Growth performances and meat yield characteristics of commercial cockerels fed antibiotic and probiotic.

OBJECTIVE: The current research aimed at investigating growth performances and meat yield characteristics of commercial cockerels supplemented with antibiotics and probiotics to the diet.
MATERIALS AND METHODS: A total of 1,350 commercial cockerels (ISA Brown) were indiscriminately distributed to 3 treatment groups, each having three replications of 150-day-old chicks based on completely randomized design. The basal diet was treated as the control, while the experimental groups receiving Enrofloxacin 1 gm/kg and Protexin 1 gm/kg feed were considered as antibiotic and probiotic groups, respectively. Bodyweight, feed intake (FI), feed conversion ratio (FCR), and other relevant characteristics were recorded weekly until 49 days of trial. In the end, similar number (10) of birds from each replicate group were slaughtered to determine the carcass characteristics.
RESULTS: Significantly, better results were found in the overall growth performances of the cockerels in the probiotic-fed treatment group. Highly significant differences were also found in live bodyweight, weight gain, daily gain, FI, FCR, survivability, dressing percentage, abdominal fat, breast meat, drumstick, and thigh weight in the probiotic-fed treatment group compared to the others.
CONCLUSION: The results of the present study indicate that the inclusion of dietary probiotics has a superior performance to antibiotics and may have the potentiality to be used as an alternative growth enhancer in the diet of cockerels. Copyright: © Journal of Advanced Veterinary and Animal Research.

Introduction

Cockerel farming has become popular in Bangladesh in recent years due to a comparatively low chick price than that of layers or broilers. Cockerel meat has a high demand for various social and cultural occasions like marriage ceremony, anniversary programs, and reunions. It has an enormous daily demand in restaurants than that of broiler meat. The sensory characteristics like taste, flavor, juiciness, and tenderness are almost close to the indigenous chicken. Less abdominal fat, lower disease susceptibility, mortality, and morbidity are also the prime reasons as to why farmers have been showing more interest in cockerel farming in the country [1]. People usually rear broilers or layer chickens with the supplementation of feed additives like an antibiotic, prebiotic, probiotic, symbiotic, or other available commercial additives. Antibiotic and probiotic have the well-recognized capability of killing or inhibiting the development of disease-producing bacteria or microorganisms that are present in the chicken body and thus improve growth performances [2, 3].

However, the use of antibiotics as a promoter in animal and poultry feed has been barred by concerned organizations globally [4]. Researchers are suggesting probiotics as an alternative to antibiotics because they not only interrupt the performance of pathogens in the intestines but also have a potential role in increasing the bioavailability of minerals that helps in the improvement of growth and effective utilization of feeds [5]. The prevalence of diseases also reduces with the judicial application of probiotics. It also promotes the immune system and influences the morphology and function of intestines [6]. But the use of probiotics and antibiotics in rearing cockerels is still unknown. Thus, the present study was undertaken to compare and evaluate the growth performances and meat yield characteristics of commercial cockerel (ISA Brown) fed antibiotic and probiotic as feed supplementation.

Material and Methods

Ethical approval

Animal Welfare and Experimentation Ethics Committee of Bangladesh Agricultural University gave formal approval for the experiment upon birds [Reference no.: AWEEC/BAU/2017(22)].

Experimental site

This study was carried out at a farm of a local farmer of Hobirbari Union at Valuka Upazila, Mymensingh district of Bangladesh from March to April 2017.

Management of birds and design of experiment

A total of 1,350 commercial cockerel (ISA Brown), 150-day-old chicks (DOCs) having average bodyweight (BW) of about 36 gm, were taken to conduct a 49-day experiment. The ISA Brown species was chosen for the experiment because the cockerels of this strain are very popular among farmers, which might be due to its ease of availability and comparatively lower price. The DOCs were indiscriminately allocated into three groups; group-1 was considered as the control, while group-2 and group-3 were considered as antibiotic and probiotic-treated groups, respectively, having around 450 chicks per group. Each treatment group was again divided into three replications (150 chicks/replication). As no feeding standard was establish for the cockerels, considering the purpose of the current study, the basal ration was formulated as per National Research Council standard for broiler chickens [7]. The birds were provided with different forms of feed, as presented in Table 1, throughout the experiment. In group-2, commercial antibiotic (Enrofloxacin) was administrated at 1 gm/kg feed. At the same time, group-3 was supplemented with 1 gm of a commercial probiotic mixture (Protexin) in the same amount of feed for the entire period of the experiment. Enrofloxacin and Protexin were chosen in the present trial because the majority of the farmers were using these chemicals in the study location due to their availability. The birds in all the three groups received identical management, and feed and safe drinking water were supplied ad libitum basis. Newcastle, Fowl Pox, and Gumboro disease vaccines were administered to the birds.

Table 1.

Composition of experimental diets.

