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Anim Biosci > Volume 30(5); 2017 > Article
Abdel-Hafeez, Saleh, Tawfeek, Youssef, and Abdel-Daim: Effects of probiotic, prebiotic, and synbiotic with and without feed restriction on performance, hematological indices and carcass characteristics of broiler chickens

Abstract

Objective

This study was conducted to investigate the effects of probiotic, prebiotic and synbiotic with and without feed restriction on broilers performance, blood parameters, carcass characteristics, and feed cost of production from 1 to 56 days of age.

Methods

Two hundred and forty unsexed one day-old chicks of Arbor Acres breed were used. Two trials, I and II, were conducted, with 120 birds in both. Each trial was divided into 4 equal groups. The birds in trial I were fed ad libitum throughout the experiment, while the chicks in trial II were fed ad libitum during the first week of age, then subjected to 5 hours/d of feed restriction from the beginning of the second week up to the end of the experiment. In both trials, the birds in group 1 were fed on a control diet while the other groups were given the same control diet supplemented either with a probiotic in group 2, prebiotic in group 3, or synbiotic in group 4.

Results

It was found that chicks fed diets supplemented with probiotic, prebiotic and synbiotic (with and without feed restriction) exhibited higher body weight and feed efficiency than chicks fed the control diets. The feed additives in both trials did not affect hemoglobin, serum total protein, albumin, globulin, glucose, and total cholesterol, except the packed cell volume which was increased in the additive treatments with restriction at the end of the experiment. Moreover, the dietary treatments did not influence the carcass yield. However, the relative weights of liver, gizzard and proventriculus, small intestine and bursa of fabricius were found to be increased. The additives decreased the visible fat in the carcass, with more decreasing effect in the additive groups with restriction. The lowest feed cost per kg of weight gain was observed in the birds fed diets supplemented with synbiotic, probiotic and prebiotic. Feed restriction improved the feed conversion ratio, economic return, but decreased the feed intake, serum total cholesterol and visible fat in comparison with non-restricted groups.

Conclusion

The biological feed additives could be routinely added to broiler diets, especially when a feed restriction program is followed. Finally, it can be recommended to restrict feed, and add probiotic or synbiotic to increase weight, improve feed conversion rate and reduce feed cost of production.

INTRODUCTION

Probiotics are microbial feed supplements which beneficially affect the host by improving its intestinal microbial balance and the intestinal mucosal barrier against deleterious agents [1]. In the meantime, prebiotics have been defined as non-digestible substances that provide a beneficial physiological effect on the host by selectively stimulating the favourable growth or activity of a limited number of indigenous bacteria [2]. A combination of probiotics and prebiotics as a single product is called synbiotics. It is a form of synergism that improves and optimizes the nutrient digestion and absorption [3]. The probiotic with its prebiotic food can survive well in the digestive system and could reduce the count of pathogenic bacteria and increase the population of useful microflora in gut [4].
Some manipulatory procedures to the feeding strategies of poultry such as feed restriction can be applied in order to improve feed conversion and cost, and reducing metabolic diseases and fat deposition in broiler carcasses [5]. Maheri-Sis et al [6] evaluated the effect of several feed restriction programs at different phases of age on performance and carcass yield of broiler chickens. The best age for restriction was found to be between the second and third weeks of age, as before 7 days of age the restriction is liable to cause intestinal underdevelopment and productive performance decrease in broilers. Rosa et al [7] suggested a restriction of feed in broilers for two week-period to obtain complete compensation in growth.
Long period of feed restriction may induce a great stress on birds. Biological feed additives have shown to alleviate the stress caused by feed restriction and improve the immunocompetence of birds [8]. However, Saffar and Khajali [9] found that probiotics did not ameliorate the negative effects of feed restriction on broiler performance. As far as the literature denotes, the effect of biological feed additives on feed restriction stresses still has not been well studied. Therefore, the aim of the present study was to investigate the effect of the feed additives, probiotic, prebiotic and synbiotic, with and without feed restriction on production performance, blood parameters, carcass characteristics, and feed cost of production in broilers. This was done to evaluate the effects of feed additives and feed restriction independently. Moreover, the impact of used additives in alleviating the side effects, if any, of restriction was investigated.

MATERIALS AND METHODS

Birds and management

A total number of 240 one-day old broiler (Arbor Acres) chicks were procured from a commercial hatchery with an average weight of 46 g. The chicks were weighed individually, marked by using plastic rings with different colours, and distributed at random, into eight groups with 30 birds each. The birds, of each experimental group, were housed in a floor pen and wheat straw was used as a litter. A lightening period of 23 h. per day was provided throughout the experimental period. The initial brooding temperature was 33°C in the first week of age and reduced gradually 2°C per week until reaching about 20°C at the end of the experiment. Chicks were allowed to have free access to water and feed along the experimental period except in the groups used to test feed restriction.

Experimental design and diets

Two trials, I and II, were conducted at the same time and location, with 120 chicks in both. Each trial was divided into 4 equal groups. Trial I included four groups fed on ad libitum basis during the experimental period, while the feed restriction in trial II was applied on the other four groups. In trial II, the chicks in the different groups were fed ad libitum during the first week of age, while from the beginning of the second week up to the end of the experimental period, the birds were subjected to 5 hours of feed restriction daily (from 9 to 12 am and from 1 to 3 pm).
The experimental diets used in this study were formulated from the commonly used feedstuffs. The used ingredients were analyzed for proximate composition using the standard methods according to AOAC [10]. Based on the nutrient contents of the ingredients, the diets were formulated to satisfy the broiler’s nutritional needs stated by NRC for poultry [11] which recommends a metabolizable energy density of 3,200 kcal/kg in all the phase-diets and 23%, 20%, and 18% crude protein in starter, grower and finisher, respectively. The diets of the different chick groups were formulated to be isocaloric and isonitrogenous. The physical and chemical composition of the different diets is displayed in Table 1.
The experimental period lasted for 8 weeks and included 3 feeding phases starter (0 to 3 wk), grower (3 to 6 wk) and finisher (6 to 8 wk) diets. It included four formulated diets in each feeding phase and in each trial. The birds in group 1 were fed on the negative control diet (without feed additives). The other groups were given the same control diet supplemented either with a probiotic (Enhancer, at a dosage of 0.250 kg/ton in the three feeding phases) in group 2, or prebiotic (Bio–Mos, at a rate of 2.0, 1.0, and 0.5 kg/ton in starter, grower, and finisher phase, respectively) in group 3, or synbiotic in group 4. The synbiotic used in this experiment was designed to be half the amounts of the used probiotic and prebiotic. Accordingly, the synbiotic was a mixture of 0.125 kg probiotic (Enhancer, USA) with 1.0, 0.5, and 0.25 kg of prebiotic (Bio-Mos, USA) in the three phase diets, reaching a level of 1.13, 0.63, 0.38 kg/ton in starter, grower and finisher diets, respectively. The additives added substituted equal amounts of yellow corn and their levels were provided according to the recommendations of the producing companies. Probiotic “Enhancer” is a product of Performance Plus International Company (Naperville, Chicago, IL, USA). Each gram of the product contains totally not less than 5×1010 colony forming units of both Bacillus licheniformis and Bacillus subtilis. The prebiotic “Bio–Mos” is a product of Alltech Company, Nicholasville, KY, USA. It is a commercial product of phosphorylated mannan-oligosaccharides (MOS) derived from the cell wall of certain strains of Saccharomyces cerevisiae. The same diets were used in trial II but with a feed restriction regime application.

