Go to Top Go to Bottom
Anim Biosci > Volume 30(4); 2017 > Article
Son, Park, and Kim: Determination and prediction of digestible and metabolizable energy concentrations in byproduct feed ingredients fed to growing pigs

Abstract

Objective

An experiment was conducted to determine digestible energy (DE) and metabolizable energy (ME) of different byproduct feed ingredients fed to growing pigs, and to generate prediction equations for the DE and ME in feed ingredients.

Methods

Twelve barrows with an initial mean body weight of 31.8 kg were individually housed in metabolism crates that were equipped with a feeder and a nipple drinker. A 12×10 incomplete Latin square design was employed with 12 dietary treatments, 10 periods, and 12 animals. A basal diet was prepared to mainly contain the corn and soybean meal (SBM). Eleven additional diets were formulated to contain 30% of each test ingredient. All diets contained the same proportion of corn:SBM ratio at 4.14:1. The difference procedure was used to calculate the DE and ME in experimental ingredients. The in vitro dry matter disappearance for each test ingredient was determined.

Results

The DE and ME values in the SBM sources were greater (p<0.05) than those in other ingredients except high-protein distillers dried grains. However, DE and ME values in tapioca distillers dried grains (TDDG) were the lowest (p<0.05). The most suitable regression equations for the DE and ME concentrations (kcal/kg on the dry matter [DM] basis) in the test ingredients were: DE = 5,528–(156×ash)–(32.4×neutral detergent fiber [NDF]) with root mean square error = 232, R2 = 0.958, and p<0.001; ME = 5,243–(153 ash)–(30.7×NDF) with root mean square error = 277, R2 = 0.936, and p<0.001. All independent variables are in % on the DM basis.

Conclusion

The energy concentrations were greater in the SBM sources and were the least in the TDDG. The ash and NDF concentrations can be used to estimate the energy concentrations in the byproducts from oil-extraction and distillation processes.

INTRODUCTION

Oilseed meals are used primarily as a protein source [1], but play a role as an energy source in swine diets. Soybean meal (SBM) is one of the most commonly used oilseed meals in the swine diet. However, alternative feed ingredients, which can replace the SBM in the swine diet, are needed as the price of SBM has been continuously increasing. An accurate determination of energy concentrations of the ingredients is important to use relatively cheaper feed ingredients in the swine diet. However, studies about energy concentrations in various protein sources for pigs are limited.
The digestible energy (DE) and metabolizable energy (ME) concentrations of the feed ingredients are ideally determined via animal experiment, which is the most accurate method. However, because animal experiments are time-consuming and costly, equations for predicting the energy concentrations of feed ingredients can be used as an alternative method [2]. Additionally, the in vitro dry matter disappearance (IVDMD) of ingredients can also be useful for predicting energy concentration in ingredients for swine diets [3]. However, the use of equations can be limited to the range of nutrient compositions in the ingredients that were used to generate the equations [4,5]. We hypothesized that energy concentrations in the feed ingredients with large range of chemical composition can be estimated using prediction equations with the IVDMD as an independent variable. The objectives were to determine the DE and ME of 9 byproducts from the oil-extraction process and 2 byproducts from distillation process fed to growing pigs and to generate equations that predict the DE and ME of byproduct feed ingredients.

MATERIALS AND METHODS

Animal care

The experimental procedure was approved by the Institutional Animal Care and Use Committee at Konkuk University (KU 12062).

Diet and feeding

Twelve barrows with a mean initial body weight of 31.8 kg (standard deviation = 2.7) were used to determine the DE and ME concentrations of sesame meal produced in Korea, two sources of dehulled SBM produced in Korea (SBM-KD1 and SBM-KD2), SBM produced in India (SBM-I), high-protein distillers dried grains (HPDDG) produced from corn in the USA, perilla meal (PM) produced in Korea, canola meal produced in Indonesia, copra meal produced in the Philippines, corn germ meal produced in Korea, palm kernel expellers produced in Malaysia, and tapioca distillers dried grains (TDDG) produced in China (Table 1). The palm kernel product was classified as the expellers because the concentration of ether extract in the feed ingredient was 6.97% [6].
The pigs were placed in metabolic cages equipped with a feeder and a nipple drinker. A 12×10 incomplete Latin square design was employed with 12 dietary treatments, 10 periods, and 12 animals. Potential carryover effects were balanced using a spreadsheet-based program [7]. The quantity of feed provided daily per pig was calculated as approximately 2.7 times the estimated energy requirement for maintenance (i.e., 106 kcal of ME per kg body weight0.75) adjusted in the NRC [8] based on the calculated ME concentration in the diets. The feed was divided into two equal meals and fed to pigs at 0730 and 1630. Water was available at all times. Body weight was measured at the end of each period to determine feed allowance.
A basal diet contained corn and SBM as the sole energy sources. Eleven additional diets were formulated to contain 30% of each test ingredient (Table 2). All diets contained the same proportion of corn:SBM ratio at 4.14:1. Vitamins and minerals were adequate to meet requirement estimates in the literature [8].

