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Prevention of Salmonella infection by contact using intestinal flora of adult birds and/or a mixture of organic acids

Controle da transmissão de Salmonella por contato entre aves de exploração comercial pelo uso de flora intestinal de aves adultas e/ou uma mistura de ácidos orgânicos

Abstracts

This study was carried out to assess the ability of competitive exclusion and a mixture of organic acids to prevent Salmonella infection by contact between newly hatched chicks. A bird infected with Salmonella was placed in a box containing non-infected birds, previously treated with a broth culture of faeces of adult birds (CE) and/or a mixture of organic acids. The number of Salmonella organisms in the caeca of the contact birds was estimated at 4 and 8 days post-challenge. The birds were infected with Salmonella Typhimurium, Salmonella Enteritidis (both repeated 5 times), Salmonella Agona and Salmonella Infantis (3 repetitions). The same approach was used to test the mixture of organic acids alone. In this case the birds received feed containing 0.8% of a mixture of formic acid (70%) and propionic acid (30%). Also, a third trial was carried out with birds inoculated with the broth culture of faeces and fed with feed containing the mixture of organic acids. Appropriate controls were included. Whereas the birds from the control groups and the groups treated with the mixture of organic acids were heavily infected with Salmonella, those pre-treated with CE or CE plus the mixture of organic acids had no viable cells per gram of caecal contents.

Salmonella; competitive exclusion; organic acids; by-contact infection; poultry


O presente trabalho avaliou a prevenção da disseminação de quatro sorotipos de Salmonella, de interesse em avicultura e saúde pública (Salmonella Typhimurium, Salmonella Agona, Salmonella Infantis e Salmonella Enteritidis), entre aves recém-nascidas, com o intuito de diminuir a disseminação de salmonelas em rebanhos avícolas por aves que contraíram a infecção pela via vertical. Analisou-se experimentalmente a administração de microbiota intestinal de aves adultas em aves recém-nascidas, a incorporação de uma mistura de ácidos orgânicos na ração e a associação desses dois tratamentos, em grupos onde colocou-se uma ave infectada, para provocar a transmissão por contato. A microbiota intestinal de aves adultas mostrou-se eficiente no controle da colonização cecal nos quatro ensaios realizados, com os diferentes sorotipos. A mistura de ácidos orgânicos na ração não foi eficaz em prevenir a colonização cecal e a associação dos tratamentos demonstrou que não há interferência entre eles, permanecendo a ação da microbiota de aves adultas.

Salmonella; exclusão competitiva; ácidos orgânicos; infecção por contato; aves comerciais


PREVENTION OF SALMONELLA INFECTION BY CONTACT USING INTESTINAL FLORA OF ADULT BIRDS AND/OR A MIXTURE OF ORGANIC ACIDS

Gláucia Helaine de Oliveira1; Angelo Berchieri Junior1* * Corresponding author. Mailing address: Faculdade de Ciências Agrárias e Veterinárias da UNESP, Via de Acesso Paulo Donato Castellane, S/N, CEP 14870-000, Jaboticabal, SP, Brasil. Telefax (+5516) 3224275. E-mail erchieri@fcav.unesp.br ; Paul A. Barrow2

1Faculdade de Ciências Agrárias e Veterinárias, Universidade Estadual Paulista, Jaboticabal, SP, Brasil. 2Institute for Animal Health, Compton Laboratory, Compton, Berkshire, United Kingdown

Submitted: November 03, 1999; Returned to authors for corrections: April 06, 2000; Approved: June 09, 2000

ABSTRACT

This study was carried out to assess the ability of competitive exclusion and a mixture of organic acids to prevent Salmonella infection by contact between newly hatched chicks. A bird infected with Salmonella was placed in a box containing non-infected birds, previously treated with a broth culture of faeces of adult birds (CE) and/or a mixture of organic acids. The number of Salmonella organisms in the caeca of the contact birds was estimated at 4 and 8 days post-challenge. The birds were infected with Salmonella Typhimurium, Salmonella Enteritidis (both repeated 5 times), Salmonella Agona and Salmonella Infantis (3 repetitions). The same approach was used to test the mixture of organic acids alone. In this case the birds received feed containing 0.8% of a mixture of formic acid (70%) and propionic acid (30%). Also, a third trial was carried out with birds inoculated with the broth culture of faeces and fed with feed containing the mixture of organic acids. Appropriate controls were included. Whereas the birds from the control groups and the groups treated with the mixture of organic acids were heavily infected with Salmonella, those pre-treated with CE or CE plus the mixture of organic acids had no viable cells per gram of caecal contents.

