Phytobiotic Activity of Piper Auritum and Ocimum Basilicum on Avian E. Coli

Aguilar-Urquizo, E; Itza-Ortiz, MF; Sangines-Garcia, JR; Pineiro-Vázquez, AT; Reyes-Ramirez, A; Pinacho-Santana, B

doi:10.1590/1806-9061-2019-1167

ABSTRACT

Natural antimicrobials, known as phytobiotics, are used in bacterial infections. The objective of this study was to evaluatethe phytobiotic activity, in vitro and in vivo, of an extract and an essential oil of Piper auritum and Ocimum basilicum on avian Eschericia coli serotype O2 in broiler chickens experimentally infected. For the in vitro test, extracts at 4, 8, 12 and 16% in water-based solvent or alcohol at 70% were prepared from leaves of both plants. In the essential oils, solvents at 10% were used. A concentration of 1×10⁸ CFU mL^-1 of bacteria was seeded and on each sense disc, 25 µL of the extract or essential oil were poured, except on the positive or negative control. The diameter of the inhibition zone (DIZ) of bacterial growth was measured. In the in vivo test, 40 chickens were inoculated, by intratracheal route, with a bacterial suspension of 1 × 10⁸ CFU mL^-1. E. col was identified and isolated from the organs; mortality, morbidity and relative weight of the organs were measured, and postmortem lesions and histopathologic findings were observed. A completely randomized design and the Kruskal-Wallis test for data analysis was used. By increasing the concentration of the extract, DIZ was greater; at the time of slaughter, differences in body weight (p<0.05) were found and the majority of lesions were observed in lungs. It is concluded that leave extracts of P. auritum and O. basilicum had phytobiotic activity on E. col serotype O2.

Keywords:
Colibacillosis; phytobiotic; Piper auritum; Ocimum basilicum

INTRODUCTION

It is calculated that about 100,000 plants produce secondary metabolites (Dixon, 2004Dixon RA. Phytoestrogens. Annual Review of Plant Biology 2004;55:225-261.) and the biological activity of some of them is well known (Gurib-Fakim, 2006Gurib-Fakim A. Medicinal plants: traditions of yesterday and drugs of tomorrow. Molecular Aspects of Medicine 2006;27(1):1-93.). These plants are used without restriction, in dose or age of the animal, in the form of extracts or essential oils, as an alternative to growth promotive antimicrobials (AGP), due to their capacity to elevate digestive enzyme activity (Adebolu & Abiola, 2005Adebolu TT, Abiola SO. Antimicrobial activity of leaf extracts of Ocimum gratissimum on selected diarrhoea causing bacteria in southwestern Nigeria. African Journal of Biotechnology 2005;4(7):682-684.), nutrient absorption, increase in food intake (Chávez et al., 2015Chávez L, López A, Parra JE. La inclusión de cepas probióticas mejora los parámetros inmunológicos en pollos de engorde. Revista CES Medicina Veterinaria y Zootecnia 2015;10(2):160-169.), reduction in undesirable bacterial population (Acosta et al., 2003Acosta M, González M, Araque M, Velazco E, Khouri N, Rojas L, et al. Composición química de los aceites esenciales de Ocimum basilicum L. var basilicum, O. basilicum L. var purpurenscens, O. ratissimum L., y O. tenuiflorum L., y su efecto antimicrobiano sobre bacterias multirresistentes de origen nosocomial. Revista de la Facultad de Farmacia 2003;45(1):19-24.), decreased intestinal activity associated with lymphatic system and increased precaecal digestion of nutrients; generally reflecting greater intestinal flora balance (Witte, 2000Witte W. Antimicrobial therapy in a Historical perspective. Acta Veterinaria Scandinavica 2000;93:7-16.; Windisch et al., 2008Windisch W, Schedle K, Plitzner C, Kroismayr A. Use of phytogenic products as feed additives for swine and poultry. Journal of Animal Science 2008;86:E140-E148.).

Some plants or part of them contain natural antimicrobials that are known as phytobiotics, these types of antimicrobials are considered as potentially safe sources (Griggs & Jacob, 2005Griggs PJ, Jacob PJ. Alternatives to antibiotics for organic poultry production. Journal Applied Poultry Research 2005;14:750-756.; Rodríguez, 2011Rodríguez SEN. Uso de agentes antimicrobianos naturales en la conservación de frutas y hortalizas. Ra Ximhai 2011;7(1):153-170.). This activity has been associated with secondary metabolites, such as: carvacrol, thymol, eugenol, safrole, perillaldehyde, cinnamaldehyde, α terpineol, linalool and cinnamic acid (Lataoui & Tantaoui-Elaraki, 1994; Consentino et al., 1999; Burt, 2004Burt S. Essential oils: their antibacterial properties and potential applications in foods-a review. International Journal of Food Microbiology 2004;94:223-253.; Burt et al., 2005). Other reported components are borneol, γ-terpinene and p cymene that have a synergic or antagonic activity (Consentino et al., 1999; Vardar-Ünlü et al., 2003Vardar-Ünlü G, Candan F, Sökmen A, Daferera D, Polissiou M, Sökmen M, et al. Antimicrobial and antioxidant activity of the essential oil and methanol extracts of thymus pectinatus fisch. et mey. var. pectinatus (Lamiaceae). Jorunal Agriculture Food Chemistry 2003;51(1):63-67.).

Escherichia coli is a normal habitant of the intestine of birds and can remain for a long time in poultry farms (Cortes, 2008Cortes RC. Escherichia coli: generalidades. México: Facultad de Medicina Veterinaria y Zootecnia, UNAM; 2008.; García-Compean et al., 2011García-Compean L, Itza-Ortiz M, Ramón Ugalde JP, Sangines-García JR, Ortiz de la Rosa B, Zamora-Bustillos R, et al. Escherichia coli vaccine and laying hens mortality after a heat stress challenge in tropical climate. Journal of Animal and Veterinary Advance 2011;10(1):96-99.) without causing any adverse effect, since it generally responds to a secondary infection subsequent to a Mycoplasma sp first attack and particularly by the infectious bronchitis virus, which is a predisposing factor of colibacillosis (Cook et al., 1991Cook JA, Huggins MB, Ellis MM. Use of an infectious bronchitis virus and Escherichia coli model infection to assess the ability to vaccinate successfully against infectious bronchitis in the presence of maternally-derived immunity. Avian Pathology 1991;20:619-626.; Nakamura et al., 1999) or even micro environmental due to high concentrations of ammoniac, CO₂ or dust; the latter damages the cilia of the respiratory tract, causing colibacillosis, the main cause of condemned carcasses and considered as potential public health problem (Dozois et al., 2000Dozois CM, Dho-Moulin M, Brée A, Fairbrother JM, Desautels C, Curtiss III R. Relationship between the Tsh autotransporter and pathogenicity of avian Eschericha coli and localization and analysis of the Tsh genetic region. Infection and Immunity 2000;68:4145-4154.; Mellata et al., 2003Mellata M, Dho-Moulin M, Dozois CM, Curtiss III R, Lehoux B, Fairbrother JM. Role of avian pathogenic Eschericha coli virulence factors in bacterial interaction with chicken heterophils and macrofages. Infection and immunity 2003;71:494-503.; García-Compean et al., 2011).

Among E. coli properties there is the belonging of specific serotypes such as: 01:K1, 02:K1, 35 and O78:K80 (Dho-Moulin & Fairbrother, 1999Dho-Moulin M, Fairbrother JM. Avian pathogenic Escherichia coli (APEC). Veterinary Research 1999;30(2-3):299-316.; Ewers et al., 2003Ewers C, Janssen T, Wieler LH. Avian pathogenic Escherichia coli (APEC). Berlin Munch Tierarztl Wochenschr 2003;116(9-10):381-95.) being serogroups O2 and O78 responsible for 80% of the infections caused by colibacillosis in the field (Dho-Moulin & Fairbrother, 1999; Horne et al., 2000Horne SM, Pfaff-McDonough SJ, Giddings CW, Nolan LK. Cloning and sequencing of the iss gene from a virulent avian Escherichia coli. Avian Diseases 2000;44:179-184.; Ewers et al., 2003; Blanc et al., 2007Blanc V, Cortés P, Mesa R, Miro E, Navarro F, Llagostera M. Characterization of plasmids encoding extended-spectrum -lactamase and CMY-2 in Escherichia coli isolated from animal farms. International Journal of Antimicrobial Agents 2007;31(1):76-78.). Up to date, bacterial resistance to antimicrobials is already known, due to its uncontrolled use (Kalra, 1998Kalra YP. Handbook of reference methods for plant analysis. Boca Raton: CRC Press; 1998.; Kalemba & Kunicka, 2003Kalemba D, Kunicka A. Antibacterial and antifungal properties of essential oils. Bentham Science Publishers 2003;10(10):813-829.).

The genus Piper contains approximately 1500 species, with nearly 1000 species in tropical America. It has been widely studied for being an important source of bioactive components, with antimicrobial properties for human, plants and animals (Dorman & Deans, 2000Dorman HJD, Deans SG. Antimicrobial agents from plants: antibacterial activity of plant volatile oils. Journal of Applied Microbiology 2000;88:308-316.; Kato & Furlan, 2007Kato MJ, Furlan M. Chemistry and evolution of Piperaceae. Pure Applied Chemistry 2007;79:529-538.; Regasini et al., 2009Regasini LO, Cotinguiba F, De-Araújo AM, Jorge KM, Scorzoni L, Mendes-Giannini MJ, et al. Antimicrobial activity of Piper arboreum and Piper tuberculatum (Piperaceae) against opportunistic yeasts. African Journal of Biotechnology 2009;8(12):2866-2870.; Monzote et al., 2010Monzote L, García M, Montalvo AM, Scull R, Miranda M. Chemistry, cytotoxicity and antileishmanial activity of the essential oil from Piper auritum. Memory Institute Oswaldo Cruz 2010;105(2):168-173.).