Sample collection

An experimental period consisted of a 4-d adaptation period and a 4-d collection period. Feed refusals were collected and dried in a forced-air drying oven at 55°C until constant weight, and then weighed after cooling at room temperature. Feces were quantitatively collected according to the marker-to-marker procedure [9]. Chromic oxide was used as an indigestible marker and was included at 0.5% in morning meals on d 5 and 9. Fecal collection was started when the green color of marker begin to appear in the feces, and ended when the green color appeared again. Urine was collected from 1400 on d 5 to 1400 on d 9 using plastic containers including a 200 mL of 2 N HCl. A 200 mL aliquot of urine from each animal was placed in a plastic bottle. All feces and the urine were stored at −20°C immediately after collection.

Chemical analysis

The fecal samples were dried in a forced-air drying oven at 55°C and ground before analysis. All diet and fecal samples were dried in a forced-air drying oven at 135°C for 2 h to analyze dry matter [10]. The urine samples were dried according to a method described previously [11]. Approximately 3 mL of the urine sample was added to a cotton ball (0.3 to 0.4 g) placed in a stainless steel crucible. The weight of crucible, cotton ball, and urine was recorded, and then the samples were dried in a freeze dryer for 24 h. Samples of the diets, ingredients, feces, and urine were analyzed for gross energy (GE) concentration using a bomb calorimeter (C 2000; IKA, Staufen, Germany). Ingredient samples were analyzed for crude protein (CP; method 990.03), ether extract (method 920.39), crude fiber (method 978.10) and ash (method 942.05) [12]. Diet and ingredient samples were also analyzed for neutral detergent fiber (NDF; method 2002.04), acid detergent fiber (ADF; method 973.18), calcium (method 978.02), and phosphorus (method 946.06) [12]. The diet samples were also analyzed for the CP and ash according to the aforementioned procedures. Duplicate analyses were performed for the all samples, but the GE concentration was analyzed in triplicate.

Calculation

After the chemical analyses, energy digestibility and metabolizability were calculated using the amount of energy intake and excreted feces and urine. The DE and ME concentrations in the sum of corn and SBM in the basal diet were calculated by dividing energy concentration in the basal diet by the sum of corn and SBM concentrations. The DE and ME concentrations of the test ingredients were calculated using a difference procedure [9].

In vitro dry matter disappearance

The IVDMD of 11 ingredients was determined using procedures reported in previous studies [1315] with minor modification. The procedure consisted of three steps, and each step simulated digestion in the stomach, small intestine, and large intestine of pigs. In the first step, 0.5 g of ingredient sample was placed in a 100-mL flask with 25 mL of phosphate buffer solution (0.1 M, pH 6.0) and 10 mL of 0.2 M HCl. Then the pH was adjusted to 2.0 using a 1 M HCl or 1 M NaOH solution, and 1 mL of pepsin solution (25 mg/mL; ≥250 units/mg solid, P7000, Pepsin from porcine gastric mucosa, Sigma-Aldrich, St. Louis, MO, USA) was added. The test flasks were incubated in a shaking incubator at 39°C for 2 h.
In the second step, 10 mL of phosphate buffer solution (0.2 M, pH 6.8) and 5 mL of 0.6 M NaOH solution were added in the test flasks. Then the pH was adjusted to 6.8, and 1 mL of pancreatin solution (100 mg/mL; 4×USP, P1750, Pancreatin from porcine pancreas, Sigma-Aldrich, USA) was added. Then the test flasks were incubated in a shaking incubator at 39°C for 4 h.
In the third step, 10 mL of 0.2 M ethylenediaminetetraacetic acid solution was added in the test flasks. The pH was adjusted to 4.8. As a substitution of microbial enzyme, 0.5 mL of Viscozyme (V2010, Viscozyme L, Sigma-Aldrich, USA) was added. Then the test flasks were incubated in a shaking incubator for 18 h at 39°C.
Following the incubation, undigested residues were filtered in glass filter crucibles containing 500 mg of celite as filter aid using the Fibertec System (Fibertec System 1021 Cold Extractor, Tecator, Höganäs, Sweden). Undigested residues in glass filter crucibles were rinsed twice with 10 mL of 95% ethanol and 99.5% acetone. Then, glass filter crucibles with undigested samples were dried at 130°C for 6 h. After 1 h cooling in a desiccator, glass filter crucibles were weighed. The IVDMD for each ingredient was measured in triplicate.

