Performance, Gut Integrity, Enterobacteria Content in Ceca of Broiler Fed Different Eubiotic Additives

García-Reyna, A; Cortes-Cuevas, A; Juárez-Ramírez, M; Márquez-Mota, CC; Gómez-Verduzco, G; Arce-Menocal, J; Ávila-González, E

doi:10.1590/1806-9061-2021-1608

ABSTRACT

An experiment was carried out to study the effect of different eubiotics on productive characteristics, intestinal integrity, as well as the content of enterobacteria in the cecum of broiler chickens. A completely randomized design with five treatments and 8 replicates of 25 birds each was used. In total 1000 mixed broiler chickens from Ross308 strain, one day old were obtained from a commercial hatchery. The birds were housed on concrete floors in a conventional house. A sorghum+soybean meal control diet was used, to which the additives under study were added. The treatments were distributed as follows: T1 = Control diet without antibiotic or eubiotic; T2 = T1 + bacteriophages; T3 = T1 + antibiotic; T4 = T1 + probiotic; T5 = T1 + symbiotic. The results obtained at 49 days of age for weight gain and feed conversion rate improved (p<0.05) with the addition of the antibiotic and eubiotics. A lower (p<0.05) intestinal density was observed with the probiotic. The height, width, and area of villi in duodenum was higher (p<0.05) when antibiotic and eubiotics were included. In the histological score, in duodenum, the antibiotic and eubiotics resulted with a higher score (p<0.05), associated to a physiological and controlled inflammation response that allowed improving productivity. Finally, the relative expression of enterobacteria, such as Lactobacillus salivarius, allowed associating positive changes in the microbiome and better productive parameters when including the symbiotic, with comparable results to the antibiotic when including the eubiotics.

Keywords:
Antibiotics; Bacteriophages; Probiotic; Symbiotic; Poultry Nutrition

INTRODUCTION

Currently, the development of feed additives as alternatives to the use of antibiotic growth promoters (AGP) in broiler diets and other productive species is still under investigation. Although several studies show that it is complicated to match the productive and economic results obtained with the use of antibiotics, the implications of continuing to use them are also known; environmental contamination, risks to aquatic organisms and, of course, antimicrobial resistance, which implies a global challenge in the control of infectious diseases (Sethiya, 2016Sethiya, NK. Review on natural growth promoters available for improving gut health of poultry:An alternative to antibiotic growth promoters. Asian Journal of Poultry Science 2016;10(1):1-29.; Al-Khalaifah, 2018Al-Khalaifah HS. Benefits of probiotics and/or prebiotics for antibiotic-reduced poultry. Poultry Science 2018;97(11):1807-15.; Oviedo-Rondón, 2019Oviedo-Rondón, EO. Holistic view of intestinal health in poultry. Animal Feed Science Technology 2019;250:1-8.; Selaledi et al., 2020Selaledi LA, Hassan ZM, Manyelo TG, Mabalebele M. The current status of the alternative use to antibiotics in poultry production:an African perspective. Antibiotics 2020;9(9):594.). The topic of intestinal health has maintained interest in those additives classified as biomodulators of the intestinal microbiota or also called eubiotics, derived from eubiosis, understood as a balance of the intestinal microbial ecosystem (Iebba et al., 2016Iebba V, Totino V, Gagliardi A, Santangelo F, Cacciotti F, Trancassini M, et al. Eubiosis and dysbiosis:the two sides of the microbiota. New Microbiologica 2016;39:1-12.; Oviedo-Rondón, 2019) and that their use promotes among other things animal welfare and food safety (Sethiya, 2016; Oviedo-Rondón, 2019). Some of these additives have been known for several decades, such as probiotics, prebiotics, organic acids, phytobiotics, enzymes (Caly et al., 2015Caly DL, D'Inca R, Auclair E, Drider D. Alternatives to antibiotics to prevent necrotic enteritis in broiler chickens:A microbiologist's perspective. Frontier in Microbiology 2015;6:1-12.; Sethiya, 2016) and recently the use of new commercial alternatives, such as bacteriophages. Among them, probiotics and symbiotics (probiotic+prebiotic), are widely used as AGP alternatives in poultry production, for its low production cost (Oviedo-Rondón, 2019). These additives promote the proliferation of desirable bacteria in the gut by competitive exclusion, competing for nutrients, immunomodulation, production of antimicrobial compounds and of course, growth of the probiotic organism, by providing a substrate available to the probiotic fermentation in case of the prebiotic (Roberts et al., 2015Roberts T, Wilson J, Guthrie A, Cookson K, Vancraeynest D, Shaeffer R, et al. New issues and science in broiler chicken intestinal health:Emerging technology and alternative interventions. Journal Applied Poultry Research 2015;24:257-66.; Sethiya, 2016; Bajagai et al., 2016; Oviedo-Rondón, 2019). As for bacteriofages, models have already been used to investigate the dynamics of the phage-bacteria ecosystem (killing, lysogenization, passage of the bacteriophage from one strain to another),as described by De Paepe (2014). However, despite the research done on these alternatives there is much to be understood and tested regarding their effects on intestinal health and integrity, by reduction of the inflammatory response and better immune response against pathogenic bacteria, without affecting productive performance (M’Sadeq et al., 2015M'Sadeq SA, Wu S, Swick RA, Choct M. Towards the control of necrotic enteritis in broiler chickens with in-feed antibiotics phasing-out worldwide. Animal Nutrition 2015;1:1-11.; Sethiya, 2016; Tarradas et al., 2020Tarradas J, Tous N, Esteve-Garcia E, Brufau AJ. The control of intestinal inflammation:A major objective in the research of probiotic strains as alternatives to antibiotic growth promoter in poultry. Microorganisms 2020;8(2):148-64.). Therefore, within eubiotic nutrition, what is sought is the combination of additives for each circumstance, which allows promoting the presence of a balanced and “healthy” intestinal microbiome (Yasar et al., 2017Yasar S, Okutan I, Tosun, R. Testing novel eubiotic additives: Its health and performance effects in commercially raised farm animals. Journal of the Institute of Science and Technology 2017;7(4):297-308.) as well as the integrity of the mucosal barrier, optimization of gut morphology and digestibility, reduction in nutrient excretion and intestinal immunomodulation that help control inflammation (Oviedo-Rondón, 2019; Tarradas et al., 2020) and prevent the transition from physiological to pathological inflammation, which normally reduces productivity. Therefore, the present study was conducted to evaluate the effect of adding eubiotics to the diet of broilers on productive performance, carcass characteristics, intestinal integrity, and the count of some enterobacteria in ceca.

MATERIALS AND METHODS

The research was carried out at the Center for Teaching, Research, Extension and Poultry Production of the Faculty of Veterinary Medicine and Zootechnics of the UNAM. In total 1000 mixed broiler chickens from Ross308 strain, one day old were obtained from a commercial hatchery. All chicks were received with an average initial weight of 43 g, vaccinated against Gumboro-Marek’s disease and later against Newcastle disease at 10 days of age. The birds were randomly distributed in 40 compartments; they were housed for 7 weeks in a natural environment house with cement floor pens, wood-shavings litter, with a density of 10 birds/m² and tunnel breeding. They were kept under a natural light program, with an average of 11 hours of light per day. All animal care and technical procedures were approved by the Institutional Subcommittee for the Care and Use of Experimental Animals (protocol DC-2018/2-5) of the faculty mentioned above.