Data collection

Growth performance

The chicks were individually weighed to the nearest gram at the beginning of the experiment, and every week thereafter till the end of the experiment. The gain in body weight (BW) of birds per week was calculated as the difference between the initial and end weight at a given week. The diets were offered to the chicks daily at 9 o’clock in the morning and the weekly feed intake was calculated by the difference between the offered and remained amounts. The total feed consumption per week was divided by the number of birds in each group to obtain the average weekly feed intake per bird. The feed intake was calculated after correction for that used by dead birds. The feed conversion ratio was calculated by dividing the amount of feed consumed in a certain period by the gain in weight at the same period (with consideration of dead birds), expressed in the same weight units. During the experimental period, daily mortalities were recorded for each group and mortality rate was calculated.

Blood parameters

Blood samples were collected from the brachial vein of 5 chicks in each group at 21, 42, and 56 days of age. The samples were collected into eppendorf tubes with ethylenediaminetetraacetic acid (EDTA), as an anticoagulant to measure hemoglobin and packed cell volume. Other blood samples were collected in non-EDTA tubes and allowed to clot for one hour, at room temperature, and then centrifuged at 3,000 rpm for 20 min, for serum separation. Collected sera were stored in a deep freezer at −20°C until chemically analyzed. At the time of analysis, the samples were thawed and analyzed for total protein, albumin, glucose and total cholesterol.
Hemoglobin concentration (g/dL) was estimated using hemoglobin kit according to cyanomethemoglobin method and the packed cell volume (%) by microhematocrite centrifuge. Serum total protein (g/dL) was determined colorimetrically, while albumin (g/dL) value was measured by bromocresol green method. Globulin concentration (g/dL) was calculated as the difference between total protein and albumin. Serum glucose (mg/dL) and total cholesterol (mg/dL) were also monitored colorimetrically. Commercial test kits of Diamond diagnostic company, Egypt were used for measuring the previous mentioned blood parameters except the total protein which was determined by using a reagent kit of Biostc Company, Egypt.

Carcass characteristics

Five birds from each group, close to the average live BW, were selected at the end of the grower and finisher phases of the experiment. Birds were weighed to the nearest gram, subjected to 24 h-feed withdrawal with free access to water, reweighed and slaughtered by neck cutting. After five minutes of bleeding, each bird was scalded, defeathered, and eviscerated after removal of head, neck and legs. The carcass without giblets was weighed, expressed as a percentage of its live weight and considered as the carcass yield. In addition, the weight of the liver (without gall bladder), gizzard and proventriculus, heart, spleen, bursa of fabricius, small intestine, the two caeca, and visible fat (around the viscera, gizzard, and subcutaneously) was recorded and its relation to the live BW of the bird, in percentage, was calculated.

Feed cost of production

To determine the economic efficiency for meat production, the cost of each one kg BW gain was calculated, in each feeding phase and at the overall of the experimental period. In each feeding phase, the cost of the diets consumed was divided by the weight gain, or the price of each kg feed was multiplied by the rate of feed conversion, to get the cost of each kg gain. Overall the experiment, the cost of the diets consumed in each treatment was calculated and divided by the total weight gain of the chicks to get the cost of each kg gain produced. The cost of the experimental diets was estimated depending upon the local current prices of the different ingredients and additives at the time of the experiment.

Statistical analysis

The statistical analyses were performed using SPSS statistical program (IBM, version 20, Chicago, IL, USA, 2011). The data were analyzed using the general linear model (GLM) procedure. Analysis of variance (ANOVA) tests were used for analyses of variance accompanied by Duncan’s multiple range test to detect the differences between the treatments. Moreover, ANOVA with repeated measurements was applied for BW results. In addition, the statistical tests were conducted for each trial independently as well as for both trials together. The results are presented as means±standard error of the mean. Probability values less than 0.05 (p<0.05) was considered significant.

RESULTS

Performance and feed cost of production

Data on weekly live BW development, performance and feed cost of production are presented in Table 2 and 3 respectively. The initial BW of chicks did not differ (p>0.05) between the dietary treatments.

Trial I (Ad libitum feeding)

Birds fed diets supplemented with probiotic, prebiotic and synbiotic had a greater (p<0.05) BW compared with controls. Moreover, synbiotic and probiotic supplemented birds had a greater (p<0.01) BW than birds supplemented with the prebiotic. The effect of the added additives on BW started at the fifth week with the probiotic, with an increase of 10% compared with the control. While, the effect of the prebiotic started at the sixth week with an increase of 6%, and at the second week in the synbiotic group with an increase of 8%. The number of dead birds during the experiment (0 to 8 weeks) was one bird (3.33%) in the control group and two birds (6.67%) in each of probiotic, prebiotic and synbiotic groups.
The cumulative feed intake during the starter period was not affected among the different experimental groups. However, it increased during grower and finisher periods for birds supplemented with probiotic and synbiotic compared with the prebiotic and control groups. The feed consumption in the prebiotic group was higher than the control one during the grower period but not in the finisher.
The feed conversion ratio (FCR) for birds supplemented with probiotic was 1.17, 1.68, and 2.14 at the starter, grower and finisher periods, respectively, compared with 1.40, 1.83, and 2.76 for the control. In the prebiotic and synbiotic treatments, the feed conversion rate was 1.30 and 1.15 at the starter, 1.77 and 1.61 at the grower, and 2.45 and 2.10 at the finisher, respectively. The cumulative FCR in the 8 weeks was 1.70, 1.82, and 1.64 for probiotic, prebiotic, and synbiotic, respectively, compared with 1.94 for the control, with the clearest effect in synbiotic and probiotic groups.
The cost of feed for the control diet was 3.92, 3.57, and 3.26 LE (Egyptian pound or Livre Egyptienne)/kg at the starter, grower and finisher periods, respectively. While, the cost of kg feed in diets containing the additives was slightly higher than the control. The additives greatly improved the feed cost of production at the starter, especially in probiotic and synbiotic groups where each kg gain cost 4.62 LE in both treatments compared with 5.49 LE in the control. At the grower period, the kg gain produced by the same additives cost 6.03 and 5.83 LE compared with 6.53 LE for the control. At the finisher, each kg gain in the probiotic, prebiotic, and symbiotic cost 7.04, 8.09, and 6.93 LE, respectively, compared with 9.0 LE in the control. In the total period, the three additives had the least costs but the probiotic and synbiotic had the lowest costs 5.99 and 5.85 LE, respectively, compared with 6.86 LE for the control and 6.56 LE for the prebiotic.

