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Kwak, Kim, Lee, Lee, and Choi: Effect of Feeding a Mixed Microbial Culture Fortified with Trace Minerals on the Performance and Carcass Characteristics of Late-fattening Hanwoo Steers: A Field Study

Abstract

This study was conducted to determine the effects of feeding a trace minerals-fortified microbial culture (TMC) on the performance and carcass characteristics of late-fattening Hanwoo steers. A mixture of microbes (0.6% [v/w] of Enterobacter sp., Bacillus sp., Lactobacillus sp., and Saccharomyces sp.) was cultured with 99% feedstuff for ensiling and 0.4% trace minerals (zinc, selenium, copper, and cobalt). Sixteen late-fattening steers (mean age, 21.8 months) were allocated to two diets: a control diet (concentrate mix and rice straw) and a treated diet (control diet+3.3% TMC). At a mean age of 31.1 months, all the steers were slaughtered. The addition of TMC to the diet did not affect the average daily weight gain of the late fattening steers, compared with that of control steers. Moreover, consuming the TMC-supplemented diet did not affect cold carcass weight, yield traits such as back fat thickness, longissimus muscle area, yield index or yield grade, or quality traits such as meat color, fat color, texture, maturity, marbling score, or quality grade. However, consumption of a TMC-supplemented diet increased the concentrations of zinc, selenium, and sulfur (p<0.05) in the longissimus muscle. With respect to amino acids, animals consuming TMC showed increased (p<0.05) concentrations of lysine, leucine, and valine among essential amino acids and a decreased (p<0.05) concentration of proline among non-essential amino acids. In conclusion, the consumption of a TMC-supplemented diet during the late-fattening period elevated the concentrations of certain trace minerals and essential amino acids in the longissimus muscle, without any deleterious effects on performance and other carcass characteristics of Hanwoo steers.

INTRODUCTION

It is well known that directly feeding microbes to animals is beneficial to animal agriculture production (Kwak and Kang, 2006; Yang et al., 2006; Zhou et al., 2009). Benefits derived from the consumption of these microbes include improved ruminal acidosis prevention, gut microbial balance, feed intake, weight gain, and feed efficiency in ruminants (Yoon and Stern, 1995; Krehbiel et al., 2003). For instance, direct consumption of a yeast culture increased feed intake in lactating Holstein cows (Williams et al., 1991; Robinson and Garrett, 1999) and Hereford steers (Adams et al., 1981), resulting in improved animal performance.
The use of microorganisms in animal diets has also been shown to improve mineral balance. For instance, Yoon and Stern (1995) reported that yeast culture supplementation improved the retention of minerals (potassium, copper, and iron) in growing ruminants. Moreover, Cole et al. (1992) reported that lambs fed yeast culture tended to have a better balance of zinc and iron, and the dietary addition of a mixed microbial (Bacillus and Saccharomyces) culture was effective in improving mineral bioavailability to beef steers (Kwak et al., 2012). Furthermore, feeding a diet supplemented with certain trace minerals and a mixture of microbes (Bacillus and Saccharomyces) improved the growth, meat yield, and quality of beef steers (Kim et al., 2007a).
Trace mineral deficiency impairs productivity in ruminants. Dietary trace minerals such as zinc and copper are essential components of enzymes and stimulate cattle growth (National Research Council, 2000). Addition of zinc to cattle diets improved growth and carcass characteristics (Greene et al., 1988; Spears and Kegley, 2002). Copper deficiency frequently occurs because antagonists such as molybdenum, sulfur, and iron are frequently high in ruminant diets and reduce the bioavailability of copper (Underwood and Suttle, 1999). Accordingly, the use of either supplemented trace minerals or mixed microbes, or a combination of these, has been shown to positively affect ruminant performance. Supplementation with mixed microbial cultures is a conventional practice at the majority of Hanwoo farms in Korea. If the culture is fortified with certain deficient trace minerals, an associative effect of these two products could be expected. Therefore, we hypothesized that feeding a trace minerals-fortified microbial culture (TMC) may positively affect the production and meat quality of Hanwoo steers.
Accordingly, this study was conducted to determine the effects of TMC on the growth performance and carcass characteristics of late-fattening Hanwoo steers fed rice straw as the main roughage source.

