Effect of the Ratio of Non-fibrous Carbohydrates to Neutral Detergent Fiber and Protein Structure on Intake, Digestibility, Rumen Fermentation, and Nitrogen Metabolism in Lambs

Article information

Asian-Australas J Anim Sci. 2015;28(10):1419-1426
1College of Animal Science, Jinling Institute of Technology, Nanjing, Jiangsu 210038, China.
*Corresponding Author: Q. Y. Diao. Tel: +86-10-82106055, Fax: +86-10-62169105, E-mail: diaoqiyu@caas.cn
Feed Research Institute, Chinese Academy of Agricultural Sciences, Key Laboratory of Feed Biotechnology of Ministry of Agriculture, Beijing 100081, China
Received 2015 January 08; Revised 2015 April 06; Accepted 2015 April 20.

Abstract

This study aimed to investigate the effect of the ratio of non-fibrous carbohydrates to neutral detergent fibre (NFC/NDF) and undegraded dietary protein (UDP) on rumen fermentation and nitrogen metabolism in lambs. Four Dorper×thin-tailed Han crossbred lambs, averaging 62.3±1.9 kg of body weight and 10 mo of age, were randomly assigned to four dietary treatments of combinations of two levels of NFC/NDF (1.0 and 1.7) and two levels of UDP (35% and 50% of crude protein [CP]). Duodenal nutrient flows were measured with dual markers of Yb and Co, and microbial N (MN) synthesis was estimated using 15N. High UDP decreased organic matter (OM) intake (p = 0.002) and CP intake (p = 0.005). Ruminal pH (p<0.001), ammonia nitrogen (NH3-N; p = 0.008), and total volatile fatty acids (p<0.001) were affected by dietary NFC/NDF. The ruminal concentration of NH3-N was also affected by UDP (p<0.001). The duodenal flow of total MN (p = 0.007) was greater for lambs fed the high NFC/NDF diet. The amount of metabolisable N increased with increasing dietary NFC:NDF (p = 0.02) or UDP (p = 0.04). In conclusion, the diets with high NFC/NDF (1.7) and UDP (50% of CP) improved metabolisable N supply to lambs.

INTRODUCTION

Reduction of N excretion to the environment has drawn increasing concern in recent years as inputs of ammonia have increased by more than 50% since 1950 (Asman et al., 1998). Intensive animal production systems are responsible for this change as farm manure has been identified as a major source of nitrate pollution (Lord, 1996), which poses a threat to the quality of water, air, soil, and ultimately human health. Globally, the size of livestock production is still increasing because of the rising demands for high-quality animal products. Therefore, N losses from livestock production are of great importance.

The N output of livestock production systems can be reduced by improving N utilisation by animals (Hoekstra et al., 2007). In ruminants, the asynchrony between the degradation rate of carbohydrates and proteins in the rumen lowers N utilisation efficiency (Stern et al., 1994). Although such an asynchrony can be partly overcome by use of protein supplements, elevated feed costs and further reduced N utilisation could be expected. Optimising ruminal fermentation and increasing microbial protein production in the rumen can be achieved by manipulation of dietary carbohydrates as well as proteins (Clark et al., 1992). An increase in non-fibrous carbohydrates (NFC) can be implemented by elevating concentrate levels, improved feed intake, nutrient digestibility, and microbial protein synthesis in the rumen (Ramos et al., 2009). However, in previous studies, the influence of dietary protein was not taken into consideration, and therefore, it is unclear whether factors such as protein components (ruminal degraded protein/undegraded dietary protein, RDP/UDP) had influences on those indices, as Reynal and Broderick (2005) reported that increasing dietary UDP to a certain level decreased feed intake and microbial N (MN) in cattle.

This study aimed to investigate whether dietary NFC/NDF and UDP influences N metabolism, especially duodenal N utilisation in Dorper×thin-tailed Han crossbred lambs used for lamb meat production in China. We hypothesised that the level of NFC and UDP could act collectively on N metabolism.