Trial II (Restricted feeding)

It was found that the BW of control group reached about 1,748 g at the 8th week of which 38% in the starter, 36% in the grower, and 26% in the finisher period, with no clear effect of the restriction on the rate of growth. The other three groups reached at the eighth week about 2,415, 2,108, and 2,325 g with a percentage of 138%, 121%, and 133% of the control group (100%). The effect of the added additives on BW started at the fourth week with an increase of 9% in the probiotic group, and at the fifth week with an increase of 8% in the prebiotic and 10% increase in the synbiotic. It was noticed that at the third week the weight of control group was 13% less than the ad libitum control and continued in this trend till it was 81% of the ad libitum weight, so that the BW was 19% lower at the end of the experiment. Also, the BW of additive groups in this trial was significantly lower (p<0.05) than the corresponding ones in the ad libitum trial, starting also from the third week. The mortality rate throughout the experiment was 3.33% (one bird) in probiotic group and 6.67% (two birds) in prebiotic one and no mortality in the control and synbiotic ones.
The cumulative feed intake was not affected among the different experimental groups at the starter period. However, it was increased during grower and finisher periods for birds supplemented with probiotic, prebiotic and synbiotic compared with the control group. Feed restriction decreased the feed intake when each group in this trial was compared with its corresponding one in the unrestricted trial.
The feed conversion ratio in the three additive groups (2, 3, and 4) was 1.13, 1.18, and 1.11 at the starter, 1.62, 1.67, and 1.58 at the grower, and 1.27, 2.05, and 1.91 at the finisher, respectively, compared with 1.26, 1.76, and 2.23 at the three phases for the control. The cumulative FCR was 1.60, 1.64, and 1.56 at the end of the experiment in the three additive groups (2, 3, and 4) compared with 1.71 for the control. It was noted that there was no great difference among groups, and also the improving effect was not so large. Moreover, restriction decreased the feed intake but improved the feed conversion ratio. The FCR in the restricted control reached 1.26, 1.76, and 2.23 at the starter, grower and finisher periods, respectively compared with 1.40, 1.83, and 2.76 in the ad libitum control and with a cumulative ratio of 1.71 in restriction and 1.94 in ad libitum. Also, the feed efficiency of each additive group in this trial was higher than its corresponding one in the unrestricted trial.
Addition of additives with restriction improved the cost of kg gain, at the starter, to be 4.46, 4.81, and 4.46 LE in the three groups (2, 3, and 4), respectively, while in the control it was 4.94 LE; the prebiotic had the least effect. The probiotic and synbiotic continued to be the most effective in the grower and finisher periods. In the total period, each kg gain cost 5.66, 5.56 LE in probiotic and synbiotic groups, respectively, compared with 6.07 LE in the control. Prebiotic was the least effective and the kg gain in this group cost 5.90 LE Feed restriction improved the feed cost of production in the control to be 4.94, 6.28, and 7.27 LE at the starter, grower, and finisher periods, respectively, compared to 5.49, 6.53, and 9.0 LE in the ad libitum control group, an improvement reaching a maximum of 19%. Similar to the control, the feed cost of production in the additive groups in this trial was lower than its corresponding ones in the ad libitum trial.

Blood and serum biochemical indices

Blood parameters were measured at the end of starter, grower and finisher periods. Their data are shown in Table 4.

Trial I (Ad libitum feeding)

Hemoglobin level in the control group was 14.05, 15.28, and 16.20 g/dL at 3rd, 6th, and 8th week, respectively, while, packed cell volume was 30.91%, 33.62%, and 36.64%. The values of hemoglobin and packed cell volume in the additive groups (2, 3, and 4) were in the same range of that of the control. Thus, there were no statistical differences (p>0.05) in hemoglobin and packed cell volume percentage between the control and the other groups in ad libitum feeding. In addition, total protein levels, in the control, showed 2.86, 3.05, and 3.52 g/dL at 3rd, 6th, and 8th week, respectively. The readings with albumin were 1.46, 1.78, and 1.95 g/dL and with globulin were 1.40, 1.27, and 1.57 g/dL at the three age periods. In the control, serum glucose concentration was 241.33, 245.0, and 269.33 mg/dL, while total cholesterol was 132.67, 141.67, and 157.33 mg/dL at 3rd, 6th, and 8th week, respectively. Also, the values of the tested serum parameters in the additive groups (2, 3, and 4) were similar to that of the control, resulting in no statistical differences (p>0.05) among the treatments.

Trial II (Restricted feeding)

There were no statistical differences (p>0.05) among the treatments in hemoglobin and serum parameters. However, packed cell volume % was increased (p<0.05), at the 8th week only, in the additive groups compared to the control. Moreover, hemoglobin, packed cell volume, total protein and albumin levels were not affected (p>0.05) by feed restriction. Nevertheless, there was a slight significant (p<0.05) decrease in globulin due to restriction. Also, restriction of feed slightly decreased the level of serum glucose at the 3rd week of age, but significantly (p<0.05), by only 20 mg/dL. Serum total cholesterol concentration was not affected by feeding regime except a slight decrease (p<0.05) in feed restriction at the 8th week of age (132.67 vs 157.33 mg/dL). Moreover, there were no significant differences (p>0.05) in blood and serum parameters between the feed additive treatments in this trial with its corresponding ones in the unrestricted trial.

Carcass characteristics

Carcass traits were determined at the end of grower and finisher periods. Their results are presented in Table 5.

Trial I (Ad libitum feeding)

At the end of the grower period, feeding the three kinds of additives increased (p<0.05) the relative weight of gizzard and proventriculus, spleen, bursa of fabricius, and the two ceca (except the probiotic). The most important effect in the three additives was the decrease (p<0.05) in the visible fat. However, the additives did not affect (p>0.05) the carcass yield, liver, heart, and small intestine.
At the end of the finisher period, the additives had inconsistent trend, an increase (p<0.05) in the relative weight of liver in probiotic and synbiotic, gizzard, and proventriculus in prebiotic, and the two caeca in prebiotic and synbiotic. In addition, a decrease in the relative weight of heart and visible fat was found in probiotic, prebiotic and synbiotic. However, the feed additives did not influence (p>0.05) the carcass yield, spleen, bursa of fabricius, and small intestine.

