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Asian-Australasian Journal of Animal Sciences logoLink to Asian-Australasian Journal of Animal Sciences
. 2016 Feb 24;29(3):384–389. doi: 10.5713/ajas.15.0141

Effect of Dietary Beta-Glucan on the Performance of Broilers and the Quality of Broiler Breast Meat

Sun Hee Moon 1, Inyoung Lee 2, Xi Feng 1, Hyun Yong Lee 1, Jihee Kim 1, Dong Uk Ahn 1,3,*
PMCID: PMC4811790  PMID: 26950870

Abstract

A total of 400, one day-old commercial broiler chicks were divided into five diet groups (negative control, positive control group with 55 ppm Zn-bacitracin, 15 ppm β-glucan, 30 ppm β-glucan, and 60 ppm β-glucan) and fed for six weeks. Ten broilers were allotted to each of 40 floor pens. Eight floor pens were randomly assigned to one of the 5 diets. Each diet was fed to the broilers for 6 weeks with free access to water and diet. The survival rate, growth rate, feed efficiency, and feed conversion rate of the broilers were calculated. At the end of the feeding trial, the birds were slaughtered, breast muscles deboned, and quality parameters of the breast meat during storage were determined. The high level of dietary β-glucan (60 ppm) showed better feed conversion ratio and survival rate than the negative control. The survival rate of 60 ppm β-glucan-treated group was the same as that of the antibiotic-treated group, which showed the highest survival rate among the treatments. There was no significant difference in carcass yield, water holding capacity, pH, color, and 2-thiobarbituric acid reactive substances values of chicken breast meat among the 5 treatment groups. Supplementation of 60 ppm β-glucan to broiler diet improved the survival rate and feed conversion rate of broilers to the same level as 55 ppm Zn-bacitracin group. The result indicated that use of β-glucan (60 ppm) can be a potential alternative to antibiotics to improve the survival and performance of broilers. However, dietary β-glucan showed no effects on the quality parameters of chicken breast meat.

Keywords: β-Glucan, Broiler, Growth Performance, Physicochemical Properties

INTRODUCTION

β-1,3-Glucan is a functional polymer consisting of glucose with β-1,3 linkage and can be isolated from various sources, including grains, mushrooms and bacteria. β-1,3-Glucan is known to enhance immunity and bioactivity by promoting secretion of cytokines, activating macrophages, natural killer cells and neutrophils, and have antitumor, antibacterial and antiviral effects (Brown and Gordon, 2005). β-Glucan also functions as an adjuvant for monoclonal antibody immunotheraphy because it can induce cellular cytotoxicity by recruiting tumoricidal granulocytes as killer cells. β-1,3-Glucan is known to increase antibody production by activating the B cells, has a complementing function in mAB-mediated cancer immunology, and activates the secretion of IL-1, IL-2, TNF-α. Therefore, β-glucan can stimulate the cell-mediated immune reactions, which activates the macrophage, NK cell, and cytotoxic T cell (Bohn and BeMiller, 1995; Vetvicka et al., 2007; Chen et al., 2008). As a result, β-1,3-glucan can enhance the resistance against infection of microorganisms and virus by improving i) non-specific immunity, which may protect animals against infection, ii) host defense mechanism, and iii) growth rate and reduce mortality. Thus, β-glucan may be used as a replacement for dietary antibiotics in animal feeds.

Beta Polo, mainly composed of β-1,3-glucan, is a natural feed additive for poultry. Beta-Polo stimulates immune system and improves host defense mechanism, consequently reducing mortality and enhancing growth (Guo et al., 2003). The quality of meat is significantly influenced by the degree of stresses in animals during growing, transportation, pre-slaughter handling and processing. Therefore, dietary β-1,3-glucan can have significant impact to the quality of meat because it can reduce oxidative stress in birds during growing periods. However, few literature is available in the area.

The objectives of this study were to determine i) the effects of dietary β-glucan on the survival rate, growth rate, feed efficiency, and feed conversion rate of broilers, and ii) the effects of dietary β-glucan on the carcass yield, and color, pH, water holding capacity, composition and storage stability of broiler breast meat.