Statistical analysis

Data were analyzed using the MIXED procedure of SAS (SAS Inst. Inc., Cary, NC, USA). Outliers (difference from median> 2×interquartile range) were removed from the dataset for the final statistical analysis. The model included dietary treatment as a fixed variable and animal and period as random variables. Least squares means of each treatment were calculated, and the difference in means was tested using the PDIFF option with the Tukey’s adjustment. The experimental unit was a pig, and the statistical significance was set at p-value <0.05.
Correlation coefficients (r) between nutrient compositions and energy concentrations were determined using the CORR procedure of SAS. A Multiple linear regression analysis was conducted by the REG procedure of SAS in order to generate regression equations for the DE and ME of the ingredients based on nutrient contents and IVDMD of the ingredients as independent variables. The most representative prediction equation was selected based on the STEPWISE procedure of SAS. A prediction equation for the DE:GE ratio was developed using the REG procedure of SAS with IVDMD as an independent variable.

RESULTS

Nutrient composition

Values for the GE of the ingredients ranged from 3,875 to 4,924 kcal/kg on an as-is basis (Table 1). The CP concentration of the ingredients ranged from 15.3% to 50.0%, and the NDF concentration ranged from 7.35% to 61.4% on an as-is basis.

Digestible and metabolizable energy

Feed intake during the collection period was greater (p<0.05) for the basal, palm kernel expellers, and TDDG diets than that for the HPDDG and canola meal diets (Table 3). Energy digestibility of the basal and SBM-containing diets was greater (p<0.05) than that of the other diets. The DE concentration in the SBM-KD1 diet was greater (p<0.05) than that in the other experimental diets except the SBM-KD2 diet. The ME concentration in the SBM-KD1 diet was also greater (p<0.05) than that in the other diets except the SBM-KD2 and SBM-I diets. The DE and ME in the TDDG diet were the lowest (p<0.05) among the experimental diets. The DE and ME (kcal/kg on an as-fed basis) in the three sources of SBM ingredients were greater (p<0.05) than those in the other experimental ingredients except the HPDDG (Table 4). The DE and ME in the TDDG were also the lowest (p<0.05) among the experimental ingredients.

Prediction equations for energy concentrations and energy digestibility

The DE and ME in the ingredient samples were correlated (p<0.05) with the crude fiber, ash, NDF, ADF, IVDMD, and DE:GE ratio (Table 5). A high correlation (p<0.001) was observed between the DE and ME. The NDF and ADF were negatively correlated (p<0.01) with the DE in the byproduct feed ingredients. The R2 and p-values of the equation and independent variables were used to evaluate the suitability of the prediction equations, and 3 prediction equations for each of DE and ME were chosen based on the suitability (Tables 6 and 7). The most suitable regression equation for the DE in the byproduct feed ingredients was equation 2: DE (kcal/kg on the dry matter basis) = 5,528–(156×ash)–(32.4×NDF) with root mean square error = 232, R2 = 0.958, and p-value <0.001. The most suitable regression equation for ME in the byproduct feed ingredients was equation 2: ME (kcal/kg on the dry matter basis) = 5,243–(153×ash)–(30.7×NDF) with root mean square error = 277, R2 = 0.936, and p-value <0.001. All independent variables are presented in % on the dry matter basis. A linear relationship was observed between the energy digestibility and IVDMD (r2 = 0.534 and p = 0.011; Figure 1).