MATERIALS AND METHODS

Preparation of the mixed microbial culture

The organisms in the mixed microbial inoculum used in this experiment were isolated and identified previously in our lab (Kim et al., 2007b; 2008). The inoculum included Enterobacter ludwigii KU201-3, Bacillus cereus KU206-3, Bacillus subtilis KU3, Lactobacillus plantarum KU5, and Saccharomyces cerevisiae; these strains were each inoculated at 0.12%. Bacillus sp. and Enterobacter sp. were cultured in plate count broth (5 g casein, 2.5 g yeast extract, and 1 g/L dextrose) at 36°C for 24 h; Lactobacillus sp. was cultured in de Man, Rogosa and Sharpe (MRS) broth (0881, Difco Laboratories Inc., Detroit, MI, USA) at 36°C for 24 h, and Saccharomyces sp. was cultured in yeast malt broth (0711, Difco Laboratories Inc., USA) at 30°C for 48 h.
These microbes (0.6% v/w) were inoculated into a mixture of 19.6% ground corn grain, 16.0% soybean meal, 24.4% defatted rice bran, 20.0% bentonite, 12.2% spent mushroom substrate, 3.3% jujube (low quality), 2.5% molasses, 1.6% MgO, and 0.4% trace minerals, fermented for 5 days, and dried. The chemical composition is presented in Table 1. The rice straw used was freshly baled.
The control diet (formulated concentrate mix+rice straw) lacked trace minerals, as shown in Table 2. Dietary zinc and copper levels in the late-fattening period were lower than the National Research Council (2000) requirement of beef cattle. Compounds containing trace minerals such as sodium selenite, zinc sulfate, copper sulfate, and cobalt sulfate were added to the microbial culture to fully satisfy the National Research Council (2000) requirement (1.5-fold requirement for each mineral). For reference, the chemical composition of the control diet was 84.4% dry matter (DM), 12.1% crude protein (CP), 2.9% ether extract (EE), 34.1% neutral detergent fiber (NDF), 18.2% acid detergent fiber (ADF), and 7.5% crude ash.

Animals and treatments

All animal care protocols were approved by the Konkuk University Institutional Animal Care and Use Committee. Sixteen late-fattening Hanwoo steers (mean age, 21.8 months; mean body weight [BW], 514±7.5 kg) were randomly assigned to four pens. Each pen measured 50 m2 in area (5 m×10 m).
The steers were fed one of two diets: a control diet (formulated concentrate mix and rice straw), and a treated diet (control diet+3.3% TMC). The microbial culture was fed to the steers during the late-fattening period. The concentrate mix was freely accessed at a rate of 9 kg per day, and rice straw was restricted to 1.2 kg/d (as-fed basis). Feed with a TMC topdressing was provided twice a day (07:00 and 18:00). Animals always had free access to fresh water. The total feeding period was 9.3 months. The BW of the steers was measured monthly throughout the feeding trial, using a scale (BI-2RB, CAS, Yangju, Korea).

Carcass characteristics

At a mean age of 31.1 months, the steers were withdrawn from the experimental diets 24 h before slaughter. Following a 48-h carcass chill, the yield and quality grade of each carcass was measured using Korean carcass grading standards, specified in the Korean Livestock Enforcement Regulation (Korean Ministry of Agriculture and Forest, 2007). Quality grades were classified as 1++ (very high quality), 1+, 1, 2, and 3 (low quality). Back fat thickness and the longissimus muscle area were measured at the 13th rib. Yield index was calculated as follows: yield index = 68.184–(0.625×back fat thickness [mm])+(0.130×longissimus muscle area [cm2])–(0.024× cold carcass weight [kg])+3.23. Yield grades were classified as A (high yield), B, and C (low yield): grade A = higher than 67.5; grade B = higher than 62.0 and lower than 67.5; and grade C = lower than 62.0. The grading ranged between 1 and 27, with higher numbers indicating better quality: marbling (1 = devoid, 27 = abundant); meat color (1 = bright cherry red, 7 = extremely dark red); fat color (1 = white, 7 = dark yellow); texture (1 = soft, 3 = firm); and maturity (1 = youthful, 9 = mature).