MATERIALS AND METHODS

Experimental design and diets

The study was approved by the Institutional Animal Care and Use Committee at Iowa State University (Approval # 2-12-7313-G). Four hundred, one-day-old commercial broiler chicks were divided into five dietary groups (eight replications×10 birds each replication) and fed the following diets for six weeks. NC was the negative control group (basal diet, antibiotics-free); PC, the positive control group (55 ppm Zn-bacitracin, approved for broilers and commonly used); 15 BG, 15 ppm β-glucan; 30 BG, 30 ppm β-glucan; and 60 BG, 60 ppm β-glucan. The β-glucan product containing 25% 1,3-β-glucan was obtained from Naturence Co., Ltd. (Sejong, Korea) and used to formulate the BG treatments.

All five diets were prepared on corn-soybean basal diet, which met or exceed the NRC requirements (NRC, 1994) for birds during the trial. The formula and chemical composition of the basal diets are shown in Table 1. Crude protein, metabolizable energy, Ca, P, lysine and methionine levels in the four diets were adjusted to the same levels. Ten broilers were allotted to each of 40 floor pens (experimental units), weighed, and wing banded. Eight floor pens were randomly assigned to one of the five experimental diets with different amounts of 1,3-β-glucan. Each of the dietary treatment was fed to the respective broiler groups for six weeks. Broilers had free access to water and diet. The growth and feed consumption of broilers were measured weekly during the feeding trial. At the end of the feeding trial, survival rate, feed consumption, and feed conversion rate were calculated.

Table 1.

Composition of the basal (control) diet (%)

Items Starter (1 to 14 d) Grower (14 to 28 d) Finisher (14 to 42 d)
Ingredient
 Corn 56.3 60.02 67.87
 DDGS 5 5 0
 Meat/bone meal 3 3 3
 Soybean meal 48 31.3 26.71 24.02
 Soy oil 1.12 2.16 2.52
 Salt 0.36 0.36 0.28
 DL methionine 0.27 0.24 0.19
 Threonine 0 0.01 0
 Bio-Lys 0.27 0.31 0.22
 Limestone 0.69 0.74 0.74
 Dicalcium Phos 0.96 0.72 0.57
 Choline chloride 60 0.1 0.1 0.1
 Vitamin premix1 0.63 0.63 0.5
Calculated values
 Crude protein (%) 22.95 21.08 18.99
 Poult (ME kcal/kg) 3,000 3,100 3,200
 Calcium (%) 0.9 0.85 0.8
 Phos (%) 0.74 0.67 0.61
 Avail Phos (%) 0.45 0.4 0.35
 Fat (%) 4.44 5.52 5.7
 Fibre (%) 2.83 2.76 2.51
 Met (%) 0.63 0.58 0.49
 Cys (%) 0.37 0.34 0.32
 Me+Cys (%) 1 0.92 0.81
 Lys (%) 1.33 1.21 1.07
 His (%) 0.6 0.55 0.5
 Tryp (%) 0.25 0.22 0.2
 Thr (%) 0.86 0.8 0.71
 Arg (%) 1.5 1.35 1.23
 Iso (%) 0.95 0.86 0.76
 Leu (%) 1.96 1.83 1.69
 Phe (%) 1.09 1 0.9
 Tyr (%) 0.8 0.73 0.67
 Val (%) 1.07 0.98 0.88
 Gly (%) 1.04 0.97 0.91
 Ser (%) 1.07 0.98 0.88
 Phe+Tyr (%) 1.89 1.73 1.57
 Phytate P (%) 0.22 0.21 0.2
 Na (%) 0.19 0.19 0.15
 Cl (%) 0.29 0.29 0.23
 K (%) 0.91 0.82 0.75
 Linoleic acid (%) 1.69 2.16 2.34
 Na+K-Cl 233.52 211.54 192.7

DDGS, distillers dried grains with soluble; ME, metabolizable energy.