DISCUSSION

Most nutrient compositions of ingredients were within range of previous studies [2,4]. In this study, the lowest DE and ME values in the TDDG diet can be explained mainly by the largest fecal energy output in the pigs fed the TDDG diet. Although GE intake by pigs fed the TDDG diet was not different from most of the other experimental diets, the dry feces output of pigs fed the TDDG diet was the greatest among the experimental diets. The large quantity of fecal output may be caused by the high fiber concentration in the TDDG, which increases passage rate of digesta and lowers time for digestion and absorption of nutrients [16,17]. Therefore, fecal GE output of pigs fed the TDDG diet was greater than that of pigs fed the other experimental diets except the PM diet despite being the lowest GE in dry feces. For these reasons, the DE in the TDDG diet may be less than that in the other experimental diets. The TDDG diet had the lowest ME value, which may have occurred because the TDDG diet had the lowest DE and the urinary GE output of pigs fed the TDDG diet was not different from most of the other experimental diets.
The DE and ME in the sesame meal were less than values in the literature [2,4], which appear to be due to the greater NDF and ADF concentrations in the sesame meal used in this experiment than the fiber concentrations in the literature [2,4]. Dietary fiber negatively affects the energy utilization [16,18]. Thus, although the GE of sesame meal in this experiment was similar to values in the literature, the DE:GE ratio was less in this experiment than that reported in the literature [2,4].
The GE, DE, and ME in the two sources of SBM-KD were within the range of previous values [2,4,19,20]. The DE, ME, and DE:GE ratio in the SBM-I were similar to the previous values [2,4].
The DE and ME in the HPDDG were less than previous values [4,11,21,22], but were similar with a previous value [23]. The GE in the HPDDG used in this experiment was within the range of previous values, but the DE:GE ratio was less than that in previous studies, resulting in a lower DE and ME in the HPDDG used in this experiment. We cannot clearly explain why energy digestibility was less compared with previous studies; however, it may be a result of unknown factors, such as region, variety, manufacturing process, or the presence of anti-nutritional factors.
The energy concentrations and nutrient composition in the canola meal determined were comparable with previous values [4,20,24,25]. In the present study, the average daily feed intake for the pigs fed the canola meal diet was the least among the pigs fed other diets. The glucosinolate which is an anti-nutritional factor in the canola meal may contribute to the low feed intake. It has been known that the dietary glucosinolates have an adverse effect on the feed intake for pigs [26]. The GE, DE, and ME in the copra meal used in this experiment were less than those reported in the literature [4,27]. In particular, the DE:GE ratio of copra meal was less in our study compared with the previous values. This reason may be that the NDF and ADF concentrations in the copra meal used in this experiment were greater than those used previously, and a relatively large proportion of non-starch polysaccharides, such as mannans, may have been present in copra meal [28], which can be an anti-nutritional factor. The concentrations and digestibility of energy in the corn germ meal were within the range of previous values [2,4,21,23, 29]. The GE, DE, and ME in the palm kernel expellers were also within the range of previous studies [2,4,5,27].
The DE and ME in the PM and TDDG for pigs have not been reported. The DE:GE ratios of PM and TDDG were considerably less than those of other test ingredients. However, the CP concentration in the PM and TDDG was relatively greater than that in corn, and the CP concentration in the PM was fairly comparable to the CP in the SBM. Therefore, the PM and TDDG would be good alternative ingredients if studies are conducted to improve the energy efficiency of PM and TDDG. Further research is needed to determine the amino acid composition and digestibility of PM and TDDG.
In this study, there was a negative correlation between the fiber and DE concentration in the test ingredients, which agree with previous studies [30]. Although the most suitable equation for the ME was equation 1 considering the root mean square error, R2, and p-value for the model, the CP as the independent variable was excluded because no significant correlation was found between the ME and CP. In a previous study [3], the IVDMD was highly correlated with energy digestibility in an in vivo experiment, and was a good predictor to estimate energy digestibility. A strong relationship between the energy digestibility and IVDMD was also observed in this experiment.
In conclusion, the three sources of SBM had greater energy concentrations than that in most of the byproduct feed ingredients and had greater energy digestibility than that in other byproduct feed ingredients fed to growing pigs. The ash and NDF were useful for estimating energy concentrations in the byproduct feed ingredients. The IVDMD was also useful to estimate energy digestibility.

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

This work was supported by the Rural Development Administration (Republic of Korea; PJ907038). This paper was written as part of Konkuk University’s research support program for its faculty on sabbatical leave in 2016.

Figure 1
Relationship between energy digestibility and in vitro dry matter disappearance for growing pigs. An equation for energy digestibility in 11 byproduct feed ingredients fed to growing pigs was generated using 3-step in vitro dry matter diappearance as an independent variable (n = 11).
ajas-30-4-546f1.gif
Table 1
Energy and nutrient composition of experimental ingredients1) (as-is basis)
Item Ingredient

Sesame meal Soybean meal-dehulled-Korea 1 Soybean meal-dehulled-Korea 2 Soybean meal-India High-protein distillers dried grains Perilla meal Canola meal Copra meal Corn germ meal Palm kernel expellers Tapioca distillers dried grains
Dry matter (%) 97.0 90.2 90.2 90.1 91.5 90.3 91.4 90.2 94.1 89.6 93.3
Gross energy (kcal/kg) 4,688 4,299 4,332 4,221 4,924 4,240 4,235 4,095 4,699 4,407 3,875
Crude protein (%) 50.0 47.1 47.4 39.6 38.0 43.2 37.5 21.8 21.4 15.3 18.4
Ether extract (%) 6.05 2.46 0.74 0.84 5.24 1.08 1.85 1.76 8.27 6.97 3.12
Crude fiber (%) 9.3 4.6 5.7 5.1 7.3 18.8 9.6 13.6 10.4 17.0 22.7
Ash (%) 11.0 6.2 6.3 6.3 1.4 9.0 9.5 6.7 2.4 4.7 14.9
Neutral detergent fiber (%) 28.1 7.4 8.7 9.6 39.0 44.7 24.7 55.1 43.4 61.4 56.2
Acid detergent fiber (%) 17.5 7.2 9.1 8.2 20.1 25.9 18.1 32.2 14.6 36.8 47.3
Calcium (%) 2.15 0.64 0.67 0.70 0.13 1.71 1.01 0.62 0.13 0.43 0.77
Phosphorus (%) 1.32 0.64 0.62 0.53 0.25 1.25 0.95 0.54 0.53 0.55 0.22

1) Data are the mean of duplicate analyses of each ingredient.

