkey agar. Suspected E. coli colonies were confirmed by means of positive glucose/lactose fermentation, gas production, and absence of H2S production on Kligler iron agar (Oxoid), indole production (Indole spot on; Becton Dickinson, USA) and absence of aesculine hydrolysis (Bile aesculin agar; Oxoid). The Kirby–Bauer disk diffusion method was used for susceptibility testing (NeoSensitabs, Rosco, Denmark) of 14 antimicrobials (amoxicillin–clavulanic acid, ampicillin, apramycin, ceftiofur, chloramphenicol, enrofloxacin, florphenicol, flumequine, gentamicin, neomycin, nalidixic acid, streptomycin, tetracycline, trimethoprim–sulfonamide). The guidelines of the Clinical Laboratory Standards Institute (CLSI) were followed for standardization of inoculums, incubation conditions and internal quality control organisms (CLSI M31-A3). After 18 h of incubation, inhibition zones were read and interpreted according to the veterinary manufacturer's guidelines according to CLSI [Reference Persoons2]. Susceptibility test results were converted to a binary outcome: sensitive vs. non-sensitive (resistant+intermediate) [Reference Persoons2]. The susceptibility test results (sensitive or resistant) of the 13 antimicrobials excluding ceftiofur were tested at the bacterium level as potential covariables for ceftiofur resistance.

The samples obtained in the first five flocks were additionally plated on MacConkey plates enriched with 8 μg/ml ceftiofur. Isolates growing on this medium were further examined for the presence of ESBLs [Reference Smet20].

The questionnaire was completed on-farm by means of a personal interview with the farmer. Hygiene scores (three categories: visibly clean, some contamination, dirty) were awarded by the interviewer without the farmer's involvement. The same questionnaire was used for all farms and on both sampling occasions, the interviewer was also the same on all occasions. Information was gathered on 31 different potential farm-level risk factors: on-farm presence of other animals, pets, rodents, season, type of drinking water, quality checks of drinking water, use of disposable clothing for visitors, use of footbaths at entrance of stable and hygienic condition, hygienic condition of the stable, cleaning procedure, temperature of cleaning, disinfection procedure, sanitary transition period, application system for medicines and hygienic condition of the reservoir for medication application, rinsing of the reservoir after treatment, acidification of drinking water, feed mill, feed changes, use of anticoccidials, stocking density, hatchery, breed, litter material, humidity of the litter, temperature regimen, depopulation regimen, Salmonella status, mortality, and treatments applied.

A multilevel logistic regression model with ceftiofur resistance as a binomial outcome variable was fit to the data. All covariables and all 31 factors were tested univariably. The shape of the relationship with the outcome variable was assessed for all continuous variables by plotting the log odds of the outcome vs. the continuous variable [Reference Parkin21]. If there was a nonlinear relationship, the continuous variable was categorized. The variables with a P value of ⩽0·2 (odds ratio different from 1) were withheld as input in the multivariable multilevel logistic regression model. Pearson and Spearman correlation coefficients were calculated to explore the relationship between all selected independent variables. If correlation between two variables was >0·6, only the most significant variable was retained in the model. The model was built in MLW in (University of Bristol, Bristol, UK), with the factor ‘farm’ included as a random effect to account for the repeated observations per farm. The model was built backwards, gradually excluding the non-significant factors to finally only retain significant factors. To check for the presence of confounding, a Mantel–Haenszel analysis was performed. Confounding was considered present if changes in the odds ratio of >20% could be observed. Interaction effects were checked for all significant main factors in the model.

RESULTS

E. coli was recovered in 92·3% of all samples, resulting in 2076 isolates. The overall prevalence of ceftiofur resistance found in E. coli was 34% in the first sampling of the farms and 42% at the second sampling. A large between-farm variation was seen; at the first sampling round, farm levels of ceftiofur resistance ranged between 8% and 62%, and for the second round between 9% and 73%. The isolation on ceftiofur-supplemented plates for the samples from flocks 1–5 resulted in a growth percentage of 63%. The results of the detection of ESBLs have been published in Smet et al. [Reference Smet20].