1

Vitamin premix; 0.2 ppm Selenium, 6,608 IU vitamin A, 2,203 ICU vitamin D3, 14 IU vitamin E, 0.88 mg menadione, 9.35 μg vitamin B12, 33 μg biotin, 358 mg choline, 1.1 mg folic acid, 33 mg niacin, 8.8 mg pantothenic acid, 0.88 mg pyridoxine, 4.4 mg riboflavin, 1.1 mg thiamine)/kg basal diet. The diets were formulated to be iso-caloric based on energy values for feed ingredients published by the National Research Council, and were formulated on a total amino acid basis for methionine, threonine, and lysine.

Slaughtering

At the end of the feeding trial, half of the birds (200) were slaughtered in the Meat Lab at Iowa State University following USDA guidelines (Brant et al., 1982) and carcass weight were obtained 24 h after slaughter. Breast muscles were deboned from the carcasses the next day and used to measure color, water holding capacity, cooking loss, ultimate pH, and storage stability.

Growth performance

Body weight and feed intake per cage were recorded, and feed conversion rate was calculated based on feed intake divided by body weight gain throughout the experiment after adjusting mortality.

Physicochemical properties of broiler breast meat

The analyses of the color, pH and water holding capacity in the broiler meat samples were conducted on one of the two breast muscles obtained from each animal by random selection.

Color measurements

Color was measured using a Labscan spectrophotometer (Hunter Associated Labs Inc., Reston, VA, USA) (AMSA, 1991) that had been calibrated against white and black reference tiles covered with the same film as those used for meat samples. Commission Internationale de l’Eclairage (CIE) L* (lightness), a* (redness), and b* (yellowness) values were obtained using illuminant A (light source). Area view and port size were 0.64 and 1.02 cm, respectively. An average value from two random locations of the meat surface was used for statistical analysis.

pH

The pH values of the breast muscle were measured in duplicate with a pH meter. About 10 g of the sample was minced to small pieces and homogenized with 90 mL of distilled water for 60 s using a Polytron homogenizer. The pH values were measured immediately after the homogenization.

Water holding capacity

Water-holding capacity was measured using the centrifugation method of Bertram et al. (2001). Breast samples were cut parallel to the muscle fiber direction, which is about 2.0 cm long and 0.5 cm×0.2 cm in cross-sectional area. The samples were weighed and placed in test tubes with a filter paper (Whatman No. 1) cushion. The tubes were sealed with parafilm and then centrifuged at 400×g at 4°C for 60 min. After centrifugation, the samples were weighed again. Water holding capacity was calculated as the percentage difference in weight before and after centrifugation. Eight replications were conducted for each treatment.

Lipid oxidation (2-thiobarbituric acid reactive substances, TBARS)

Lipid oxidation of breast meat was assessed on the basis of malondialdehyde (MDA) formed during the refrigerated storage. Lipid oxidation was determined using a 2-thiobarbituric acid reactive substances (TBARS) method (Ahn et al., 1998). Meat sample (5 g) was placed in a 50-mL test tube and homogenized with 15 mL deionized distilled water for 15 s at high speed (Type PT 10/35; Brinkman Instrument Inc., Westbury, NY, USA). The meat homogenate (1 mL) was transferred to a disposable test tube, and butylated hydroxytoluene (7.2%, 50 μL) and thiobarbituric acid (TBA)/trichloroacetic acid (TCA) solution (2 mL) were added. The sample was mixed using a vortex mixer, and then incubated in a 90°C water bath for 15 min to develop color. After cooling, the samples were centrifuged at 3,000×g for 15 min at 4°C. The absorbance of the resulting upper layer was read at 531 nm against a blank prepared with 1 mL deionized distilled water and 2 mL TBA/TCA solution. The amounts of TBARS were expressed as mg of MDA per kg of meat.

Statistical analysis

Experiments were carried out in eight replications, and the results represent the average values of the replications. Samples were compared by One way analysis of variance followed by Tukey’s multiple comparison test (SPSS version 18, SPSS Inc., Chicago, Illinois). Statistical significance was set at p<0.05.