Trial II (Restricted feeding)

At the end of the grower period, addition of the additives with restricted feeding did not affect the carcass yield and the relative weight of internal organs, except a significant increase (p<0.05) in the liver, gizzard and proventriculus, heart, small intestine, and the two ceca (except the probiotic). In addition, the additives decreased (p<0.05) the visible fat than the restricted control. Moreover, the feed restriction and additive groups decreased (p<0.05) the visible fat but increased (p<0.05) the gizzard and proventriculus, and small intestine, when compared with its corresponding ones in the unrestricted trial. The relative weight of liver was higher in probiotic and synbiotic, but lower in restricted control when compared with the corresponding groups in the ad libitum trial.
At the end of the finisher period, use of the three additives with restricted feeding did not make any change to the carcass yield and the relative weight of internal organs, except an increase (p<0.05) in the liver in the three groups, and gizzard and proventriculus in prebiotic and synbiotic. Nevertheless, the additives decreased significantly (p<0.05) the visible fat. Moreover, the restriction and additive addition decreased more the visible fat, when compared with its corresponding groups in the unrestricted trial. While, the relative weight of the liver was higher in prebiotic only in comparison with the ad libitum prebiotic group.

DISCUSSION

In this study some attempts were made to improve the feed utilization and conversion using well-famed, biological feed additives - probiotic, prebiotic and synbiotic - in addition to the benefit gained from the feed restriction program. Feed restriction is one of the feeding strategies in which the feed is put off for several hours during the day in order to improve feed conversion and reduce the fat deposition in carcasses [5]. Feed restriction may represent an effective tool for improving the economic return. Because of the feed restriction, feed intake and growth were expected to be reduced with an end weight less than normal in spite of an improvement in feed conversion and carcass quality. The biological additives probiotic, prebiotic and synbiotic were used to test their effect in increasing feed intake so improving growth and increasing the end weight.

Performance and feed cost of production

Trial I (Ad libitum feeding)

At the end of the experiment, the BW of birds supplemented with probiotic, prebiotic and synbiotic was increased to be 2,774, 2,344, and 2,907 g, respectively, vs 2,171 g for the control. This increase in BW represents about 128%, 108%, and 134% of the control (100%) for the additive groups respectively, indicating that the prebiotic was the lowest in effect while synbiotic was the highest. The effect of synbiotic could be related to synergism between probiotic and prebiotic, which increase the digestion and absorption of nutrients [3]. The marked improvement in BW of chicks fed on supplemented diets in this study is fully consistent with the results of the previous studies [12,13]. In contrast, Salehimanesh et al [14] reported that using these additives in the broiler rations had no significant effects on BW and gain. Variations among reports of researches could be related to bird age, sex, breed, overall farm hygiene, environmental stress, type, concentration and dosage, methods of using, and frequency of application [14].
The mortality in this trial was low and varied between one to two birds throughout the different groups, indicating no effect of dietary treatments on mortality. But these losses might be due to the climatic influence and individual differences. The same finding was reported in Sarangi et al [13] who concluded that mortality % was not significantly affected by using the feed additives. However, Riad et al [15] reported that the addition of feed additives decreased the mortality rate. The reduction in mortality was attributed to the inhibitory effects of these additives towards enteric micro-organisms via modifying the intestinal pH.
The feed intake started to increase at the grower period in the probiotic, prebiotic and synbiotic, but in the prebiotic group there was no more increase at the finisher. At the end of the experiment, the increase in feed consumption reached about 112%, 101%, and 114% for probiotic, prebiotic and synbiotic respectively, compared with the control. These results indicated that the probiotic and synbiotic had the same effect and the prebiotic with no clear effect. So, addition of additives, especially the probiotic and synbiotic, seems to increase the appetite and feed intake. The increase in feed intake was observed also in the study of Riad et al [15]. However, other studies [13,14] found that feed intake of broilers did not differ significantly by dietary inclusion of probiotics. The effect of probiotic, prebiotic and synbiotic on the efficiency of feed utilization started from the starter period, however, the increase in feed intake and weight commenced at the grower period. The efficiency was improved in feed additive groups with the clearest effect in synbiotic and probiotic groups. Addition of additives saved 0.30 kg feed for every 1 kg gain on maximum and 0.12 kg on minimum, decreasing the end cost of 1 kg live BW. The results totally coincided with the observations of Riad et al [15] who reported that using probiotic, prebiotic and their combination in broiler diets lowered feed conversion. The improvement may be due to that biological feed additives alter the intestinal pH which modifies both microbial population and nutrient absorption improving the efficiency of feed utilization [1]. In addition, the additives can increase the villus height and intestinal length, resulting in an increased surface area capable of greater absorption of available nutrients [16]. Contradictory results were obtained by Sarangi et al [13] who found a non-significant difference in feed conversion ratio of broiler chickens in prebiotic, probiotic, and synbiotic groups when compared with control group.
The additives supplementation in this study greatly reduced the feed cost of production. The obtained results agreed with Riad et al [15] and Saiyed et al [12] who reported that supplementation of broiler diets with biological additives have a positive effect on the economic return. Addition of feed additives to broiler diets was found to enhance BW gains, feed conversion ratio, stimulated bird’s immunity and reduced mortality rate and subsequently improved net return and cost of production [14]. The lowest feed cost per kg live weight of chickens was found in the experimental groups containing probiotic and synbiotic which had also the lowest FCR compared to the other two groups (control and prebiotic).

Trial II (Restricted feeding)

This trial tested the effect of the additives in correcting the negative effect of restriction on chick performance. The effect of the feed restriction was clear in the control, while it was nullified in the additive groups especially in the probiotic and synbiotic. The best of the three was the probiotic followed by the synbiotic, while the prebiotic in spite of its being effective in nullifying the effect of restriction, and was the lowest. So, it is wise to recommend addition of probiotic, prebiotic or synbiotic with restriction. Restricted groups reached the same weight as with ad libitum fed control, as in prebiotic, or exceeded by 11% and 7% in probiotic and synbiotic, respectively. Congruent with our findings, various researchers have reported lower weight gains and market weights in feed-restricted vs full-fed birds [17,18]. Contrasting results have been cited by Mahmud et al [19]. In restriction, the growth decreased because the chicken consuming protein and energy less than their needs. Probiotics had shown to alleviate the stress caused by feed restriction and improve the immunocompetence of birds [9]. The amount of feed consumed in this trial reached its utmost in the probiotic group; it reached 3,789 g which constitutes 130% when compared with the control (100%). The amount consumed in the synbiotic was in the second level of increase, where it reached 122% compared with the control, while in the prebiotic group the feed intake was the lowest and reached only 116%. So, in spite of feed restriction, 5 hours a day, the additives increased the feed intake with a very clear effect with the probiotic and synbiotic. Comparing the two control groups of both trials, it was found that feed restriction decreased the BW at the end by about 19% due to a decrease in feed intake reaching 29%. Feed restriction decreased feed intake 22% in the starter, 27% in the grower, and 36% in the finisher. There is no place for a compensatory growth to occur as the birds did not get a period of ad libitum feeding to allow them to compensate. Many researches indicated that feed intake was significantly decreased during restriction but become higher than un-restricted birds after ad libitum feeding [17,18]. Saffar and Khajali [9] reported that feed intake of birds on restricted feeding with and without probiotic were significantly lower than the full fed control.
In this trial, the feed efficiency in the three additive groups (2, 3, and 4) was higher than the control one. The improvement in efficiency did not exceed 0.15 kg feed for every kg BW, on maximum. So, adding the probiotic, prebiotic or synbiotic improved the BW due to the increase in feed consumption but not due to the increase in efficiency of utilization. Restriction decreased the feed intake but improved the feed conversion ratio compared with the ad libitum groups. So, restriction is beneficial from the feed conversion point of view but on the other hand decreases feed intake and by turn BW. Adding the three additives corrected the feed intake to a degree more than the control, and corrected the BW to a level more than at feeding ad libitum regime (especially, probiotic and synbiotic vs ad libitum control) and in addition slightly improved the feed conversion ratio. Feed restriction has been observed to improve feed conversion ratio than ad libitum feeding [20]. Poor FCR in ad libitum fed birds could be attributed to availability of less time for digestion, whereas feed restricted birds might have proper time for utilization of nutrients in the feed more efficiently leading to better FCR than full-fed birds. In contrast, Mahmud et al [19] did not report significant differences in feed conversion due to feed restriction. Ultimately, the obtained data showed clearly that the feed utilization was improved when the restricted birds were fed diets supplemented with additives. The effects of diet supplementation with these kinds of additives were almost identical in both restricted and fully fed birds.
Feed restriction decreased the feed cost of production in the control group at the starter, grower, and finisher periods compared to the ad libitum control one. Also, addition of additives with restriction reduced the production cost when compared with non-restricted groups. These results are in agreement with results of previous researchers [6,21] who indicated that feed restriction may be a good potential strategy to reduce the cost of feed in broiler meat production or to counter feed shortages or high cost of feed. Cost of production declined with the restriction because the feed intake declined correspondingly. This is so because feed accounts for 55% to 75% of production cost and feed restricted birds generally eat less than unrestricted ones. Moreover, feed restricted birds consumed less feed and found ample time to properly digest, absorb and metabolize [20].