MATERIALS AND METHODS

Animals and dietary treatments

This study was conducted from July 2013 to November 2013 at the Experimental Station of the Chinese Academy of Agricultural Sciences (CAAS), Beijing, China. The experimental procedures were approved by the Animal Ethics Committee of CAAS, and humane animal care and handling procedures were followed throughout the experiment.

Four 10-month-old Dorper×thin-tailed Han crossbred non-castrated ram lambs (62.3±1.9 kg body weight) were surgically fitted with ruminal and duodenal cannula and were used in this study approximately 6 mo after the surgery. The lambs were randomly assigned to four dietary treatments, including two levels of NFC (40% and 50% of dry matter [DM]) and UDP (35% and 50% of crude protein [CP]) according to a 4×4 Latin-square experimental design. Experimental diets were iso-nitrogenous and iso-energetic. The ingredients and chemical composition of the experimental diets are presented in Table 1. Lambs were fed twice daily at 08:00 h and 16:00 h with ad libitum intake, allowing for approximately 10% refusal. Clean water was available at all times. Each experimental period lasted for 24 d. The first 7 d were used for adaptation to the dietary treatment, and the lambs were then moved into individual metabolism crates for 12 d, including 7 d of adaption and 5 d of a digestibility trial. Finally the duodenal and ruminal digesta were sampled consecutively for 5 d.

Ingredients and chemical compositions of experimental diets (% of DM)

Yb and Co were used as the markers for particulate and liquid phases in the rumen, respectively, to determine the flow of digesta from the rumen to the duodenum. Simultaneously, 15N was used as an external microbial marker. All markers were mixed with the concentrate prior to pelleting (Ma et al., 2013). Approximately 1.44 kg of YbCl3·6H2O and 4.32 kg of Li-Co-EDTA (2.92 kg of C4H6O4·Co·H2O, 3.42 kg of EDTA, and 500 g of LiOH) and 1.08 kg of (15NH4)2SO4 (15N, 10% of atoms) was dissolved in 40 L of deionised water and then sprayed on 1.44 kg of concentrate diet before pelleting. Daily marker consumption approximated 500 mg of Yb and Co and 20 mg of 15N for each lamb. Prior to offering the marked feed, a priming dose of half of the daily marker intake was administered through the rumen cannula of each animal (Ma et al., 2013).

Measurements and sample collection

In the digestibility trial, faecal samples were collected daily from days 16 to 20. Faecal samples were weighed daily, and then, a 10% sample was collected. The samples were pooled for each animal, dried at 65°C, and then ground through a 1-mm sieve before analysis. Urine from each lamb was also collected daily in a bucket containing 100 mL of 7.2 NH2SO4. The volume was measured and then diluted to 5 L with tap water, and a sample of 20 mL was collected, pooled for each animal, and stored at −20°C for the analysis of total N. The samples of feed were also collected daily, combined, dried at 65°C for 72 h, and ground through a 1-mm sieve. Feed refusals were also weighed, sampled, dried, ground, and combined for each lamb before analysis.

From days 21 to 23, a 100-mL sample of duodenal digesta was collected every 6 h, moving the collection time forward 2 h each day to obtain the samples at 2-h intervals (i.e., 08:00, 14:00, and 20:00 on day 21; 02:00, 06:00, 12:00, 18:00, and 24:00 hours on day 22; and 04:00, 10:00, 16:00, and 22:00 on day 23). The duodenal digesta were frozen at −20°C and thawed before analysis, and a volume of 800 mL was separated into particulate and liquid fractions as described by Ma et al. (2013). Nutrient concentrations and markers were determined in each fraction for the apparent ruminal digestibility of nutrients and the digesta flow from the rumen to the duodenum. An additional sample of the duodenal digesta (10 mL) was centrifuged at 20,000 g, 4°C for 20 min, and the supernatant was stored for analysis of ammonia N.