Piper auritum belongs to Piperaceae family. It is native to Mexico and is widely distributed in tropical America (Roig, 1988Roig JT. Plantas medicinales aromáticas o venenosas de Cuba. 5th ed. La Habana: Editorial Científico-Técnica; 1988.). Valsara (1994Valsara T. Screening of indian medicinal plants for antimicrobial activity. Journal Ethnobiology 1994;35(3):275-283.) and Oudhia (2003Oudhia P. Traditional medicinal uses in India. Journal of Planta Medical 2003;5(5):175-179.) demonstrated that this plant has antiseptic, antifungic and antioxidant effect, the latter is very near to the reported for α-tocopherol (Ramya et al., 2010Ramya DK, Karthikumar S, Jegatheesan K. Isolation of potential antibacterial and antioxidant compounds from Acalypha indica and Ocimum basilicum. African Journal of Plant Science 2010;4(5):163-166.). The chemical analysis of the essential oil of Piper auritum reveals that safrole is its main component, occupying about 70 to 90% (Gupta et al., 1985Gupta MP, Arias DT, Williams NH, Bos R, Tattje DHE. Safrole, the main component of the essential oil from Piper auritum of Panama. Journal of Natural Products 1985;48(2):330-343.; García et al., 2007García RA, Leyva MA, Martínez MJR, Staschenko EE. Determinación de la composición química y actividad antioxidante in vitro del aceite esencial de Piper auritum Kunth (Piperacea) difundida en la Costa Colombiana. Scientia et Technica 2007;13(033):439-442.; Sánchez et al., 2009Sánchez Y, Pino O, Correa TM, Iglesia A, Naranjo E. Estudio químico y microbiológico del aceite esencial de Piper auritum Kunth (caisimón de anís). Revista de Protección Vegetal 2009;24(1):230-238.). Besides safrole, the essential oil of Piper auritum contains about 40 substances in lower amount, such as: thymol, carvacrol, myristicin, linalool, borneol, camphor, cineol, methyl eugenol and a wide variety of benzene components (Domínguez et al., 1962Domínguez XA, Rojas P, Carza MD, Córdova JA. Preliminary study of 20 plants from the central territory of Quintana Roo, México. Revista Química Mexicana 1962;6:213-215.; Oliveira et al., 2004Oliveira LHW, Ehringhausm Ch, Yoshio PK. Genetic diversity of Pimenta longa genotypes (Piper spp., Piperaceae) of the Embrapa Acre germplasm collection. Genetics and Molecular Biology 2004;27(1):74-82.).

The genus Ocimum L. is formed by about 30 species, 16 of which are native to Africa. Its distribution area goes from tropics to subtropics of America and Europe (Mahabir, 1995Mahabir G. 270 plantas medicinales iberoamericanas. Santa Fe de Bogotá: Editorial Presencia; 1995.). It has antimicrobial and spasmolytic properties (Acosta et al., 2003Acosta M, González M, Araque M, Velazco E, Khouri N, Rojas L, et al. Composición química de los aceites esenciales de Ocimum basilicum L. var basilicum, O. basilicum L. var purpurenscens, O. ratissimum L., y O. tenuiflorum L., y su efecto antimicrobiano sobre bacterias multirresistentes de origen nosocomial. Revista de la Facultad de Farmacia 2003;45(1):19-24.; Ramya et al., 2010Ramya DK, Karthikumar S, Jegatheesan K. Isolation of potential antibacterial and antioxidant compounds from Acalypha indica and Ocimum basilicum. African Journal of Plant Science 2010;4(5):163-166.). The reported active components of O. basilicum, basilicum variety are: linalool (54.28 %), 4- allylanisole (26.50%), eugenol (9.54%), 1.8 cineol (4.21%) and for purpurascens variety are: E-methyl cinnamate (55.95%), linalool (21.30%), Z-methyl cinnamate (16.85%) and 1.8 cineol (1.44%), besides having phenolic acids derived from cinnamate acid and flavonoids (Acosta et al., 2003). Roldán et al. (2010Roldán LP, Díaz GJ, Duringer JM. Composition and antibacterial activity of essential oils obtained from plants of the Lamiaceae family against pathogenic and beneficial bacteria. Revista Colombiana de Ciencias Pecuarias 2010;23:451-461.) indicate that the largest components of O. basilicum are: β-linalool (46.67%) and estragole (27.43%).

The objective of this study was to evaluate the phytobiotic activity of the extract and essential oil of Piper auritum and Ocimum basilicum, first in vitro determining the diameter of the inhibition zone of bacterial growth and in vivo, in the productive performance, bacterial growth, relative weight of organs and histopathologic findings in broiler chickens experimentally infected with avian Escherichia coli serotype O2.

MATERIAL AND METHODS

Collection of samples and storage.

The leaves of Piper auritum and Ocimum basilicum were recollected in the Unidad de Producción e Investigación Agrícola y Pecuaria of the Instituto Tecnológico de Conkal. The leaves were dried in a forced air oven at 60°C for 24 hours; subsequently, they were milled in order to obtain flour from the leaves using a sieve size of 1 mM thickness. The experiment consisted of two tests, the first was in vitro and the second in vivo.

In vitro test

Preparation of aqueous extract

Four, eight, twelve and sixteen grams of flour from leaves of each plant were weighed, submerged in 100 mL of boiling distilled water and underwent decoction for 15 minutes, and then was filtered using a cloth of linen (López-Casamayor, 2007López-Casamayor EJ. Estudio fitoquímico y aproximación genética en especies de la sección Plinthine del Género Arenaria (Cariophyllaceae). Granada: Universidad de Granada; 2007.). Once the extract was cooled it was filtered again using Whatman paper number 2 (López-Casamayor, 2007).

Preparation of alcoholic extract

Four, eight, twelve and sixteen grams of flour from the leaves of each plant were weighed and submerged in 100 mL of alcohol at 70%. The solutions were agitated using a hot plate stirrer (IKA, C-MAG-HS7, North Carolina, USA) for 15 minutes and allowed to sit for 48 hours at room temperature. Extracts were first filtered using a cloth of linen (López-Casamayor, 2007López-Casamayor EJ. Estudio fitoquímico y aproximación genética en especies de la sección Plinthine del Género Arenaria (Cariophyllaceae). Granada: Universidad de Granada; 2007.), followed by centrifugation at 7000 rpm for 10 minutes using a centrifuge (Beckman TJ-6, Illinois, USA); the supernatant was filtered using a Whatman paper number 2 (Mamoru et al., 1996Mamoru K, Mujo K, Takehiko Y. Antifungal activity against food-borne fungi of Aspidistra elatior Blume. Journal of Agriculture and Food Chemistry 1996;44(1):301-303.; Tequida-Meneses et al., 2002Tequida-Meneses M, Cortez-Rocha M, Rosas-Burgos EC, López-Sandoval S, Corrales-Maldonado C. Efecto de extractos alcohólicos de plantas silvestres sobre la inhibición de crecimiento de Aspergillus flavus, Aspergillus niger, Penicillium chrysogenum, Penicillium expansum, Fusarium moniliforme y Fusarium poae. Revista Iberoamericana de Micología 2002;19:84-88.). Both extracts were poured into amber glass bottles and stored in the refrigerator. At the time of use they were sterilized by filtration using Millipore membrane of 0.8 to 0.2 µM (López- Casamayor, 2007).

Obtaining essential oils

Forty grams of flour from the leaves of each plant were weighed, submerged in 200 mL of distilled water or 200 mL of alcohol at 70% and allowed to sit for 48 hours at room temperature. Both solutions were subjected to steam stripping using a rotavapor (Büchi, R-114, Switzerland), at a temperature of 70°C and at 40 rpm (Sánchez-Castellanos, 2006Sánchez-Castellanos FJ. Extracción de aceites esenciales. Experiencia Colombiana. Annales do 2º Congreso Internacional de Plantas Medicinales y Aromáticas; 2006 Oct 19-21; Vale del Cauca: Universidad Nacional de Colombia Sede Palmira; 2006.). Oils obtained were poured into amber glass bottles and stored in the refrigeration at 4°C until further usage (Sánchez-Castellanos, 2006).

Inoculation of Petri dishes

Petri dishes with eosin methylene blue agar were inoculated with 1× 10⁸ CFU mL^-1 of E. coli serotype O2 in the four directions using a swab. The correct density of the inoculum was performed using the method described by Sánchez et al. (2009Sánchez Y, Pino O, Correa TM, Iglesia A, Naranjo E. Estudio químico y microbiológico del aceite esencial de Piper auritum Kunth (caisimón de anís). Revista de Protección Vegetal 2009;24(1):230-238.). The Sensi-Discs had a diameter of 6 mM and were made with Whatman paper number 2 and were distributed on the agar at no less than 22 mM from each other and 14 mM from the border of the Petri dish. Negative controls of distilled water and alcohol at 70% were used for the extracts; petroleum ether was used in the essential oils. Positive controls were also used for essential extracts and oils, which consisted of commercial Sensi-Discs (Whatman, Sigma-Aldrich, Mexico) loaded with Enrotrim at 10% (enrofloxacin and trimethoprim), Macromycin E (colistin sulphate, erythromycin thocyanate and ethylenediamine dehydroiodide) and Doxy20 (doxycycline at 20%). On each Sensi-Disc, 25 µL of extract (aqueous or alcohol at 70%) or essential oil were poured, except on negative or positive control. The inoculated Petri dishes were incubated at 35°C for 18 hours for subsequent measurement.

Phytobiotic activity measurement

Agar diffusion method, described by Kirby-Bauer (Bauer et al., 1966Bauer A, Kirby WMM, Sherris JC, Turck M. Antibiotic susceptibility testing by a standardized single disk method. American Journal of Clinical Pathology 1966;45:493-496.), was used for measuring antimicrobial activity by presence or absence of the diameter in the inhibition zone (DIZ) of bacterial growth. The diameters were measured on the back of the Petri dish, placed against a brilliant light, using a millimeter rule in angles of 120°. The average of three measures was reported (Koneman et al., 1991Koneman EW, Allen SD, Dowell VR, Sommers HM. Diagnóstico microbiológico. Ciudad de México: Editorial Médica Panamericana; 1991.).

In vivo test

Preparation of the strain

E. coli strain was cultured on eosin methylene blue agar at 37°C for 24 hours. The obtained culture was centrifuged at 3,400×g for 15 minutes; subsequently, it was washed and resuspended in PBS (pH 7.4). Bacterial concentration was measured by spectrophotometer at 660 mM and an absorbance of 0.8, using a plate reader (Thermo Scientific, Multiskan GO, Germany).

