Antimicrobial growth promoters and Salmonella spp., Campylobacter spp. in poultry and swine, Denmark. (Dispatches).The use of antimicrobial growth promoters in Danish food animal production was discontinued in 1998. Contrary to concerns that pathogen load would increase; we found a significant decrease in Salmonella in broilers, swine, pork, and chicken meat and no change in the prevalence of Campylobacter Campylobacter Genus of gram-negative spiral-shaped bacteria infecting mammals. Many species, especially C. fetus, cause miscarriage in sheep and cattle. C. jejuni is a common cause of food poisoning. Sources include meats (particularly chicken) and unpasteurized milk. in broilers. ********** Antimicrobial growth promoters are antimicrobial drags added to animal feed to enhance growth and improve feed efficiency of food animals. In the United States, the use of antimicrobial growth promoters also includes elements of prophylaxis, which are not allowed in Europe. Antimicrobial growth promoters have been widely used in Danish food animal production since the 1970s. On February 15, 1998, the Danish cattle and broiler broiler a young (about 8 weeks old) male or female chicken weighing 3 to 3.5 lb. industries, reacting to consumer concerns over food safety, voluntarily stopped the use of all antimicrobial growth promoters. The pig industry stopped using the growth promoters in pigs over 35 kg; all use was phased out in 1999. Despite concerns that no longer using the growth promoters would have a wide range of negative effects (e.g., an increase in disease and death, poor growth rates Growth Rates The compounded annualized rate of growth of a company's revenues, earnings, dividends, or other figures. Notes: Remember, historically high growth rates don't always mean a high rate of growth looking into the future. , increased feed consumption, increased fecal shedding, and enhanced shedding or carriage of foodborne pathogens such as Salmonella or Campytobacter), producers in the broiler and pig industries discontinued the use. Studies have shown that antimicrobial drags reduce part of the intestinal flora while potentially decreasing pathogen shedding (1-3). For these reasons, producers believed that removing antimicrobial growth promoters could cause human pathogenic intestinal bacteria in food animals to increase. Another concern was that increased fecal shedding could lead to contamination of carcasses at slaughter and increased risk for foodborne infection in humans. Our study examines the effect of discontinued use of antimicrobial growth promoters on the prevalence of Salmonella in Danish broiler flocks, chickens after slaughter, swine herds, and pork end products. We also examine the effect on Campylobacter in Danish broiler flocks. The Study Data for this analysis were obtained from routine monitoring programs in Danish broilers and swine. Approximately 450,000 broiler and chicken samples and 830,000 swine and pork samples are tested each year. A detailed description of sample collection methods and numbers of samples is available (4). Broiler flocks have been tested for Salmonella since 1989 and for Campylobacter since the end of 1995. Initially, flocks were tested for Salmonella by the collection of 16 fecal samples; however, since June 2000, five "sock samples" (Samples were taken by placing a sock over the collector's shoes. The collector walks through the poultry house; the socks absorb fecal samples) have been collected. Antemortem antemortem /an·te·mor·tem/ (an?te-mor´tem) [L.] occurring before death. an·te·mor·tem adj. Before death. antemortem performed or occurring before death. samples are obtained 2-3 weeks before slaughter by collecting five pairs of sock samples per flock (4). Before November 2000, postmortem postmortem /post·mor·tem/ (post-mort´im) performed or occurring after death. post·mor·tem adj. Relating to or occurring during the period after death. n. See autopsy. Salmonella sampling was conducted by examination of five pooled swab samples each consisting of 10 neck-skin samples per flock. After November 2000, postmortem sampling came from batches of poultry parts. Because of this change, we excluded postmortem data (after November 2000) from analysis. Broiler flocks are monitored for Campylobacter by examination of cloacal cloacal emanating from or pertaining to cloaca. cloacal kiss the contact which occurs during insemination in birds when the vent of the female is everted exposing the cloacal mucosa against which the phallus of the male is pressed. swabs from 10 birds per flock or batch at slaughter. Since June 1995, swine herds have been continuously monitored for Salmonella by serologic testing of "meat juice" (10g of muscle tissue are collected from the neck, diaphragm or tenderloin of the animal. This sample is placed