Samples of ruminal digesta (300 mL) were collected at 6-h intervals from days 24 to 25 for the determination of ruminal fermentation parameters and MN (i.e., 08:00, 14:00, and 20:00 on day 24; and 02:00, 05:00, 11:00, 17:00, and 23:00, on day 25). The ruminal samples were obtained through the cannula from five different sites within the rumen using a syringe attached to a plastic tube (20-mm internal diameter). The pH of the digesta was measured immediately using a pH metre (Model PB-10, Sartorius Co., Gottingen, Germany). Thereafter, approximately 50 mL of the digesta was filtered through one layer of cheesecloth. A 10-mL sample of the strained fluid was collected, acidified with 2 mL 25% (w/v) metaphosphoric acid, and stored frozen at −20°C for analysis of volatile fatty acids (VFA) and ammonia nitrogen (NH3-N). The remaining 250 mL of digesta was used to separate out a bacterial pellet through differentiated centrifugation, and the procedures were the same as described by Ma et al. (2013). The pellet was transferred into a centrifuge tube with a minimum amount of distilled water and stored at −20°C for analysis of total N and 15N enrichment.

Chemical analysis

DM (method 930.15), organic matter (OM; method 967.05), CP (method 977.02), ether extract (EE; method 920.39) and ash (method 942.05) were measured according to the Association of Official Analytical Chemists methods (AOAC, 1990). Neutral detergent fibre (NDF) and acid-detergent fibre (ADF) were determined according to Van Soest et al. (1991) and Goering and Van Soest (1970), respectively. Dietary components of RDP were estimated using an in situ method by incubating samples in the rumen for 72 h as described by Volden and Harstad (1995). Ruminal VFA were measured with a flame ionisation detector in a gas chromatograph (GC522, Wufeng Instruments, Shanghai, China) using a 15-mL semi-capillary glass column (0.53 mm in diameter) packed with Chromosorb 101 (Johns-Monville, Denver, CO, USA) with N2 as carrier gas at a column temperature of 120°C. Before analysis, caproic acid was added to each sample as an internal standard. Ammonia N was assessed by the colorimetric method of Chaney and Marbach (1962). The isotopic abundance of 15N in bacterial N and duodenal fractions was determined by isotope ratio mass spectrometry (Finnigan Mat 251, Thermo Fisher Scientific Inc., San Jose, CA, USA). The concentration of Yb and Co in the digesta was determined by inductively coupled plasma emission spectrometry (X series 2 ICP-MS, Thermo Fisher Scientific Inc., Waltham, MA, USA).

Calculations and statistical analysis

Duodenal flows of nutrients were determined by reconstitution of the duodenal digesta based on Yb and Co concentrations and the content of the nutrients in the particulate and whole fractions. MN in the duodenum was determined by using 15N as an external microbial marker. For the calculation of MN yield with 15N, the microbial non-ammonia N (NAN) flow to the duodenum was estimated as follows:

MN/NANdigesta=(E-NANdigesta)/(E-Nbacteria)

where (E–NANdigesta) and (E–Nbacteria) are the 15N enrichments of digesta NAN and rumen bacterial N, respectively. Based on the observation that the natural abundance of 15N from ruminal microbes and duodenal digesta was similar (Ahvenjärvi et al., 2002), duodenal digesta samples were analysed for 15N before using marked feed, and a value of 0.363 was taken as the 15N background for both the microbial and duodenal digesta.

Metabolisable N=total NAN-(faecal N+endogenous N)

Endogenous N was calculated as 2.8 g N/kg DM intake according to Bartram (1987).

Data were analysed as a mixed model using MIXED procedure of SAS (version 9.1; SAS Institute, Inc., Cary, NC, USA). The statistical model is shown below:

Y=μ+α+β+γ(α)+c+ɛ

where μ is the overall mean; α is the random effect of the square; β is the random effect of period; γ(α) is the random effect of lamb within the square; c is the fixed effect of treatment, and ɛ is the random error.

Observations of the ruminal pH, VFA, and ammonia N were analysed as repeated measures. The statistical model is shown below:

Y=μ+α+β+γ(α)+c+t+c×t+ɛ

where μ, α, β, γ(α), and c are described as above; t is the effect of time; c×t is the interaction between treatment and time, and ɛ is the random error. Data for each variable were analysed using compound symmetry, unstructured, and autoregressive covariance structures. The test that satisfied the minimum Akaike’s information criterion was chosen. Effects were declared significant when p<0.05.