Ethical Considerations of the Study

The management and care of the chickens were in accordance with Animal Research Ethics and following guidelines approved in official techniques of animal care and health in Mexico (Ley Federal de Sanidad Animal; articles 19 to 22), NOM-033-ZOO-1995: Humanitarian slaughter of domestic and wild animals, and the international guiding principles for biomedical research involving animals by the Council for International Organizations of Medical Sciences (CIOMS).

Experimental animals

A total of 50 Ross 308 male chickens, 35 days old, without vaccines, coming from a clean and safe zone, were distributed in five treatments with ten replicates each one (Table 1). Each treatment was located in 5 experimental pens of approximately 1.95 m², each equipped with a gallon type waterer (JAT, Jalisco, México). The negative control group was located in a distant pen and isolated from the experimental shed equipped with sanitary rugs to avoid cross-contamination.

Thumbnail

Table 1
Distribution of chickens inoculated with avian E. coli serotype O2 and treated with extracts of leaves with phytobiotic properties.

Chicken inoculation

After a period of adaptation of seven days in the experimental pens, chickens were inoculated with 0.5 mL of a bacterial suspension of 1×10⁸ CFU mL^-1 of E. coli serotype O2 by intratracheal route, using 1 mL syringe (Kwaga et al., 1994Kwaga JKP, Allan BJ, Van Den Hurk JV, Seida H, Potter AA. A carAB mutant of avian pathogenic Escherichia coli serogroup 02 is attenuated and effective as a live oral vaccine against colibacillosis in turkey. Infection and Immunity 1994;62(9):3766-3772.; Yunis et al., 2002Yunis R, Ben-David A, Heller ED, Cahaner A. Antibody responses and morbidity following infection with infectious bronchitis virus and challenge with Escherichia coli, in lines divergently selected on antibody response. Poultry Science 2002;81:149-159; Rawiwet & Chansiripornchai, 2009Rawiwet V, Chansiripornchai N. The efficacy of Escherichia coli AroA-Live vaccine in broilers against avian E. coli serotype O78 infection. Thai Journal of Veterinary Medicine 2009;39(4):337-342.).

Extract administration

Thirty mL of aqueous extract was orally administered to each chicken 36 hours post inoculation, using a 1 mL syringe without needle (Plastipak, México); subsequently, it was administered every morning until 24 hours before being humanely slaughtered.

Evaluated variables

Chickens were fed a diet based on soybean-sorghum, free of antibiotics, fungicides and coccidiostats. Body weights were recorded at the beginning (36 days), at the moment of inoculation (42 days) and at the end of the trial (59 days). At the end of the trial, chickens were humanely slaughtered according to the Mexican Official Standard NOM 033-ZOO-1995. Immediately, bursa of Fabricious, liver, heart, kidney, lung, spleen and gastrointestinal track were weighed. Weights were recorded as relative percentage of body weight (Huff et al., 2006Huff WE, Huff GR, Rath NC, Donoghue AM. Evaluation of the influence of bacteriophage titer on the treatment of colibacillosis in broiler chickens. Poultry Science 2006;85:1373-1377.).

Mortality and morbidity were measured as: 1) mortality: for chickens who died during the first nine days postinoculation and showed postmortem lesions of colibacillosis; 2) morbidity: for chickens that survived inoculation until the trial ended and showed lesions of colibacillosis at necropsy (Rawiwet & Chansiripornchai, 2009Rawiwet V, Chansiripornchai N. The efficacy of Escherichia coli AroA-Live vaccine in broilers against avian E. coli serotype O78 infection. Thai Journal of Veterinary Medicine 2009;39(4):337-342.). The integrity of air sacs, lung, pericardium and liver was observed and histopathologic findings of only lung and liver were described (Kleven et al., 1972Kleven SH, King DD, Anderson DP. Airsacculitis in broilers from Mycoplasma synovie: effect on air-sac lesions of vaccinating with infectious bronchitis and Newcastle virus. Avian Disease 1972;16(4):915-924.; Charleston et al., 1998Charleston B, Gate JJ, Aitken IA, Stephan B, Froyman R. Comparison of the efficacies of three fluoroquinolone antimicrobial agents, given as continuous or pulsed-water medication, against Escherichia coli infection in chickens. Antimicrobial Agents and Chemotherapy 1998;42(1):83-87.).

Isolation, identification and quantification of E. coli

Samples (10 g) of lung, liver, heart and spleen were taken and ground according to the technique described by Willis et al. (2008Willis WL, Goktepe I, Isikhuemhen OS, Reed M, King K, Murray C. The effect of mushroom and pokeweed extract on Salmonella, egg production, and weight loss in molting hen. Poultry Science 2008;87:2451-2457.). The pool was diluted in serials (1:10) in 0.1% of saline solution. Subsequently, 100 µL of each dilution was placed on Agar McConkey and incubated at 37°C for 24 hours for its subsequent bacterial quantification as CFU g^-1 transformed to Log base 10 (Mitsche et al., 2004Mitsch P, Zitterl-Eglseer K, Kohler B, Gabler C, Losa R, Zimpernik I. The Effect of two different blends of essential oil components on the proliferation of Clostridium perfringens in the intestines of broiler chickens. Poultry Science 2004;83:669-675.; Willis et al., 2008).

Statistical analysis

A completely randomized design was used to analyze the variables of the diameter of the inhibition zone of bacterial growth of five treatments. One chicken was considered as experimental unit and the percentages of relative weights of the organs were analyzed using Kruskal-Wallis test, previous transformation of percentual data to square root of arc sine (Dughetti & De Carli, 1999Dughetti AC, De Carli DL. Utilización de distintos insecticidas y formulaciones en el control de Delia spp. en cebolla [informe técnico]. Provincia de Buenos Aires: Estación Experimental Agropecuaria INTA Hilario Ascasubi; 1999.). Only mortality was described. The differences between means were analyzed using Tukey test, considering significant an alpha of 0.05 (Mendahall, 1994). Data were analyzed using the statistical program SPSS v 15.0 for Windows.

RESULTS AND DISCUSSION

The aqueous extracts of P. auritum and O. basilicum had less bactericide effect than their alcoholic extracts at 4% levels. The aqueous extracts had a DIZ of 9.6 and 9.0 mM while, in the alcoholic extracts, DIZ were of 16.4 mM and 13.9 mM for P. auritum and O. basilicum, respectively (Table 2).

Thumbnail

Table 2
Diameters of the inhibition zone of bacterial growth (mM)¹ of avian E. coli serotype O2, challenged with extracts of leaves with phytobiotic properties.

The obtained results show that both plants inhibit E. coli growth; however, while using alcohol at 70% as solvent in the preparation of alcoholic extracts, DIZ increased due to high polarity of the alcohol that allows to obtain an extract whose chemical composition contains the greater part of the components of the plant, polar or not polar; allowing to obtain an extract with greater quantity of secondary metabolites with phytobiotic activity (Sharapin, 2000Sharapin N. Fundamentos de tecnología de productos fitoterapéuticos. Santa Fé de Bogotá: Quebecor-Impreandes; 2000.), compared to the low solubility of water before the hydrocarbon skeleton of some phytobiotic components found in aqueous extracts (Kalemba & Kunicka, 2003Kalemba D, Kunicka A. Antibacterial and antifungal properties of essential oils. Bentham Science Publishers 2003;10(10):813-829.). Authors such as Hernández et al. (2003), Adebolu & Abiola, (2005Adebolu TT, Abiola SO. Antimicrobial activity of leaf extracts of Ocimum gratissimum on selected diarrhoea causing bacteria in southwestern Nigeria. African Journal of Biotechnology 2005;4(7):682-684.) and Nwinyi-Obinna et al. (2009Nwinyi-Obinna C, Chinedu-Nwodo S, Ajani-Olayinka O, Ikpo-Chinwe O, Ogunniran-Kehinde O. Antibacterial effects of extracts of Ocimum gratissimum and Piper guineense on Escherichia coli and Staphylococcus aureus. African Journal of Food Science 2009;3(3):77-81.) report that the genera studied are potential source of components with phytobiotic properties, mainly against pathogenic bacteria such as E. coli, Salmonella typhimurium and Pseudomona aeruginosa.

The percentage of the extract is an important factor in phytobiotic activity in both plants, by increasing concentrations DIZ was greater, due to greater quantity of bioactive components. Burt et al. (2007Burt SA, Van der Zee R, Koets AP, Graaff AM, Van Knapen F, Gaastra W, et al. Carvacrol induces heat shock protein 60 and inhibits synthesis of flagellin in Escherichia coli O157:H7. Applied and Environmental Microbiology 2007;73(14):4484-4490.) report that E. coli O157:H7 bacterial cell decreased gradually by increasing the concentration of carvacrol and p-cymene in the culture medium; both essential oils inhibited the synthesis of flagella; therefore, no more flagellated forms were observed.

The results of DIZ presented by the essential oils of P. auritum and O. basilicum are shown in Table 3. Smaller DIZ were obtained by petroleum ether (6.1 mM), which means that E. coli growth was not affected, while greater DIZ were for the antimicrobials Enrotrim at 10% and Macromycin with 29.6 and 29.1 mM, respectively. Phytobiotic activity of essential oils of both plants were similar (p>0.05). The DIZ were 20.2 and 20.09 for P. auritum and O. basilicum, respectively. Such activity coincides with Adebolu and Adiola (2005Adebolu TT, Abiola SO. Antimicrobial activity of leaf extracts of Ocimum gratissimum on selected diarrhoea causing bacteria in southwestern Nigeria. African Journal of Biotechnology 2005;4(7):682-684.) and Reshmi et al. (2010Reshmi SK, Sathya E, Suganya DP. Isolation of piperdine from Piper nigrum and its antiproliferative activity. African Journal of Pharmacy and Pharmacology 2010;4(8)562-573.), who report that essential oils of Piper and Ocimum gender present phytobiotic properties before several microorganisms such as S. aureus, E. coli and S. typhi.