Experimental design and diets

A completely randomized design was used with five treatments with 8 replicates of 25 birds each. A sorghum+soybean meal control diet was used to which the additives under study were added, considering 3 feeding phases: Initiation (1-21 days of age), Growing (22-35 days of age) and Finishing (36-49 days of age). The treatments were distributed as follows: T1 = control diet without antibiotic or eubiotic; T2 = T1 + bacteriophage (500 g/Ton); T3 = T1 + antibiotic (300 g/Ton); T4 = T1 + probiotic (100 g/Ton); T5 = T1 + symbiotic (500 g/Ton). The composition of the experimental control diet is shown in Table 1. Water and feed were supplied ad libitum. All additives were commercial products in powder form and were added to the diets at the levels recommended by the manufacturers. The bacteriophage-containing product was obtained from an additive manufacturing company (CTC Bio Inc.) that includes a cocktail of lyophilized bacteriophages specific for Salmonella enterica serovars Typhimurium, Enteritidis, Cholerasuis and Derby, Staphylococcus aureus, Escherichia coli (k88, k99 and f41) and Clostridium perfringens type A and C. The titers of each bacteriophage in the bacteriophage cocktail are 10⁹ pfu/g cocktail. The antimicrobial product was bacitracin-zinc and was added at 30 ppm. The probiotic contained 10⁷ CFU/g of Bacillus Subtilis (BaymixGrobig^®). The symbiotic product (PoultryStar^®ME, BIOMIN), consisted of the sum of multispecies probiotic (1.3x10¹¹ CFU/g Enterococcus faecium, 5.0x10¹⁰ CFU/g Pediococcusacidilactici, 2.1x10¹⁰ CFU/g Bifidobacterium animalis, 5.0x10⁹ CFU/g Lactobacillus reuteri, 5.0x10⁹ CFU/g Lactobacillus salivarius) and a prebiotic (Inulin).

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Table 1
Composition of the control diet used in the experiment.

Performance and Carcass parameters

At the end of each week, the body weight gain (WG) and feed intake (FI) of the birds of each treatment was obtained, as well as the feed conversion ratio (FCR) and percentage of general mortality. At 49 days of age, 26 birds per treatment were selected, identified, weighed, and slaughtered after an 8-hour fast. Each bird was subjected to the slaughter protocol of the processing plant of the aforementioned center: 1) hanging and electrically stunned, under the parameters of 25 V, 0.25 A and 460 Hz of direct current, pulsed type; 2) the slaughter was performed by unilateral neck cutting in order to be bled out for2 minutes; 3) scalded in water at 53°C for one minute; 4) mechanical plucking and manual evisceration. The weights of the carcass, abdominal fat, breast muscle (Pectoralis major) and legs (thighs and drumsticks) were obtained. For each case, the yields of carcass, abdominal fat and primal cuts were determined on a live weight basis. Skin pigmentation (yellowness) was measured in the lateral apterium region, in the live chicken and in the carcass, using a Minolta CR-400 reflectance colorimeter.

Histological preparation

At 49 days, from each treatment, one chicken per replicate (8 birds per treatment) was selected and the intestine was dissected entirely. Intestinal segment samples approximately 2 cm long were obtained from the duodenum (the midpoint of the pancreatic loop). All samples were washed with 0.9% saline and fixed in 10% neutral-buffered formalin solution for a minimum period of 24 hours at 4°C; they were subsequently processed by routine histological techniques (Laudadio et al., 2012Laudadio V, Passantino L, Perillo A, Lopresti G, Passantino A. Productive performance and histological features of intestinal mucosa of broiler chickens fed different dietary protein levels. Poultry Science 2012;91:265-70.); paraffin embedding and cross-sectioning of the segments at 5 µm thickness. Subsequently, two stains were used; hematoxicillin-eosin (HE) and Alcianblue (AB)/periodic acid-Schiff (PAS); HE staining was used for gut morphological measurements and ISI histological analysis, while PAS-AB staining was used in the goblet cell counts of duodenum in accordance to Setiawan et al. (2018Setiawan, H, Jingga, ME, Saragih, HT. The effect of cashew leaf extract on small intestine morphology and growth performance of Jawa Super Chicken. Veterinary World 2018;11(8):1047-54.). Ten well-oriented villi and 10 crypts of Lieberkühn were measured per cross-section of each intestinal segment. All the observations and measurements were performed with an optical microscope (LEICA MC170HD^®).

Intestinal morphometry measurement

The small intestine (from the end of the gizzard to 1 cm above the ileocecal junction) of each bird was excised and weighed. The length of the small intestine was obtained with a tape measure. Intestinal mass per unit of length defined as “intestinal density” was calculated as the ratio between absolute weight in grams and length in centimeters of the small intestine (g/cm) according to Alshamy et al. (2018Alshamy Z, Richardson KC, Hunigen H, Hafez HH, Plendl J, Al Masri S. Comparison of the gastrointestinal tract of a dual-purpose to a broiler chicken line: A qualitative and quantitative macroscopic and microscopic study. PLoS One 2018;13(10):e0204921.) and Riahi et al. (2020Riahi I, Marquis V, Ramos AJ, Brufau J, Esteve-Garcia E, Pérez-Vendrell VAM. Effects of deoxynivalenol-contaminated diets on productive, morphological, and physiological indicators in broiler chickens. Animals 2020;9(301):1-11.). In the duodenum, the following morphometric variables were determined: height (µm) and width (µm) of intestinal villi, crypt depth (µm) and goblet cell count. Villus height (LV) was measured as the distance from the tip of the villus to the transition region of the crypt and villus. Measurement of intestinal crypt depth was taken from the base of the villus to the submucosa. The apparent villus surface area (mm²) was calculated using the following formula: [(villus width at one-third + villus width at two-thirds) × 2^-1× villus height] used by Laudadio et al. (2012Laudadio V, Passantino L, Perillo A, Lopresti G, Passantino A. Productive performance and histological features of intestinal mucosa of broiler chickens fed different dietary protein levels. Poultry Science 2012;91:265-70.). Villus:crypt ratio was calculated dividing villus height by crypt depth. The number of goblet cells per 100 intestinal epithelial cells in intestinal sections was determined (Sun et al., 2013Sun Q, Shang Y, She R, Jiang T, Wang D, Ding Y, et al. Detection of intestinal intraepithelial lymphocytes, goblet cells and secretory IgA in the intestinal mucosa during Newcastle disease virus infection. Avian Pathology 2013;42(6):541-5.).

Intestinal histological changes

Three histological parameters were evaluated (epithelial hyperplasia, goblet cell hyperplasia and inflammatory cell infiltration of the lamina propria by lymphocytes) that were adapted to that described by Kraieski et al. (2017Kraieski AL, Hayashi RM, Sanches A, Almeida GC, Santin E. Effecy of aflatoxin experimental ingestion and Eimeira vaccine challenges on intestinal histopathology and immune cellular dynamic of broilers:applying an Intestinal Health Index. Poultry Science 2017;(96):1078-87.), in their ISI methodology (I See Inside). In this methodology, an impact factor (IF) is defined for each histological alteration in the intestine, according to the reduction in functional capacity, considering 3 features with impact factor 1, 2 and 3: Epithelial cell hyperplasia (IF = 1), Goblet cell hyperplasia (IF = 2), Inflammatory cell infiltration (IF = 3). IF = 3 has the greatest impact on organ function. Likewise, the degree of intensity or frequency observed was considered, designated as score of the alteration in each tissue qualifying from 0 to 3: 0 (absence of alteration or frequency observed), 1 (alteration up to 25% of the area or frequency observed), 2 (alteration from 25 to 50% of the area or frequency observed) and 3 (alteration extended in more than 50% of the area or frequency observed). To obtain the final value of the ISI index, the IF of each alteration is multiplied by the respective score number, and the result of all alterations are summed according to the formula ISI = ∑ (IF*S), where IF = impact factor and S = Score. For our evaluation scale the total score ranges from 0 to 18.