RESULTS

Nutrient intake and digestibility

Decreasing dietary UDP increased OM intake (p = 0.002) and CP intake (p = 0.005). Intake of EE was increased (p = 0.04) but that of NDF (p = 0.009) and ADF (p = 0.004) was reduced in lambs fed high NFC/NDF diets (Table 2). On the other hand, dietary NFC/NDF had no effect on intake of OM (p = 0.82) or CP (p = 0.17), and dietary UDP had no effect on intake of EE (p = 0.30), NDF (p = 0.36), or ADF (p = 0.41). No interaction was observed on the above nutrient intakes (p>0.05).

Effects of dietary NFC/NDF and UDP on intake and digestibility of nutrients in lambs

Increasing dietary NFC/NDF increased total-tract apparent digestibility of OM (p = 0.005) and EE (p = 0.005) but decreased that of ADF (p<0.001). Dietary NFC/NDF had no effect on total-tract digestibility of CP (p = 0.67) or NDF (p = 0.85). Dietary UDP and dietary interactions had no effect (p>0.05) on total-tract digestibility of all nutrients.

The ruminal digestibility of OM was not affected by dietary NFC/NDF (p = 0.65) or UDP (p = 0.47). Dietary NFC/NDF decreased ruminal digestibility of CP (p<0.001), NDF (p = 0.03), and ADF (p<0.001). High dietary UDP decreased ruminal digestibility of CP (p<0.001). Dietary UDP had no effect on ruminal digestibility of NDF (p = 0.13) or ADF (p = 0.26). The effect of treatment interactions on ruminal digestibility of CP (p<0.001) was observed.

High dietary NFC/NDF increased post-ruminal digestibility of OM (p<0.001), CP (p = 0.02), and NDF (p<0.001). High dietary UDP only increased post-ruminal digestibility of CP (p = 0.03). Dietary interactions were also observed in post-ruminal digestibility of CP (p = 0.02).

Ruminal characteristics

Ruminal pH and NH3-N were decreased by high NFC/NDF diets (p<0.001, Table 3). In addition, ruminal NH3-N was greater for lambs fed low UDP diets than for those fed high UDP diets (p<0.001), and the interaction between treatments was also observed (p = 0.005). Dietary UDP had no effect on ruminal pH (p = 0.53) or total VFA (p = 0.27). The ruminal total VFA (p<0.001), proportion of propionate (p<0.001) and butyrate (p = 0.003) were increased, whereas the proportion of acetate (p<0.001) and ratio of acetate to propionate (p<0.001) were decreased by high NFC/NDF diets. Dietary NFC/NDF had no effect on the proportion of isobutyrate (p = 0.30) and dietary UDP had no effect on the molar proportion of VFA (p>0.05).

Effect of dietary NFC/NDF and UDP on ruminal fermentation parameters in lambs

Duodenal N supply and N utilisation efficiency

The duodenal flow of total NAN (p = 0.03) and MN (p = 0.007) were greater for lambs fed high NFC/NDF diets (Table 4). Dietary UDP had no effect on duodenal flow of total NAN (p = 0.12) and endogenous N (p = 0.57). Dietary NFC/NDF had no effect on duodenal flow of undegraded dietary N (p = 0.43) or endogenous N (p = 0.52). The duodenal flow of MN was also increased by low UDP diets (p = 0.03). The amount of metabolisable N was increased by increasing dietary NFC/NDF (p = 0.02) or UDP (p = 0.04), and treatment interaction was observed (p = 0.02). Faecal N was not affected by dietary treatments (p>0.05), and urinary N was lowered by high NFC/NDF (p = 0.01) and high UDP diets (p = 0.04). The ratio of metabolisable N to total NAN was greater (p = 0.02) for high UDP diets (averaged 67.2%) compared with that for low UDP diets (averaged 60.2%). The ratio of metabolisable N to digestible N or to N intake was greater for high NFC/NDF diets (p = 0.02 or 0.01) and high UDP diets (p = 0.003 or 0.006), and an interaction between treatments was observed (p = 0.01).