Table 2
Ingredient composition and analyzed composition of experimental diets (as-fed basis)
Item Diet

Basal Sesame meal Soybean meal-dehulled-Korea 1 Soybean meal-dehulled-Korea 2 Soybean meal-India High-protein distillers dried grains Perilla meal Canola meal Copra meal Corn germ meal Palm kernel expellers Tapioca distillers dried grains
Ingredient (%)
 Ground corn 78.60 54.44 54.44 54.44 54.44 54.44 54.44 54.44 54.44 54.44 54.44 54.44
 Soybean meal, 48% crude protein 19.00 13.16 13.16 13.16 13.16 13.16 13.16 13.16 13.16 13.16 13.16 13.16
 Sesame meal - 30.0 - - - - - - - - - -
 Soybean meal-dehulled-Korea 1 - - 30.0 - - - - - - - - -
 Soybean meal-dehulled-Korea 2 - - - 30.0 - - - - - - - -
 Soybean meal-India - - - - 30.0 - - - - - - -
 High-protein distillers dried grains - - - - - 30.0 - - - - - -
 Perilla meal - - - - - - 30.0 - - - - -
 Canola meal - - - - - - - 30.0 - - - -
 Copra meal - - - - - - - - 30.0 - - -
 Corn germ meal - - - - - - - - - 30.0 - -
 Palm kernel expellers - - - - - - - - - - 30.0 -
 Tapioca distillers dried grains - - - - - - - - - - - 30.0
 Ground limestone 0.7 0.7 0.7 0.7 0.7 0.7 0.7 0.7 0.7 0.7 0.7 0.7
 Dicalcium phosphate 0.8 0.8 0.8 0.8 0.8 0.8 0.8 0.8 0.8 0.8 0.8 0.8
 Salt 0.4 0.4 0.4 0.4 0.4 0.4 0.4 0.4 0.4 0.4 0.4 0.4
 Vitamin-mineral premix1) 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5
Analyzed composition2)
 Dry matter (%) 88.2 90.5 88.7 89.3 88.6 88.6 89.1 89.2 89.0 90.1 89.6 90.2
 Gross energy (kcal/kg) 3,941 4,137 4,032 4,225 3,986 4,007 3,988 3,989 3,954 4,164 4,087 3,864
 Crude protein (%) 14.6 24.6 24.3 28.3 22.1 21.9 27.2 24.6 19.9 21.0 19.2 19.8
 Ash (%) 8.9 11.8 9.6 10.3 8.7 9.7 13.4 10.8 8.6 11.2 8.0 10.5

1) Provided the following quantities per kg of complete diet: vitamin A, 25,000 IU; vitamin D3, 4,000 IU; vitamin E, 50 IU; vitamin K, 5.0 mg; thiamin, 4.9 mg; riboflavin, 10.0 mg; pyridoxine, 4.9 mg; vitamin B12, 0.06 mg; pantothenic acid, 37.5 mg; folic acid, 1.10 mg; niacin, 62 mg; biotin, 0.06 mg; Cu, 25 mg as copper sulfate; Fe, 268 mg as iron sulfate; I, 5.0 mg as potassium iodate; Mn, 125 mg as manganese sulfate; Se, 0.38 mg as sodium selenite; Zn, 313 mg as zinc oxide; and butylated hydroxytoluene, 50 mg.

2) Data are the mean of duplicate analyses of each ingredient.

Table 3
Energy utilization of basal and experimental diets containing test ingredients fed to growing pigs
Item Diet SEM p-value