Key words:Salmonella, competitive exclusion, organic acids, by-contact infection, poultry

INTRODUCTION

The perception of Salmonella infection as a problem to the poultry industry has changed as the industry itself has changed. In many countries Pullorum disease and fowl typhoid are largely under control although this is not the case in many countries that have only recently intensified their industries and in those in which the high ambient temperature indicates problems with environmental hygiene (10). Avian salmonellosis, not caused by S. Pullorum and S. Gallinarum, is named paratyphoid infection, and may be caused by many serotypes of Salmonella. This disease has an important economic impact, as it may affect the animal performance and provoke morbidity and mortality in younger birds. In addition, paratyphoid salmonellosis may result in food-borne disease in humans, due to the ability to colonise the alimentary tract of the chicken, resulting in carcass contamination. From the eighties there was a dramatic increase of outbreaks of food-borne salmonellosis caused by S. Enteritidis (28, 35, 36). Poultry products were considered the main means of transmission. According to Lister (19), the bacterium was transmissible vertically. Following infection of young birds, the bacterium may be disseminated throughout the environment of the poultry house making its control very difficult. Davies and Wray (8) demonstrated the presence of Salmonella in a poultry house after depopulation and cleaning and disinfecting. The authors demonstrated that rodents present in the house had in all probability re-contaminated the house.

Poultry are much more susceptible to Salmonella infection in the beginning of life. By preventing infection among young birds, including those that are infected by vertical transmission, the frequency of infection throughout the life of the bird may be reduced (6). Control of Salmonella infection in birds may be approached in several ways. Antibiotic therapy is very simple and is used extensively. However, it may not eliminate Salmonella, may actually increase excretion and also may select for resistance (9, 13, 31). Nurmi and Rantala (25) initiated a new approach of controlling Salmonella in birds by administrating to young birds a broth culture of faeces obtained from adult birds. This method, known as competitive exclusion (CE), is adopted in many countries (22, 23) using either an anaerobically (12, 21, 29, 33) or aerobically (27) incubated culture. In view of the worsening situation in recent years regarding the Salmonella problem in both humans and poultry production this study was carried out to assess the administration of aerobic broth culture of faeces from adult birds to prevent Salmonella in young birds placed together with infected (seeder) birds.

MATERIALS AND METHODS

Bacterial strains

The work was carried out with Salmonella Typhimurium, S. Infantis, S. Agona and S. Enteritidis strains resistant to nalidixic acid and spectinomycin (NalrSpecr). Broth cultures were prepared in Brain Heart Infusion (BHI) broth incubated at 37oC for 24hs in a shaking incubator (100 strokes/ min.).

Faecal culture (CE)

Faeces from adult birds, reared in the FCAV-UNESP – Jaboticabal, São Paulo State, were inoculated into BHI broth (1:10) that was incubated statically in air at 37oC for 24hs. The culture was tested for Salmonella. The birds were inoculated into the crop with 0.1 ml of a culture diluted a thousand fold.

Acid treatment of the feed

A mixture of formic acid (70%) plus propionic acid (30%) was added into the feed at the level of 0.8%.

Birds

Newly hatched chicks from a commercial broiler hatchery were used, six birds per box. Feed with no added antibiotics or other additives and drinking water were both available ad libitum, and also was provided a heat source. Swabs from cloacae and from transport boxes of the birds were taken to assess they were free of Salmonella.

Experimental procedure

The experiment consisted of three groups with three to five repetitions. In one group the birds received 0.1ml of faecal culture broth. In the second group the birds were provided with feed containing the organic acid mixture and in the third group the birds were treated with 0.1ml of faecal broth culture together with in-feed organic acids. On the following day, an infected bird was placed inside each box containing six birds. This approach was carried out using as a challenge, Salmonella Typhimurium, S. Agona, S. Infantis , or S. Enteritidis. In a separate box, birds were inoculated with 0.1ml of Salmonella from an overnight broth culture diluted to contain approximately 105 colonies cfu/ml. The experimental design is present in Table 1.