Protocol for DNA extraction in cecal content

At day 49, 8 chickens per treatment were sacrificed and cecal content samples were collected from each chicken. The samples were placed in sterile 2 ml eppendorf vials and refrigerated for a maximum of 1.5 h. then, were frozen at -80°C until DNA extraction, whose procedure was an adaptation of the method of Wilson (1997Wilson K. Preparation of genomic DNA from Bacteria. In: Ausubel, FM, editor. Current protocols in molecular biology. New York: Wiley InterScience; 1997.). For this, 200 mg of frozen cecal contents were suspended in 1 mL of PBS (phosphate buffered saline), homogenized, and centrifuged at 389 × g for 10 min at room temperature. The supernatant was discarded, and the pellet was suspended in 567 µL of TE (Tris/EDTA) buffer and 50 µL of lysozyme (10 mg/mL) was added and incubated at 37°C for 30 min. After this time, 30 µL of 10% SDS (sodium dodecyl sulfate) and 4 µL of proteinase K (20 mg/mL) were added and incubated for 1 h at 56°C. After this time, 100 µL of 5 M NACl was added followed by 100 µL of CTAB/NaCl solution and incubated for 10 min at 65°C, then 80 µL of chloroform/isoamyl alcohol was added and centrifuged at 19064 × g for 10 min. The supernatant was taken, leaving the interphase behind. The volume was equalized with phenol/chloroform/isoamyl alcohol (PCIA). After centrifugation (19064 × g for 10 min), three phases were obtained: organic phase, interphase and aqueous phase (supernatant with DNA). Only the aqueous phase was taken. 200 µL of chloroform was added, mixed and incubated for 10 min at room temperature. Centrifuged at 19064 × g for 15 min and the supernatant was recovered. Then 500 µL of cold isopropanol was added, mixed and incubated in freezing for 24 h. It was then centrifuged at 19064 × g for 10 min and the isopropanol was decanted. Two washes were made with 300 µL of cold 70% ethanol to remove residual CTAB, centrifuging at 9726 × g for 5 min. All centrifugations were performed on Thermo Scientific Heraus Primo R. The ethanol was removed, and the DNA pellet was allowed to dry at room temperature for 30 min. Finally, the pellet was suspended in 100 µL of DNase/RNase-Free Water and frozen until DNA concentration was quantified using a spectrophotometer (NanoDrop2000, Thermo Scientific).

Real-time PCR procedure

A total volume of 20 µL of reaction mixture was prepared containing 10 µL of reagent (Kappa Sybr^® Fast DNA polymerase), 0.8 µL of lyophilized primers (forward and reverse), 2 µL of DNA and 7.2 µL of DNase/RNase-Free Water. Each DNA sample was performed in triplicate and once all the reaction samples were prepared, they were tested using a Rotor Gene Q^® thermal cycler for the DNA amplification process. The amplification conditions were set according to the instructions of the KappaSybr^® reagent commercial kit: Enzyme activation, 95°C × 3 min, followed by 40 cycles of denaturation, 95°C × 1-3 sec and Extension, 60°C × 10 sec. Primer sequences are presented in Table 2. Ct values obtained from amplification, were used to analyze relative gene expression using the 2^-ΔΔCtmethod (Livak & Schmittgen, 2001Livak KJ, Schmittgen TD. Analysis of relative gene expression data using real-time quantitative PCR and the 22DDCT Methods 2001;25(4):402-8.; Tan, 2014Tan J, Applegate TJ, Liu S, Guo Y, Eicher SD. Supplemental dietary L-arginine attenuates intestinal mucosal disruption during a coccidial vaccine challenge in broiler chickens. British Journal of Nutrition 2014, 112:1098-109.).

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Table 2
Primer used in bacterial quantification.

Statistical analysis

From the information collected, productive performance, carcass characteristics and histological examination were statistically analyzed by one-way ANOVA. Comparison of means was performed using Tukey’s test, considering a significance level of 1% and 5%. Variables expressed as percentage, were transformed to arcsine before the analysis. The Mann-Whitney statistical test was used when the data were not normally distributed. All the statistical analysis was performed using SPSS software (version 17.0, Chicago, IL, USA) with assistance from GraphPad Prism software (version 4.00; GraphPad Software, San Diego, CA).

RESULTS

Productive performance and carcass characteristics

Regarding productive data at 49 days of age, a higher BWG and a lower FCR (p<0.01) were obtained in the chickens that received eubiotics and the antibiotic. Analyzing FI and percentage of mortality (Table 3), no significant differences (p>0.05) were found between treatments. In carcass characteristics (Table 4),broiler chickens fed the antibiotic showed a higher (p<0.05) carcass yield than control diet and the others were similar. No statistical differences (p>0.05) were found in the yield of breast muscle, thighs+drumsticks, and yellowness between treatments.

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Table 3
Effect of eubiotics on productive performance in broiler chickens at 49 days of age.

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Table 4
Effect of eubiotics on carcass characteristics in broiler chickens at 49 days of age.

Intestinal morphology and histometry

In total intestinal density (g/cm), it was observed (Figure 1) that treatment with the control diet had higher intestinal density (p00.01) compared to the diet containing probiotic, and the other groups presented similar results. The measurements of intestinal villi (Table 5) in duodenum improved (p<0.01) with the use of eubiotics and antibiotic.

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Table 5
Effect of eubiotics on histological measurements (duodenum) in broiler chickens at 49 days of age.

Figure 1
Effect of eubiotics on intestinal density (g/cm) in broiler chickens at 49 d. Vertical lines associated with histogram bars represent standard error of the mean for the total histologic score. ^a,b,abIndicate significant differences (p<0.01).

Intestinal histological changes

Using the histological ISI evaluation in duodenum (Figure 2), a higher (p<0.01) total ISI score considering epithelial changes and inflammatory changes was found when using the antibiotic and eubiotics when compared with the control group. The changes that favored this higher total score, were in accordance with the obtained in goblet cell hyperplasia and inflammatory cell infiltration.

Figure 2
Total sum of the histologic alteration score in the duodenum of broiler chickens supplemented with eubiotics. Epithelial hyperplasia (IF=1), Goblet cell hyperplasia (IF=2), Inflammatory infiltration in the lamina propria (IF=3). ^abIndicate significant differences (p<0.01).

Relative expression of enterobacteria

In relation to the fold change of relative quantification of enterobacteria determined by real time PCR can be found in Figure 3. In ceca, in the case of E. coli, an increase (p<0.05) of 2.9 times more in its expression level was obtained when using bacteriophages than the control group at 49 days of age. For C. perfringens, it was overexpressed 7.3 times (p<0.05) more when the probiotic B. subtilis was added than the control group in chickens at 49 days of age. Regarding L. salivarius, the use of the symbiotic allowed a 2-fold increase in its expression level compared to the control treatment; however, there was no significant difference (p>0.05).