Effect of dietary NFC/NDF and UDP on duodenal supply and utilisation efficiency of protein in lambs

DISCUSSION

Nutrient intake

The intake of OM was improved with decreasing UDP in the current study. The OM intake increased with decreasing UDP and ranged from 1.3 to 1.5 kg/d. These observations were in accordance with those of Kiran and Mutsvangwa (2007) who found that increasing dietary RDP from 60% to 70% of CP increased OM intake (ranging from 1.2 to 1.4 kg/d) in growing lambs. It has been reported that dietary RDP can promote intake by enhancing gastrointestinal motility (Egan and Moir, 1965).

Dietary NFC/NDF had no influence on OM intake in this trial. Commonly, an increase in dietary NFC can be achieved by increasing the level of concentrates. Therefore, the results of the current study are comparable with those obtained by Cantalapiedra-Hijar et al. (2009) and Ramos et al. (2009), who found no effect of dietary concentrate:forage ratios (30:70 and 70:30) on OM intake in both goats and sheep fed above maintenance. It is possible that the range of dietary NFC in the current study (from 40% to 50% of DM) was not wide enough to affect OM or CP intake. The differences in NFC of the diets were mainly due to the variance in NDF concentrations, which were 40% and 30% in the low and high NFC diet, respectively. However, Allen (2000) noted that no effect of NDF ranging from 25% to 40% was found on DM intake in dairy cows, although feed intake generally decreases with increasing NDF. Therefore, the lack of NFC/NDF effects on OM or CP intake might have been resulted from the fact that the diets were both iso-energetic and iso-nitrogenous.

Nutrient digestibility

Total-tract digestibility of OM was affected by NFC/NDF but not UDP. Although, it is generally accepted that ruminal microbes can better utilise diets of high NFC level, a corresponding increase in ruminal digestibility of OM was not observed. As digestibility is the result of digestion and passage rate, it could be inferred that these two factors were counterbalanced in the current study. On the other hand, it was reported that protein degradability hardly influenced OM digestion when the diets contained adequate CP (Cecava et al., 1991).

Total-tract digestibility of CP was not affected by either NFC/NDF or UDP. However, an effect of treatment interactions was observed on both ruminal and post-ruminal digestibility of CP. Generally, diets containing high levels of UDP or NFC have higher passage rates than those containing low levels of UDP or NFC/NDF, and therefore, the reduction of ruminal digestibility of CP when a high UDP or NFC/NDF diet was fed could be expected.

Increase in NFC/NDF depressed the ruminal digestibility of NDF in the current study. Supplemental NFC had negative effects on NDF digestion because of the associated reduction in ruminal pH (Mould and Ørskov, 1983), and the threshold below which cellulytic activity would be inhibited was approximately 6.0 (Mould et al., 1983). The observed ruminal pH in lambs fed high NFC diets was below 6.0 for most of the time, which could explain the corresponding decrease in ruminal digestibility of NDF. Nevertheless, total-tract digestibility of NDF was compensated for by the increased post-ruminal digestibility of NDF, which resulted in the unaffected total tract digestibility of NDF by treatments. The large intestine has an active microbial population that can effectively degrade fibre, and it was reported that delignified postruminal digesta was hydrolysed by caecal microflora (Bailey and Macrae, 1970). On the other hand, a high proportion of NFC in the hind-gut may stimulate the growth of microbes, which might largely explain the increase in post-ruminal digestibility of NDF observed for high NFC diets.

Ruminal fermentation characteristics

Lambs fed high NFC/NDF diets displayed a sharper decrease in ruminal pH after each feeding, and similar patterns were also reported in heifers (Pina et al., 2009) and dairy cows (Agle et al., 2010). It is obvious that high NFC/NDF diets provided more fermentable carbohydrate for microbes to produce organic acids and, in addition, decreased saliva secretion due to the reduction in rumination time, which collectively led to the reduction of pH.

The ruminal concentration of NH3-N was affected by NFC/NDF and UDP, as well as their interactions. Similar to the studies conducted by Pina et al. (2009) in beef heifers, low dietary UDP resulted in a higher ruminal NH3-N concentration because more degraded N was supplied to ruminal microbes. A higher NH3-N was found in low NFC/NDF diets compared with high NFC/NDF diets in the present study, which is in accordance with studies in dairy cows demonstrating that the provision of fermentable carbohydrates reduced ammonia production by reducing deamination or enhancing microbial capture of released ammonia in the rumen (Hristov et al., 2005).