Chemical and microbial analyses

Representative samples of the test feeds that were fed to the Hanwoo steers were collected and stored at −20°C for later analysis. Immediately before analysis, all samples were dried and ground to pass through a 1-mm filter by using a sample mill (Cemotec, Tecator, Skanor, Sweden). The DM fraction was quantified by drying the samples at 60°C for 48 h to reach a constant weight. The CP, EE, NDF, ADF, and crude ash contents were determined by the AOAC (2000) method.
The longissimus muscle was removed at the 12th to 13th rib, retained from each steer, and frozen until later analysis. For mineral analysis of the rib muscle, samples were analyzed for calcium, phosphorus, magnesium, potassium, sodium, sulfur, manganese, zinc, selenium, copper, iron, cobalt, and molybdenum by inductively coupled argon plasma emission spectroscopy (ICP-OES 5300DV, Perkin Elmer, Billerica, MA, USA), as described by Braselton et al. (1997).
Microbial analyses of the samples (sample size, 25 g) were conducted according to the AOAC (2000) method. Specifically, the total bacterial count was determined on plate count agar (Difco Laboratories Inc., USA) after incubation at 30°C for 48 h. The lactic acid bacterial count was determined using MRS agar plates (Difco Laboratories Inc., USA) after incubation at 36°C for 24 h. The yeast count was determined on yeast malt agar plates (Difco Laboratories Inc., USA) after incubation at 36°C for 48 h. The mixed microbial culture contained each species at a viable cell concentration in excess of 106 cfu/g.

Statistical analysis

Data were subjected to one-way analysis of variance by using the general linear model procedure (Statistix7, 2000). The means of the control diet and the treated diet were compared using the Student’s t-test (Statistix7, 2000). Significant differences were detected at p<0.05.

RESULTS AND DISCUSSION

Body weight gain and feed intake

Consumption of a TMC-supplemented diet did not affect steer growth rates significantly, although it increased the average BW by 26 kg (14% of the control group weight) and average daily BW gain by 0.09 kg (Table 3). Compared to the control group, the TMC-fed group showed a relatively narrow range of BW gain, indicating the desirably consistent growth of individual steers. In terms of feed intake, the concentrate mix intake was higher in the TMC-fed group than in the control group, although the rice straw intake was similar. This increase in concentrate mix intake appears to be responsible for the increased BW gain observed in TMC-fed steers.
The feed intake mechanism thus appears to be more complicated than expected because many factors can influence it. Deficiency of copper resulted in reduced feed intake and subsequently reduced growth (National Research Council, 2005). Deficiency of zinc reduced feed intake, growth, and feed efficiency and impaired immune function (National Research Council, 2005). An impaired immune system, resulting from deficiency of certain minerals, generally reduces feed intake and growth (Adams, 2001). Therefore, supplementation of minerals and microbes in the diet may have led to recovery from conditions of an impaired immune system and mineral deficiency to consequently improve feed intake, leading to improved BW gain. In addition, the TMC itself showed high palatability, possibly due to the included flavor enhancers such as molasses and jujube. The highly palatable TMC pellets may have induced more frequent consumption of the concentrate mix, resulting in increased feed intake. Alternatively, the highly palatable TMC pellets may have increased rumen microbial mass and further stimulated feed fermentation and digestion, thereby possibly acting as a positive feedback system to improve feed intake, as suggested by Adams (2001).

Evaluation of the quantity and quality of meat

Carcass characteristics

The consumption of TMC-supplemented feed tended (p = 0.09) to increase the cold carcass weight by an average of 24 kg and did not affect yield traits such as dressing percentage, back fat thickness, longissimus muscle area, yield index, or yield grade. Moreover, quality traits such as marbling score, meat color, fat color, texture, maturity, or quality grade were not affected by TMC-supplementation (Table 4). The favorable increase in weight observed in steers fed the TMC-supplemented diet resulted in greater carcass weights. The sale price was about 4.1% higher for the steers fed TMC than for the control steers. In contrast, Mir and Mir (1994) reported that feeding live yeast to Hereford steers did not affect carcass characteristics such as carcass weight, dressing percentage, backfat thickness, loin eye area, and yield index. Moreover, Kim et al. (2007a) reported that feeding a 1% microbial culture to Hanwoo steers had no effect on meat characteristics. However, dietary supplementation of zinc and other trace minerals has been shown to positively affect cattle performance and increase carcass weight (Spears and Kegley, 2002; Spears, 2003). In another study (Kim and Lee, 2014) on feeding black sugar and mineral premix to fattening Hanwoo steers, cold carcass weight was found to increase with no differences in yield and quality traits. In the present study, the combined use of microbes and trace minerals tended to improve carcass weight.