Figure 3
Effects of eubiotics in broiler chickens on the relative expression in cecum of A) E. coli, B) C. perfringens and C) L. salivarius. Error bars represent the standard error of the mean of the relative expressions. *Indicate significant differences (p<0.05).

DISCUSSION

Different studies support that the broiler performance with the use of eubiotics is comparable to that obtained with AGP (Mountzouris et al., 2010; Ghazanfari et al., 2015Ghazanfari SI, Mohammadi ZI, Adib Moradi MII. Effects of Coriander Essential Oil on the Performance, Blood Characteristics, Intestinal Microbiota and Histological of Broilers. Brazilian Journal of Poultry Science 2015;17(4):419- 26.; Gao et al., 2017Gao P, Ma C, Sun Z, Wang L, Huang S, Su X, et al. Feed-additive probiotics accelerate yet antibiotics delay intestinal microbiota maturation in broiler chicken. Microbiome 2017;5:91.; Hussein et al., 2020Hussein EOS, Ahmed SH, Abudabos AM, Aljumaah MR, Alkhulaifi MM, Nassan MA, et al. Effect of antibiotic, phytobiotic and probiotic supplementation on growth, blood indices and intestine health in broiler chicks challenged with Clostridium perfringens. Animals 2020;10:507.), although according to other authors, these additives do not cover the economic and productive benefits of an antibiotic (Al-Khalaifah, 2018Al-Khalaifah HS. Benefits of probiotics and/or prebiotics for antibiotic-reduced poultry. Poultry Science 2018;97(11):1807-15.; Oviedo-Rondón, 2019Oviedo-Rondón, EO. Holistic view of intestinal health in poultry. Animal Feed Science Technology 2019;250:1-8.). In the present study, FCR was optimized by 5% when including the antibiotic and eubiotics in the diet, also obtaining a higher carcass yield when the antibiotic was used with respect to the control group (74% vs. 72.5%). Gao et al. (2017) reported a similar improvement (5.9%) in FCR when using a probiotic (Lactobacillus plantarum) compared with a combination of antibiotics, just like Hussein et al. (2020) who, using Bacillus spores (genera subtilis and licheniformis) and a phytobiotic compound to supplement diets of broiler chickens infected with C. perfringens, obtained a BWG, FCR and mortality comparable to the group treated with antibiotic (avilamycin). A study performed with bacteriophages (0.5 and 1 g/kg), showed a higher BWG than the control group, without effect in FCR (Upadhaya et al.,2021Upadhaya SD, Ahn JM, Cho JH, Kim JH, Kim JY, Kang DK, et al. Bacteriophage cocktail supplementation improves growth performance, gut microbiome and production traits in broiler chickens. Journal of Animal Science and Biotechnology 2021;12(49):1-12.). In the gut morphological evaluation, the intestinal density (g/cm) was higher in the broiler chickens of the control group, with respect to the chickens fed B. subtilis-added diet. An increase in intestinal density may be related to changes in the intestinal mucosa, which in some mammals represents more than 50% of the thickness of the intestine, in duodenum and jejunum (Di Donato et al., 2013), and is possibly even greater in birds where the villi are usually higher than that of mammals (Smyth, 2016Smyth JA. Pathology and diagnosis of necrotic enteritis:is it clear-cut?. Avian Pathology 2016;45(3):282-7.). On the other hand, it is known that, although intestinal weight and length in chickens decrease after the first week of age, this is compensated by an increase in intestinal density to maintain nutrient delivery function (Ravindran et al., 2006Ravindran V, Wu YB, Thomas DG, Henri Morel PC. Influence of whole wheat feeding on the development of gastrointestinal tract and performance of broiler chickens. Australian Journal of Agricultural Research 2006;57:21-6.), which may indicate that birds with higher intestinal mass have better nutrient utilization. However, Cardinal et al. (2019) when evaluating a reduced protein diet in broilers, observed that supplementation of a protease reduced the thickness of the lamina propria and epithelial surface, which was associated with improved nutrients transport and absorption, and thus higher productivity. In another study, when using a mycotoxin metabolite in broilers, it was observed a lower intestinal density derived, according to their conclusions, from a lower villi height (Riahi et al., 2020Riahi I, Marquis V, Ramos AJ, Brufau J, Esteve-Garcia E, Pérez-Vendrell VAM. Effects of deoxynivalenol-contaminated diets on productive, morphological, and physiological indicators in broiler chickens. Animals 2020;9(301):1-11.). When changes in intestinal thickness result in villi atrophy and thinning of the tunica muscularis, macroscopically, the intestinal wall becomes more translucent, which can be used as an evaluation parameter for dysbacteriosis (Teirlynck et al., 2011Teirlynck E, Gussem MDE, Dewulf J, Haesebrouck F, Ducatelle R, Van Immerseel F. Morphometric evaluation of "dysbacteriosis" in broilers. Avian Pathology 2011;40(2):139-44.). This dysbacteriosis due to acute infection or tissue damage manifests as pathological inflammation, but when the immune response of the chickens is appropriate, the inflammation is of a physiological type (Kogut et al., 2018Kogut MH, Genovese KJ, Swaggerty CL, He H, Broom L. Inflammatory phenotypes in the intestine of poultry:not all inflammation is created equal. Poultry Science 2018;97(7):2339-46). To this extent, it can be explained why the tendency to a lower intestinal density implied a better productive response, as obtained in this study. In the histometry of intestinal villi, a greater height and area of villi in duodenum was recorded, in chickens supplemented with the antibiotic and eubiotics, being this intestinal segment, important in the digestion and absorption of nutrients (Apajalahti & Vienola, 2016Apajalahti J, Vienola K. Interaction between chicken intestinal microbiota and protein digestión. Feed Science and Technology 2016;221:323-30.). Something similar was reported in other experiments, where using probiotics, prebiotics and phytobiotics, improved characteristics of the villi (Markovic et al., 2009; Giannenas et al., 2014Giannenas I, Tsalie E, Triantafillou E, Hessenberger S, Teichmann K, Mohnl M, et al. Assessment of probiotics supplementation via feed or water on the growth performance, intestinal morphology and microbiota of chickens after experimental infection with Eimeria acervuline, Eimeria maxima y Eimeria tenella. Avian Pathology 2014;43(3):209-16.; Hussein et al., 2020). Elhassan et al., (2018Elhassan MMO, Ali AM, Blanch A, Kehlet AB, Madekurozwa MC. Morphological responses of the small intestine of broiler chicks to dietary supplementation with a probiotic, acidifiers, and their combination. Journal Applied Poultry Research 2018;28:108-17.) found that the use of B. subtilis in chickens improved mucosal integrity in the duodenum, reporting an increase in villi height, as well as in the percentage of intact villi and a reduction of somatostatin immunoreactive cells. When compared with the use of an acidifier, it showed better results for jejunum and ileum. For the specific case of bacteriophages, there are data confirming that an increase in villi height is possible, in duodenum and jejunum, as shown by Kim et al. (2017Kim JS, Hosseindoust A, Lee SH, Choi YH, Kim MJ, Lee JH, et al. Bacteriophage cocktail and multi-strain probiotics in the feed for weanling pigs:effects on intestine morphology and targeted intestinal coliforms and Clostridium. Animal 2017;11(1):45-53.) in weaned piglets and that it was possible to verify it in the present investigation, at least for duodenum. When analyzing the histological score based on epithelial changes and inflammatory cell infiltration of the lamina propria, the results of the research may be associated with a low-grade inflammation status, since from a total score of 18, maximum values of 10 were reached in the duodenum, with a higher score in the broiler chicken fed additives. The above, because of an increase in epithelial changes and inflammatory cell infiltration, which positively affected intestinal integrity, obtaining a better histometry of intestinal villi, which contributed to intestinal health. In contrast, Ghazanfari et al. (2015), when supplementing broiler diets with antibiotic and coriander essential oil, reported an increase in villus height and crypt depth, but at the same time, a decrease in epithelial layer thickness and number of goblet cells in the villi, which shows that epithelial cell hyperplasia plays a dynamic role in intestinal integrity and functionality. Cardinal et al. (2019) in their evaluation of intestinal health, recorded the best productive performance associated with a lower histological score, although