into a container consisting of an upper coffee-filter like part to hold the meat and a lower tube-like part. The container is frozen overnight at -20[degrees]C and subsequently allowed to thaw at 4[degrees]C for 24 hours Adv. 1. for 24 hours - without stopping; "she worked around the clock" around the clock, round the clock , causing release of the meat juice into the lower part of the tube. This juice is then tested for Salmonella antibodies) samples from each herd producing >100 finishers (pigs 30-50 kg) per year. In July 2001, this requirement changed to herds producing >200 finishers per year. The number of samples taken is dependent on herd size. Based on serologic se·rol·o·gy n. pl. se·rol·o·gies 1. The science that deals with the properties and reactions of serums, especially blood serum. 2. results, herds are placed into categories. Level 1 herds have no or few seroreactors (animals that test positive for Salmonella), and no intervention is required. Level 2 herds have a higher proportion of seroreactors, and the herd owner must seek advice on reducing the prevalence of Salmonella. Level 3 herds have a large proportion of seroreactors, and the herd owner must seek advice and slaughter under special hygienic conditions. Since July 1993, Salmonella in pork has been measured by monthly samples of cuts of meat from slaughterhouses. The number of samples depends on the number of animals slaughtered. In January 2001, the sampling method changed to carcass swabs. Consequently, data from 2001 were not included in this analysis (4). Data were divided into two periods: before (P1) and after (P2) withdrawal of antimicrobial growth promoters. To account for factors such as seasonality, equal time periods were used for comparison; however, periods varied from 12 to 36 months, depending on availability of data. Although the voluntary discontinuation on purchasing antimicrobial growth promoter containing feed for broilers was initiated on February 15, depletion of feed stocks may have taken several weeks. To account for this and for the uneven withdrawal of antimicrobial growth promoters in pigs, data from 1998 (broilers) and 1998-1999 (swine) were excluded from analysis. The resulting time periods are found in Table 1. For this analysis, the mean prevalence of positive flocks (broilers), the percentage of herds classified as level 2 or level 3 (swine herds), and the percentage of positive samples (pork) were obtained by month for P1 and P2. Using these data, the mean prevalence for P1 and P2 were calculated and differences in means were evaluated by a t test by using SAS (1) (SAS Institute Inc., Cary, NC, www.sas.com) A software company that specializes in data warehousing and decision support software based on the SAS System. Founded in 1976, SAS is one of the world's largest privately held software companies. See SAS System. version 8.0 (SAS Institute, Inc., Cary, NC). The prevalence of Salmonella and Campylobacter in broilers and swine between 1995 and 2001 is shown in the Figure. [FIGURE OMITTED] The mean percentage of broiler flocks testing positive for Salmonella during P1 (before withdrawal) was 14.4% (range 3.7% to 33.6%) for antemortem examination and 17% (range 8.1% to 38.8%) for postmortem (Table 2) P2 samples averaged 2.4% (range 0.2% to 5.8%) and 4.9% (range 0.7% to 24.9%), respectively. A comparison of means showed that the prevalence of Salmonella was significantly lower in the period following withdrawal of antimicrobial growth promoters for both antemortem (p<0.0001) and postmortem samples (p<0.0001). The average percentage of broiler flocks testing positive for Campylobacter during P1 was 35.3% (11.4% to 64.%8) and P2 was 40.8 (18% to 77%). No statistical difference existed in the mean prevalence between the two periods (p=0.2470). The percentage of swine herds classified as level 2 or level 3 during P1 was 5% (4.2% to 6.2%) and 3.3% (2.5% to 4.4%) for P2. A comparison of means showed that the average percentage of swine herds classified as level 2 or 3 was significantly lower in the period following the withdrawal of antimicrobial growth promoters (p<0.0001). The percentage of Salmonella isolated from fresh pork samples dropped from 1.1% (0.5% to 1.8%) in P1 to 0.8% (0.4% to 1.5%) in P2. Although the-change is small, the period following the withdrawal of antimicrobial growth promoters was significantly lower (p=0.0290). Conclusions Contrary to concerns that withdrawal of antimicrobial growth promoters would cause an increase in pathogen load, we found a decrease in Salmonella prevalence in broilers, chicken, swine, and pork and no change in the prevalence of Campylobacter in broilers. Previous studies on this topic have shown mixed results. Two observational studies observational studies, n.pl an investigational method involving