The total ruminal VFA was higher for lambs fed high NFC/NDF diets (average 104.30 mmol/L) than those fed low NFC/NDF (average 94.76 mmol/L) diets. Ruminal concentrations of total VFA are in agreement with values reported with sheep under similar dietary conditions (Ramos et al., 2009). Ma et al. (2014) also proved that high dietary level NFC could improve ruminal concentration of total VFA. Increasing NFC decreased the molar proportion of acetate but increased that of propionate, which is similar to those reported by Carro et al. (2000). However, Ramos et al. (2009) found the molar proportion of acetate decreased with increasing NFC. Factors such as feeding regimes (e.g., time and amount) and sampling time could contribute to the discrepancy in ruminal VFA profiles in the abovementioned studies. Higher butyrate concentration was found when lambs were fed diets with higher NFC, which was consistent to those reported by Ma et al. (2014).

Duodenal N metabolism

MN was increased with increasing NFC/NDF and decreasing UDP. As more concentrate is offered, more fermentable carbohydrates are available for ruminal microbes to synthesise microbial protein when the dietary protein supply is equal. The MN was improved by an average of 20% (27% in low NFC/NDF diet and 17% in high NFC/NDF diet) when the dietary level of UDP decreased from 54% to 38% of CP in the current study. However, no effect of level of UDP on MN was observed by Pina et al. (2009) in heifers. The microbial marker or flow marker used for calculating MN could partially be responsible for the differences between their study and ours. On the other hand, the low concentrate diet (20%) used in their study could, to some extent, have limited the use of RDP by microbes, resulting in insignificant MN yield.

The protein requirement for ruminants is expressed in terms of metabolisable protein (MP) to depict the true protein absorbed from the small intestine, including microbial protein from the rumen and UDP (National Research Council, 2007). The duodenal digestibility of microbial protein is difficult to measure, and often constants are used. In addition, no standard methods exist for measuring duodenal digestibility of undegraded protein. Therefore, MP, in most cases, is represented using theoretical values rather than determined values. In this context, the metabolisable N measured in our study could to some extent better reflect the utilisation of protein by lambs. In the current study, lambs fed a high concentrate and UDP diet had the highest metabolisable N, ratio of metabolisable N to either digestible N or N intake, and excreted the lowest amount of urinary N, indicating that balancing dietary carbohydrates and protein is important in maximising N utilisation and reducing N excretion.

CONCLUSION

An increase in dietary UDP reduced intake and ruminal digestibility of CP. Ruminal NH3-N decreased with increasing dietary UDP or NFC/NDF, and dietary treatment interactions were observed. Diets with high levels of NFC/NDF improved MN and metabolisable N, as well as the ratio of metabolisable N to digestible protein or N intake and reduced urinary N output in lambs.

ACKNOWLEDGMENTS

This study was conducted as part of the National Technology Program for the Meat Sheep Industry of China (Program No. nycytx-39) funded by the Ministry of Agriculture of the People’s Republic of China and Special Fund for Agro-scientific Research in the Public Interest (201303143). All authors participated in the writing of the final draft of the manuscript and agreed with the final format. The authors state that there are no conflicts of interest.

Notes

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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Table 1

Ingredients and chemical compositions of experimental diets (% of DM)