Thumbnail

Table 3
Diameter of the zone of inhibition of bacterial growth (mM)¹ of avian E. coli serotype O2, challenged with essential oils of leaves with phytobiotic properties.

At the beginning of the experiment and at the moment of inoculation, the birds had a similar weight (p>0.05); however, at slaughter these were different (p<0.05) (Table 4). There was no difference (p>0.05) between the highest body weight recorded on chickens of group 1, inoculated and treated with P. auritum extract and chickens of group 4, inoculated and treated with Enrofloxacin at 10%. Chickens inoculated and treated with O. basilicum had similar body weight (p>0.05) to those of negative control (group 5), but lower than the group of P. auritum extracts (p>0.05). The difference in body weights recorded was due to chickens inoculated with E. coli, because of severe anorexia mainly caused by lesions in organs such as: liver, spleen, kidney and digestive system (Dunnington et al., 1991Dunnington EA, Siegel PB, Gross WB. Escherichia coli challenge in chicken selected for high or low antibody response and differing in haplotypes at the major histocompatibility complex. Avian Diseases 1991;35(4):937-940.; Gomis et al., 1997Gomis SM, Watts T, Riddell C, Potter AA, Allan B. Experimental reproduction of Escherichia coli cellulitis and septicemia in broiler chickens. Avian Disease 1997;41:234-240.; Huff et al., 2006Huff WE, Huff GR, Rath NC, Donoghue AM. Evaluation of the influence of bacteriophage titer on the treatment of colibacillosis in broiler chickens. Poultry Science 2006;85:1373-1377.).

Thumbnail

Table 4
Body weight of chicken inoculated with avian E. coli serotype O2, treated with extracts of leaves with phytobiotic properties.

With respect to relative weights of the organs (Table 5), there was a difference in liver weight (p<0.05). The highest relative weight of the liver was recorded in group 3 (2.58%) and the smallest in group 5 (1.61%). In groups 1 and 2 treated with P. auritum and O. basilicum, respectively, the liver relative weight was superior (p>0.05) to 2.0% and lower (p<0.05) than in group 3, which suggests a hepatomegaly caused by colibacillosis. P. auritum and O. basilicum had a beneficial therapeutic effect on chickens, decreasing the inflammatory response caused by pathogenic stimulus reflected in lower weight of the liver, with regard to group 3 (negative control). Several protein groups are synthesized in the liver as response to microbial challenge that can increase the relative size of this organ, which allows the estimation of the intensity of an inflammatory response (Korver et al., 1998Korver DR, Roura E, Klasing KC. Effect of dietary energy level and oil source on broiler performance and response to an inflammatory challenge. Poultry Science 1998;77:1217-1227.; Willcox & Bodeker, 2000Willcox ML, Bodeker G. Plant-based malaria control: research initiative on traditional antimalarial methods. Parasitology Today 2000;16 (6):220-221; Chávez et al., 2015Chávez L, López A, Parra JE. La inclusión de cepas probióticas mejora los parámetros inmunológicos en pollos de engorde. Revista CES Medicina Veterinaria y Zootecnia 2015;10(2):160-169.).

Thumbnail

Table 5
Relative weight (%) of chicken organs inoculated with avian E. coli serotype O2, treated with extracts of leaves with phytobiotic properties.

Differences (p<0.05) were found in the relative weight of the gastrointestinal track (WGIT). The greatest WGIT was recorded in group 5 (6.94%), while the lowest was in group 4 (5.39%); regarding groups 1 and 2, they had similar weights (p>0.05). The relative weight of bursa of Fabricious (WBF) was greater (p<0.05) in group 2 (0.18%), followed by group 5 (0.16%) and the lowest weight was in group 3 (0.10%). The relative weights of lung (WL) were only different (p<0.05) in group 5 (0.53%) with regards to the other groups, which means that inflammatory response in chickens inoculated with E. coli increased in WL, coinciding with Lau et al. (2010Lau GL, Sieo CC, Tan WS, Hair-Bejo M, Jalila A, Ho YW. Efficacy of a bacteriophage isolated from chickens as a therapeutic agent for colibacillosis in broiler chickens. Poultry Science 2010;89:2589-2596.), who reported that chicken inoculated with E. coli O78:K80 showed higher weight (p<0.05) in lungs compared to those not inoculated. It is important to mention that the route of inoculation was intratracheal, favoring lesions originated in the respiratory system.

The quantification of CFU (log₁₀) of E. coli isolated from organs (Table 6) was greater (p<0.05) in the lungs of group 4 with Enrofloxacin at 10%, bacterial growth can be translated as a possible resistance to the use of some antimicrobials and where in field E. coli has already been reported resistant to this product (Itza-Ortiz, 2018Itza-Ortiz M. Personal communication. Ciudad Juárez: Universidad Autónoma de Ciudad Juárez; 2018. personal communication). The lowest concentration of E. coli was observed in groups 2 and 1, regarding the other groups (p<0.05); the aforementioned supports phytobiotic activity of P. auritum and O. basilicum extracts on avian E. coli serotype O2.

Thumbnail

Table 6
Concentration (log₁₀ CFU g^-1) of avian E. coli serotype O2 in pool of heart, liver and spleen, and lungs of inoculated chicken and treated with extracts of leaves with phytobiotic properties.

It is possible that secondary metabolites present in P. auritum extracts or oils, such as safrole, besides synergism with other substances as thymol, carvacrol, myristicin, linalool, borneol, camphor, cineol, methyl eugenol and a wide variety of benzene components, are inhibiting bacterial growth (Domínguez et al., 1962Domínguez XA, Rojas P, Carza MD, Córdova JA. Preliminary study of 20 plants from the central territory of Quintana Roo, México. Revista Química Mexicana 1962;6:213-215.; Oliveira et al., 2004Oliveira LHW, Ehringhausm Ch, Yoshio PK. Genetic diversity of Pimenta longa genotypes (Piper spp., Piperaceae) of the Embrapa Acre germplasm collection. Genetics and Molecular Biology 2004;27(1):74-82.). However, between phytobiotic extracts studied, the smallest growth of E. coli was obtained in O. basilicum, due to its active components, such as: β-linalool, estragole, linalool, 4-allyl anisole and eugenol; besides having phenolic acids derived from cinnamic acid and flavonoids (Acosta et al., 2003Acosta M, González M, Araque M, Velazco E, Khouri N, Rojas L, et al. Composición química de los aceites esenciales de Ocimum basilicum L. var basilicum, O. basilicum L. var purpurenscens, O. ratissimum L., y O. tenuiflorum L., y su efecto antimicrobiano sobre bacterias multirresistentes de origen nosocomial. Revista de la Facultad de Farmacia 2003;45(1):19-24.; Roldán et al., 2010Roldán LP, Díaz GJ, Duringer JM. Composition and antibacterial activity of essential oils obtained from plants of the Lamiaceae family against pathogenic and beneficial bacteria. Revista Colombiana de Ciencias Pecuarias 2010;23:451-461.), they form complexes with proteins and polysaccharides present in the external membrane of the cell, destabilizing the function of the membrane and cellular wall, causing microorganism death (Aguilar et al., 2007Aguilar CN, Rodríguez R, Gutierrez-Sanchez G, Augur C, Favela-Torres E, Prado-Barragán LA, et al. Microbial tannases: advances and perpectives. Applied Microbiology Biotechnology 2007;76:47-59.). Lee et al. (2003Lee KW, Everts H, Kappert HJ, Yeom KH, Beynen AC. Dietary carvacrol lowers body weight gain but improves feed conversion in female broiler chickens. Journal Applied Poultry Research 2003;12:394-399.) report that isoprene, chemical unity of terpenoids, which derive in three phenols, with phytobiotic properties: thymol, carvacrol and eugenol, can dissociate the external membranes of Gram negative bacteria, such as E. coli and S. typhimurium.

There was higher frequency of aerosaculitis (Table 7) in chickens inoculated with E. coli, because the route of inoculation was intratracheal. As shown, it was more severe in group 3. Aerosaculitis observed in group 3, coincides with the reported by Lau et al. (2010Lau GL, Sieo CC, Tan WS, Hair-Bejo M, Jalila A, Ho YW. Efficacy of a bacteriophage isolated from chickens as a therapeutic agent for colibacillosis in broiler chickens. Poultry Science 2010;89:2589-2596.), who indicate that 100% of inoculated chickens with E. coli serotype O78 showed this pathology. Presence of pericarditis and perihepatitis indicate a systemic infection and it was similar in groups 1 to 4; similar data were reported by Lau et al. (2010), in presence of pericarditis and perihepatitis in chicken inoculated with E. coli serotype O78:K80. Likewise, Rawiwet and Chansiripornchai (2009Rawiwet V, Chansiripornchai N. The efficacy of Escherichia coli AroA-Live vaccine in broilers against avian E. coli serotype O78 infection. Thai Journal of Veterinary Medicine 2009;39(4):337-342.) report greater incidence of aerosaculitis than pericarditis and perihepatitis in chicken inoculated with E. coli serotype O78.

Thumbnail

Table 7
Morbidity of chickens inoculated with avian E. coli serotype O2, and treated with extracts of leaves with phytobiotic properties.

Mortality in group 3 was 20%, 10% for group 2 and for the other groups (1, 4 and 5) there was no mortality; mortality rate of field, caused by E. coli infection could be 10% (Shane, 1981Shane SM. Colisepticemia: cause, prevention in commercial broiler flocks. Poultry Digestion 1981;40:370-374.; Wray et al., 1996Wray C, Davies RH, Corkish JD. Enterobacteriaceae. In: Jordan FTW, Pattison M, editors. Poultry diseases. London: WB Saunders; 1996. p.9-43.).