description of the associations be-tween interventions and outcomes. Outcomes research and practice audits are examples of this investigational method. found that penicillin given to swine increased total bacterial and Enterobacteriaceae counts (5,6). Other experiments found that avoparcin increased Salmonella shedding in broilers and excretion rates had a dose-response effect with increasing concentrations of avoparcin (7,8). A series of experiments in broilers showed that avoparcin, nitrovin, tylosin tylosin an antibiotic produced by cultures of Streptomyces fradiae, with a structure similar to erythromycin. It is effective against gram-positive bacteria generally and especially those susceptible to members of the macrolide group. , flavomycin, and lincomycin lincomycin (lĭng'kōmī`sĭn), antibiotic isolated from bacteria of the genus Streptomyces. Similar in activity to erythromycin, it is effective against most gram-positive organisms including staphylococci, some streptococci, and caused increased shedding of Salmonella in most experiments, while virginiamycin virginiamycin an antibiotic mixture of virginiamycin M1 and virginiamycin S1, produced in cultures of Streptomyces virginiae; active against gram-positive cocci. Used mostly as a feed additive for pigs to promote growth. and bacitracin bacitracin (băs'ĭtrā`sĭn), antibiotic produced by a strain of the bacterial species Bacillus subtilis. It is widely used for topical therapy such as for skin and eye infections; it is effective against gram-positive bacteria, had little or no effect and sodium arsenilate decreased shedding (9-11). Holmberg et al. found that both avoparcin and monensin monensin used as a growth promotant in ruminants, produced by cultures of Streptomyces cinnamonensis. Not to be used in horses because of its toxicity in this species. Large doses in cattle and normal doses in horses cause sudden death due to heart failure. reduced shedding of S. Infantis in broilers but a combination of the two increased shedding (12). Bolder et al. showed that flavophospholipol and salinomycin decreased Salmonella shedding in broilers but had no significant effect on the shedding of C. jejuni (13). Our study is unique because we included a large sample of animals under natural conditions, included both animals and products, and examined the combined effect of many antimicrobial growth promoters. However, several factors should be kept in mind when interpreting the results. First, our analysis cannot elucidate the impact that withdrawal of an individual antimicrobial growth promoter had on a particular pathogen or in a particular species. In addition, since avoparcin was withdrawn in 1995, any immediate effects seen from its discontinued use will be demonstrated in P1 of our study instead of P2. Despite a change in sampling methods for broilers in June 2000 and swine herds in July 2001, these data were included in analysis. Both changes increased the sensitivity of sampling, in theory leading to a higher prevalence. Since this change occurred during P2, it would tend to bias our results toward the null; thus, including these samples gives our study a more conservative result. Finally, our study only describes the prevalence of Salmonella and Campylobacter after the withdrawal of antimicrobial growth promoters. Effects such as productivity, changes in therapeutic antimicrobial drug use and economic impact are described in another study (14). Our findings only show a temporal relationship between withdrawal and reduction, and one should be cautious not to infer causality. The fact that the decrease was seen before and during the use of antimicrobial growth promoters suggests that other factors play a role. The most obvious of these factors is the effect of the ongoing surveillance and control programs in food-producing animals food-producing animals see food animals. . Programs in broilers and swine, described each year in the Annual Report on Zoonosis Zoonosis Definition Zoonosis, also called zoonotic disease refers to diseases that can be passed from animals, whether wild or domesticated, to humans. (4), have been in effect since the late 1980s and mid-1990s and have made a substantial impact on reducing the prevalence of Salmonella in primary food production. What is clearly shown from this analysis is that Salmonella and Campylobacter rates have not increased in food animal carriers since antimicrobial growth promoters were withdrawn in 1998. This finding, combined with evidence that the withdrawal has taken place without remarkably noticeable effects on the productivity in broilers (15) and swine, is of particular importance in light of the emerging problem of antimicrobial drug-resistant human pathogenic organisms, which are associated with the use of antimicrobial growth promoters.