Meat mineral profile

The effect of feeding TMC on the meat mineral profiles of steers is presented in Table 5. The treatment significantly affected (p<0.05) the mineral concentrations in the longissimus muscle. Compared with the control steers, TMC-fed steers displayed increased concentrations of zinc and selenium (p<0.05), but showed similar concentrations of copper, iron, manganese, cobalt, and molybdenum within the longissimus muscle. More specifically, the longissimus muscle of steers fed the TMC contained 15.5% higher zinc, 46.7% higher selenium, and 14.8% higher (p = 0.07) total trace mineral concentrations than those observed in the longissimus muscle of the control steers. The longissimus muscle of steers fed TMC had consistently higher concentrations of most of the trace minerals compared to those in the longissimus muscle of the control steers. The range of mineral concentrations was intermediate to the values reported by Westing et al. (1985) and Williams et al. (1983).
The control diet in this study contained more potassium, sodium, iron, and manganese, and less magnesium, zinc, and selenium (data not presented) than the dietary requirement specified in the Korean Feeding Standard Establishment Council (2007) and National Research Council (2000) guidelines. Dietary incorporation of these deficient minerals for TMC-fed steers resulted in higher retention in the longissimus muscle. Similarly, Yoon and Stern (1995) reported that yeast culture supplementation improved the retention of minerals (potassium, copper, and iron) in growing ruminants. Moreover, Cao et al. (2000) reported that zinc supplementation in ruminant diets that were deficient in zinc resulted in increased zinc content in the muscle of the animals. When probiotics with bentonite were fed to steers for 22 months, the longissimus muscle showed higher concentrations of zinc (49%), copper (100%), and iron (34.5%) (Kwak et al., 2012). The inconsistencies between the results of these studies and those of the present investigation seem to be due to different dietary factors and feeding conditions. In the present study, the addition of copper sulfate to the feed did not increase copper concentration in the muscle, possibly because dietary supplementation of sulfur reduces copper absorption (Spears, 2003). That being said, the muscle selenium content significantly increased even though dietary supplementation of sulfur reduces the bioavailability of selenium (Spears, 2003).
With respect to the major minerals within the longissimus muscle (Table 6), TMC-supplementation did not affect concentrations of calcium, phosphorus, magnesium, potassium, and sodium, but increased the concentration of sulfur (p<0.0005), relative to that in the control. This phenomenon was attributed to the dietary sulfur contributed by sulfate forms of zinc, copper, and cobalt in the feed.

Meat amino acid profile

Effect of the TMC-supplemented dietary treatment on the amino acid composition of the longissimus muscle is presented in Table 7. The amino acid composition of the longissimus muscle was affected by the dietary treatment (p<0.05). TMC consumption increased (p<0.05) the concentrations of lysine, leucine, and valine, and tended (p<0.08) to increase the concentration of methionine among the essential amino acids and decreased (p<0.05) the concentration of proline among the non-essential amino acids. Dietary supplementation of sulfur in the sulfate form of trace minerals apparently resulted in the increased muscular retention of the sulfur amino acid methionine. However, another sulfur amino acid, cysteine, which can be synthesized from methionine (National Research Council, 1998), was not affected by this treatment. Additional energy supply, apparently by increased feed intake in the present study, can improve amino acid synthesis in the rumen by increasing microbial growth, and improve amino acid flow into the lower digestive tract as suggested by Asplund (1994). When additional nitrogen and sulfur are available in the rumen, limiting essential amino acids can be synthesized by the rumen microbes. Microbial protein is a high-quality protein because it has higher concentration of essential amino acids than does vegetable protein (Ishler et al., 1996). This increase in microbial amino acid digestion and retention likely induced increases in the concentrations of certain essential amino acids in the longissimus muscle.
Most mammals can synthesize proline from arginine and glutamate, and proline and its metabolites constitute one-third of the amino acids in the collagen proteins, which provide the muscles with the strength and structure required for movement and general function (Wu et al., 2011). However, it is not currently clear why proline concentration decreased in the present study.