Histological lesions were more severe in group 3 than in groups 1, 2 and 4. Lung parenchyma showed multiple granulomas with necrotic center located in the lumen, surrounded by heterophils, lymphocytes, macrophages and giant cells (Figure 1); the aforementioned was not observed in groups 1 and 4; being less frequent in group 2. Air capillaries were more thickened in group 1. Histological findings suggest a restorative process of the damaged tissue; mainly in group 3, where necrotic tissue is being replaced by granulation tissue. Also, there is an immunological response, due to the presence of giant cells, macrophages, lymphocytes and few heterophils (Woolcock, 1979Woolcock JB. Bacterial infection and immunity in domestic animals. Amsterdam: St Elsevier Scientific Publishing; 1979. p.35-39;169-176.; Ridell, 1987Ridell C. Avian histopathology. Jacksonville: American Association of Avian Pathologists; 1987.). Heterophils are cells whose main function is the phagocytosis of several particles such as bacteria and other microorganisms (Banks, 1996Banks WJ. Histología veterinaria aplicada. 2nd ed. Ciudad de México: Editorial el Manual Moderno; 1996.), the lowest amount observed of granulation, can be due to the fact that necropsy of chickens was performed nine days after inoculation and heterophil infiltration occurs in early infections, in the first 48 hours post inoculation (Barnes et al., 2003Barnes HJ, Vaillancourt JP, Gross WB. Colibacillosis. In: Saif YM, editor. Diseases of poultry. 11th ed. Ames: Iowa State Press; 2003. p.631-656.).

Figure 1
Histological section of liver of Group 2 (chickens challenged with E. coli O2 and treated with extracts of O. basilicum) and Group 3 (chickens challenged with E. coli O2 and untreated).

Plant extracts with phytobiotic activity can act in the same manner as GPA, preventing immunological stress and its metabolic changes caused by the bacterial inoculum preventing immune activation (Roura et al., 1992Roura E, Homedes J, Klasing KC. Prevention of immunologic stress contributes to the growth-permitting ability of dietary antibiotics in chicks. Journal of Nutrition 1992;122:2383-2390.). It is important to mention that there were lesions not associated with E. coli, but to a mixture of etiological agents; especially in the respiratory track, where an inflammation can respond to an unlimited number of infectious agents (Barnes et al., 2003Barnes HJ, Vaillancourt JP, Gross WB. Colibacillosis. In: Saif YM, editor. Diseases of poultry. 11th ed. Ames: Iowa State Press; 2003. p.631-656.). The lesions observed in the liver of group 2 had the largest organization of hepatocyte cords in the hepatic parenchyma, possibly due to the therapeutic effect of O. basilicum extracts. Moderate multifocal hepatic lipidosis was observed in groups 1 and 2; group 3 showed mild multifocal. Hepatic lipidosis is caused by micotoxins in food, not by E. coli (Ridell, 1987Ridell C. Avian histopathology. Jacksonville: American Association of Avian Pathologists; 1987.); which means that chickens in group 3 had lower amount of food intake.

CONCLUSION

Extracts of the leaves of P. auritum and O. basilicum had phytobiotic activity on E. coli; with concentration higher than 8% and DIZ was observed above 10 mM. The solvent used in the extraction of active components of the plant can be an important factor in its activity, since larger DIZ were obtained with the alcoholic extracts; in addition to this, the aqueous extract at 10% of P. auritum promoted food intake, reflecting a weight similar to commercial antimicrobial, which decreased the severity of the infection. Total E. coli count in lungs, heart, liver and spleen in chickens with P. auritum and O. basilicum extracts was lower than the obtained in chicken groups treated with commercial antimicrobial. Macroscopic lesions were observed in chickens with evidence of systemic illness, caused by bacterial inoculation; nevertheless, a greater number of repetitions are necessary to obtain the therapeutic effect caused by the extracts, since lesion classification according to its severity could be provided.