Basal Sesame meal Soybean meal-dehulled-Korea 1 Soybean meal-dehulled-Korea 2 Soybean meal-India High-protein distillers dried grains Perilla meal Canola meal Copra meal Corn germ meal Palm kernel expellers Tapioca distillers dried grains
Observation (n) 10 10 9 9 10 8 9 5 8 10 10 8
Feed intake (kg/d) 1.82a 1.79ab 1.80ab 1.73abc 1.72abc 1.58bc 1.78ab 1.49c 1.81ab 1.70abc 1.82a 1.82a 0.15 <0.001
GE intake (Mcal/d) 7.18a 7.42a 7.23a 6.93ab 6.85ab 6.68ab 7.13a 5.97b 7.14a 7.10a 7.46a 7.04ab 0.62 0.003
Dry feces output (kg/d) 0.20d 0.41b 0.19d 0.20d 0.20d 0.26cd 0.41b 0.25cd 0.36b 0.29c 0.37b 0.51a 0.03 <0.001
GE in dry feces (kcal/kg) 4,545b 4,239d 4,285cd 4,381c 4,311cd 4,757a 4,371c 4,002e 4,504b 4,794a 4,538b 4,077e 32 <0.001
Fecal GE output (kcal/d) 904e 1,726b 816e 862e 881e 1,240d 1,800ab 1,013de 1,632bc 1,373cd 1,688b 2,059a 120 <0.001
Energy digestibility (%) 87.0a 76.4c 88.3a 87.3a 87.0a 81.6b 74.1d 83.0b 77.1c 80.6b 77.3c 71.0e 0.7 <0.001
DE in diet (kcal/kg) 3,428bc 3,161e 3,560a 3,500ab 3,466b 3,446bc 2,954f 3,312d 3,049f 3,357cd 3,159e 2,744g 29 <0.001
Urine output (kg/d) 4.00ab 2.66ab 3.66ab 4.35a 3.48ab 2.84ab 2.98ab 2.14ab 3.51ab 2.52ab 3.01ab 2.16b 0.62 0.015
GE in urine (kcal/kg) 62.6bc 119a 65.6bc 61.8bc 70.2bc 96.2abc 89.7abc 114ab 50.4c 99.4ab 69.9bc 81.1abc 12.4 <0.001
Urinary GE output (kcal/d) 160c 286a 196bc 191bc 195bc 240ab 242ab 217abc 170bc 199bc 159c 134c 27 <0.001
ME in diet (kcal/kg) 3,343b 3,003ef 3,455a 3,385ab 3,354ab 3,301bc 2,821g 3,171cd 2,958f 3,242c 3,072de 2,667h 29 <0.001

SEM, standard error of the mean; GE, gross energy; DE, digestible energy; ME, metabolizable energy.

a–h Means within a row without a common superscript letter differ (p<0.05).

Table 4
Energy values of byproduct feed ingredients fed to growing pigs
Item Ingredient SEM p-value

Sesame meal Soybean meal-dehulled-Korea 1 Soybean meal-dehulled-Korea 2 Soybean meal-India High-protein distillers dried grains Perilla meal Canola meal Copra meal Corn germ meal Palm kernel expellers Tapioca distillers dried grains
Observation (n) 10 9 9 10 8 9 5 8 10 10 8
As-fed basis
 GE (kcal/kg) 4,688 4,299 4,332 4,221 4,924 4,240 4,235 4,095 4,699 4,407 3,875
 DE (kcal/kg) 2,592e 3,925a 3,725ab 3,610ab 3,544bc 1,907f 3,096d 2,219f 3,247cd 2,586e 1,202g 101 <0.001
 ME (kcal/kg) 2,269ef 3,782a 3,552ab 3,445ab 3,271bc 1,672g 2,832cd 2,122f 3,071c 2,506de 1,157h 101 <0.001
 DE:GE ratio 0.55c 0.91a 0.86a 0.86a 0.72b 0.45d 0.73b 0.54c 0.69b 0.59c 0.31e 0.02 <0.001
 ME:DE ratio 0.88b 0.96a 0.95a 0.95a 0.92ab 0.88b 0.91ab 0.96a 0.95a 0.97a 0.97a 0.01 <0.001
 ME:GE ratio 0.48d 0.88a 0.82a 0.82a 0.66b 0.39e 0.67b 0.52cd 0.65b 0.57c 0.30f 0.02 <0.001
Dry matter basis
 GE (kcal/kg) 4,832 4,767 4,802 4,684 5,380 4,695 4,631 4,540 4,992 4,918 4,152
 DE (kcal/kg) 2,630d 4,381a 4,063ab 4,036ab 3,962b 2,046e 3,375c 2,413de 3,412c 2,747d 1,132f 113 <0.001
 ME (kcal/kg) 2,279e 4,222a 3,872ab 3,850ab 3,655b 1,785f 3,081cd 2,306e 3,222c 2,661de 1,087g 112 <0.001

SEM, standard error of the mean; GE, gross energy; DE, digestible energy; ME, metabolizable energy.

a–h Means within a row without a common superscript differ (p<0.05).

Table 5
Correlation coefficients between nutrient composition and energy concentration in byproduct feed ingredients for growing pigs (as-fed basis)
Item Correlation coefficient (r)

EE CF Ash NDF ADF GE DE ME IVDMD DE:GE ratio
CP −0.48 −0.63* 0.02 −0.82** −0.74** 0.23 0.52 0.47 0.72* 0.52
EE - 0.10 −0.40 0.44 0.17 0.50 −0.06 −0.07 −0.34 −0.17
CF - - 0.50 0.84** 0.92*** −0.51 −0.93*** −0.91*** −0.81** −0.92***
Ash - - - 0.07 0.43 −0.86*** −0.68* −0.68* −0.14 −0.57
NDF - - - - 0.89*** −0.12 −0.75** −0.73* −0.90*** −0.81**
ADF - - - - - −0.45 −0.86*** −0.84** −0.92*** −0.87***
GE - - - - - - 0.62* 0.58 0.11 0.47
DE - - - - - - - 1.00*** 0.67* 0.98***
ME - - - - - - - - 0.65* 0.99***
IVDMD - - - - - - - - - 0.73**

EE, ether extract; CF, crude fiber; NDF, neutral detergent fiber; ADF, acid detergent fiber; GE, gross energy; DE, digestible energy; ME, metabolizable energy; IVDMD, in vitro dry matter disappearance.