Meat fatty acid profile

Effect of TMC consumption on the fatty acid composition of the longissimus muscle is presented in Table 8. The fatty acid composition and saturated or unsaturated fatty acid ratios of the longissimus muscle were not affected by the dietary treatment. Similarly, feeding probiotics with bentonite to beef cattle for 22 months did not affect the fatty acid composition of the longissimus muscle (Kwak et al., 2012).
In conclusion, TMC supplementation during the late-fattening period enhanced the concentrations of certain trace minerals and essential amino acids in the longissimus muscle without inducing any deleterious effects on the performance and other carcass characteristics of Hanwoo steers.

CONCLUSION

The results of the present study indicate that TMC supplementation in the diet of late-fattening Hanwoo steers could be recommended to improve carcass weight, meat quality, and net income without negatively affecting animal health and carcass characteristics. The use of TMC in the beef cattle diet induced higher bioavailability of certain trace minerals and sulfur. Moreover, ingestion of the inorganic sulfate form of trace minerals improved the retention of certain essential amino acids in the muscle. Thus, TMC supplementation could aid in maintaining the health and welfare of beef steers.

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 study was carried out with the support of the “Cooperative Research Program for Agriculture Science and Technology Development (Project No. PJ009382012015)”, the Rural Development Administration, Republic of Korea.

Table 1
Chemical compositions of feeds fed to fattening Hanwoo steers1 (%, DM basis)
Item Concentrate mix Rice straw Microbial culture2
DM 87.0 65.3 84.8
Crude protein 13.0 4.0 16.7
Ether extract 3.1 1.3 0.5
Neutral detergent fiber 30.5 70.7 26.1
Acid detergent fiber 15.9 42.6 16.0
Crude ash 7.3 11.3 26.8

DM, dry matter.

1 Means of 3 observations.

2 Mixed microbes (0.6% v/w) were inoculated into the mixture of 19.6% ground corn grain, 16.0% soybean meal, 24.4% defatted rice bran, 20.0% bentonite, 12.2% spent mushroom substrate, 3.3% low quality jujube, 2.5% molasses, 1.6% MgO, and 0.4% trace minerals, fermented for 5 days, and dried.

Table 2
Zinc and Copper levels in the control diet (dry matter basis)
Control diet (mg/kg) Requirement of beef cattle (mg/kg)1
Zinc 20.0 30.0
Copper 4.5 10.0
Table 3
Growth and feed intake of late fattening Hanwoo steers fed trace mineral-fortified microbial culture (TMC)
Item Control (kg) TMC added (kg) SE p-value
Growth1
 Initial wt (21.8 mo old) 517 512 15 0.72
 Final wt (31.1 mo old) 698 719 19 0.31
 Gain 181 207 16 0.12
 Average daily gain 0.63 0.72 0.05 0.12
  Range 0.45–0.87 0.67–0.76 - -
Feed intake2
 Concentrate mix 9.1 9.5 0.2 0.12
 Rice straw 1.2 1.2 0.1 0.12

SE, standard error.

1 Means of 8 observations.

2 Means of 2 observations and on a wet basis.

Table 4
Meat characteristics of Hanwoo steers fed with trace mineral-fortified microbial culture (TMC) during the late fattening period1
Item Control TMC added SE p-value
Cold carcass weight (kg) 406 430 13 0.09
Yield traits
 Dressing (%) 62.3 64.3 1.3 0.14
 Backfat thickness (mm) 12.6 15.4 2.5 0.29
Longissimus muscle area (cm2) 79.8 82.3 4.6 0.60
 Yield index 64.1 62.2 1.8 0.31
 Yield grade2 2.00 2.25 0.40 0.54
Quality traits
 Marbling score3 4.6 4.1 0.9 0.59
 Meat color4 4.63 4.88 0.23 0.29
 Fat color5 3.25 3.00 0.25 0.34
 Texture6 1.75 1.63 0.26 0.64
 Maturity7 1.88 2.00 0.13 0.34
 Quality grade8 (%)
  1++, heads 1 (12.5) 0 - -
  1+, heads 2 (25.0) 3 (37.5) - -
  1, heads 1 (12.5) 2 (25.0) - -
  2, heads 4 (50.0) 3 (37.5) - -
 Sale price (million won) 6.27 6.53 0.49 0.60

SE, standard error.