REFERENCES

Acosta M, González M, Araque M, Velazco E, Khouri N, Rojas L, et al. Composición química de los aceites esenciales de Ocimum basilicum L. var basilicum, O. basilicum L. var purpurenscens, O. ratissimum L., y O. tenuiflorum L., y su efecto antimicrobiano sobre bacterias multirresistentes de origen nosocomial. Revista de la Facultad de Farmacia 2003;45(1):19-24.
Adebolu TT, Abiola SO. Antimicrobial activity of leaf extracts of Ocimum gratissimum on selected diarrhoea causing bacteria in southwestern Nigeria. African Journal of Biotechnology 2005;4(7):682-684.
Aguilar CN, Rodríguez R, Gutierrez-Sanchez G, Augur C, Favela-Torres E, Prado-Barragán LA, et al. Microbial tannases: advances and perpectives. Applied Microbiology Biotechnology 2007;76:47-59.
Banks WJ. Histología veterinaria aplicada. 2nd ed. Ciudad de México: Editorial el Manual Moderno; 1996.
Barnes HJ, Vaillancourt JP, Gross WB. Colibacillosis. In: Saif YM, editor. Diseases of poultry. 11th ed. Ames: Iowa State Press; 2003. p.631-656.
Bauer A, Kirby WMM, Sherris JC, Turck M. Antibiotic susceptibility testing by a standardized single disk method. American Journal of Clinical Pathology 1966;45:493-496.
Blanc V, Cortés P, Mesa R, Miro E, Navarro F, Llagostera M. Characterization of plasmids encoding extended-spectrum -lactamase and CMY-2 in Escherichia coli isolated from animal farms. International Journal of Antimicrobial Agents 2007;31(1):76-78.
Burt S. Essential oils: their antibacterial properties and potential applications in foods-a review. International Journal of Food Microbiology 2004;94:223-253.
Burt SA, Van der Zee R, Koets AP, Graaff AM, Van Knapen F, Gaastra W, et al. Carvacrol induces heat shock protein 60 and inhibits synthesis of flagellin in Escherichia coli O157:H7. Applied and Environmental Microbiology 2007;73(14):4484-4490.
Burt SA, Vlielander R, Haagsman HP, Veldhuizen EJA. Increase in activity of essential oil components carvacrol and thymol against Escherichia coli O157:H7 by addition of food stabilizers. Journal of Food Protection 2005;68(5):919-926.
Charleston B, Gate JJ, Aitken IA, Stephan B, Froyman R. Comparison of the efficacies of three fluoroquinolone antimicrobial agents, given as continuous or pulsed-water medication, against Escherichia coli infection in chickens. Antimicrobial Agents and Chemotherapy 1998;42(1):83-87.
Chávez L, López A, Parra JE. La inclusión de cepas probióticas mejora los parámetros inmunológicos en pollos de engorde. Revista CES Medicina Veterinaria y Zootecnia 2015;10(2):160-169.
Cook JA, Huggins MB, Ellis MM. Use of an infectious bronchitis virus and Escherichia coli model infection to assess the ability to vaccinate successfully against infectious bronchitis in the presence of maternally-derived immunity. Avian Pathology 1991;20:619-626.
Cortes RC. Escherichia coli: generalidades. México: Facultad de Medicina Veterinaria y Zootecnia, UNAM; 2008.
Cosentino S, Tuberoso CIG, Pisano B, Satta M, Mascia V, Arzedi E, et al. In vitro antimicrobial activity and chemical composition of Sardinian thymus essential oils. Letters in Applied Microbiology 1999;29:130-135.
Dho-Moulin M, Fairbrother JM. Avian pathogenic Escherichia coli (APEC). Veterinary Research 1999;30(2-3):299-316.
Dixon RA. Phytoestrogens. Annual Review of Plant Biology 2004;55:225-261.
Domínguez XA, Rojas P, Carza MD, Córdova JA. Preliminary study of 20 plants from the central territory of Quintana Roo, México. Revista Química Mexicana 1962;6:213-215.
Dorman HJD, Deans SG. Antimicrobial agents from plants: antibacterial activity of plant volatile oils. Journal of Applied Microbiology 2000;88:308-316.
Dozois CM, Dho-Moulin M, Brée A, Fairbrother JM, Desautels C, Curtiss III R. Relationship between the Tsh autotransporter and pathogenicity of avian Eschericha coli and localization and analysis of the Tsh genetic region. Infection and Immunity 2000;68:4145-4154.
Dughetti AC, De Carli DL. Utilización de distintos insecticidas y formulaciones en el control de Delia spp. en cebolla [informe técnico]. Provincia de Buenos Aires: Estación Experimental Agropecuaria INTA Hilario Ascasubi; 1999.
Dunnington EA, Siegel PB, Gross WB. Escherichia coli challenge in chicken selected for high or low antibody response and differing in haplotypes at the major histocompatibility complex. Avian Diseases 1991;35(4):937-940.
Ewers C, Janssen T, Wieler LH. Avian pathogenic Escherichia coli (APEC). Berlin Munch Tierarztl Wochenschr 2003;116(9-10):381-95.
García RA, Leyva MA, Martínez MJR, Staschenko EE. Determinación de la composición química y actividad antioxidante in vitro del aceite esencial de Piper auritum Kunth (Piperacea) difundida en la Costa Colombiana. Scientia et Technica 2007;13(033):439-442.
García-Compean L, Itza-Ortiz M, Ramón Ugalde JP, Sangines-García JR, Ortiz de la Rosa B, Zamora-Bustillos R, et al. Escherichia coli vaccine and laying hens mortality after a heat stress challenge in tropical climate. Journal of Animal and Veterinary Advance 2011;10(1):96-99.
Gomis SM, Watts T, Riddell C, Potter AA, Allan B. Experimental reproduction of Escherichia coli cellulitis and septicemia in broiler chickens. Avian Disease 1997;41:234-240.
Griggs PJ, Jacob PJ. Alternatives to antibiotics for organic poultry production. Journal Applied Poultry Research 2005;14:750-756.
Gupta MP, Arias DT, Williams NH, Bos R, Tattje DHE. Safrole, the main component of the essential oil from Piper auritum of Panama. Journal of Natural Products 1985;48(2):330-343.
Gurib-Fakim A. Medicinal plants: traditions of yesterday and drugs of tomorrow. Molecular Aspects of Medicine 2006;27(1):1-93.
Hernández F, Madrid J, García V, Orengo J, Megías D. Influence of two plant extracts on broilers performance, digestibility, and digestive organ size. Poultry Science 2004;(83):169-174.
Horne SM, Pfaff-McDonough SJ, Giddings CW, Nolan LK. Cloning and sequencing of the iss gene from a virulent avian Escherichia coli. Avian Diseases 2000;44:179-184.
Huff WE, Huff GR, Rath NC, Donoghue AM. Evaluation of the influence of bacteriophage titer on the treatment of colibacillosis in broiler chickens. Poultry Science 2006;85:1373-1377.
Itza-Ortiz M. Personal communication. Ciudad Juárez: Universidad Autónoma de Ciudad Juárez; 2018.
Kalemba D, Kunicka A. Antibacterial and antifungal properties of essential oils. Bentham Science Publishers 2003;10(10):813-829.
Kalra YP. Handbook of reference methods for plant analysis. Boca Raton: CRC Press; 1998.
Kato MJ, Furlan M. Chemistry and evolution of Piperaceae. Pure Applied Chemistry 2007;79:529-538.
Kleven SH, King DD, Anderson DP. Airsacculitis in broilers from Mycoplasma synovie: effect on air-sac lesions of vaccinating with infectious bronchitis and Newcastle virus. Avian Disease 1972;16(4):915-924.
Koneman EW, Allen SD, Dowell VR, Sommers HM. Diagnóstico microbiológico. Ciudad de México: Editorial Médica Panamericana; 1991.
Korver DR, Roura E, Klasing KC. Effect of dietary energy level and oil source on broiler performance and response to an inflammatory challenge. Poultry Science 1998;77:1217-1227.
Kwaga JKP, Allan BJ, Van Den Hurk JV, Seida H, Potter AA. A carAB mutant of avian pathogenic Escherichia coli serogroup 02 is attenuated and effective as a live oral vaccine against colibacillosis in turkey. Infection and Immunity 1994;62(9):3766-3772.
Lattaoui N, Tantaoui-Elaraki A. Individual and combined antibacterial activity of the main components of three thyme essential oils. Rivista Italiana EPPOS 1994;13:13-19.
Lau GL, Sieo CC, Tan WS, Hair-Bejo M, Jalila A, Ho YW. Efficacy of a bacteriophage isolated from chickens as a therapeutic agent for colibacillosis in broiler chickens. Poultry Science 2010;89:2589-2596.
Lee KW, Everts H, Kappert HJ, Yeom KH, Beynen AC. Dietary carvacrol lowers body weight gain but improves feed conversion in female broiler chickens. Journal Applied Poultry Research 2003;12:394-399.
López-Casamayor EJ. Estudio fitoquímico y aproximación genética en especies de la sección Plinthine del Género Arenaria (Cariophyllaceae). Granada: Universidad de Granada; 2007.
Mahabir G. 270 plantas medicinales iberoamericanas. Santa Fe de Bogotá: Editorial Presencia; 1995.
Mamoru K, Mujo K, Takehiko Y. Antifungal activity against food-borne fungi of Aspidistra elatior Blume. Journal of Agriculture and Food Chemistry 1996;44(1):301-303.
Mellata M, Dho-Moulin M, Dozois CM, Curtiss III R, Lehoux B, Fairbrother JM. Role of avian pathogenic Eschericha coli virulence factors in bacterial interaction with chicken heterophils and macrofages. Infection and immunity 2003;71:494-503.
Mendenhall W, Beaver RJ. Introduction to linear model and the design and analysis of experiments. In: Mendenhall W, editor. Introduction to probability and statistics. Belmont: Duxbury Press; 1994. p.244 251.
Mitsch P, Zitterl-Eglseer K, Kohler B, Gabler C, Losa R, Zimpernik I. The Effect of two different blends of essential oil components on the proliferation of Clostridium perfringens in the intestines of broiler chickens. Poultry Science 2004;83:669-675.
Monzote L, García M, Montalvo AM, Scull R, Miranda M. Chemistry, cytotoxicity and antileishmanial activity of the essential oil from Piper auritum. Memory Institute Oswaldo Cruz 2010;105(2):168-173.
Nakaruma CV, Nakaruma TU, Bando E, Melo AFN, Cortez DAG, Diaz-Filho BP. Antibacterial activity of Ocimum gratissimum L. essential Oil. Memory Institute Oswardo Cruz 1999;94:675-578.
Nwinyi-Obinna C, Chinedu-Nwodo S, Ajani-Olayinka O, Ikpo-Chinwe O, Ogunniran-Kehinde O. Antibacterial effects of extracts of Ocimum gratissimum and Piper guineense on Escherichia coli and Staphylococcus aureus. African Journal of Food Science 2009;3(3):77-81.
Oliveira LHW, Ehringhausm Ch, Yoshio PK. Genetic diversity of Pimenta longa genotypes (Piper spp., Piperaceae) of the Embrapa Acre germplasm collection. Genetics and Molecular Biology 2004;27(1):74-82.
Oudhia P. Traditional medicinal uses in India. Journal of Planta Medical 2003;5(5):175-179.
Ramya DK, Karthikumar S, Jegatheesan K. Isolation of potential antibacterial and antioxidant compounds from Acalypha indica and Ocimum basilicum. African Journal of Plant Science 2010;4(5):163-166.
Rawiwet V, Chansiripornchai N. The efficacy of Escherichia coli AroA-Live vaccine in broilers against avian E. coli serotype O78 infection. Thai Journal of Veterinary Medicine 2009;39(4):337-342.
Ridell C. Avian histopathology. Jacksonville: American Association of Avian Pathologists; 1987.
Regasini LO, Cotinguiba F, De-Araújo AM, Jorge KM, Scorzoni L, Mendes-Giannini MJ, et al. Antimicrobial activity of Piper arboreum and Piper tuberculatum (Piperaceae) against opportunistic yeasts. African Journal of Biotechnology 2009;8(12):2866-2870.
Reshmi SK, Sathya E, Suganya DP. Isolation of piperdine from Piper nigrum and its antiproliferative activity. African Journal of Pharmacy and Pharmacology 2010;4(8)562-573.
Rodríguez SEN. Uso de agentes antimicrobianos naturales en la conservación de frutas y hortalizas. Ra Ximhai 2011;7(1):153-170.
Roig JT. Plantas medicinales aromáticas o venenosas de Cuba. 5th ed. La Habana: Editorial Científico-Técnica; 1988.
Roldán LP, Díaz GJ, Duringer JM. Composition and antibacterial activity of essential oils obtained from plants of the Lamiaceae family against pathogenic and beneficial bacteria. Revista Colombiana de Ciencias Pecuarias 2010;23:451-461.
Roura E, Homedes J, Klasing KC. Prevention of immunologic stress contributes to the growth-permitting ability of dietary antibiotics in chicks. Journal of Nutrition 1992;122:2383-2390.
Sánchez Y, Pino O, Correa TM, Iglesia A, Naranjo E. Estudio químico y microbiológico del aceite esencial de Piper auritum Kunth (caisimón de anís). Revista de Protección Vegetal 2009;24(1):230-238.
Sánchez-Castellanos FJ. Extracción de aceites esenciales. Experiencia Colombiana. Annales do 2º Congreso Internacional de Plantas Medicinales y Aromáticas; 2006 Oct 19-21; Vale del Cauca: Universidad Nacional de Colombia Sede Palmira; 2006.
Shane SM. Colisepticemia: cause, prevention in commercial broiler flocks. Poultry Digestion 1981;40:370-374.
Sharapin N. Fundamentos de tecnología de productos fitoterapéuticos. Santa Fé de Bogotá: Quebecor-Impreandes; 2000.
Tequida-Meneses M, Cortez-Rocha M, Rosas-Burgos EC, López-Sandoval S, Corrales-Maldonado C. Efecto de extractos alcohólicos de plantas silvestres sobre la inhibición de crecimiento de Aspergillus flavus, Aspergillus niger, Penicillium chrysogenum, Penicillium expansum, Fusarium moniliforme y Fusarium poae. Revista Iberoamericana de Micología 2002;19:84-88.
Valsara T. Screening of indian medicinal plants for antimicrobial activity. Journal Ethnobiology 1994;35(3):275-283.
Vardar-Ünlü G, Candan F, Sökmen A, Daferera D, Polissiou M, Sökmen M, et al. Antimicrobial and antioxidant activity of the essential oil and methanol extracts of thymus pectinatus fisch. et mey. var. pectinatus (Lamiaceae). Jorunal Agriculture Food Chemistry 2003;51(1):63-67.
Woolcock JB. Bacterial infection and immunity in domestic animals. Amsterdam: St Elsevier Scientific Publishing; 1979. p.35-39;169-176.
Willcox ML, Bodeker G. Plant-based malaria control: research initiative on traditional antimalarial methods. Parasitology Today 2000;16 (6):220-221
Willis WL, Goktepe I, Isikhuemhen OS, Reed M, King K, Murray C. The effect of mushroom and pokeweed extract on Salmonella, egg production, and weight loss in molting hen. Poultry Science 2008;87:2451-2457.
Windisch W, Schedle K, Plitzner C, Kroismayr A. Use of phytogenic products as feed additives for swine and poultry. Journal of Animal Science 2008;86:E140-E148.
Witte W. Antimicrobial therapy in a Historical perspective. Acta Veterinaria Scandinavica 2000;93:7-16.
Wray C, Davies RH, Corkish JD. Enterobacteriaceae. In: Jordan FTW, Pattison M, editors. Poultry diseases. London: WB Saunders; 1996. p.9-43.
Yunis R, Ben-David A, Heller ED, Cahaner A. Antibody responses and morbidity following infection with infectious bronchitis virus and challenge with Escherichia coli, in lines divergently selected on antibody response. Poultry Science 2002;81:149-159

Publication Dates

Publication in this collection
24 Aug 2020
Date of issue
2020

History

Received
16 Aug 2019
Accepted
10 Dec 2019

This is an open-access article distributed under the terms of the Creative Commons Attribution License

[1] Acosta M, González M, Araque M, Velazco E, Khouri N, Rojas L, et al. Composición química de los aceites esenciales de Ocimum basilicum L. var basilicum, O. basilicum L. var purpurenscens, O. ratissimum L., y O. tenuiflorum L., y su efecto antimicrobiano sobre bacterias multirresistentes de origen nosocomial. Revista de la Facultad de Farmacia 2003;45(1):19-24.

[2] Adebolu TT, Abiola SO. Antimicrobial activity of leaf extracts of Ocimum gratissimum on selected diarrhoea causing bacteria in southwestern Nigeria. African Journal of Biotechnology 2005;4(7):682-684.