Data of viable counts were transformed logarithmically (log 10) and subjected to analysis of variance. Media were compared statistically by t test (p < 0.05).

Bacteriological examination

Four and eight days post-treatment three birds from each box were killed for an estimation of the viable numbers of Salmonella in the caecal contents. This was done by an adaptation of the method of Barrow et al. (3) using Brilliant Green agar containing sodium nalidixate (100 ug/ml) and spectinomycin (100 ug/ml).

RESULTS

Table 2 presents the results of the evaluation of the faecal culture either alone or associated with treatment with a mixture of organic acids in newly born birds challenged with Salmonella Typhimurium, S. Agona, S. Infantis, S. Enteritidis.

The contents of Table 2 show that the competitive exclusion treatment alone or associated with in-feed organic acids was able to completely prevent intestinal colonization by Salmonella. The use of organic acids did not interfere with the effectiveness of the CE but alone was not able to prevent the caecal colonization by all Salmonella serotypes.

DISCUSSION

There is a great deal of current concern about avian salmonellosis with regard to avian disease and particularly to food-poisoning salmonellae. The control of paratyphoid salmonellae in birds is a difficult task. Newly hatched chicks are highly susceptible to infection with Salmonella organisms. Infection at this time may follow hatchery infection. Infected young birds excrete Salmonella in the faeces in greater number and for longer than do chickens infected when they are older (4, 24, 32). This increase in resistance is explained by the gradual acquisition by the chickens of the microorganisms that constitute its normal intestinal microflora (1, 7, 26, 30). Attempts to increase the resistance of the newly hatched chick to a level observed in the older chicken have centred on the administration of cultures or suspensions of caecal contents or faeces obtained from healthy adult chickens.

The competitive exclusion system first proposed by Nurmi and Rantala (25) has been used and studied extensively over many years (22). Despite the fact that previous authors (11, 21) have suggested the necessity of anaerobic incubation this methodology does not fit in with the finding that CE mixtures may be administered to birds either by spray or in drinking water (22) or that broth cultures incubated aerobically may also be successfully (27). Static broth cultures would anyway develop very low oxygen tensions after facultative anaerobic bacteria reach stationary phase and there seems no reason why such cultures should be effective. The observation of an effect against S. Infantis, has been noted previously (25, 34). The present and previous findings are important because the outbreaks of food-poisoning salmonellae originating from hatchery derived birds acquire their infection by vertical transmission (19) and Salmonella organisms may spread very easily among birds in the first few days after hatch (10).

The addition of organic acids into the feeds is used to varying degrees to control Salmonella in the feed (2, 17, 37). In the present study the incorporation of organic acid into the feed did not prevent the infection of birds placed in contact with an experimentally infected bird. Humphrey and Lanning (17) had partial success working with adult birds, but they were unable to prevent the vertical transmission. In contrast, Berchieri Jr. and Barrow (5) observed a good reduction in the mortality by Salmonella Gallinarum again, it was thought, by affecting the rate of infection between infected and uninfected birds. These data show that the results may depend upon the Salmonella serotype used as a challenge organism. The approach including organic acid mixture into the feed was carried out to assess its interference on the CE action. It was concluded that the organic acid mixture did not interfere with the CE action. The choice of the acids, the concentration and the method of administration in this research were based on previously published work (5, 14, 16, 17, 18, 20).

The presented results using the combination of organic acids in the ration and faecal culture are in agreement with Hinton et al. (15) who showed that this combination was effective.

In conclusion an aerobically cultured CE preparation is able to prevent intestinal colonization by Salmonella Typhimurium, Salmonella Infantis, Salmonella Agona, Salmonella Enteritidis in birds infected by contact, and organic acids incorporated in the feed do not interfere with the CE method.

ACKNOWLEDGEMENTS

The authors gratefully acknowledge the technical assistance of Antonio José dos Santos and Aparecida Rodrigues Batista and to FAPESP, CNPq and FUNDUNESP for financial support.