Table 1. Description of time intervals used for data analysis, by
species and pathogen (a)
Species Pathogen Period 1 (P1) Period 2 (P2)
Broilers Salmonella Jan 1995-Dec 1997 Jan 1999-Dec 2001
(antemortem)
Salmonella Jan 1996-Oct 1997 Jan 1999-Oct 2000
(postmortem)
Campylobacter Jan 1996-Dec 1997 Jan 1999-Dec 2000
Swine Salmonella Jan 1996-Dec 1997 Jan 2000-Dec 2001
Salmonella (pork) Jan 1997-Dec 1997 Jan 2000-Dec 2000
(a) Period 1 and 2 refer to the time periods before (P1) and after (P2)
the withdrawal of antimicrobial growth promoters
Table 2. Comparison of the average prevalence of Salmonella and
Campylobacter in broiler flocks, chicken meat, swine herds, and pork
products before and after withdrawal of antimicrobials for use as
growth promoters
Period 1 (a) Period 1 standard
mean (range) deviation
Salmonella
Broilers (antemortem) 14.4 (3.7-33.6) 8.3902
Broilers (postmortem) 17.0 (8.1-38.8) 7.9125
Swine 5.0 (4.2-6.2) 0.5904
Pork 1.1 (0.5-1.8) 0.3895
Campylobacter
Broilers (antemortem) 35.3 (11.4-64.8) 16.6290
Period 2 (b) Period 2 standard p value
mean (range) deviation
Salmonella
Broilers (antemortem) 2.4 (0.2-5.8) 1.3215 <0.0001
Broilers (postmortem) 4.9 (0.7-24.9) 5.0493 <0.0001
Swine 3.3 (2.5-4.4) 0.5347 <0.0001
Pork 0.8 (0.4-1.5) 0.2839 0.0290
Campylobacter
Broilers (antemortem) 40.8 (18.0-77.0) 16.1185 0.2470
(a) Before withdrawal of antimicrobial growth promoters.
(b) After withdrawal of antimicrobial growth promoters.
The opinions expressed by authors contributing to this journal do not necessarily reflect the opinions of the Centers for Disease Control and Prevention Centers for Disease Control and Prevention (CDC), agency of the U.S. Public Health Service since 1973, with headquarters in Atlanta; it was established in 1946 as the Communicable Disease Center. or the institutions with which the authors are affiliated. References (1.) Girard AE, English AR, Evangelisti DG, Lynch JE, Solomons IA. Influence of subtherapeutic sub·ther·a·peu·tic adj. Below the dosage levels used to treat diseases: subtherapeutic feeding of penicillin to livestock. sub levels of a combination of neomycin neomycin (nē'ōmī`sĭn), broad spectrum antibiotic effective against both gram positive and gram negative bacteria (see Gram's stain). and oxytetracycline oxytetracycline /oxy·tet·ra·cy·cline/ (ok?se-tet?rah-si´klen) a broad-spectrum tetracycline antibiotic produced by Streptomyces rimosus, used as the base or the hydrochloride salt. on Salmonella Typhimurium Salmonella ty·phi·mu·ri·um n. A bacterium that causes food poisoning. in swine, calves, and chickens. Antimicrob Agents Chemother 1976;10:89-95. (2.) Evangelisti DG, English AR, Girard AE, Lynch JE, Solomons IA. Influence of subtherapeutic levels of oxytetracycline on Salmonella Typhimurium in swine, calves, and chickens. Antimicrob Agents Chemother 1975;8:664-72. (3.) Jarolman H, Shirk shirk In Islam, idolatry and polytheism, both of which are regarded as heretical. The Qu'ran stresses that God does not share his powers with any partner (sharik) and warns that those who believe in idols will be harshly dealt with on the Day of Judgment. RJ, Langworth BF. Effect of chlortetracycline chlortetracycline /chlor·tet·ra·cy·cline/ (-tet-rah-si´klen) a broad-spectrum antibiotic obtained from Streptomyces aureofaciens; used as the hydrochloride salt. feeding on the Salmonella reservoir in chickens. J Appl Bacteriol 1976;40:153-61. (4.) Annual report on zoonosis in Denmark 2000. Copenhagen: Danish Ministry of Agriculture and Fisheries; 2000. Available from: URL URL in full Uniform Resource Locator Address of a resource on the Internet. The resource can be any type of file stored on a server, such as a Web page, a text file, a graphics file, or an application program. : http://www.vetinst.dk (5.) Bridges JH, Dyer IA, Burkhart WC. Effects of penicillin and streptomycin streptomycin (strĕp'tōmī`sĭn), antibiotic produced by soil bacteria of the genus Streptomyces and active against both gram-positive and gram-negative bacteria (see Gram's stain), including species resistant to other on the growth rate and bacterial count bacterial count Public health The concentration of coliform bacteria in water, a quantity that loosely correlates with the level of contamination of drinking and recreational waters. See Public water. in the feces of the pig. J Anim Sci 1952; 11:474-9. (6.) Bridges JH, Dyer IA, Powers JJ. Penicillin