[3] Aguilar CN, Rodríguez R, Gutierrez-Sanchez G, Augur C, Favela-Torres E, Prado-Barragán LA, et al. Microbial tannases: advances and perpectives. Applied Microbiology Biotechnology 2007;76:47-59.

[4] Banks WJ. Histología veterinaria aplicada. 2nd ed. Ciudad de México: Editorial el Manual Moderno; 1996.

[5] Barnes HJ, Vaillancourt JP, Gross WB. Colibacillosis. In: Saif YM, editor. Diseases of poultry. 11th ed. Ames: Iowa State Press; 2003. p.631-656.

[6] Bauer A, Kirby WMM, Sherris JC, Turck M. Antibiotic susceptibility testing by a standardized single disk method. American Journal of Clinical Pathology 1966;45:493-496.

[7] Blanc V, Cortés P, Mesa R, Miro E, Navarro F, Llagostera M. Characterization of plasmids encoding extended-spectrum -lactamase and CMY-2 in Escherichia coli isolated from animal farms. International Journal of Antimicrobial Agents 2007;31(1):76-78.

[8] Burt S. Essential oils: their antibacterial properties and potential applications in foods-a review. International Journal of Food Microbiology 2004;94:223-253.

[9] Burt SA, Van der Zee R, Koets AP, Graaff AM, Van Knapen F, Gaastra W, et al. Carvacrol induces heat shock protein 60 and inhibits synthesis of flagellin in Escherichia coli O157:H7. Applied and Environmental Microbiology 2007;73(14):4484-4490.

[10] Burt SA, Vlielander R, Haagsman HP, Veldhuizen EJA. Increase in activity of essential oil components carvacrol and thymol against Escherichia coli O157:H7 by addition of food stabilizers. Journal of Food Protection 2005;68(5):919-926.

[11] Charleston B, Gate JJ, Aitken IA, Stephan B, Froyman R. Comparison of the efficacies of three fluoroquinolone antimicrobial agents, given as continuous or pulsed-water medication, against Escherichia coli infection in chickens. Antimicrobial Agents and Chemotherapy 1998;42(1):83-87.

[12] Chávez L, López A, Parra JE. La inclusión de cepas probióticas mejora los parámetros inmunológicos en pollos de engorde. Revista CES Medicina Veterinaria y Zootecnia 2015;10(2):160-169.

[13] Cook JA, Huggins MB, Ellis MM. Use of an infectious bronchitis virus and Escherichia coli model infection to assess the ability to vaccinate successfully against infectious bronchitis in the presence of maternally-derived immunity. Avian Pathology 1991;20:619-626.

[14] Cortes RC. Escherichia coli: generalidades. México: Facultad de Medicina Veterinaria y Zootecnia, UNAM; 2008.

[15] Cosentino S, Tuberoso CIG, Pisano B, Satta M, Mascia V, Arzedi E, et al. In vitro antimicrobial activity and chemical composition of Sardinian thymus essential oils. Letters in Applied Microbiology 1999;29:130-135.

[16] Dho-Moulin M, Fairbrother JM. Avian pathogenic Escherichia coli (APEC). Veterinary Research 1999;30(2-3):299-316.

[17] Dixon RA. Phytoestrogens. Annual Review of Plant Biology 2004;55:225-261.

[18] Domínguez XA, Rojas P, Carza MD, Córdova JA. Preliminary study of 20 plants from the central territory of Quintana Roo, México. Revista Química Mexicana 1962;6:213-215.

[19] Dorman HJD, Deans SG. Antimicrobial agents from plants: antibacterial activity of plant volatile oils. Journal of Applied Microbiology 2000;88:308-316.

[20] Dozois CM, Dho-Moulin M, Brée A, Fairbrother JM, Desautels C, Curtiss III R. Relationship between the Tsh autotransporter and pathogenicity of avian Eschericha coli and localization and analysis of the Tsh genetic region. Infection and Immunity 2000;68:4145-4154.

[21] Dughetti AC, De Carli DL. Utilización de distintos insecticidas y formulaciones en el control de Delia spp. en cebolla [informe técnico]. Provincia de Buenos Aires: Estación Experimental Agropecuaria INTA Hilario Ascasubi; 1999.

[22] Dunnington EA, Siegel PB, Gross WB. Escherichia coli challenge in chicken selected for high or low antibody response and differing in haplotypes at the major histocompatibility complex. Avian Diseases 1991;35(4):937-940.

[23] Ewers C, Janssen T, Wieler LH. Avian pathogenic Escherichia coli (APEC). Berlin Munch Tierarztl Wochenschr 2003;116(9-10):381-95.

[24] García RA, Leyva MA, Martínez MJR, Staschenko EE. Determinación de la composición química y actividad antioxidante in vitro del aceite esencial de Piper auritum Kunth (Piperacea) difundida en la Costa Colombiana. Scientia et Technica 2007;13(033):439-442.

[25] García-Compean L, Itza-Ortiz M, Ramón Ugalde JP, Sangines-García JR, Ortiz de la Rosa B, Zamora-Bustillos R, et al. Escherichia coli vaccine and laying hens mortality after a heat stress challenge in tropical climate. Journal of Animal and Veterinary Advance 2011;10(1):96-99.

[26] Gomis SM, Watts T, Riddell C, Potter AA, Allan B. Experimental reproduction of Escherichia coli cellulitis and septicemia in broiler chickens. Avian Disease 1997;41:234-240.

[27] Griggs PJ, Jacob PJ. Alternatives to antibiotics for organic poultry production. Journal Applied Poultry Research 2005;14:750-756.

[28] Gupta MP, Arias DT, Williams NH, Bos R, Tattje DHE. Safrole, the main component of the essential oil from Piper auritum of Panama. Journal of Natural Products 1985;48(2):330-343.

[29] Gurib-Fakim A. Medicinal plants: traditions of yesterday and drugs of tomorrow. Molecular Aspects of Medicine 2006;27(1):1-93.

[30] Hernández F, Madrid J, García V, Orengo J, Megías D. Influence of two plant extracts on broilers performance, digestibility, and digestive organ size. Poultry Science 2004;(83):169-174.

[31] Horne SM, Pfaff-McDonough SJ, Giddings CW, Nolan LK. Cloning and sequencing of the iss gene from a virulent avian Escherichia coli. Avian Diseases 2000;44:179-184.

[32] Huff WE, Huff GR, Rath NC, Donoghue AM. Evaluation of the influence of bacteriophage titer on the treatment of colibacillosis in broiler chickens. Poultry Science 2006;85:1373-1377.

[33] Itza-Ortiz M. Personal communication. Ciudad Juárez: Universidad Autónoma de Ciudad Juárez; 2018.

[34] Kalemba D, Kunicka A. Antibacterial and antifungal properties of essential oils. Bentham Science Publishers 2003;10(10):813-829.

[35] Kalra YP. Handbook of reference methods for plant analysis. Boca Raton: CRC Press; 1998.

[36] Kato MJ, Furlan M. Chemistry and evolution of Piperaceae. Pure Applied Chemistry 2007;79:529-538.

[37] Kleven SH, King DD, Anderson DP. Airsacculitis in broilers from Mycoplasma synovie: effect on air-sac lesions of vaccinating with infectious bronchitis and Newcastle virus. Avian Disease 1972;16(4):915-924.

[38] Koneman EW, Allen SD, Dowell VR, Sommers HM. Diagnóstico microbiológico. Ciudad de México: Editorial Médica Panamericana; 1991.

[39] Korver DR, Roura E, Klasing KC. Effect of dietary energy level and oil source on broiler performance and response to an inflammatory challenge. Poultry Science 1998;77:1217-1227.

[40] Kwaga JKP, Allan BJ, Van Den Hurk JV, Seida H, Potter AA. A carAB mutant of avian pathogenic Escherichia coli serogroup 02 is attenuated and effective as a live oral vaccine against colibacillosis in turkey. Infection and Immunity 1994;62(9):3766-3772.

[41] Lattaoui N, Tantaoui-Elaraki A. Individual and combined antibacterial activity of the main components of three thyme essential oils. Rivista Italiana EPPOS 1994;13:13-19.

[42] Lau GL, Sieo CC, Tan WS, Hair-Bejo M, Jalila A, Ho YW. Efficacy of a bacteriophage isolated from chickens as a therapeutic agent for colibacillosis in broiler chickens. Poultry Science 2010;89:2589-2596.

[43] Lee KW, Everts H, Kappert HJ, Yeom KH, Beynen AC. Dietary carvacrol lowers body weight gain but improves feed conversion in female broiler chickens. Journal Applied Poultry Research 2003;12:394-399.

[44] López-Casamayor EJ. Estudio fitoquímico y aproximación genética en especies de la sección Plinthine del Género Arenaria (Cariophyllaceae). Granada: Universidad de Granada; 2007.

[45] Mahabir G. 270 plantas medicinales iberoamericanas. Santa Fe de Bogotá: Editorial Presencia; 1995.

[46] Mamoru K, Mujo K, Takehiko Y. Antifungal activity against food-borne fungi of Aspidistra elatior Blume. Journal of Agriculture and Food Chemistry 1996;44(1):301-303.

[47] Mellata M, Dho-Moulin M, Dozois CM, Curtiss III R, Lehoux B, Fairbrother JM. Role of avian pathogenic Eschericha coli virulence factors in bacterial interaction with chicken heterophils and macrofages. Infection and immunity 2003;71:494-503.

[48] Mendenhall W, Beaver RJ. Introduction to linear model and the design and analysis of experiments. In: Mendenhall W, editor. Introduction to probability and statistics. Belmont: Duxbury Press; 1994. p.244 251.

[49] Mitsch P, Zitterl-Eglseer K, Kohler B, Gabler C, Losa R, Zimpernik I. The Effect of two different blends of essential oil components on the proliferation of Clostridium perfringens in the intestines of broiler chickens. Poultry Science 2004;83:669-675.

[50] Monzote L, García M, Montalvo AM, Scull R, Miranda M. Chemistry, cytotoxicity and antileishmanial activity of the essential oil from Piper auritum. Memory Institute Oswaldo Cruz 2010;105(2):168-173.