the differences were only observed in three histological measurements; decrease in lamina propria thickness, epithelial thickness and enterocyte proliferation, without changes in goblet cells and inflammatory infiltration. Intestinal changes of this type were also reported by Hassan et al. (2014Hassan HMA, Youssef AW, El-Daly EF, Abd El-Azeem NA, Hassan ER, Mohamed MA. Performance, caecum bacterial count and ileum histology of broilers fed different direct-fed microbials. Asian Journal of Poultry Science 2014;8(4):106-14.) who indicated that the use of probiotics favored a better performance due to the increase in villi height and size and depth of the crypts, as well as an increased amount of goblet cells in the epithelial layer of the crypts, revealing an active hyperplasia in the villi and crypts of Lieberkühn, which is comparable to what was obtained in the present investigation. In some cases, there are reports that the use of B. subtilis can induce epithelial hyperplasia and moderate metaplasia of the intestinal epithelium into goblet cells, registering intestinal epithelium regeneration (Hussein et al., 2020),which can be compared with the results of current experiment suggesting that the goblet cell hyperplasia and histometry of the villi in the gut, favored intestinal functionality and performance, as well as the treatment with bacteriophages with a higher ratio of goblet cells per 100 epithelial cells also improved productive performance. It is known that this hyperplasia of goblet cells and mucus production can be induced by beneficial bacteria, as demonstrated by Huang et al. (2019Huang L, Luo L, Zhang Y, Wang Z, Xia Z. Effects of the dietary probiotic, Enterococcus faecium NCIMB11181, on the intestinal barrier and system immune status in Escherichia coli O78-challenged broiler chickens. Probiotics and Antimicrobial Proteins 2019;11(3):946-56.), who reported an improvement in the relative mRNA expression of proteins that compose tight junctions, claudin and mucin 2 when using E. faecium in chickens challenged with E. coli, whereas a reduction in E. coli counts was obtained from the third day post-infection. In the evaluation of the content of enterobacteria in the ceca, chickens that received diets supplemented with bacteriophages and bacitracin showed an increase in E. coli without changes in the expression of the other bacteria at 49 days of age. Engberg et al. (2000Engberg RM, Hedemann MS, Leser TD, Jensen BB. Effect of Zinc Bacitracin and Salinomycin on intestinal microflora and performance of broilers. Poultry Science 2000;79:1311-9.) indicated that bacitracin can decrease the population of C. perfringens and L. salivarius, although it didn’t happen in this study. Respecting bacteriophages, Kim et al. (2017), observed that when they were added to piglets, a decrease in colonization by coliforms and Clostridium spp. was observed, as well as an increase in the population of Lactobacillus spp., different from what was observed in this study. Lactobacillus salivarius was found higher than the control group, this occurred when symbiotic was added to the diet, although no statistical difference was recorded. It is noteworthy that this symbiotic does contain L. salivarius as probiotic bacteria, and it was the only one in which a clear tendency was found in its increase. Something that is important to mention is that there was an under expression of L. salivarius in the ceca of the chickens treated with B. subtilis, and that according to previous studies it is known that this probiotic bacterium usually stimulates the presence of bacteria of the genus Lactobacillus, especially L. reuteri, because it produces subtilisin and catalase that facilitate its growth (Al-Khalaifah et al., 2018), and therefore can stimulate a change in microbial composition and diversity in broilers by increasing beneficial microorganisms, contributing to protection against Salmonella infection (Oh et al., 2017Oh JK, Pajarillo EAB, CHae JP, Kim IH, Yang DS, Kang Dae-Kyung. Effects of Bacillus subtilis CSL2 on the composition and functional diversity of the faecal microbiota of broiler chickens challenged with Salmonella Gallinarum. Journal of Animal Science and Biotechnology 2017;8(1):1-9.). The relationship between B. subtilis and L. reuteri could not be ascertained, so it is suggested to look for L. reuteri in the ceca in a next experiment. Also, the addition of probiotics such as L. reuteri and Bifidobacterium is related to the stimulation in the production of MUC2 and the increase in the thickness of the mucus layer (Paone & Cani, 2020Paone P, Cani PD. Mucus barrier, mucins and gut microbiota: the expected slimy partners? Gut 2020;69:2232-43.) which may explain what was obtained in the present study, that, although a greater expression of L. salivarius was not demonstrated, there was an increase in the hyperplasia of goblet cells in the duodenum with the use of eubiotics. In general, what has been seen so far has shown that the use of multiespecie probiotics or symbiotics help to increase the population of Lactobacillus spp. in, ileum or ceca, as well as to decrease the population of bacteria such as E. coli and sometimes C. perfringens (Mountzouris et al., 2010; Giannenas et al., 2014; Dibaji et al., 2014Dibaji SM, Seidavi A, Asadpour L, Silva FM da. Effect of a symbiotic on the intestinal microflora of chickens. Journal Applied Poultry Research 2014;23:1-6.). The genus Lactobacillus are an effective tool to positively alter the microbiome, as quoted verbatim by Gao et al. (2017), who proved, that the maturation of the gut microbiome, was greatly accelerated with the use of a strain of L. plantarum, increasing the population of Lactobacillus spp., while the maturation was delayed when antibiotic were used, however, the productivity using the antibiotic was still possible, certainly because the antibiotic promoted the growth of beneficial bacteria. According to Tarradas et al. (2020Tarradas J, Tous N, Esteve-Garcia E, Brufau AJ. The control of intestinal inflammation:A major objective in the research of probiotic strains as alternatives to antibiotic growth promoter in poultry. Microorganisms 2020;8(2):148-64.), it has been seen that in some cases, the mechanisms of action of probiotics, such as L. salivarius and B. animalis, change in the presence of pathogens, which implies that the same changes may not always be observed, so in particular situations they will act as pro-inflammatory or as anti-inflammatory, being considered immuno-modulators, that is why Adedokun & Olojede (2019Adedokun SA, Olojede OC. Optimizing gastrointestinal integrity in poultry: The role of nutrients and feed additives. Frontiers in Veterinary Science 2019:5(348):1-11.) do not recommend the use of these products in healthy birds, without a minimum of intestinal stress or challenge. In the case of bacteriophages, some authors claim that they can also modify the microbiome, even with the presence of temperate bacteriophages that do not lyse bacteria (De Paepe et al., 2014). Upadhaya et al. (2021) using bacteriophages as alternative additives to APCs, indicated that the relative abundance of L. salivarius increased from 18.86 % (control group) to 37.80 and 40.13% with bacteriophages at 0.5 and 1% respectively in ileal mucosa of broilers at 35 days of age. It should be added that the use of bacteriophages, as commercial additives, requires more information to prove their mode of action and their effectiveness in the productive scale (Clavijo & Vives, 2018Clavijo V, Vives FMJ. The gastrointestinal microbiome and its association with the control of pathogens in broiler chicken production: a review. Poultry Science 2018;97:1006-21.). Finally, the findings observed in the present study suggest that there was a physiological inflammation, which according to Cardoso et al. (2020Cardoso DPG, Farnell M, Farnell Y, Kogut MH. Dietary factors as triggers of low-grade chronic intestinal inflammation in poultry. Microorganisms 2020;8(139):1-10.), can be defined as a controlled intestinal inflammatory response, in which only positive intestinal histological changes were observed, evident in the duodenum by the use of the antibiotic and eubiotics, together with the optimal growth of intestinal villi, which can be interpreted as described by Kim & Ho (2010), as a balance and dynamic interactions between intestinal epithelial cells, increased digestive capacity and immunomodulation that is associated with the integrity and maintenance of the intestinal mucosa, promoted by the adequate colonization of beneficial bacteria, which could only be observed as a trend of colonization by L. salivarius when using the symbiotic.