In the univariable analysis of bacterium-level covariables, antimicrobial resistance against four agents was seen to be significantly associated with ceftiofur resistance: resistance to amoxicillin–clavulanic acid (P<0·01), to nalidixic acid (P=0·12), to neomycin (P<0·01), and to trimethoprim–sulfomethoxazole (P<0·01). On the farm level, 14 risk factors were withheld following univariable analysis: drinking-water quality checking interval (P<0·01), absence of footbaths at the entrance of the stable (P<0·01), hygienic condition of the stable (P<0·01), hygienic condition of the medicinal treatment reservoir (P<0·01), no drinking water acidification (P<0·05), more than three feed changes per production cycle (P<0·01), anticoccidial drug administered (P<0·01), stocking density (P=0·18), hatchery (P<0·01), breed (P<0·05), litter material (P=0·06), applying two phased depopulation regimens (P=0·16), amoxicillin treatment (P<0·01) and enrofloxacin treatment (P<0·01). Checking of the correlations showed that no relevant Pearson or Spearman correlation coefficients were present in these variables.

In the multilevel multivariable model, with farm included as a random effect, the factors presented in Table 1 remained significantly associated with ceftiofur resistance.

Table 1. Results of the multilevel multivariable analysis of covariables and risk factors for ceftiofur resistance in 32 Belgian broiler farms

OR, Odds ratio; CI, confidence interval; AMC, amoxicillin-clavulanic acid; TMP-S, trimethoprim–sulfonamide.

No significant confounding was found to be present and no interaction effects were found to be significant for the variables in the model.

DISCUSSION

Although since 2000 onwards, ceftiofur has been withdrawn from use in poultry because of the lack of establishment of MRLs [Reference Bertrand1] a large increase in resistance has been observed in broilers in recent years [Reference Persoons2]. In the present study, high ceftiofur resistance prevalences in broiler E. coli could be observed, with large between-farm variations. Selective plating showed that in 63% of the samples from the first five flocks, ceftiofur-resistant E. coli were present, indicating vast spread of ESBLs in Belgian broilers. This is in contrast with the evolution of ceftiofur resistance in pigs and cattle where the use of ceftiofur is still permitted and where no important increases in resistance have been observed [Reference Casteleyn4]. These species are also less exposed to mass medication than broilers, with the exception of finishing pigs and veal calves. If cephalosporin resistance in broilers keeps increasing, the use of cephalosporins in veterinary and human medicine is likely to become heavily jeopardized [Reference Zahar22]. In a recent publication, a very high correlation (r=0·9, P<0·01) was found between ceftiofur-resistant Salmonella enterica serovar Heidelberg isolated from retail chicken and the incidence of ceftiofur-resistant Salmonella enterica serovar Heidelberg infections in humans [Reference Dutil23]. This illustrates the importance for public health of ceftiofur resistance in the broiler ecosystem.

The results of the current study indicate that many factors are associated with ceftiofur resistance in faecal E. coli. Some are biologically explainable whereas others are unexpected and more difficult to interpret. The single most expected risk factor, namely the use of ceftiofur, is not present due to the absence of any record of ceftiofur use in Belgian broilers as a result of the lack of a MRL for ceftiofur in poultry since 2000. However, possible off-label use cannot be ruled out. In Canada, increases or decreases in ceftiofur resistance in both retail chicken E. coli and Salmonella isolates were found to follow a similar trend to the use of ceftiofur in hatcheries [Reference Dutil23].

The observation in our study that hatchery of origin has a large significant effect on ceftiofur resistance level suggests that hatchery-related factors influence the occurrence of ceftiofur resistance. This might be a sequel to the historically permitted use of ceftiofur, often applied in combination with vaccination in newly hatched chicks and still having an effect due to the persistence of resistance, or due to a (continued) off-label use of ceftiofur in young chicks. Further research should be conducted to elucidate this relationship; however, the strong relationship between the use of ceftiofur in hatcheries and changing levels of ceftiofur resistance in both Salmonella and E. coli in the Canadian study allows us to rely more on the second hypothesis [Reference Dutil23]. Mentions of unnecessary or off-label use of ceftiofur in the poultry industry occur worldwide and are linked to cephalosporin resistance [Reference Collignon and Aarestrup24, Reference Webster25].