Blood and serum biochemical indices

Trial I (Ad libitum feeding)

Blood parameters were analyzed at the end of the three feeding phases. There were no statistical differences in hemoglobin and packed cell volume levels among the treatments. However, probiotic and synbiotic groups showed higher numerical values than other groups. The results were in line with the findings of Alkhalf et al [22] who found that no differences in hemoglobin (Hb) concentration due the addition of probiotic to the diet of broiler. In contrast, Beski and Sardary [23] reported that probiotics and synbiotics resulted in a significant increase in the concentration of Hb. The higher Hb concentration in the chicks receiving probiotics and synbiotics may be due to the acidic media of the alimentary tract caused by probiotic fermentation which resulted in better iron salt absorption from the small intestine. This may also cause better vitamin B complex production by useful bacteria, which may result in positively affecting blood-forming processes. Meanwhile, synbiotic could increase the digestibility percentage and availability of many nutrient elements such as proteins, mineral elements and vitamins. Absorption of these nutrients may elevate the concentration of hemoglobin. Packed cell volume % findings are in agreement with those of Hanamanta et al [24] who found that the addition of probiotic and synbiotic to broiler diet had no significant effects on packed cell volume and Hb.
Addition of probiotic, prebiotic, and synbiotic had no significant effect on total protein, albumin and globulin level. The results were in accordance with the findings of Alkhalf et al [21] reported that supplementing broiler diet with probiotic and prebiotic did not have any effect on total protein, albumin, and globulin. The results also showed that the addition of the three additives did not have any statistical effect on serum glucose level. Mokhtari et al [25] found that serum glucose of broilers was not affected significantly by synbiotics. There was also no effect for the additives addition on serum total cholesterol level but dietary supplemented treatments were numerically low. Ashayerizadeh et al [26] found that serum total cholesterol was reduced significantly by dietary supplementation of probiotic. This could be attributed to reduced absorption and/or synthesis of cholesterol in the gastro-intestinal tract by probiotic supplementation.

Trial II (Restricted feeding)

There was no effect of the feed restriction or additives addition on hemoglobin level, total protein and albumin levels. However, packed cell volume percentage was increased by the feed additives at the 8th week only, but was not affected by restriction. This may be due to the acidic media of the gut caused by probiotic fermentation which resulted in better iron absorption and vitamin B complex production by useful bacteria, which may result in increasing the packed cell volume. Moreover, a slight significant decrease in globulin level due to restriction was found, but this level within the normal range (0.7 to 2 g/dL). Nassef et al [27] showed that early feed restriction had no significant effect on serum total protein, albumin, and globulins. Also, restriction of feed slightly decreased the level of serum glucose at the 3rd week only. The results also showed that the addition of the three additives did not have any statistical effect on glucose either in ad libitum regime or the restricted one. Klasing [28] have reported that chickens maintain a steady glucose level during feed restriction.
In this trial, there was no effect for the feeding regime on total cholesterol level, except a slight decrease at the 8th week of age. Also, the additives did not affect the total cholesterol in both regimes. Nassef et al [27] showed that early feed restriction had no significant effect on serum cholesterol. In contrast, Klasing [28] mentioned that serum total lipids and triglycerides were lower in restricted broilers than those fed ad libitum. It might be due to the obligate use of considerable levels of triglycerides for energy demand during feed restriction.

Carcass characteristics

Trial I (Ad libitum feeding)

In poultry industry, one of the major concerns is to get a higher yield percentage, saleable products and consequently, to increase the edible portions. Generally, addition of feed additives may increase the rate of metabolism and eventually increased the size of most of the internal organs as observed in this study. The most significant effect of the three additives used in this work was the decrease in visible fat, especially with prebiotic and synbiotic. In contrast, carcass yield was not significantly affected by dietary treatments. Our results coincide with the observations of Midilli et al [29] who did not observe any significant impact of probiotic and Mannan-oligosaccharides on carcass yield. Mohmud et al [19] reported that the highest abdominal fat percentage value was recorded for birds fed the control diet, while the lowest value was recorded for birds fed the MOS supplemented diet. No clear mechanisms have been reported to be responsible for the reduction of lipid synthesis by prebiotics and probiotic. It might in part be due to increasing beneficial bacteria such as Lactobacillus that decrease the activity of acetyl-CoA carboxylase, which is the rate-limiting enzyme in fatty acids synthesis.

Trial II (Restricted feeding)

Feed restriction effects may be either neutral or beneficial for the whole carcass or carcass cut weights. Feed restriction and addition of additives decreased the visible fat and increased most of the giblets in size when compared with ad libitum. Addition of additives decreased more the fat and increased more the giblets. There was no effect for restriction or additives addition on carcass yield. Jahanpour et al [30] reported that both the weight and proportion of carcass cuts were not significantly affected by feed restriction programs.