CONCLUSION

The addition of the antibiotic bacitracin and eubiotics used in the present study; bacteriophages, probiotic (B. subtilis) and the symbiotic (L. salivarius, L. reuteri, E. faecium, B. animalis, P. acidolactici and inulin), in broiler diets, improved the productive performance at 49 days of age. This was congruent with what was reported in the histometric variables of the villi, as well as the histological changes that showed controlled inflammation, fundamental for the maintenance of intestinal integrity. The effect of bacteriophages showed that they promote benefits at the intestinal level as well as probiotics and symbiotics, however, it is important to continue investigating the mechanisms of action that make this possible. Considering the variability in the results of enterobacterial counts, it is recommended to contemplate the microbiome in each study, since, as a dynamic system, more research is required to understand the relationship of eubiosis with productivity. For the time being, the use of eubiotic additives, including bacteriophages, indicated that they are an alternative to the use of the growth-promoting antibiotic Bacitracin.

ACKNOWLEDGMENTS

The authors would like to acknowledge the financial support of CTCBIO DE MÉXICO S. DE R.L. DE C.V. and Elanco Salud Animal, S.A. de C.V.

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Cardinal KM, Lemos de MM, Andretta I, Schirmann GD, Belote, BL, Barrios MA, et al. Growth performance and intestinal health of broilers fed a standar or low-protein diet with the addition of a protease. Revista Brasileira de Zootecnia 2019;48.
Cardoso DPG, Farnell M, Farnell Y, Kogut MH. Dietary factors as triggers of low-grade chronic intestinal inflammation in poultry. Microorganisms 2020;8(139):1-10.
Clavijo V, Vives FMJ. The gastrointestinal microbiome and its association with the control of pathogens in broiler chicken production: a review. Poultry Science 2018;97:1006-21.
Dibaji SM, Seidavi A, Asadpour L, Silva FM da. Effect of a symbiotic on the intestinal microflora of chickens. Journal Applied Poultry Research 2014;23:1-6.
Donato P di, Pennink D, Pietra M, Cipone M, Diana A. Ultrasonographic measurement of the relative thickness of intestinal wall layers in clinically healthy cats. Journal of Feline Medicine and Surgery 2013;16(4):333-9.
Engberg RM, Hedemann MS, Leser TD, Jensen BB. Effect of Zinc Bacitracin and Salinomycin on intestinal microflora and performance of broilers. Poultry Science 2000;79:1311-9.
Elhassan MMO, Ali AM, Blanch A, Kehlet AB, Madekurozwa MC. Morphological responses of the small intestine of broiler chicks to dietary supplementation with a probiotic, acidifiers, and their combination. Journal Applied Poultry Research 2018;28:108-17.
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Huang L, Luo L, Zhang Y, Wang Z, Xia Z. Effects of the dietary probiotic, Enterococcus faecium NCIMB11181, on the intestinal barrier and system immune status in Escherichia coli O78-challenged broiler chickens. Probiotics and Antimicrobial Proteins 2019;11(3):946-56.
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Kogut MH, Genovese KJ, Swaggerty CL, He H, Broom L. Inflammatory phenotypes in the intestine of poultry:not all inflammation is created equal. Poultry Science 2018;97(7):2339-46
Kraieski AL, Hayashi RM, Sanches A, Almeida GC, Santin E. Effecy of aflatoxin experimental ingestion and Eimeira vaccine challenges on intestinal histopathology and immune cellular dynamic of broilers:applying an Intestinal Health Index. Poultry Science 2017;(96):1078-87.
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Oh JK, Pajarillo EAB, CHae JP, Kim IH, Yang DS, Kang Dae-Kyung. Effects of Bacillus subtilis CSL2 on the composition and functional diversity of the faecal microbiota of broiler chickens challenged with Salmonella Gallinarum. Journal of Animal Science and Biotechnology 2017;8(1):1-9.
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Paone P, Cani PD. Mucus barrier, mucins and gut microbiota: the expected slimy partners? Gut 2020;69:2232-43.
Ravindran V, Wu YB, Thomas DG, Henri Morel PC. Influence of whole wheat feeding on the development of gastrointestinal tract and performance of broiler chickens. Australian Journal of Agricultural Research 2006;57:21-6.
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Publication Dates

Publication in this collection
20 Feb 2023
Date of issue
2023

History

Received
06 Dec 2021
Accepted
01 Nov 2022

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

[1] Adedokun SA, Olojede OC. Optimizing gastrointestinal integrity in poultry: The role of nutrients and feed additives. Frontiers in Veterinary Science 2019:5(348):1-11.

[2] Al-Khalaifah HS. Benefits of probiotics and/or prebiotics for antibiotic-reduced poultry. Poultry Science 2018;97(11):1807-15.

[3] Alshamy Z, Richardson KC, Hunigen H, Hafez HH, Plendl J, Al Masri S. Comparison of the gastrointestinal tract of a dual-purpose to a broiler chicken line: A qualitative and quantitative macroscopic and microscopic study. PLoS One 2018;13(10):e0204921.

[4] Apajalahti J, Vienola K. Interaction between chicken intestinal microbiota and protein digestión. Feed Science and Technology 2016;221:323-30.

[5] BagajaiY, Klieve A, Dart P, Wayne B. Probiotics in animal nutrition: Production, impact, and regulation. Rome: FAO Animal Production and Health; 2016.

[6] Caly DL, D'Inca R, Auclair E, Drider D. Alternatives to antibiotics to prevent necrotic enteritis in broiler chickens:A microbiologist's perspective. Frontier in Microbiology 2015;6:1-12.

[7] Cardinal KM, Lemos de MM, Andretta I, Schirmann GD, Belote, BL, Barrios MA, et al. Growth performance and intestinal health of broilers fed a standar or low-protein diet with the addition of a protease. Revista Brasileira de Zootecnia 2019;48.