and streptomycin affect the microflora microflora /mi·cro·flo·ra/ (-flor´ah) the microscopic vegetable organisms of a special region. Microflora The bacterial population in the intestine. of the intestinal tract of pigs. J Anim Sci 1953;12:96-101. (7.) Barrow PA, Smith HW, Tucker JF. The effect of feeding diets containing avoparcin on the excretion of Salmonella by chickens experimentally infected with natural sources of Salmonella organism. J Hyg (Lond) 1984;93:439-444. (8.) Barrow PA. Further observations on the effect of feeding diets containing avoparcin on the excretion of Salmonella by experimentally infected chickens. Epidemiol Infect 1989;102:239-52. (9.) Smith HW, Tucker JF. The effect of feeding diets containing permitted antibiotics on the fecal excretion of Salmonella Typhimurium by experimentally infected chickens. J Hyg (Lond) 1975;75:293-301. (10.) Smith HW, Tucker JF. The effect of antimicrobial feed additives on the colonization of the alimentary tract alimentary tract n. See alimentary canal. alimentary tract see alimentary canal, digestive system. alimentary tract abnormal motility includes hypermotility, hypermotility, stasis. of chickens by Salmonella Typhimurium. J Hyg (Lond) 1978;80:217-31. (11.) Smith HW, Tucker JF. Further observations on the effect of feeding diets containing avoparcin, bacitracin, and sodium arsenilate on the colonization of the alimentary tract of poultry by Salmonella organisms. J Hyg (Lond) 1980;84:137-50. (12.) Holmberg T, Wierup M, Engstrom B. The effect of feeding diets containing avoparcin and monensin on the occurrence of Salmonella in caecum cae·cum n. Variant of cecum. caecum see cecum. and liver in experimentally infected chickens. Poult poult a young turkey. Sci 1984;63:1144-8. (13.) Bolder NM, Wagenaar JA, Putirulan FF, Veldman KT, Sommer Sommer is a surname, from the German and Danish word for the season "summer". It may refer to:
n. Gas bacillus. Clostridium perfringens Infectious disease An anaerobic gram-positive spore-forming rod, widely distributed in nature and present in the , Salmonella enteritidis Salmonella en·ter·it·i·dis n. Gärtner's bacillus. , and Campylobacter jejuni Campylobacter jejuni Vibrio jejuni, Campylobacter fetus ssp jejuni A curved or spiral gram-negative bacillus with a single polar flagellum Epidemiology Linked to contact with domestic and farm animals, unpasteurized milk, primates, day care in broiler after experimental infection. Poult Sci 1999;78:1681-9. (14.) Emborg H, Ersboll A, Heuer O, Wegener H. Effekten af ophor med brag af antibiotiske vaekstfremmere pa produktiviteten I den danske slagtekyllingeproduktion. Dansk Veterinaertidsskrift 2001;84:6-10. (15.) Emborg H, Ersboll A, Heuer O, Wegener H. The effect of discontinuing the use of antimicrobial growth promoters on the productivity in the Danish broiler production. Prev Vet Med 2001;50:53-70. Address for correspondence: Mary Christine Evans, Danish Zoonosis Centre, Danish Veterinary Institute, Bulowsvej 27, DK-1790 Copenhagen V, Denmark; fax: +(45) 35 30 03 77; email: mce@vetinst.dk Mary C. Evans * and Henrik Wegener * * Danish Veterinary Institute, Copenhagen, Denmark Ms. Evans holds a master's degree in public health epidemiology from Emory University. She was formerly employed in the foodborne diseases branch at Centers for Disease Control and Prevention and currently works as a research epidemiologist at the Danish Zoonosis Centre in Copenhagen, Denmark. Her research interests include infectious disease epidemiology and international health issues. Dr. Wegener is a professor of zoonoses Zoonoses Infections of humans caused by the transmission of disease agents that naturally live in animals. People become infected when they unwittingly intrude into the life cycle of the disease agent and become unnatural hosts. epidemiology at the Danish Veterinary Institute and Royal Veterinary and Agricultural University Royal Veterinary and Agricultural University - Address: Thorvaldsensvej 40, DK-1871 Frederiksberg C, Denmark. of Copenhagen, Denmark. His research interests involve epidemiology of foodborne zoonoses, antimicrobial resistance in the food chain, and microbial microbial pertaining to or emanating from a microbe. microbial digestion the breakdown of organic material, especially feedstuffs, by microbial organisms. risk assessment. |
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