[51] Nakaruma CV, Nakaruma TU, Bando E, Melo AFN, Cortez DAG, Diaz-Filho BP. Antibacterial activity of Ocimum gratissimum L. essential Oil. Memory Institute Oswardo Cruz 1999;94:675-578.

[52] Nwinyi-Obinna C, Chinedu-Nwodo S, Ajani-Olayinka O, Ikpo-Chinwe O, Ogunniran-Kehinde O. Antibacterial effects of extracts of Ocimum gratissimum and Piper guineense on Escherichia coli and Staphylococcus aureus. African Journal of Food Science 2009;3(3):77-81.

[53] Oliveira LHW, Ehringhausm Ch, Yoshio PK. Genetic diversity of Pimenta longa genotypes (Piper spp., Piperaceae) of the Embrapa Acre germplasm collection. Genetics and Molecular Biology 2004;27(1):74-82.

[54] Oudhia P. Traditional medicinal uses in India. Journal of Planta Medical 2003;5(5):175-179.

[55] Ramya DK, Karthikumar S, Jegatheesan K. Isolation of potential antibacterial and antioxidant compounds from Acalypha indica and Ocimum basilicum. African Journal of Plant Science 2010;4(5):163-166.

[56] Rawiwet V, Chansiripornchai N. The efficacy of Escherichia coli AroA-Live vaccine in broilers against avian E. coli serotype O78 infection. Thai Journal of Veterinary Medicine 2009;39(4):337-342.

[57] Ridell C. Avian histopathology. Jacksonville: American Association of Avian Pathologists; 1987.

[58] Regasini LO, Cotinguiba F, De-Araújo AM, Jorge KM, Scorzoni L, Mendes-Giannini MJ, et al. Antimicrobial activity of Piper arboreum and Piper tuberculatum (Piperaceae) against opportunistic yeasts. African Journal of Biotechnology 2009;8(12):2866-2870.

[59] Reshmi SK, Sathya E, Suganya DP. Isolation of piperdine from Piper nigrum and its antiproliferative activity. African Journal of Pharmacy and Pharmacology 2010;4(8)562-573.

[60] Rodríguez SEN. Uso de agentes antimicrobianos naturales en la conservación de frutas y hortalizas. Ra Ximhai 2011;7(1):153-170.

[61] Roig JT. Plantas medicinales aromáticas o venenosas de Cuba. 5th ed. La Habana: Editorial Científico-Técnica; 1988.

[62] Roldán LP, Díaz GJ, Duringer JM. Composition and antibacterial activity of essential oils obtained from plants of the Lamiaceae family against pathogenic and beneficial bacteria. Revista Colombiana de Ciencias Pecuarias 2010;23:451-461.

[63] Roura E, Homedes J, Klasing KC. Prevention of immunologic stress contributes to the growth-permitting ability of dietary antibiotics in chicks. Journal of Nutrition 1992;122:2383-2390.

[64] Sánchez Y, Pino O, Correa TM, Iglesia A, Naranjo E. Estudio químico y microbiológico del aceite esencial de Piper auritum Kunth (caisimón de anís). Revista de Protección Vegetal 2009;24(1):230-238.

[65] Sánchez-Castellanos FJ. Extracción de aceites esenciales. Experiencia Colombiana. Annales do 2º Congreso Internacional de Plantas Medicinales y Aromáticas; 2006 Oct 19-21; Vale del Cauca: Universidad Nacional de Colombia Sede Palmira; 2006.

[66] Shane SM. Colisepticemia: cause, prevention in commercial broiler flocks. Poultry Digestion 1981;40:370-374.

[67] Sharapin N. Fundamentos de tecnología de productos fitoterapéuticos. Santa Fé de Bogotá: Quebecor-Impreandes; 2000.

[68] Tequida-Meneses M, Cortez-Rocha M, Rosas-Burgos EC, López-Sandoval S, Corrales-Maldonado C. Efecto de extractos alcohólicos de plantas silvestres sobre la inhibición de crecimiento de Aspergillus flavus, Aspergillus niger, Penicillium chrysogenum, Penicillium expansum, Fusarium moniliforme y Fusarium poae. Revista Iberoamericana de Micología 2002;19:84-88.

[69] Valsara T. Screening of indian medicinal plants for antimicrobial activity. Journal Ethnobiology 1994;35(3):275-283.

[70] Vardar-Ünlü G, Candan F, Sökmen A, Daferera D, Polissiou M, Sökmen M, et al. Antimicrobial and antioxidant activity of the essential oil and methanol extracts of thymus pectinatus fisch. et mey. var. pectinatus (Lamiaceae). Jorunal Agriculture Food Chemistry 2003;51(1):63-67.

[71] Woolcock JB. Bacterial infection and immunity in domestic animals. Amsterdam: St Elsevier Scientific Publishing; 1979. p.35-39;169-176.

[72] Willcox ML, Bodeker G. Plant-based malaria control: research initiative on traditional antimalarial methods. Parasitology Today 2000;16 (6):220-221

[73] Willis WL, Goktepe I, Isikhuemhen OS, Reed M, King K, Murray C. The effect of mushroom and pokeweed extract on Salmonella, egg production, and weight loss in molting hen. Poultry Science 2008;87:2451-2457.

[74] Windisch W, Schedle K, Plitzner C, Kroismayr A. Use of phytogenic products as feed additives for swine and poultry. Journal of Animal Science 2008;86:E140-E148.

[75] Witte W. Antimicrobial therapy in a Historical perspective. Acta Veterinaria Scandinavica 2000;93:7-16.

[76] Wray C, Davies RH, Corkish JD. Enterobacteriaceae. In: Jordan FTW, Pattison M, editors. Poultry diseases. London: WB Saunders; 1996. p.9-43.

[77] Yunis R, Ben-David A, Heller ED, Cahaner A. Antibody responses and morbidity following infection with infectious bronchitis virus and challenge with Escherichia coli, in lines divergently selected on antibody response. Poultry Science 2002;81:149-159

Group	Treatment	Dose	Inoculated (E. coli)
1	Piper auritum	30 mL of extract at 10%	Yes
2	Ocimum basilicum	30 mL of extract at 10%	Yes
3	Control	Without extract and without antimicrobial	Yes
4	Control	Enrofloxacin at 10%	Yes
5	Control*		No

	Aqueous Extract		Alcoholic Extract		Negative Control		Positive Control
	Pa²	Ob	Pa	Ob	Ad³	Al	EN	DX	MM
4%	9.6^b±0.8	9.0^b±0.7	16.4^fg±0.9	13.9^ef±1.7	6.3^a±0.4	10.1^bc±1.0	32.0^k±1.2	24.6^j±1.2	30.2^k±2.4
8%	10.8^bcd±0.8	10.7^bc±0.7	20.5^hi±1.1	16.5^fg±2.0
12%	11.7^bcde±0.7	11.9^bcde±0.4	21.5^hi±1.6	19.0^gh±1.4
16%	13.1^de±0.9	12.5^cde±0.8	22.0^ij±2.5	22.1^ij±1.4

Plant		Control
Piper auritum	Ocimum basilicum	EP²	EN³	DX	MM
20.2^b ±3.9	20.09^b ±1.9	6.1^a ±0.2	29.6^c ±3.1	23.6^b ±2.3	29.1^c ±4.2

Treatments¹	Body weight²
	Initial weight	Inoculation weight	Weight at slaughter
Group 1	2118.30 ±110.29	2703.00 ±148.34	3439.00^a ±157.33
Group 2	2081.40 ±109.35	2748.50 ±131.61	3390.50^ab ±176.89
Group 3	2126.50 ±143.90	2630.50 ±294.62	3160.00^b ±510.32
Group 4	2133.60 ±196.26	2754.00 ±224.39	3426.00^a ±295.17
Group 5	2123.10 ±113.80	2747.00 ±157.90	3360.00^ab ±145.27

	Treatments²
	Group 1¹	Group 2	Group 3	Group 4	Group 5
PC³	0.50 ±0.06	0.48 ±0.08	0.48 ±0.13	0.46 ±0.05	0.51 ±0.05
PH	2.06^b ± 0.32	2.01^b ±0.42	2.58^c ±0.81	1.87^ab ±0.32	1.61^a ±0.09
PB	0.07 ±0.03	0.07 ±0.03	0.09 ±0.03	0.06 ±0.01	0.06 ±0.00
PTGI	6.11^ab ±0.92	6.30^b ±0.61	6.45^b ±1.94	5.39^a ±0.86	6.94^b ±0.66
PBF	0.13^ab ±0.04	0.18^c ±0.05	0.10^a ±0.05	0.14^bc ±0.02	0.16^bc ±0.03
PP	0.69^b ±0.12	0.71^b ±0.13	0.73^b ±0.20	0.70^b ±0.15	0.53^a ±0.09
PR	0.69 ±0.20	0.66 ±0.14	0.72 ±0.30	0.61 ±0.22	0.76 ±0.10

Brasil

Brasil

Phytobiotic Activity of Piper Auritum and Ocimum Basilicum on Avian E. Coli

ABSTRACT

INTRODUCTION

MATERIAL AND METHODS

Collection of samples and storage.

In vitro test

Preparation of aqueous extract

Preparation of alcoholic extract

Obtaining essential oils

Inoculation of Petri dishes

Phytobiotic activity measurement

In vivo test

Preparation of the strain

Ethical Considerations of the Study

Experimental animals

Chicken inoculation

Extract administration

Evaluated variables

Isolation, identification and quantification of E. coli

Statistical analysis

RESULTS AND DISCUSSION

CONCLUSION

REFERENCES

Publication Dates

History

	Treatments¹
Sign	Group 1	Group 2	Group 3	Group 4	Group 5
Aerosaculitis²	8/10	7/10	10/10	8/10	0/10
Pericarditis	4/10	3/10	7/10	4/10	0/10
Perihepatitis	4/10	4/10	7/10	4/10	0/10

	Treatments²
	Group 1	Group 2	Group 3	Group 4	Group 5
Pool	4.06 ±0.86¹	2.64 ±0.47	5.75 ±3.03	6.03 ±2.87	0.00 ±0.00
Lungs	3.92 ±0.97^ab	1.87 ±0.87^a	6.32 ±1.48^bc	7.36 ±1.59^c	0.00 ±0.00