[8] Cardoso DPG, Farnell M, Farnell Y, Kogut MH. Dietary factors as triggers of low-grade chronic intestinal inflammation in poultry. Microorganisms 2020;8(139):1-10.

[9] Clavijo V, Vives FMJ. The gastrointestinal microbiome and its association with the control of pathogens in broiler chicken production: a review. Poultry Science 2018;97:1006-21.

[10] Dibaji SM, Seidavi A, Asadpour L, Silva FM da. Effect of a symbiotic on the intestinal microflora of chickens. Journal Applied Poultry Research 2014;23:1-6.

[11] Donato P di, Pennink D, Pietra M, Cipone M, Diana A. Ultrasonographic measurement of the relative thickness of intestinal wall layers in clinically healthy cats. Journal of Feline Medicine and Surgery 2013;16(4):333-9.

[12] Engberg RM, Hedemann MS, Leser TD, Jensen BB. Effect of Zinc Bacitracin and Salinomycin on intestinal microflora and performance of broilers. Poultry Science 2000;79:1311-9.

[13] Elhassan MMO, Ali AM, Blanch A, Kehlet AB, Madekurozwa MC. Morphological responses of the small intestine of broiler chicks to dietary supplementation with a probiotic, acidifiers, and their combination. Journal Applied Poultry Research 2018;28:108-17.

[14] Faseleh JM, Shokryazdan P, Idrus Z, Ebrahimi R, Liang JB. In Ovo and dietary administration of oligosaccharides extracted from palm kernel cake influence general health of pre- and neonatal broiler chicks. PLoS One 2017;12(9):e0184553.

[15] Gao P, Ma C, Sun Z, Wang L, Huang S, Su X, et al. Feed-additive probiotics accelerate yet antibiotics delay intestinal microbiota maturation in broiler chicken. Microbiome 2017;5:91.

[16] Ghazanfari SI, Mohammadi ZI, Adib Moradi MII. Effects of Coriander Essential Oil on the Performance, Blood Characteristics, Intestinal Microbiota and Histological of Broilers. Brazilian Journal of Poultry Science 2015;17(4):419- 26.

[17] Giannenas I, Tsalie E, Triantafillou E, Hessenberger S, Teichmann K, Mohnl M, et al. Assessment of probiotics supplementation via feed or water on the growth performance, intestinal morphology and microbiota of chickens after experimental infection with Eimeria acervuline, Eimeria maxima y Eimeria tenella. Avian Pathology 2014;43(3):209-16.

[18] Hassan HMA, Youssef AW, El-Daly EF, Abd El-Azeem NA, Hassan ER, Mohamed MA. Performance, caecum bacterial count and ileum histology of broilers fed different direct-fed microbials. Asian Journal of Poultry Science 2014;8(4):106-14.

[19] Huang L, Luo L, Zhang Y, Wang Z, Xia Z. Effects of the dietary probiotic, Enterococcus faecium NCIMB11181, on the intestinal barrier and system immune status in Escherichia coli O78-challenged broiler chickens. Probiotics and Antimicrobial Proteins 2019;11(3):946-56.

[20] Hussein EOS, Ahmed SH, Abudabos AM, Aljumaah MR, Alkhulaifi MM, Nassan MA, et al. Effect of antibiotic, phytobiotic and probiotic supplementation on growth, blood indices and intestine health in broiler chicks challenged with Clostridium perfringens. Animals 2020;10:507.

[21] Iebba V, Totino V, Gagliardi A, Santangelo F, Cacciotti F, Trancassini M, et al. Eubiosis and dysbiosis:the two sides of the microbiota. New Microbiologica 2016;39:1-12.

[22] Kim YS, Ho SB. Intestinal goblet cells and mucins in health and disease:recent insights and progress. Current Gastroenterology Reports 2010;12(5):319-30.

[23] Kim JS, Hosseindoust A, Lee SH, Choi YH, Kim MJ, Lee JH, et al. Bacteriophage cocktail and multi-strain probiotics in the feed for weanling pigs:effects on intestine morphology and targeted intestinal coliforms and Clostridium. Animal 2017;11(1):45-53.

[24] Kogut MH, Genovese KJ, Swaggerty CL, He H, Broom L. Inflammatory phenotypes in the intestine of poultry:not all inflammation is created equal. Poultry Science 2018;97(7):2339-46

[25] Kraieski AL, Hayashi RM, Sanches A, Almeida GC, Santin E. Effecy of aflatoxin experimental ingestion and Eimeira vaccine challenges on intestinal histopathology and immune cellular dynamic of broilers:applying an Intestinal Health Index. Poultry Science 2017;(96):1078-87.

[26] Laudadio V, Passantino L, Perillo A, Lopresti G, Passantino A. Productive performance and histological features of intestinal mucosa of broiler chickens fed different dietary protein levels. Poultry Science 2012;91:265-70.

[27] Livak KJ, Schmittgen TD. Analysis of relative gene expression data using real-time quantitative PCR and the 22DDCT Methods 2001;25(4):402-8.

[28] M'Sadeq SA, Wu S, Swick RA, Choct M. Towards the control of necrotic enteritis in broiler chickens with in-feed antibiotics phasing-out worldwide. Animal Nutrition 2015;1:1-11.

[29] Marcovik R, Sefer D, Krstic M, Petrujkic B. Effect of different growth promoters on broiler performance and gut morphology. Archivos de Medicine Veterinaria 2009;41:163-9.

[30] Mountzouris KC, Dalaka E, Palamidi I, Paraskeuas V, Demey V, Theodoropoulos G, et al. Evaluation of yeast dietary supplementation in broilers challenged or not with Salmonella on growth performance, cecal microbiota composition and Salmonella in ceca, cloacae and carcass skin. Poultry Science 2015;94:2445-55.

[31] Oh JK, Pajarillo EAB, CHae JP, Kim IH, Yang DS, Kang Dae-Kyung. Effects of Bacillus subtilis CSL2 on the composition and functional diversity of the faecal microbiota of broiler chickens challenged with Salmonella Gallinarum. Journal of Animal Science and Biotechnology 2017;8(1):1-9.

[32] Oviedo-Rondón, EO. Holistic view of intestinal health in poultry. Animal Feed Science Technology 2019;250:1-8.

[33] Paepe M de, Leclerc M, Tinsley CR, Petit Marie-Agnes. Bacteriophages: an underestimated role in human and animal health?. Frontiers in Cellular Infection Microbiology 2014;4(39):1-11.

[34] Paone P, Cani PD. Mucus barrier, mucins and gut microbiota: the expected slimy partners? Gut 2020;69:2232-43.

[35] Ravindran V, Wu YB, Thomas DG, Henri Morel PC. Influence of whole wheat feeding on the development of gastrointestinal tract and performance of broiler chickens. Australian Journal of Agricultural Research 2006;57:21-6.

[36] Riahi I, Marquis V, Ramos AJ, Brufau J, Esteve-Garcia E, Pérez-Vendrell VAM. Effects of deoxynivalenol-contaminated diets on productive, morphological, and physiological indicators in broiler chickens. Animals 2020;9(301):1-11.

[37] Roberts T, Wilson J, Guthrie A, Cookson K, Vancraeynest D, Shaeffer R, et al. New issues and science in broiler chicken intestinal health:Emerging technology and alternative interventions. Journal Applied Poultry Research 2015;24:257-66.