1 Means of 8 observations.

2 Scored: grade A = 1 (lean), B = 2, C = 3 (fat).

3 Scored: grade 1 = poor, grade 9 = excellent.

4 Scored: grade 1 = scarlet, grade 7 = dark red.

5 Scored: grade 1 = white, grade 7 = yellow.

6 Scored: grade 1 = good, grade 3 = bad.

7 Scored: grade 1 = fully mature, grade 9 = least mature.

8 Scored: grade 1++ = 1 (best), 1+ = 2, 1 = 3, 2 = 4, 3 = 5 (poorest).

Table 5
Trace mineral composition (fresh basis) of longissimus muscle of Hanwoo steers fed with trace mineral-fortified microbial culture (TMC) during the late fattening period1
Item Control (ppm) TMC added (ppm) SE p-value
Zinc 69.0a 79.7b 4.8 0.0425
Copper 1.36 1.49 0.11 0.2618
Selenium 0.30a 0.44b 0.05 0.0195
Iron 25.2 29.9 2.3 0.0710
Manganese 0.20 0.23 0.02 0.1885
Cobalt 0.11 0.13 0.01 0.1102
Molybdenum 0.03 0.04 0.01 0.4860
Total 97.0 111.4 6.9 0.0734

SE, standard error.

1 Means of 8 observations.

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

Table 6
Major mineral composition (fresh basis) of longissimus muscle of Hanwoo steers fed with trace mineral-fortified microbial culture (TMC) during the late fattening period1
Item Control (ppm) TMC added (ppm) SE p-value
Calcium 71.8 77.3 5.4 0.3854
Phosphorus 606 542 119 0.6593
Magnesium 289 299 13 0.4740
Potassium 2,776 3,089 202 0.1588
Sodium 526 515 28 0.7007
Sulfur 7,735a 10,775b 654 0.0004

SE, standard error.

1 Means of 8 observations.

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

Table 7
Amino acid composition of longissimus muscle of Hanwoo steers fed with trace mineral-fortified microbial culture (TMC) during the late fattening period (%, DM basis) 1
Item Control TMC added SE p-value
Essential amino acids
 Lysine 5.5a 5.9b 0.1523 0.0321
 Leucine 4.9a 5.4b 0.1918 0.0124
 Valine 4.2a 4.4b 0.0904 0.0440
 Methionine 3.8 4.0 0.0743 0.0853
 Threonine 4.6 4.6 0.1082 0.4994
 Isoleucine 4.3 5.0 0.4617 0.1517
 Arginine 6.6 6.7 0.1545 0.4321
 Phenylalanine 4.8 4.9 0.1089 0.3190
 Histidine 4.3 4.4 0.1373 0.3779
Non-essential amino acids
 Aspartic acid 6.9 7.1 0.1438 0.1210
 Alanine 5.0 5.2 0.0998 0.1013
 Serine 4.1 4.2 0.0915 0.3551
 Glutamic acid 9.1 9.4 0.2333 0.1853
 Proline 18.5a 15.0b 1.5914 0.0438
 Glycine 4.0 4.0 0.1042 0.6386
 Cysteine 1.8 1.9 0.1514 0.6860
 Tyrosine 4.5 4.4 0.0833 0.1984

SE, standard error; DM, dry matter.

1 Means of 8 observations.

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

Table 8
Fatty acid composition (DM basis) of longissimus muscle of Hanwoo steers fed with trace mineral-fortified microbial culture (TMC) during the late fattening period1
Item Control TMC added SE p-value
Myristic acid (C14:0) 3.88 3.93 0.18 0.7903
Palmitic acid (C16:0) 29.01 29.62 0.52 0.2702
Palmitoleic acid (C16:1) 6.87 6.44 0.55 0.4546
Stearic acid (C18:0) 14.03 13.97 0.74 0.9458
Oleic acid (C18:1) 46.21 46.03 1.03 0.8647
Total saturated fatty acids 46.92 47.53 0.98 0.5437
Total unsaturated fatty acids 53.08 52.47 0.98 0.5437

DM, dry matter; SE, standard error.

1 Means of 8 observations.

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