RESULTS AND DISCUSSION

Growth performance

The feed consumption and body weight gain of broiler chicks are shown in Table 2. No differences in weekly feed consumption and body weight gain among dietary treatment groups were found during the 6-week feeding trial (p>0.05). The feed consumption of birds with PC, 15 BG and 30 BG were not different from that of the control (NC). However, high level of beta glucan (60 ppm, 60 BG) treatment showed numerically lower feed consumption than other treatments. In agreement with our results, other studies observed no effects of β-glucan on growth performance (Morales-Lopez et al., 2009; Cox et al., 2010). Hahn et al. (2006) also reported that β-glucan did not show any effects on average daily feed intake and gain to feed ratio (G:F ratio) as the β-glucan level of the diet (0, 0.1, 0.2, 0.3, and 0.4 g/kg) increased in weanling pigs.

Table 2.

Effect of β-glucan on the feed consumption and body weight gain of broiler chickens

Items 1 wk 2 wk 3 wk 4 wk 5 wk 6 wk Total
Feed consumed (kg/pen/week)
 NC 1.33±0.12 3.63±0.29 6.51±0.37 9.00±0.51 10.20±0.46 9.67±1.06 40.34±2.81
 PC 1.49±0.11 3.80±0.20 6.78±0.38 8.83±0.58 10.00±0.63 9.65±1.09 40.55±3.00
 15 BG 1.44±0.16 3.81±0.18 6.77±0.39 9.15±0.51 10.01±0.39 9.33±0.67 40.51±2.29
 30 BG 1.45±0.13 3.83±0.18 6.92±0.22 9.21±0.39 10.17±0.29 9.21±0.52 40.79±1.73
 60 BG 1.34±0.11 3.63±0.25 6.32±0.45 8.56±0.68 9.66±0.78 9.25±0.87 38.76±3.15
Body weight gain (kg/pen/week)
 NC 1.50±0.14 2.58±0.31 4.28±0.48 5.38±0.51 5.11±0.53 4.18±0.89 23.03±0.48
 PC 1.58±0.07 2.71±0.17 4.58±0.17 5.40±0.49 5.39±0.23 4.36±0.63 24.04±0.29
 15 BG 1.49±0.09 2.61±0.14 4.40±0.29 5.38±0.40 4.73±0.78 4.37±0.16 22.98±0.31
 30 BG 1.52±0.11 2.55±0.23 4.33±0.28 5.36±0.25 5.11±0.35 4.45±0.81 23.36±0.34
 60 BG 1.53±0.08 2.66±0.14 4.54±0.36 5.60±0.41 5.15±0.26 4.26±0.50 23.74±0.29

Values are mean±standard deviation of each treatment group. n = 8.

NC, negative control; PC, positive control (adding Zinc bacitracin); 15 BG, adding 15 ppm β-glucan (6 g/100 kg diet); 30 BG, adding 30 ppm β-glucan (12 g/100 kg diet); 60 BG, adding 60 ppm β-glucan (24 g/100 kg diet).

Table 3 showed the feed conversion rate of chickens fed with diets containing various concentrations of β-glucan. There was no significant difference in feed conversion rate among the five treatment groups. However, the high-level β-glucan treatment (60 ppm, 60 BG) showed numerically better feed conversion rate than the negative control (Table 3). In fact, 60 ppm β-glucan group showed better feed conversion rate than that of 55 ppm bacitracin group (PC), which is encouraging. Mao et al. (2005) reported that dietary supplement of 1,3-1,6-β-glucans from Chinese herb did not show the improvement of performances. Also, 1,3-1,6,-β-glucan extracted from Paenibacillus polymyxa showed no significant improvement in growth performances (Hwang et al., 2008). These findings suggested that β-glucans from various sources were able to cause divergent responses in relation with their structures and sources. All β-glucan treatment groups (15 BG – 60 BG) showed numerically higher survival rate than the control, and the survival rate of 60 ppm β-glucan-treated group (60 BG) was the same as that of the antibiotic-treated group (PC), which showed the highest survival rate among the treatments (Table 3). Our results suggested that >60 ppm of dietary β-glucan can have a possibility of replacing antibiotics to improve survival rate and promote growth of broilers.

Table 3.

Effect of β-glucan on the feed conversion rate and survival rate of broiler chickens

Group Feed conversion rate Survival rate (%)
NC 1.752±0.170 93.75
PC 1.687±0.101 98.75
15 BG 1.763±0.188 96.25
30 BG 1.746±0.096 96.25
60 BG 1.633±0.218 98.75

Values are mean±standard deviation of each treatment group. n = 8.