[38] Selaledi LA, Hassan ZM, Manyelo TG, Mabalebele M. The current status of the alternative use to antibiotics in poultry production:an African perspective. Antibiotics 2020;9(9):594.

[39] Sethiya, NK. Review on natural growth promoters available for improving gut health of poultry:An alternative to antibiotic growth promoters. Asian Journal of Poultry Science 2016;10(1):1-29.

[40] Setiawan, H, Jingga, ME, Saragih, HT. The effect of cashew leaf extract on small intestine morphology and growth performance of Jawa Super Chicken. Veterinary World 2018;11(8):1047-54.

[41] Smyth JA. Pathology and diagnosis of necrotic enteritis:is it clear-cut?. Avian Pathology 2016;45(3):282-7.

[42] Sun Q, Shang Y, She R, Jiang T, Wang D, Ding Y, et al. Detection of intestinal intraepithelial lymphocytes, goblet cells and secretory IgA in the intestinal mucosa during Newcastle disease virus infection. Avian Pathology 2013;42(6):541-5.

[43] Tan J, Applegate TJ, Liu S, Guo Y, Eicher SD. Supplemental dietary L-arginine attenuates intestinal mucosal disruption during a coccidial vaccine challenge in broiler chickens. British Journal of Nutrition 2014, 112:1098-109.

[44] Tarradas J, Tous N, Esteve-Garcia E, Brufau AJ. The control of intestinal inflammation:A major objective in the research of probiotic strains as alternatives to antibiotic growth promoter in poultry. Microorganisms 2020;8(2):148-64.

[45] Teirlynck E, Gussem MDE, Dewulf J, Haesebrouck F, Ducatelle R, Van Immerseel F. Morphometric evaluation of "dysbacteriosis" in broilers. Avian Pathology 2011;40(2):139-44.

[46] Torok VA, Dyson C, McKay A, Open-Keller K. Quantitative molecular assays for evaluating changes in broiler gut microbiota linked with diet and performance. Animal Production Science 2013;53:1260-8.

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	Initiation	Growing	Finishing
	1 - 21 d	22 - 35 d	36 - 49 d
Ingredient	21%	19%	17%
Sorghum	583.0	624.15	675.31
Soybeanmeal	328.7	277.50	226.80
Vegetable oil	35.08	45.71	48.23
Ortophosphate	18.79	16.61	15.41
Calcium carbonate	16.79	14.01	13.47
Salt	4.350	3.840	3.860
DL-Methionine 80%	4.130	4.005	3.610
L-Lysine HCl 78%	4.110	3.460	2.940
L-Threonine	1.900	1.560	1.220
Cholinechloride + vit/min*	2.500	2.500	2.500
Nicarbazin	0.500	0	0
Salinomicin	0	0.500	0.500
Antioxidant	0.150	0.150	0.150
Pigment	0	6.00	6.00
Total (kg)	1000	1000	1000
Nutrientcomposition
ME, Kcal/kg	2988	3176	3176
Protein %	21.00	18.00	17.00
Lysine %	1.22	1.04	0.99
Met+Cis %	0.91	0.82	0.78
Threonine %	0.93	0.72	0.71
Tryptophan %	0.27	0.23	0.22
Arginine %	1.34	1.13	1.03
Calcium %	1.05	0.90	0.85
Phosphorus disp.. %	0.50	0.45	0.42
Na %	0.22	0.19	0.18
Cl %	0.20	0.20	0.20

Microorganism	Primer sequence 5’-3’	Reference
Clostridium perfringens	F-TTACCTTTGCTGCATAATCCC R-ATAGATACTCCATATCATCCTGCT	Whelan et al., 2019Whelan RA, Doranalli K, Rinttila T, Vienola K, Jurgens G, Apajalahti J. The impact of Bacillus subtilis DSM 32315 on the pathology, performance, and intestinal microbiome of broiler chickens in a necrotic enteritis challenge. Poultry Science 2019;98(1):3450-63.
Escherichia coli	F-GTGTGATATCTACCCGCTTCGC R-AGAACGCTTTGTGGTTAATCAGGA	Faseleh et al, 2017Faseleh JM, Shokryazdan P, Idrus Z, Ebrahimi R, Liang JB. In Ovo and dietary administration of oligosaccharides extracted from palm kernel cake influence general health of pre- and neonatal broiler chicks. PLoS One 2017;12(9):e0184553.
Lactobacillus salivarius	F-GATCGCATGATCCTTAGATGAA R-GCCGATCAACCTCTCAGTTC	Torok et al., 2013Torok VA, Dyson C, McKay A, Open-Keller K. Quantitative molecular assays for evaluating changes in broiler gut microbiota linked with diet and performance. Animal Production Science 2013;53:1260-8.

Treatment	Feed intake (g)	Weight gain (g)	FCR³ (g/g)	Mortality (%)
Control	5352	2902b	1.844b	5.5
Bacteriophages	5199	2993ab	1.737a	4.0
Antibiotic	5318	3054a	1.742a	7.0
Probiotic	5303	3059a	1.734a	9.8
Symbiotic	5273	3005a	1.755a	4.5
P¹	0.387	0.001	0.0001	0.762
SEM²	5289±25	3003±14	1.762±0.01	6.1±0.92

Treatment	Carcass %	Breast muscle³ %	Thighs+Drumsticks %	Liver %	Abdominal fat %	Yelowness⁴
Control	72.5b	19.3	22.6	1.7	0.52	44.1
Bacteriophages	73.2ab	19.2	22.1	1.7	0.45	45.4
Antibiotic	74.0a	19.0	22.9	1.8	0.51	44.3
Probiotic	73.5ab	19.2	22.8	1.8	0.44	44.6
Symbiotic	72.8ab	18.8	22.8	1.9	0.64	45.2
P¹	0.020	0.371	0.916	0.174	0.168	0.656
SEM²	73.2±0.15	19.1±0.1	22.7±0.1	1.8±0.02	0.51±0.02	44.7±0.3

	Control	Bacteriophages	Antibiotic	Probiotic	Symbiotic	P³	SEM⁴
Villus height, µm	1965c	2122bc	2032bc	2166b	2441a	0.001	2145±28
Villus width, µm	209b	255a	267a	275a	274a	0.001	256±5.7
Crypt depth, µm	266ab	234b	260b	264ab	303a	0.001	266±5
Villus Surface Area, mm²	0.410c	0.536b	0.545b	0.596ab	0.677a	0.001	.553±.016
Villus: Crypt ratio¹	7.6b	9.1a	7.9ab	8.3ab	8.1ab	0.021	8.2±0.1
GC²:100 epithelial cells ratio	21.2ab	24.3a	19.5b	19.1b	22.8ab	0.001	21.3±0.5

Brasil

Brasil

Performance, Gut Integrity, Enterobacteria Content in Ceca of Broiler Fed Different Eubiotic Additives

ABSTRACT

INTRODUCTION

MATERIALS AND METHODS

Experimental design and diets

Performance and Carcass parameters

Histological preparation

Intestinal morphometry measurement

Intestinal histological changes

Protocol for DNA extraction in cecal content

Real-time PCR procedure

Statistical analysis

RESULTS

Productive performance and carcass characteristics

Intestinal morphology and histometry

Intestinal histological changes

Relative expression of enterobacteria

DISCUSSION

CONCLUSION

ACKNOWLEDGMENTS

REFERENCES

Publication Dates

History