Moreover, the use of other antimicrobials might, through cross- or co-resistance, act as covariables and select for ceftiofur resistance. In the current study this was observed for the use of amoxicillin and resistance against amoxicillin–clavulanic acid. This is in line with molecularly confirmed cross-resistance across these compounds, i.e. amoxicillin and amoxicillin–clavulanic acid may select for genes that confer resistance to extended spectrum cephalosporins like the ESBLs, CTX-M or TEM, and AmpC β-lactamases like CMY-2 [Reference Smet20]. The study of Smet et al. [Reference Smet20] indicated the presence of these genes in ceftiofur-resistant E. coli originating from the same samples used in the present study. Resistance to trimethoprim–sulfonamide was also significantly associated with ceftiofur resistance, probably through genetic linkage between trimethoprim–sulfonamide and cephalosporin resistance determinants as has already been observed in Enterobacteriaceae. Salmonella enterica serovar Virchow, can harbour dfrA1 (encoding trimethoprim resistance) and sul1 (encoding sulphonamide resistance) that are physically linked to CTX-M-2 [Reference Bertrand1].

Besides amoxicillin treatment and hatchery of origin, other flock-level management factors also proved to be significant risk factors. In disease control, hygiene and sanitation are very important and modifiable assets to prevent disease introduction and spread in a herd or flock. With regard to resistance, an inverse effect seems to be present. As an example in this study it was found that a clean treatment reservoir is a risk factor for ceftiofur resistance. This might be the result of a dilution effect by susceptible bacteria due to a soiled (‘dirty’) environment, resulting in a more diverse intestinal microbiota. Comparable results were found in tetracycline-resistant lactose-positive coliforms originating from fattening pigs in Belgium [Reference Dewulf26], where better sanitation measures were also identified as adding to the risk.

Acidification of drinking water also had a considerable effect on the intestinal flora. Acidifying drinking water induces a shift in intestinal flora because of the low acid resistance of Enterobacteriaceae. This will have a general effect on the E. coli population [Reference Owens27, Reference Garrido28]. Our results suggest that the ceftiofur-resistant subpopulation is more sensitive to the acid, resulting in a larger adverse effect on that subpopulation thereby reducing the chance of isolation. This might be the consequence of the possible loss of vitality of bacteria that often goes together with acquiring drug resistance [Reference Andersson29]. Changing the feed more than three times during the production cycle also affected the level of ceftiofur resistance. Feed changes inevitably cause stress for chickens, and can cause an increase in the prevalence of resistant bacteria, as stress is a factor that has been reported as an increasing factor for the prevalence of resistant bacteria in pigs, not linked to antimicrobial use [Reference Arnett, Cullen and Ebner30]. Moreover, increased prevalences of antimicrobial resistance linked to changes in the microbial population may be caused by the occurrence of other stress-induced genes that possibly occupy the same genetic elements of the bacteria as those that harbour resistance determinants [Reference Mathew, Cissell and Liamthong31].

The litter material on which the broilers were kept was also identified as a risk factor. Compared to wood curls, straw and flax unfavourably affected the level of ceftiofur resistance. Litter material has been described as influencing the composition of gut flora. Aktan & Sagdic [Reference Aktan and Sagdic32] observed that the litter material used can indeed affect the composition of the microbiota, as did Torok et al. [Reference Torok33], while Fries et al. [Reference Fries34] were not convinced of this finding and conversely allocated no effect of litter material to gut composition. How this would differently affect the resistant vs. non-resistant subpopulations of the same genera is not clear, but different litters may provide different bacterial growth conditions, e.g. different pH or humidity. According to our study this may also influence the magnitude of the ceftiofur-resistant E. coli population. A similar effect is seen for breed, e.g. where the Cobb breed would be favourable for the acquisition of ceftiofur resistance. This again is not readily explainable. Mentions of antimicrobial resistance being dependent on a species' breed, with comparable management, have, to our knowledge, not been made. This would then again have to be linked to different colonization conditions imposed by the breed, leading to different compositions of microbiota, which can also effect the resistant population, or it could be related to origin of the birds, e.g. parent of grandparent lines. Since no definite link between the latter two factors and the occurrence of antimicrobial resistance has been established before, these factors should be further studied in order to detect the mechanism by which they affect ceftiofur resistance in E. coli. However, it should be borne in mind that in observational studies one can never fully exclude the possibility of type I errors.

It is not yet fully understood by which mechanism all identified risk factors influence the acquisition of ceftiofur resistance in E. coli from broilers, and this warrants further research. Yet the results clearly indicate that a variety of factors are involved and that ceftiofur resistance is not solely attributable to the use or abuse of the antimicrobial or related compounds. Including these factors can also allow the control of any confounding that might exist between the association of antimicrobial use and resistance. Even though several of the working mechanisms are not yet fully understood, the observed increase in resistance merits full attention. Since many factors are modifiable through management changes, broiler production should consider adaptations that avoid the aforementioned risk factors for ceftiofur resistance from both an animal and public health point of view.