NC, negative control; PC, positive control (adding Zinc bacitracin); 15 BG; adding 15 ppm β-glucan; 30 BG, adding 30 ppm β-glucan; 60 BG, adding 60 ppm β-glucan.

Physicochemical properties of breast meat

Color is the most important perceivable quality in meat products in terms of consumer acceptance. Many factors have been shown to affect poultry meat color, such as bird sex, age, strain, method of processing, exogenous chemicals, cooking method irradiation, and freezing (Froning, 1995). Table 4 shows the color L*-values (lightness), a*-values (redness), and b*-values (yellowness) of chicken breast meat from chickens fed with various concentrations of β-glucan. The lightness of chicken breast meat decreased significantly during storage due to pigments oxidation, but no significant difference among 5 treatment groups was found. Redness and yellowness also were not influenced by the dietary treatments and storage even though there were some ups and downs in the values. This result indicated that dietary Zinc bacitracin and β-glucan had no effects on the color values of chicken breast meat. Other research agreed that β-glucan (13.45% Nutrim-10 which contain 10% β-glucan) did not affect the color characteristics in beef patties (Pinero et al., 2008).

Table 4.

Dietary effects of β-glucan on the meat color quality in broiler chickens

0 d 1 d 3 d 7 d
L* NC 60.87±2.22ay 59.98±3.17ay 59.75±2.25ay 57.49±2.19ax
PC 61.45±1.65az 59.27±1.39ay 59.07±2.77ay 55.61±2.73ax
15 BG 60.76±2.39az 58.16±2.08axy 57.49±1.35ax 59.64±1.87byz
30 BG 59.54±2.30ax 58.64±2.19ax 57.76±3.36ax 57.38±2.66ax
60 BG 61.33±2.54ay 60.34±3.90axy 57.86±2.57ax 57.90±2.81ax
a* NC 7.50±1.70ax 7.14±1.52ax 7.05±0.97ax 8.43±2.01ax
PC 7.93±1.55ax 8.27±1.22axy 7.48±1.37abx 9.29±1.44ay
15 BG 7.83±1.14ax 8.44±1.54ax 7.54±2.06abx 8.07±1.37ax
30 BG 7.73±1.60ax 8.31±0.98ax 8.86±1.64bx 8.44±2.11ax
60 BG 8.72±1.45ax 8.28±1.33ax 8.54±1.53bx 7.89±1.39ax
b* NC 12.14±1.72ax 11.67±3.08ax 10.75±0.93ax 13.74±2.79ay
PC 13.32±2.68bx 12.38±1.50ax 12.98±2.14ax 13.37±1.88ax
15 BG 12.61±1.45ax 12.38±2.32ax 11.80±3.20ax 14.09±3.11ax
30 BG 11.87±1.42ax 11.85±2.16ax 12.81±3.24ax 13.95±3.71ax
60 BG 14.48±1.11by 12.17±2.65ax 12.59±1.87ax 14.34±1.71ay

Values are mean±standard deviation of each treatment group. n = 8.

NC, negative control; PC, positive control (adding Zinc bacitracin); 15 BG, adding 15 ppm β-glucan; 30 BG, adding 30 ppm β-glucan; 60 BG, adding 60 ppm β-glucan.

a–c

Statistically significant differences (p<0.05) between column.

x–z

Statistically significant differences (p<0.05) between incubation row.

Meat pH is known to influence parameters related to meat quality including color, tenderness, flavor and shelf-life. The pH of the chicken breast with various concentrations of β-glucan is shown in Table 5. The pH of chicken breast meat was not significantly different among the dietary treatments groups even though there were some decrease in pH after 1 day of storage in all groups (p>0.05). Water holding capacity (WHC) of the chicken breast from chickens fed with various concentrations of β-glucan is shown in Table 5. The water holding capacity of the chicken breast meat was not significantly different among the treatment groups and during storage (p>0.05). There were very large variations in WHC among the breast muscles even from the same dietary treatment group. No difference in carcass yield among the treatment groups was also detected (data not shown).