CONCLUSION

The obtained results indicate that biological feed additives (probiotic, prebiotic, and synbiotic) could be routinely added to broiler diets, especially when a feed restriction program is followed. Diets supplemented with synbiotic, probiotic, and prebiotic (with and without feed restriction) improved broiler performance, without affecting blood parameters and carcass yield. Restriction and addition of additives resulted in a decreased visible fat of the carcass. Moreover, feed restriction could improve feed conversion ratio and cost of production compared to non-restricted birds. In addition, biological feed additives may be used as an anti-stress factor in feed restriction. Finally, feed additives can reduce the diet cost, with recommendation of the probiotic and synbiotic which had the lower costs. So, it is advised to restrict feed, and add probiotic or synbiotic to increase weight, improve feed conversion rate and reduce feed cost of production.

Notes

CONFLICT OF INTEREST

We certify that there is no conflict of interest with any financial organization regarding the material discussed in the manuscript.

ACKNOWLEDGMENTS

The authors would like to thank the Projects Funding and Granting Unit, Research Center, Beni-Suef University, Egypt for the help in financial support of this study.

Table 1
Physical and chemical composition (%) of the control diets
Ingredient Diets

Starter Grower Finisher
Physical composition
 Yellow corn, ground 45.77 52.53 60.72
 Soybean meal 34.94 35.20 29.10
 Corn gluten meal 6.00 0.00 0.00
 Vegetable oil1) 7.23 6.99 5.32
 Molasses, cane 2.00 2.00 2.00
 Limestone, ground 1.40 1.35 1.29
 Dicalcium phosphate 1.75 1.20 0.96
 Common salt 0.48 0.35 0.27
 DL-Methionine2) 0.13 0.08 0.04
 Minerals and vitamins premix3) 0.30 0.30 0.30
Chemical composition
 Metabolizable energy (kcal/kg) 3,204 3,203 3,201
 Dry matter 91.45 91.18 90.83
 Crude protein 23.03 20.06 18.01
 Methionine 0.51 0.39 0.32
 Methionine+Cystine 0.90 0.72 0.62
 Lysine 1.12 1.08 0.93
 Ether extract 9.52 9.38 7.87
 Crude fiber 3.05 3.13 2.92
 Calcium 1.04 0.90 0.81
 Phosphorus, available 0.46 0.35 0.30
 Sodium 0.20 0.15 0.12

1) Vegetable oil composed of 75% sunflower oil and 25% soybean oil.

2) DL-Methionine is patent commercial product of Decosta company, USA, containing 99% methionine.

3) Poultry mineral and vitamin premix (Avimix, Agri – Vet Company, Egypt): each 3 kg contains vitamin A, 12,000,000 IU; vitamin D3, 2,000,000 IU; vitamin E, 10,000 mg; vitamin K3, 2,000 mg; vitamin B1, 1,000 mg, vitamin B2, 5,000 mg; vitamin B6, 1,500 mg; vitamin B12, 10 mg; biotin, 50 mg; pantothenic acid, 10,000 mg; nicotinic acid, 30,000 mg; folic acid, 1,000 mg, choline chloride, 250,000 mg; Mn, 60,000 mg; Zn, 50,000 mg; Fe, 30,000 mg; Cu, 10,000 mg; I, 1,000 mg; Se, 100 mg; Co, 100 mg; and calcium carbonate up to 3 kg.

Table 2
Body weight development (in gram) of the chicks in the different experimental groups (Mean±SEM)
Age in weeks Trial I (Ad libitum feeding) Trial II (Restricted feeding)


Control Probiotic Prebiotic Synbiotic Control Probiotic Prebiotic Synbiotic


1 2 3 4 1 2 3 4
0 46.27±0.58Aa 46.40±0.58Aa 47.08±0.59Aa 46.68±0.58Aa 46.55±0.66Aa 45.69±0.82Aa 45.32±0.680Aa 46.39±0.68Aa
1 122.23±4.60Aa 120.00±3.85Aa 125.28±3.37Aa 125.39±4.14Aa 125.18±3.49Aa 125.73±2.99Aa 124.64±3.15Aa 126.71±3.28Aa
2 345.08±8.89Aa 342.52±8.69Aa 340.16±8.41Aa 372.93±11.84Ab 340.48±11.11Aa 358.00±6.07Aa 343.00±8.78Aa 345.04±6.37Aa
3 757.69±10.23Ba 746.28±10.89Ba 746.64±7.84B 804.93±14.99Cb 661.63±14.73Aa 704.85±10.69Ba 684.50±14.45ABa 691.64±10.20ABa
4 979.43±18.09Ca 999.86±19.22Ca 977.32±13.60Ca 1103.80±19.78Db 834.42±14.42Aa 905.69±12.13Bc 885.08±10.68ABab 867.60±15.02ABab
5 1,275.65±16.74Da 1,406.64±16.20Eb 1,312.01±13.12Da 1525.16±19.86Fc 1,034.62±14.49Aa 1,184.00±16.79Cc 1,117.32±15.14Bb 1,137.64±16.97Bb
6 1,590.22±15.97Ca 1,898.18±12.37Ec 1,689.73±13.76Db 2,014.60±18.23Fd 1,287.37±25.26Aa 1,619.57±18.62Cd 1,468.24±19.41Bb 1,559.40±19.61Bc
7 1,885.69±23.19Ba 2,354.40±19.16Dc 2,021.27±30.43Cb 2,484.89±19.90Ed 1,533.00±34.06Aa 2,024.51±30.11Cc 1,796.88±22.69Bab 1,942.53±31.39Bc
8 2,171.31±32.51Ba 2,774.47±27.83Dc 2,344.00±33.96Cb 2,907.22±26.11Ed 1,748.06±23.39Aa 2,414.84±27.89Cc 2,107.88±30.11Bb 2,324.94±34.62Cc

SEM, standard error of the mean.

a–d Means within the same row (in each trial independently) with different superscripts are significantly different (p<0.05).

A–F Means within the same row (in both trials together) with different superscripts are significantly different (p<0.05).

Table 3
Performance data as well as feed cost of production in broiler chicks of the different experimental groups
Parameters Trial I (Ad libitum feeding) Trial II (Restricted feeding)