* p<0.05;

** p<0.01;

*** p<0.001.

Table 6
Regression equations for digestible energy in byproduct feed ingredients for growing pigs (kcal/kg dry matter basis)
Regression coefficient parameter (% dry matter basis) Statistical parameter


Intercept CP CF Ash NDF RMSE R2 p-value
Equation 1 6,084 −10.1 - −153 −37.7 229 0.964 <0.001
 SE 542 9.18 - 18.0 5.86 - - -
 p-value <0.001 0.309 - <0.001 <0.001 - - -
Equation 2 5,528 - - −156 −32.4 232 0.958 <0.001
 SE 194 - - 18.0 3.35 - - -
 p-value <0.001 - - <0.001 <0.001 - - -
Equation 3 4,860 - −142 - - 399 0.859 <0.001
 SE 265 - 19.2 - - - - -
 p-value <0.001 - <0.001 - - - - -

CP, crude protein; CF, crude fiber; NDF, neutral detergent fiber; RMSE, root mean square error; SE, standard error.

Table 7
Regression equations for metabolizable energy in byproduct feed ingredients for growing pigs (kcal/kg dry matter basis)
Regression coefficient parameter (% dry matter basis) Statistical parameter


Intercept CP CF Ash NDF RMSE R2 p-value
Equation 1 6,231 −17.9 - −148 −40.1 243 0.957 <0.001
 SE 576 9.75 - 19.1 6.22 - - -
 p-value <0.001 0.109 - <0.001 <0.001 - - -
Equation 2 5,243 - - −153 −30.7 277 0.936 <0.001
 SE 232 - - 21.5 4.00 - - -
 p-value <0.001 - - <0.001 <0.001 - - -
Equation 3 4,578 - −136 - - 436 0.822 <0.001
 SE 290 - 21.0 - - - - -
 p-value <0.001 - <0.001 - - - - -

CP, crude protein; CF, crude fiber; NDF, neutral detergent fiber; RMSE, root mean square error; SE, standard error.

REFERENCES

1. Chiba LI. Protein supplements. Lewis AJ, Southern LL, editorsSwine nutrition. Washington DC: CRC Press; 2001. p. 803–37.
crossref
2. Sauvant D, Perez JM, Tran G. Tables of composition and nutritional value of feed materials: pigs, poultry, sheep, goats, rabbits, horses, and fish. 2nd edWageningen, The Netherlands: Wageningen Academic Publishers; 2004.

3. Park CS, Son AR, Kim BG. Prediction of gross energy and digestible energy in copra meal, palm kernel meal, and cassava root fed to pigs. J Anim Sci 2012;90:221–3.
crossref
4. Committee on Nutrient Requirements of Swine, National Research Council. Nutrient requirements of swine. 11th edWashington, DC: National Academy Press; 2012.

5. Son AR, Ji SY, Kim BG. Digestible and metabolizable energy concentrations in copra meal, palm kernel meal, and cassava root fed to growing pigs. J Anim Sci 2012;90:140–2.
crossref pmid
6. Stein HH, Casas GA, Abelilla JJ, Liu YH, Sulabo RC. Nutritional value of high fiber co-products from the copra, palm kernel, and rice industries in diets fed to pigs. J Anim Sci Biotechnol 2015;6:56.
crossref pmid pmc
7. Kim BG, Kim T. A program for making completely balanced Latin Square designs employing a systemic method. Rev Colom Cienc Pecua 2010;23:277–82.
crossref pdf
8. Committee on Nutrient Requirements of Swine, National Research Council. Nutrient requirements of swine. 10th edWashington, DC: National Academy Press; 1998.

9. Kong C, Adeola O. Evaluation of amino acid and energy utilization in feedstuff for swine and poultry diets. Asian-Australas J Anim Sci 2014;27:917–25.
crossref pmid pmc pdf
10. Ahn JY, Kil DY, Kong C, Kim BG. Comparison of oven-drying methods for determination of moisture content in feed ingredients. Asian-Australas J Anim Sci 2014;27:1615–22.
crossref pmid pmc
11. Kim BG, Petersen GI, Hinson RB, Allee GL, Stein HH. Amino acid digestibility and energy concentration in a novel source of high-protein distillers dried grains and their effects on growth performance of pigs. J Anim Sci 2009;87:4013–21.
crossref pmid
12. Horwitz W, Latimer GW. AOAC International. Official methods of analysis of AOAC International. 18th edGaithersburg, MD: AOAC International; 2005.