Table 5.

Dietary effects of β-glucan on the pH values and the water holding capacity in broiler chickens

Items 0 d 1 d 3 d 7 d
pH
 NC 6.30±0.14bx 6.22±0.17ax 6.20±0.12ax 6.29±0.09ax
 PC 6.12±0.10ax 6.24±0.08ax 6.27±0.07ax 6.18±0.09ax
 15 BG 6.42±0.09cy 6.23±0.10ax 6.22±0.09ax 6.24±0.11ax
 30 BG 6.48±0.12cy 6.21±0.15ax 6.22±0.14ax 6.23±0.10ax
 60 BG 6.12±0.14ax 6.18±0.13ax 6.20±0.09ax 6.21±0.07ax
Water holding capacity
 NC 83.66±2.16ax 82.91±4.47ax 81.76±4.78ax 81.51±5.47ax
 PC 83.18±2.55ax 81.90±3.02ax 85.06±5.12ax 81.18±6.22ax
 15 BG 84.49±2.43ay 83.59±6.51ay 85.38±5.35ay 77.09±6.09ax
 30 BG 82.50±3.26ax 82.40±4.38ax 82.31±5.89ax 79.34±5.30ax
 60 BG 81.27±3.25ax 81.12±4.39ax 81.02±3.28ax 82.86±3.06ax

Values are mean±standard deviation of each treatment group. n = 8.

NC, negative control; PC, positive control (adding Zinc bacitracin); 15 BG, adding 15 ppm β-glucan; 30 BG, adding 30 ppm β-glucan; 60 BG, adding 60 ppm β-glucan.

a–c

Statistically significant differences (p<0.05) between column.

x–z

Statistically significant differences (p<0.05) between row.

Lipid oxidation of the raw chicken breast meat during storage is shown in Table 6. The TBARS values of chicken breast were not differ significantly among the treatment groups. The TBARS values of chicken breast meat during the 7-day storage time differ significantly: 3d-stored samples had the lowest and 7 day-stored samples had the highest values. However, the difference does not have much practical meaning to the meat quality at these low values. Dileep et al. (2011) demonstrated that β-glucan had radical scavenging ability while trying to use as hemopoietic stimulant/radioprotectant, and Thondre et al. (2011) reported that the free radical scavenging ability of β-glucan is due to the presence of polyphenol and antioxidant content in the commercial β-glucan sample. All the TBARS values of raw chicken breast meat are very low, indicating that raw chicken breasts are highly resistant to oxidative changes during storage. Although dietary β-glucan showed some effects to broiler performances, but did not show significant effect to the meat quality.

Table 6.

Dietary effects of β-glucan on the lipid oxidation in raw broiler chicken breast meat

0 d 3 d 7 d
NC 0.16±0.07ay 0.09±0.01ax 0.20±0.03ay
PC 0.17±0.04axy 0.14±0.16ax 0.26±0.03ay
15 BG 0.14±0.04ay 0.08±0.02ax 0.21±0.04az
30 BG 0.15±0.04ax 0.11±0.01ax 0.22±0.06ay
60 BG 0.15±0.04ay 0.08±0.01ax 0.21±0.03az

Values are mean±standard deviation of each treatment group. n = 8.

NC, negative control; PC, positive control (adding Zinc bacitracin); 15 BG, adding 15 ppm β-glucan; 30 BG, adding 30 ppm β-glucan; 60 BG, adding 60 ppm β-glucan.

a–c

Statistically significant differences (p<0.05) between column.

x–z

Statistically significant differences (p<0.05) between row.

CONCLUSION

Dietary supplementation with β-glucan improved survival rate and feed efficiency. In general, these responses indicated that β-glucan can be a potential alternative to antibiotic growth promoter in order to improve growth performance. However, dietary β-glucan showed no effects on the quality parameters of chicken breast meat.

ACKNOWLEDGMENTS

This study was supported jointly by Naturence Co., Ltd., Korea and the Next-Generation BioGreen 21 Program (No. PJ00964305), Rural Development Administration, Republic of Korea.

Footnotes

CONFLICT OF INTEREST

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

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