Control Probiotic Prebiotic Synbiotic Control Probiotic Prebiotic Synbiotic


1 2 3 4 1 2 3 4
Starter phase (0–3 wk)
 Weight gain (g) 711.42±11.28Ca 699.88±10.77Ca 699.56±7.92Ca 758.25±14.87Db 615.08±14.99Aa 659.16±10.76Ba 639.18±12.31ABa 645.25±10.22ABa
 Feed intake (g) 997.84 820.69 910.29 872.43 776.88 742.33 757.41 715.16
 Feed conversion ratio (g/g) 1.40 1.17 1.30 1.15 1.26 1.13 1.18 1.11
 Mortality rate (%) - - - - - - - -
 Feed cost (LE/kg) 3.92 3.95 4.08 4.02 3.92 3.95 4.08 4.02
 Feed cost of production (LE/kg) 5.49 4.62 5.30 4.62 4.94 4.46 4.81 4.46
Grower phase (3–6 wk)
 Weight gain (g) 832.53±17.69BCa 1,151.90±14.01Ec 943.09±15.70Db 1,209.67±26.43Ed 625.74±27.12Aa 914.72±25.04Bc 783.74±22.01Bb 867.76±24.39Cc
 Feed intake (g) 1,521.46 1,936.08 1,665.89 1,951.65 1,103.98 1,478.15 1,311.60 1,374.52
 Feed conversion ratio (g/g) 1.83 1.68 1.77 1.61 1.76 1.62 1.67 1.58
 Mortality rate (%) 3.33 3.33 6.67 6.67 - 3.33 6.67 -
 Feed cost (LE/kg) 3.57 3.59 3.64 3.62 3.57 3.59 3.64 3.62
 Feed cost of production (LE/kg) 6.53 6.03 6.44 5.83 6.28 5.82 6.08 5.72
Finisher phase (6–8 wk)
 Weight gain (g) 581.09±37.05Ba 876.29±37.80Ec 654.27±41.52Cb 892.62±29.28Fc 460.69±28.97Aa 795.27±33.36Dc 639.64±23.39Cb 765.54±32.90CDc
 Feed intake (g) 1,604.05 1,874.68 1,601.00 1,872.40 1,028.86 1,568.83 1,308.62 1,462.12
 Feed conversion ratio (g/g) 2.76 2.14 2.45 2.10 2.23 1.97 2.05 1.91
 Mortality rate (%) - 3.45 - - - - - -
 Feed cost (LE/kg) 3.26 3.29 3.30 3.30 3.26 3.29 3.30 3.30
 Feed cost of production (LE/kg) 9.00 7.04 8.09 6.93 7.27 6.48 6.77 6.30
The overall period (0–8 wk)
 Weight gain (g) 2,125.04±34.65BCa 2,728.07±27.94Fc 2,296.92±26.68Cb 2,860.54±26.21Gd 1,701.51±23.67Aa 2,369.15±28.12Ed 2,062.56±30.22Bb 2,278.55±34.68Dc
 Feed intake (g) 4,123.35 4,631.45 4,177.18 4,696.48 2,909.72 3,789.31 3,377.63 3,551.80
 Feed conversion ratio (g/g) 1.94 1.70 1.82 1.64 1.71 1.60 1.64 1.56
 Mortality rate (%) 3.33 6.67 6.67 6.67 - 3.33 6.67 -
 Total feed cost (LE/total gain)1) 14.58 16.35 15.07 16.72 10.32 13.41 12.17 12.66
 Feed cost of production (LE/kg) 6.86 5.99 6.56 5.85 6.07 5.66 5.90 5.56

LE, Egyptian pound or Livre Egyptienne.

a–d Means within the same row (in each trial independently) with different superscripts are significantly different (p<0.05).

A–F Means within the same row (in both trials together) with different superscripts are significantly different (p<0.05).

1) Total feed cost (LE/total gain) = starter (gain×feed cost of production)+grower (gain×feed cost of production)+finisher (gain×feed cost of production).

Table 4
Blood and serum biochemical indices in the different experimental groups at the end of the starter, grower and finisher periods (Mean±SEM)
Parameters Trial I (Ad libitum feeding) Trial II (Restricted feeding)


Control Probiotic Prebiotic Synbiotic Control Probiotic Prebiotic Synbiotic


1 2 3 4 1 2 3 4
Starter phase
 Hemoglobin (g/dL) 14.05±0.44Aa 15.05±0.27Aa 14.34±0.69Aa 15.60±0.53Aa 13.76±0.54Aa 14.34±0.69Aa 13.74±0.23Aa 13.95±0.33Aa
 Packed cell volume (%) 30.91±0.96Aa 33.14±0.62Aa 31.56±1.48Aa 34.48±1.12Aa 30.62±0.55Aa 31.58±1.52Aa 30.26±0.53Aa 30.63±0.78Aa
 Total protein (g/dL) 2.86±0.21Aa 2.99±0.14Aa 2.84±0.15Aa 2.98±0.13Aa 2.52±0.10Aa 2.70±0.09Aa 2.66±0.11Aa 2.75±0.16Aa
 Albumin (g/dL) 1.46±0.14Aa 1.60±0.11Aa 1.61±0.03Aa 1.68±0.04Aa 1.47±0.09Aa 1.51±0.10Aa 1.47±0.04Aa 1.52±0.05Aa
 Globulin (g/dL) 1.40±0.10Aa 1.39±0.03Aa 1.23±0.11Aa 1.30±0.09Aa 1.05±0.03Aa 1.19±0.1Aa 1.19±0.06Aa 1.23±0.05Aa
 Glucose (mg/dL) 241.33±4.81Aa 248.33±16.01Aa 237.67±5.24Aa 236.67±10.13Aa 221.00±4.93Aa 221.33±7.31Aa 215.33±10.84Aa 217.67±12.41Aa
 Total cholesterol (mg/dL) 132.67±11.05Aa 129.16±3.69Aa 123.33±11.47Aa 120.33±4.67Aa 121.34±11.20Aa 121.33±12.68Aa 118.33±7.51Aa 116.67±9.53Aa
Grower phase
 Hemoglobin (g/dL) 15.28±0.26Aa 15.81±0.34Aa 15.07±0.44Aa 16.21±0.79Aa 13.92±0.25Aa 14.80±0.44Aa 14.22±0.23Aa 14.5±0.58Aa
 Packed cell volume (%) 33.62±0.57Aa 34.78±0.61Aa 33.25±0.88Aa 35.46±1.68Aa 31.08±1.31Aa 32.62±1.24Aa 31.27±0.53Aa 31.86±1.32Aa
 Total protein (g/dL) 3.05±0.09Aa 3.26±0.12Aa 3.04±0.12Aa 3.31±0.05Aa 2.69±0.13Aa 3.09±0.31Aa 3.02±0.16Aa 3.21±0.19Aa
 Albumin (g/dL) 1.78±0.04Aa 1.93±0.21Aa 1.86±0.20Aa 1.99±0.07Aa 1.70±0.17Aa 1.80±0.12Aa 1.78±0.28Aa 1.85±0.07Aa
 Globulin (g/dL) 1.27±0.06Aa 1.33±0.10Aa 1.18±0.08Aa 1.32±0.02Aa 0.99±0.04Aa 1.29±0.13Aa 1.24±0.12Aa 1.36±0.23Aa
 Glucose (mg/dL) 245.0±5.57Aa 269.33±20.28Aa 247.0±10.69Aa 252.33±9.95Aa 232.0±8.39Aa 240.67±7.88Aa 234.33±13.78Aa 237.0±8.96Aa
 Total cholesterol (mg/dL) 141.67±11.72Aa 136.00±10.26Aa 133.0±8.72Aa 130.67±13.62Aa 124.67±8.45Aa 125.67±11.05Aa 119.33±9.39Aa 119.33±5.81Aa
Finisher phase
 Hemoglobin (g/dL) 16.20±0.41Aa 17.03±0.33Aa 16.40±0.27Aa 17.57±0.96Aa 15.38±0.65Aa 16.89±0.38Aa 16.42±0.38Aa 16.57±0.33Aa
 Packed cell volume (%) 35.64±0.89Aa 37.56±0.69Aa 36.02±0.55Aa 37.95±1.02Aa 33.53±0.37Aa 37.15±0.86Ab 35.98±0.70Ab 36.44±0.67Ab
 Total protein (g/dL) 3.52±0.05Aa 3.72±0.24Aa 3.61±0.21Aa 3.91±0.18Aa 3.16±0.40Aa 3.55±0.28Aa 3.53±0.42Aa 3.65±0.27Aa
 Albumin (g/dL) 1.95±0.05Aa 2.18±0.19Aa 2.04±0.14Aa 2.49±0.26Aa 1.76±0.13Aa 2.05±0.17Aa 1.98±0.17Aa 2.09±0.12Aa
 Globulin (g/dL) 1.57±0.02Aa 1.54±0.07Aa 1.57±0.07Aa 1.42±0.15Aa 1.40±0.02Aa 1.50±0.16Aa 1.55±0.26Aa 1.56±0.12Aa
 Glucose (mg/dL) 269.33±7.17Aa 290.33±15.60Aa 270.33±13.78Aa 281.67±34.59Aa 254.33±12.72Aa 274.67±21.83Aa 262.0±15.50Aa 263.0±11.79Aa
 Total cholesterol (mg/dL) 157.33±11.55Aa 152.33±10.48Aa 148.33±4.33Aa 138.0±5.51Aa 132.67±12.14Aa 126.67±6.74Aa 123.34±16.76Aa 122.67±13.24Aa