Nutrients/parameters	Starter (0–21 days)	Grower(22–35 days)	Finisher (36–49 days)
Moisture (%)	11	11	11
CP (%)	21	20	19
Ash (%)	4.5	4.5	5
Ca (%)	1.00	0.95	0.90
Ava. P (%)	0.45	0.45	0.42
Methionine (%)	0.48	0.45	0.42
Lysine (%)	1.15	1.05	1.00
ME (kcal/kg)	2950	3000	3050
Feed type	Mash	Crumble	Pellet

Measurements

Individual BW, gain, feed conversion ratio (FCR), and pen-wise weekly feed intake (FI) were recorded until the end of the experiment. Mortality was adjusted from time to time to calculate the FCR. A total of 30 birds (10 from each replicate) from each treatment group were slaughtered, applying the Halal method, to determine the meat yield characteristics.

Statistical analysis

The Statistical Package for the Social Sciences version 20.0 [8] was used to analyze all the recorded data. For significant differences among groups, a p-value of < 0.05 was considered and Duncan’s Multiple Range Test [9] was used to compare the means.

Results

Overall growth performance

In the experiment conducted, the overall performances (Table 2) were found to be better in the probiotic-treated group than that in the antibiotic and control groups. The weights of the DOCs were very similar (p > 0.05) in all the three groups. Live bodyweight (LBW), weight gain (WG), average daily gain (ADG), and survivability were highly significant (p < 0.0001). At the same time, significant differences were also found in FCR (p < 0.001) and FI (p < 0.05) of cockerels.

Table 2.

Growth performance of cockerels in different dietary treatments.

Parameters	Treatments			p-value
	Control	Antibiotic	Probiotic
Initial bodyweight (gm)	36.33 ± 0.33	36.67±0.67	36.00±0.58	0.702
Final bodyweight (gm)	704.33 ± 6.36c	778.0±5.77b	820.0±4.62a	0.0001
Body WG (gm/bird)	668.33 ± 6.36c	742.00±5.77b	784.00±4.61a	0.0001
Total FI (gm/bird)	1,700.84 ± 10.66a	1,746.18±19.34b	1,614.88±39.89a	0.032
FCR	2.54 ± 0.04c	2.35±0.04b	2.06±0.06a	0.001
ADG (gm/day)	13.63 ± 0.13c	15.14±0.12b	16.00±0.09a	0.0001
Survivability (%)	95.71 ± 0.23b	97.76 ± 0.23a	98.44±0.22a	0.0001

Means with different superscripts in the same row are differ significantly; Values indicate mean ± SE; SE means Standard Errors.

Live bodyweight and gain

The results of the current research, shown in Table 2, indicated highly significant (p < 0.0001) LBW, WG, and ADG in the probiotic-treated group compared to the antibiotic and control groups. The ADG pattern of birds showed (Fig. 1) that the growth rate of the probiotic-treated group was almost higher throughout the experimental period compared to the other two groups.

Figure 1.

ADG (gm/bird/day) of the cockerels at different ages of the experiment.

Feed intake

The results of the present study revealed that cockerels from the probiotic-treated group consumed a comparatively lower (p < 0.05) amount of feed (Table 2) than those in the other two groups. The highest amount of FI was observed in the antibiotic-treated group in the experiment. The weekly FI patterns of the birds (Fig. 2) represented that it was almost similar during the starting and termination period of the experiment in all three dietary groups, while a lower intake was observed in probiotic-fed birds from the second to the sixth week of age.

Figure 2.

Average FI (gm/bird/week) of cockerels from beginning to end of the experiment.

Feed conversion ratio

While comparing cockerel’s FCR, a significant difference (p < 0.001) was observed in probiotic-fed birds of the present trial, followed by the antibiotic and control groups (Table 2). The weekly FCR patterns of birds (Fig. 3) indicated that it was better in the probiotic dietary treatment group from inception to termination of the experiment. At the same time, a slight fluctuation was observed in the antibiotic group.

Figure 3.

Average FCR of cockerels at different ages during the experimental period.

Survivability

The survivability percentage of cockerels was found to be significantly higher (p < 0.001). The results are presented in Table 2. The mortality rate was comparatively higher in the control group, followed by the antibiotic- and probiotic-treated groups.

Carcass characteristics

The mean value of the meat yield characteristics of cockerels is shown in Table 3. High differences (p < 0.001) were found in the dressing percentage of the probiotic-fed group, followed by the antibiotic and control groups. Significant differences were also observed in blood, abdominal fat, breast meat, thigh and drumstick, gizzard, feather, skin, and heart weight among the three dietary treatment groups. But the weight of the liver, pancreas, spleen, and intestine were observed to be non-significant (p > 0.05) in all the three groups.

Table 3.

Mean value of meat yield characteristics of cockerels in different weeks.