ACKNOWLEDGEMENTS

This work was supported by a grant of the Federal Public Service of Health, Food Chain Safety and Environment (grant number RT-06/3-ABRISK). All the participating farmers are acknowledged for their willingness to cooperate in this study.

DECLARATION OF INTEREST

None.

References

REFERENCES

1.Bertrand, S, et al. Clonal emergence of extended-spectrum beta-lactamase (CTX-M-2)-producing Salmonella enterica serovar Virchow isolates with reduced susceptibilities to ciprofloxacin among poultry and humans in Belgium and France (2000 to 2003). Journal of Clinical Microbiology 2006; 44: 28972903.CrossRefGoogle ScholarPubMed
2.Persoons, D, et al. Prevalence and persistence of antimicrobial resistance in broiler indicator bacteria. Microbial Drug Resistance 2010; 16: 67–.74CrossRefGoogle ScholarPubMed
3.Verloo, D, et al. Descriptive epidemiology of the resistance observed in Escherichia coli isolated from healthy cattle, pigs and broilers, their meat and meat products. Proceedings of the Flemish Society for Veterinary Epidemiology and Economics, 11 December 2003, pp. 67.Google Scholar
4.Casteleyn, C, et al. Antimicrobial resistance in Escherichia coli from farm animals, hares, septic material and waste water in Flanders. Flemisch Veterinary Journal 2006; 75: 2330.Google Scholar
5.Briñas, L, et al. Mechanisms of resistance to expanded-spectrum cephalosporins in Escherichia coli isolates recovered in a Spanish hospital. Journal of Antimicrobial Chemotherapy 2005; 56: 11071110.CrossRefGoogle Scholar
6.Batchelor, M, Threlfall, EJ, Liebana, E. Cephalosporin resistance among animal-associated Enterobacteria: a current perspective. Expert Reviews of Anti-infective Therapy 2005; 3: 403417.CrossRefGoogle ScholarPubMed
7.Kojima, A, et al. Extended-spectrum-beta-lactamase-producing Escherichia coli strains isolated from farm animals from 1999 to 2002: report from the Japanese Veterinary Antimicrobial Resistance Monitoring Program. Antimicrobial Agents and Chemotherapy 2005; 49: 35333537.CrossRefGoogle ScholarPubMed
8.Zahar, JR, et al. Extension of beta-lactamases producing bacteria is a worldwide concern. Medical Science 2009; 25: 939944.Google ScholarPubMed
9.Daniels, JB, et al. Role of ceftiofur in selection and dissemination of blaCMY-2-mediated cephalosporin resistance in Salmonella enterica and commensal Escherichia coli isolates from cattle. Applied and Environmental Microbiology 2009; 75: 36483655.CrossRefGoogle ScholarPubMed
10.Potz, NA, et al. London & South East ESBL Project Group. Prevalence and mechanisms of cephalosporin resistance in Enterobacteriaceae in London and South-East England. Journal of Antimicrobial Chemotherapy 2006; 58: 320326.CrossRefGoogle Scholar
11.Gupta, A, et al. National Antimicrobial Resistance Monitoring System PulseNet Working Group. Emergence of multidrug-resistant Salmonella enterica serotype Newport infections resistant to expanded-spectrum cephalosporins in the United States. Journal of Infectious Diseases 2003; 188: 17071716.CrossRefGoogle Scholar
12.Collignon, P, et al. World Health Organization ranking of antimicrobials according to their importance in human medicine: a critical step for developing risk management strategies for the use of antimicrobials in food production animals. Clinical Infectious Diseases 2009; 49: 132141.CrossRefGoogle ScholarPubMed
13.Winokur, PL, et al. Evidence for transfer of CMY-2 AmpC beta-lactamase plasmids between Escherichia coli and Salmonella isolates from food animals and humans. Antimicrobial Agents and Chemotherapy 2001; 45: 27162722.CrossRefGoogle Scholar
14.Bywater, RJ. Veterinary use of antimicrobials and emergence of resistance in zoonotic and sentinel bacteria in the EU. Journal of Veterinary Medicine, Series B: Infectious Diseases and Veterinary Public Health 2004; 51: 361363.CrossRefGoogle ScholarPubMed
15.Witte, W. Selective pressure by antibiotic use in livestock. International Journal of Antimicrobial Agents 2000; 16: 1924.CrossRefGoogle ScholarPubMed