RESUMO

Controle da transmissão de Salmonella por contato entre aves de exploração comercial pelo uso de flora intestinal de aves adultas e/ou uma mistura de ácidos orgânicos

O presente trabalho avaliou a prevenção da disseminação de quatro sorotipos de Salmonella, de interesse em avicultura e saúde pública (Salmonella Typhimurium, Salmonella Agona, Salmonella Infantis e Salmonella Enteritidis), entre aves recém-nascidas, com o intuito de diminuir a disseminação de salmonelas em rebanhos avícolas por aves que contraíram a infecção pela via vertical. Analisou-se experimentalmente a administração de microbiota intestinal de aves adultas em aves recém-nascidas, a incorporação de uma mistura de ácidos orgânicos na ração e a associação desses dois tratamentos, em grupos onde colocou-se uma ave infectada, para provocar a transmissão por contato. A microbiota intestinal de aves adultas mostrou-se eficiente no controle da colonização cecal nos quatro ensaios realizados, com os diferentes sorotipos. A mistura de ácidos orgânicos na ração não foi eficaz em prevenir a colonização cecal e a associação dos tratamentos demonstrou que não há interferência entre eles, permanecendo a ação da microbiota de aves adultas.

Palavras-chave:Salmonella, exclusão competitiva, ácidos orgânicos, infecção por contato, aves comerciais

20. McHan, F.; Shotts, E.B. Effect of feeding selected short-chain fatty acids on the in vivo attachment of Salmonella typhimurium in chick ceca. Avian Dis., 36:139-142, 1992.

21. McHAN, F; Cox, N.A.; Bailey J.S.; Blankenship, L.C.; Stern, N.J. The influence of physical and environmental variables on the in vitro attachment of Salmonella typhimurium to the ceca of chickens. Avian Dis. 32:215-219, 1988.

22. Mead, G.C.; Impey, C.S.. The present status of the Nurmi concept for reducing carriage of food-poisaning Salmonellae and other pathogens in live poultry. In: Smaldres, F.J.M. Elimination of Pathogenic Organisms from Meat and Poultry. Elsevier, Amsterdam., 1987, p.55-77.

23. Miles, R..D. Manipulation of the microflora of the gastrointesitnal tract: natural ways to prevent colonization by pathogens. Proceedings of the Altech Biotechnology in the Feed Industry, Florida, 1993, p.135-150.

24. Milner, K.C.; Shaffer, M..F. Bacteriologic studies of experimental Salmonella infections in hicks. J. Infect. Dis., 90:81-96, 1952.

25. Nurmi, E.; Rantala, M.. New aspects of Salmonella infection in broiler production. Nature, London, 241:210-201, 1973.

26. Ochi, Y.; Mitsuoka, T.; Sega T. Untersuchungen über die Darmflora des Huhnes III. Mitteilung: die Entwicklung der Darmflora von küken bis zum Huhn. Zentrablat Bakteriologie Mikrobiologie und Hygiene I Abt Originale, 193:80-95, 1964.

27. Rambousek, M.J.; Iba, A.M..; Stachissini, A.V.M.; Berchieri Jr, A. The effect of carbohidrate administration on experimental infection with Salmonella serotypes in chickens. Rev. Microbiol, 26:32-36, 1995.

28. Rodrigue, D.C.; Tauxe., R..V.; Rowe, B. International increase in Salmonella enteritidis: a new pandemic? Epidemiol. Infect., 105:21-27, 1990.