SEM, standard error of the mean.

a,b Means within the same row (in each trial independently) with different superscripts are significantly different (p<0.05).

A,B Means within the same row (in both trials together) with different superscripts are significantly different (p<0.05).

Table 5
Relative carcass and organ weights (% of body weight) of the different experimental groups at the end of the grower and finisher periods (Mean±SEM)
Character (%) Trial I (Ad libitum feeding) Trial II (Restricted feeding)


Control Probiotic Prebiotic Synbiotic Control Probiotic Prebiotic Synbiotic


1 2 3 4 1 2 3 4
Grower phase
 Dressing value 69.36±0.88Aa 70.99±0.39Aa 70.70±0.32Aa 71.63±1.16Aa 69.11±0.86Aa 69.69±0.18Aa 69.60±0.43Aa 69.91±0.97Aa
 Liver 2.77±0.09Ba 2.82±0.06Ba 2.74±0.02Ba 2.85±0.06Ba 2.15±0.03Aa 3.11±0.03Cc 2.75±0.01Bb 3.14±0.01Cc
 Gizzard and proventriculus 2.47±0.03Aa 2.72±0.17ABCab 2.89±0.04CDb 2.79±0.03BCDb 2.58±0.07ABa 3.03±0.04Db 3.14±0.03Db 3.08±0.04Eb
 Heart 0.72±0.03Aa 0.66±0.02Aa 0.69±0.01Aa 0.70±0.02Aa 0.65±0.02Aa 0.71±0.02Ab 0.74±0.01Ab 0.82±0.02Ac
 Spleen 0.09±0.06Aa 0.20±0.01Cb 0.20±0.01Cb 0.20±0.01Cb 0.15±0.01Ba 0.16±0.01Ba 0.15±0.01Ba 0.17±0.01Ca
 Bursa of fabricius 0.09±0.01Aa 0.13±0.01Ab 0.12±0.00Ab 0.13±0.01Ab 0.10±0.00Aa 0.13±0.01Aa 0.13±0.00Aa 0.15±0.01Aa
 Small intestine 3.51±0.03Aa 3.52±0.02Aa 3.50±0.01Aa 3.64±0.26 ABa 3.67±0.01ABa 3.89±0.04BCc 3.79±0.01ABCb 4.07±0.01Cd
 Two caeca 0.48±0.00Aa 0.47±0.02Aa 0.62±0.01Cb 0.73±0.01Dc 0.52±0.03ABa 0.54±0.01ABa 0.65±0.02Cb 0.74±0.03Dc
 Visible fat1) 2.30±0.16Cb 1.20±0.03Ba 0.94±0.25ABa 1.07±0.01Ba 1.18±0.01Bc 0.98±0.03ABb 0.67±0.08Aa 0.87±0.02ABb
Finisher phase
 Dressing value 71.71±1.33Aa 73.72±0.79Aa 73.75±1.49Aa 73.99±0.80Aa 70.13±1.64Aa 72.57±1.66Aa 72.03±0.26Aa 72.94±0.69Aa
 Liver 2.26±0.02Aa 2.51±0.06BCb 2.33±0.02Aa 2.59±0.01Cb 2.30±0.01Aa 2.54±0.01Cc 2.45±0.01Bb 2.66±0.02Dd
 Gizzard and proventriculus 2.30±0.02Ba 2.30±0.02Ba 2.47±0.01Cb 2.35±0.03Ba 2.32±0.04Ba 2.32±0.02Aa 2.53±0.04Cb 2.46±0.02Db
 Heart 0.87±0.01Ad 0.67±0.01Aa 0.81±0.02Ac 0.71±0.00Ab 0.78±0.03Aa 0.73±0.02Aa 0.79±0.02Aa 0.77±0.01Aa
 Spleen 0.13±0.01Aa 0.15±0.01ABa 0.15±0.01ABa 0.17±0.01ABa 0.15±0.01ABa 0.18±0.01ABa 0.17±0.01ABa 0.22±0.02Ca
 Bursa of fabricius 0.06±0.01Aa 0.08±0.01Aa 0.08±0.01Aa 0.09±0.00Aa 0.06±0.00Aa 0.07±0.00Aa 0.06±0.00Aa 0.07±0.00Aa
 Small intestine 2.56±0.02Aa 2.61±0.07Aa 2.58±0.02Aa 2.79±0.01Ba 2.57±0.06Aa 2.58±0.03Aa 2.57±0.03Aa 2.79±0.05Ba
 Two caeca 0.44 ±0.03Aa 0.49±0.02Aab 0.54±0.00ABb 0.66±0.03Dc 0.57±0.02Ca 0.56±0.01Ca 0.57±0.01Ca 0.59±0.01Ca
 Visible fat1) 2.64±0.01Fd 2.12±0.01Ec 0.96±0.05Ba 1.71±0.06Db 1.49±0.09Cb 0.75±0.05Aa 0.64±0.05Aa 0.75±0.03Aa

SEM, standard error of the mean.

a–d Means within the same row (in each trial independently) with different superscripts are significantly different (p<0.05).

A–F Means within the same row (in both trials together) with different superscripts are significantly different (p<0.05).

1) Visible fat is the fat found around the viscera and subcutaneously.

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