16.Aarestrup, FM, Wegener, HC. The effects of antibiotic usage in food animals on the development of antimicrobial resistance of importance for humans in Campylobacter and Escherichia coli. Microbes and Infection 1999; 1: 639644.CrossRefGoogle ScholarPubMed
17.Witte, W. Ecological impact of antibiotic use in animals on different complex microflora: environment. International Journal of Antimicrobial Agents 2000; 14: 321325.CrossRefGoogle ScholarPubMed
18.Wang, H, Chen, M. China Nosocomial Pathogens Resistance Surveillance Study Group. Surveillance for antimicrobial resistance among clinical isolates of gram-negative bacteria from intensive care unit patients in China, 1996 to 2002. Diagnostic Microbiology and Infectious Disease 2005; 51: 201208.CrossRefGoogle Scholar
19.Kennedy, KJ, Roberts, JL, Collignon, PJ. Escherichia coli bacteraemia in Canberra: incidence and clinical features. Medical Journal of Australia 2008; 188: 209213.CrossRefGoogle ScholarPubMed
20.Smet, A, et al. Diversity of extended-spectrum beta-lactamases and class C beta-lactamases among cloacal Escherichia coli isolates in Belgian broiler farms. Antimicrobial Agents and Chemotherapy 2008; 52: 12381243.CrossRefGoogle Scholar
21.Parkin, TD, et al. Horse-level risk factors for fatal distal limb fracture in racing Thoroughbreds in the UK. Equine Veterinary Journal 2004; 36: 513519.CrossRefGoogle ScholarPubMed
22.Zahar, JR, et al. Addressing the challenge of extended-spectrum beta-lactamases. Current Opinion in Investigational Drugs 2009; 10: 172180.Google ScholarPubMed
23.Dutil, L, et al. Ceftiofur resistance in Salmonella enterica serovar Heidelberg from chicken meat and humans, Canada. Emerging Infectious Diseases 2010; 16: 4854.CrossRefGoogle ScholarPubMed
24.Collignon, P, Aarestrup, FM. Extended-spectrum beta-lactamases, food, and cephalosporin use in food animals. Clinical Infectious Diseases 2007; 44: 13911392.CrossRefGoogle ScholarPubMed
25.Webster, P. Poultry, politics, and antibiotic resistance. Lancet 2009; 374: 773774.CrossRefGoogle ScholarPubMed
26.Dewulf, J, et al. Tetracycline-resistance in lactose-positive enteric coliforms originating from Belgian fattening pigs: degree of resistance, multiple resistance and risk factors. Preventive Veterinary Medicine 2007; 78: 339351.CrossRefGoogle ScholarPubMed
27.Owens, B, et al. Effects of different feed additives alone or in combination on broiler performance, gut microflora and ileal histology. British Poultry Science 2008; 49: 202212.CrossRefGoogle ScholarPubMed
28.Garrido, MN, et al. Acidified litter benefits the intestinal flora balance of broiler chickens. Applied and Environmental Microbiology 2004; 70: 52085213.CrossRefGoogle ScholarPubMed
29.Andersson, DI. Persistence of antibiotic resistant bacteria. Current Opinion in Microbiology 2003; 6: 452456.CrossRefGoogle ScholarPubMed
30.Arnett, DB, Cullen, P, Ebner, PD. Characterization of resistance patterns and detection of apramycin resistance genes in Escherichia coli isolated from swine exposed to various environmental conditions. International Journal of Food Microbiology 2003; 89: 1120.Google Scholar
31.Mathew, AG, Cissell, R, Liamthong, S. Antibiotic resistance in bacteria associated with food animals: a United States perspective of livestock production. Foodborne Pathogens and Disease 2007; 4: 115133.CrossRefGoogle ScholarPubMed
32.Aktan, S, Sagdic, O. Dried rose (Rosa damascene Mill.) dreg: an alternative litter material in broiler production. South African Journal of Animal Science 2004; 34: 7579.CrossRefGoogle Scholar
33.Torok, VA, et al. Influence of different litter materials on cecal microbiota colonization in broiler chickens. Poultry Science 2009; 88: 24742481.CrossRefGoogle ScholarPubMed
34.Fries, R, et al. Microflora of two different types of poultry litter. British Poultry Science 2005; 46: 668672.CrossRefGoogle ScholarPubMed
Figure 0

Table 1. Results of the multilevel multivariable analysis of covariables and risk factors for ceftiofur resistance in 32 Belgian broiler farms