13. Boisen S, Fernández JA. Prediction of the total tract digestibility of energy in feedstuffs and pig diets by in vitro analyses. Anim Feed Sci Technol 1997;68:277–86.
crossref
14. Kong C, Park CS, Kim BG. Effects of an enzyme complex on in vitro dry matter digestibility of feed ingredients for pigs. Springerplus 2015;4:261.
crossref pmid pmc
15. Park KR, Park CS, Kim BG. An enzyme complex increases in vitro dry matter digestibility of corn and wheat in pigs. Springerplus 2016;5:598.
crossref pmid pmc
16. Ravindran V, Kornegay ET, Webb KE. Effects of fiber and virginiamycin on nutrient absorption, nutrient retention and rate of passage in growing swine. J Anim Sci 1984;59:400–8.
crossref pmid
17. Kim BG, Lindemann MD, Cromwell GL, Balfagon A, Agudelo JH. The correlation between passage rate of digesta and dry matter digestibility in various stages of swine. Livest Sci 2007;109:81–4.
crossref
18. Noblet J, Le Goff G. Effect of dietary fibre on the energy value of feeds for pigs. Anim Feed Sci Technol 2001;90:35–52.
crossref
19. Baker KM, Stein HH. Amino acid digestibility and concentration of digestible and metabolizable energy in soybean meal produced from conventional, high-protein, or low-oligosaccharide varieties of soybeans and fed to growing pigs. J Anim Sci 2009;87:2282–90.
crossref pmid
20. Berrocoso JD, Rojas OJ, Liu Y, et al. Energy concentration and amino acid digestibility in high-protein canola meal, conventional canola meal, and soybean meal fed to growing pigs. J Anim Sci 2015;93:2208–17.
crossref pmid
21. Widmer MR, McGinnis LM, Stein HH. Energy, phosphorus, and amino acid digestibility of high-protein distillers dried grains and corn germ fed to growing pigs. J Anim Sci 2007;85:2994–3003.
crossref pmid
22. Xue PC, Dong B, Zang JJ, Zhu ZP, Gong LM. Energy and standardized ileal amino acid digestibilities of Chinese distillers dried grains, produced from different regions and grains fed to growing pigs. Asian-Australas J Anim Sci 2012;25:104–13.
crossref pmid pmc
23. Gutierrez NA, Serao NVL, Kerr BJ, Zijlstra RT, Patience JF. Relationships among dietary fiber components and the digestibility of energy, dietary fiber, and amino acids and energy content of nine corn coproducts fed to growing pigs. J Anim Sci 2014;92:4505–17.
crossref pmid
24. Rodriguez DA, Sulabo RC, Gonzalez-Vega JC, Stein HH. Energy concentration and phosphorus digestibility in canola, cottonseed, and sunflower products fed to growing pigs. Can J Anim Sci 2013;93:493–503.
crossref
25. Adeola O, Kong C. Energy value of distillers dried grains with solubles and oilseed meals for pigs. J Anim Sci 2014;92:164–70.
crossref pmid
26. Woyengo TA, Beltranena E, Zijlstra RT. Nonruminant nutrition symposium: Controlling feed cost by including alternative ingredients into pig diets: A review. J Anim Sci 2014;92:1293–305.
crossref pmid
27. Sulabo RC, Ju WS, Stein HH. Amino acid digestibility and concentration of digestible and metabolizable energy in copra meal, palm kernel expellers, and palm kernel meal fed to growing pigs. J Anim Sci 2013;91:1391–9.
crossref pmid
28. Saittagaroon S, Kawakishi S, Namiki M. Characterisation of polysaccharides of copra meal. J Sci Food Agric 1983;34:855–60.
crossref
29. Rojas OJ, Liu Y, Stein HH. Phosphorus digestibility and concentration of digestible and metabolizable energy in corn, corn coproducts, and bakery meal fed to growing pigs. J Anim Sci 2013;91:5326–35.
crossref pmid
30. Noblet J, Perez JM. Prediction of digestibility of nutrients and energy values of pig diets from chemical analysis. J Anim Sci 1993;71:3389–98.
crossref pmid


Editorial Office
Asian-Australasian Association of Animal Production Societies(AAAP)
Room 708 Sammo Sporex, 23, Sillim-ro 59-gil, Gwanak-gu, Seoul 08776, Korea   
TEL : +82-2-888-6558    FAX : +82-2-888-6559   
E-mail : editor@animbiosci.org               

Copyright © 2024 by Asian-Australasian Association of Animal Production Societies.

Developed in M2PI

Close layer
prev next