  • 1. Barnes, E.M.; Mead, G.C.; Barnum, D.A.; Harry, E.H.. The intestinal flora of the chicken in the period 2 to 6 weeks of age, with particular reference to the anaerobic bacteria. British Poultry Sci, 13:311-326, 1972.
  • 2. Barrow, P.A.. Recent progress in the diagnosis and control of Salmonella infections in poultry. Comprehensive reports on technical items presented to the International Committee or to Regional Commissions. Office international des epizooties, Paris, 1995, p. 13-22.
  • 3. Barrow, P.A.; Tucker, J.F.; Simpson, J.M. Inhibition of colonisation of the chicken alimentary tract with Salmonella typhimurium gram-negative facultatively anaerobic bacteria. Epidemiol. Infect, 98:311-322, 1987
  • 4. Barrow, P.A; Simpson, J.M;. Lovell, M.A.. Intestinal colonization in the chicken by food poisoning Salmonella sorotypes; microbial characteristics associated with faecal excretion. Avian Pathol, 17:571-588, 1988.
  • 5. Berchieri Jr., A.; Barrow, P.A. Reduction in incidence of experimental fowl typhoid by incorporation of a commercial formic acid preparation into poultry feed. Poultry Sci, 75:339-441, 1996.
  • 6. Berchieri Jr, A.; Barrow, P.A.; Murphy, C.K.. Vertical transmission of Salmonella Gallinarum, Salmonella pullorum and Salmonella enteritidis in commercial brow-egg layers. Proceedings of Salmonella and Salmonellosis, Ploufragan, 1997, p.293-294.
  • 7. Coloe, P.J.; Bagust, J.J.; Ireland, L. Development of the normal gastrointestinal microflora of specific pathogen-free chicken. J. Hyg, 92:79-87, 1984.
  • 8. Davies, R.H.; Wray, C.. Contribution of the lesser mealworm beetle (Alphitobius diaperinus) to carriage of Salmonella enteritidis in poultry. Vet. Rec., 137:407-408, 1995.
  • 9. Gardner, P. Antibiotics in animal feeds: the need for better epidemiologic studies. J. Infect. Dis., 138:101-104, 1978.
  • 10. Gast, R.K.. Paratyphoid infections. In: Calnek, B.W.; Barnes, H.J; Beard, C.W.; Reid, W.M.; Yoder , H.W. Diseases of Poultry. Iowa State University Press, Ames, IA, 1997, p.81-121.
  • 11. Glesson, T.M.; Stavric, S.; Blanchfield, B. Protection of chicks against Salmonella infection with a mixture of pure cultures of intestinal bacteria. Avian Dis, 33:636-642, 1989.
  • 12. Goren, E.; de Jong, W.A.; Doornenbal, P.; Koopman, J.P.; Kennis, H.M.. Protection of chicks against Salmonella infection induced by spray application of intestinal microflora in the hatchery. Vet. Quartely, 6:73-79, 1984.
  • 13. Guillot, J.F.; Chaslus-Dancla, E.; Lafont, J.P. Spontaneous implantation of antibiotic-resistant Enterobactereaceae in the digestive tract of chickens in the absence of selective pressure. Antimicrobial Agents Chemotherapy, 12:697-702, 1977.
  • 14. Hinton, M.H.; Linton, A.H. Control of Salmonella infections in broiler chickens by the acid treatment of their feed. Vet. Rec, 123:416-421, 1988.
  • 15. Hinton, M.; Mead, G.C.; Impey, C.S.. Protection of chicks against environmental challenge with Salmonella enteritidis by competitive exclusion and acid treated feed. Letters Appl. Microbiol, 12:69-71, 1991.
  • 16. Hume, M.E; Corrier, D.E.; Ivie, G.W.; Deloach, J.R... Metabolism of [14C] propionic acid in broiler chicks. Poultry Sci, 72:786-793, 1993.
  • 17. Humphrey, T.J.; Lanning, D.J. The vertical transmission of salmonellas and formic acid treatment of chickens feed. A possible strategy for control. Epidemiol. Infect, 100:43-49, 1988.
  • 18. Izat, A.L.; Adams, M..H.; Cabel, M.C.; Colberg, M..; Reiber M.A; Skinner, J.T.; Waldrup, P.W. Effects of formic acid or calcium formate in feed performance and microbiological characteristics of broilers. Poultry Sci, 69:1876-1882, 1990.
  • 19. Lister, S.A. Salmonella enteritidis infection in broilers and broiler breeders. Vet. Rec. 123:350, 1988.
  • 20. McHan, F.; Shotts, E.B. Effect of feeding selected short-chain fatty acids on the in vivo attachment of Salmonella typhimurium in chick ceca. Avian Dis, 36:139-142, 1992.