Parameters	Treatments			p-value
	Control	Antibiotic	Probiotic
Dressing percentage (% BW)	50.10 ± 0.60c	51.30 ± 0.61b	54.0 ± 0.20a	0.0001
Blood weight (gm)	3.95 ± 0.05a	4.51 ± 0.01c	4.35 ± 0.03b	0.0001
Breast meat weight (gm)	10.52 ± 0.1a	10.22 ± 0.1b	10.73 ± 0.12a	0.003
Thigh+ Drumstick weight (gm)	17.05 ± 0.58c	17.83 ± 0.30b	18.80 ± 0.26a	0.006
Digestive tract weight (gm)	10.93 ± 0.31a	11.6 ± 0.07b	11.46 ± 0.06b	0.01
Skin weight (gm)	6.05 ± 0.06bc	5.98 ± 0.13a	6.26 ± 0.12c	0.044
Liver weight (gm)	2.13 ± 0.04	2.22 ± 0.03	2.17 ± 0.04	0.063
Heart weight (gm)	0.40 ± 0.04b	0.50 ± 0.02a	0.48 ± 0.04a	0.014
Gizzard weight (gm)	1.48 ± 0.02 a	1.4 ± 0.02 b	1.38 ± 0.03 b	0.004
Pancreas weight (gm)	0.21 ± 0.03	0.24 ± 0.03	0.22 ± 0.01	0.178
Spleen weight (gm)	0.13 ± 0.01	0.14 ± 0.01	0.13 ± 0.01	0.236
Abdominal fat weight (gm)	1.59 ± 0.05b	1.79 ± 0.05a	1.74 ± 0.05a	0.008
Intestinal weight (gm)	2.62 ± 0.03	2.58 ± 0.02	2.72 ± 0.11	0.096
Feather weight (gm)	9.46 ± 0.08c	8.52 ± 0.24a	9.0 ± 0.1b	0.001

BW means bodyweight,

means with different superscripts in the same row are differ significantly; Values indicates mean± SE; SE means Standard Errors.

Discussion

A group of researchers [6] reported improved WG, FI, and FCR in chickens fed with antibiotics. Many others [10] suggested probiotics for enhancing the performances of chickens as a replacement to the antibiotics. Final WG and FCR were found to be higher (p < 0.05) in birds feeding on probiotics than antibiotics [11]. A previous study [12] also reported that probiotic-fed chickens had better digestion, absorption, nutrients availability, and improved enzyme activities [13], which supports the results of the present study.

Although the authors found very limited research studies regarding feeding probiotics and antibiotics to cockerels or commercial egg-type male chickens, the current finding is in disagreement with a research team’s [14] outcomes, who found no significant difference in growth performance of Nigerian local white cockerels fed multi-strain probiotics. However, they found a similar ADG like the current study. Although a similar BWG and ADG has been reported in egg-type male growing chicken, no significant differences were reported between basal and low probiotics (1 gm/l) fed to crossbreds of Fayoumi and Rhode Island Red cockerels [15, 16]. Despite the few studies, the majority of the results stated that probiotics have a greater effect on BWG of the birds than that of antibiotic growth promoters [2,3,11,17-25]. This inconsistency might be due to the use of different strains of birds and a mixture of variable strains of bacteria in probiotic or antibiotic compositions added to the experimental diets. A higher growth rate in the probiotic supplemented group of the current research may be due to superior digestion, absorption, nutrients availability, and function of helpful enzymes.

The present research findings are in agreement with a previous study which reported less FI in probiotic-treated cockerel crossbreds [15], but differ from other reports [3,11,14,26], who have stated a higher significant FI (p < 0.05) in probiotic-fed broilers than that of the antibiotic and control groups. However, no influence of various probiotics on the FI of birds was reported in previous studies [25,27-30]. The variation of current research findings with past studies might be due to the differences in farming conditions, the strain of birds, types of probiotic strains, antibiotic mixture and variety of feed ingredients used to prepare experimental diets.

A research team [3] reported significantly better (p < 0.05) FCR feeding of probiotics to birds in comparison with the antibiotic and control groups, which supports the present findings. Experts [26] have also stated that supplementation of Saccharomyces cerevisiae, a probiotic to birds at three different levels (1, 1.5, and 2%), had improved FCR significantly. However, many previous studies found non-significant differences (p > 0.05) in FCR of low-level probiotic-treated cockerels (1 gm/l) [15] and antibiotic-treated broilers [10,30,31]. Variation of results in the current research might be because of the compensatory growth pattern of birds, the difference in the use of probiotics and antibiotic mixture, feeding, and management system of birds and geographical location.

Growth stimulants as feed additives have a positive effect on enhancing performance and improved production of meat [32], which supports the results of the present study. Studies have also revealed that growth enhancers had a positive influence on the performances of chicken [33]. But lower or non-significant differences in carcass yields, abdominal fat, breast and thigh weight fed antibiotic, probiotic, and symbiotic to birds was also reported [15,31,34]. Variation in the current findings with previous studies might be due to compensatory growth patterns of cockerels, varied environment, and management aspects involved during the experiment.

Conclusion

It is recommended that adding probiotics to the diet of a commercial cockerel (ISA Brown) as feed additive at 1 gm/kg may be better than that of the same level of antibiotic supplementation. Thus, it can be used as a substitute to antibiotic growth promoter for optimum production. However, repeated further studies with other probiotics and antibiotics, along with different commercial cockerel strains, are required to find out the optimum performance.