  • 21. McHAN, F; Cox, N.A.; Bailey J.S.; Blankenship, L.C.; Stern, N.J. The influence of physical and environmental variables on the in vitro attachment of Salmonella typhimurium to the ceca of chickens. Avian Dis 32:215-219, 1988.
  • 22. Mead, G.C.; Impey, C.S.. The present status of the Nurmi concept for reducing carriage of food-poisaning Salmonellae and other pathogens in live poultry. In: Smaldres, F.J.M. Elimination of Pathogenic Organisms from Meat and Poultry. Elsevier, Amsterdam., 1987, p.55-77.
  • 23. Miles, R..D. Manipulation of the microflora of the gastrointesitnal tract: natural ways to prevent colonization by pathogens. Proceedings of the Altech Biotechnology in the Feed Industry, Florida, 1993, p.135-150.
  • 24. Milner, K.C.; Shaffer, M..F. Bacteriologic studies of experimental Salmonella infections in hicks. J. Infect. Dis., 90:81-96, 1952.
  • 25. Nurmi, E.; Rantala, M.. New aspects of Salmonella infection in broiler production. Nature, London, 241:210-201, 1973.
  • 26. Ochi, Y.; Mitsuoka, T.; Sega T. Untersuchungen über die Darmflora des Huhnes III. Mitteilung: die Entwicklung der Darmflora von küken bis zum Huhn. Zentrablat Bakteriologie Mikrobiologie und Hygiene I Abt Originale, 193:80-95, 1964.
  • 27. Rambousek, M.J.; Iba, A.M..; Stachissini, A.V.M.; Berchieri Jr, A. The effect of carbohidrate administration on experimental infection with Salmonella serotypes in chickens. Rev. Microbiol, 26:32-36, 1995.
  • 29. Roulfe, R.D.. Population dynamics of the intestinal tract.. International Symposium on Colonization Control of Human Enteropathogens in Poultry, Athens, 1991, p. 59-76.
  • 30. Smith, H.W. The development of the flora of the alimentary tract in young animals. J. Pathol. Bacteriol, 90:495-513, 1965.
  • 31. Smith, H.W.; Tucker, J.F. The effect of antibiotic therapy on the fecal excretion of Salmonella typhimurium by experimentally infected chickens. J. Hyg, 75:275-292, 1975.
  • 32. Smith, H.W.; Tucker, J.F. The virulence of Salmonella strains for chickens: their excretion by infected chickens. J. Hyg., 84:479-488, 1980.
  • 33. Snoeyenbos, G.H.; Weinack, O.M.; Smyser, C.F. Protecting chicks and poultry from salmonellae by oral administration of "normal" gut microflora. Avian Dis., 22:273-287, 1978.
  • 34. Snoeyenbos, G.H.; Weinack, O.M; Soerjadi-Liem, A.S.; Miller, B.M.; Woodward, D.E.; Weston, C.R.. Large-scale trials to study competitive exclusion of Salmonella in chickens. Avian Dis,. 29:1004-1011, 1985.
  • 35. Tauxe, R.V. Foreword: Transmission of human bacterial pathogens through poultry (Banquet address). In: Blankenship, L.C. Colonization control of human bacterial enteropathogens in poultry. Academic Press, San Diego, 1991, p.15-23.
  • 36. Tavechio, A.T.; Fernandes, S.A.; Neves, B.C.; Dias, A.M.G.; Irino, K. Changing patterns of Salmonella serovars: increase of Salmonella enteritidis in Săo Paulo, Brazil. Rev. Inst. Med. Trop., 38:315-322, 1996.
  • 37. Thompson, J.L.; Hinton, M. Antibacterial activity of formic and propionic acids in the diet of hens on salmonellas in the crop. British Poultry Sci, 38:59-65, 1997.
  • *
    Corresponding author. Mailing address: Faculdade de Ciências Agrárias e Veterinárias da UNESP, Via de Acesso Paulo Donato Castellane, S/N, CEP 14870-000, Jaboticabal, SP, Brasil. Telefax (+5516) 3224275. E-mail
  • Publication Dates

    • Publication in this collection
      04 Oct 2000
    • Date of issue
      June 2000

    History

    • Received
      03 Nov 1999
    • Reviewed
      06 Apr 2000
    • Accepted
      09 June 2000
    Sociedade Brasileira de Microbiologia USP - ICB III - Dep. de Microbiologia, Sociedade Brasileira de Microbiologia, Av. Prof. Lineu Prestes, 2415, Cidade Universitária, 05508-900 São Paulo, SP - Brasil, Ramal USP 7979, Tel. / Fax: (55 11) 3813-9647 ou 3037-7095 - São Paulo - SP - Brazil
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