Item Low NFC/NDF High NFC/NDF


High UDP Low UDP High UDP Low UDP
Ingredient
 Ground corn 28.72 32.57 50.59 57.29
 Soybean meal 0.00 5.50 0.00 0.25
 Chinese wildrye hay 60.00 60.00 40.00 40.00
 Corn gluten meal 10.00 0.00 7.90 0.00
 Urea 0.00 0.65 0.00 1.00
 CaHPO4 0.50 0.50 0.25 0.00
 Limestone 0.12 0.12 0.60 0.80
 NaCl 0.50 0.50 0.50 0.50
 Premixa 0.16 0.16 0.16 0.16
Chemical component
 DM (% as fed) 89.72 89.65 88.85 88.11
 OM (% of DM) 93.67 92.91 94.62 94.75
 GE (KJ/g of DM) 18.32 18.47 18.43 18.50
 CP (% of DM) 10.42 10.46 10.40 10.49
 EE (% of DM) 2.66 2.60 3.17 3.21
 RDP (% of DM)b 4.85 6.41 4.74 6.65
 UDP (% of DM)c 5.57 4.04 5.68 3.96
 UDP/CP 0.53 0.39 0.55 0.37
 NDF (% of DM) 41.33 39.19 30.52 29.58
 ADF (% of DM) 24.10 23.94 17.09 16.60
 NFC (% of DM)d 39.26 40.66 50.53 51.47
 NFC/NDF 0.95 1.04 1.65 1.74

NFC, non-fibrous carbohydrates; NDF, neutral detergent fibre; UDP, undegraded dietary protein; DM, dry matter; OM, organic matter; GE, gross energy; CP, crude protein; EE, ether extract; RDP, rumen-degraded protein; ADF, acid-detergent fibre.

a

Manufactured by the Precision Animal Nutrition Research Centre, Beijing, China. One kilogram of mineral premix contained the following: CuSO4·5H20, 26,000 mg; FeSO4, 110,000 mg; MnSO4·H2O, 93,000 mg; ZnSO4·H2O, 190,000 mg; KI, 70,000 mg; Na2SeO3, 42,000 mg; CoCl2, 20,000 mg. One kilogram of vitamin premix contained the following: vitamin A 190,000,000 IU; vitamin D3 720,000,000 IU; vitamin E 17,000 IU.

b

RDP were estimated using an in situ method by incubating samples in the rumen for 72 h as described by Volden and Harstad (1995).

c

UDP = CP–RDP.

d

NFC = OM–CP–EE–NDF (Hall, 2000).

Table 2

Effects of dietary NFC/NDF and UDP on intake and digestibility of nutrients in lambs

Item Low NFC/NDF High NFC/NDF SEM p-value



High UDP Low UDP High UDP Low UDP NFC/NDF UDP Interactiona
Intake (g/d)
 OM 1,395.8 1,501.0 1,349.3 1,460.3 143.0 0.82 0.002 0.27
 CP 155.3 169.0 148.3 161.7 12.43 0.17 0.005 0.22
 EE 39.64 42.00 45.20 49.47 2.49 0.04 0.30 0.61
 NDF 615.9 633.1 435.2 455.9 40.5 0.009 0.36 0.54
 ADF 359.1 386.8 243.7 255.8 20.4 0.004 0.41 0.52
Total-tract digestibility (%)
 OM 55.90 57.92 63.38 64.57 1.31 0.005 0.43 0.84
 CP 65.13 66.82 66.24 67.50 1.47 0.67 0.79 0.95
 EE 71.58 72.18 80.38 81.86 1.52 0.005 0.54 0.75
 NDF 51.89 52.98 51.04 55.62 2.07 0.85 0.56 0.72
 ADF 47.93 48.77 34.49 37.66 2.17 <0.001 0.25 0.54
Ruminal digestibility (%)
 OM 40.74 40.15 39.84 39.17 0.37 0.65 0.47 0.52
 CP 11.8 21.6 −0.40 12.4 1.75 <0.001 <0.001 <0.001
 EE 46.17 43.58 41.16 43.61 1.36 0.25 0.02 0.26
 NDF 50.83 51.01 42.63 40.86 1.77 0.03 0.13 0.33
 ADF 44.92 44.59 35.04 36.91 4.01 <0.001 0.26 0.41
Post-ruminal digestibility (%)
 OM 15.17 17.77 23.55 25.40 2.02 <0.001 0.23 0.31
 CP 53.4 45.2 66.6 55.1 3.13 0.02 0.03 0.02
 EE 25.38 28.55 39.27 38.23 1.98 0.65 0.54 0.75
 NDF 1.06 1.98 8.41 14.75 3.02 <0.001 0.13 0.33
 ADF 3.02 4.19 −0.55 0.75 0.91 0.17 0.26 0.41

NFC, non-fibrous carbohydrates; NDF, neutral detergent fibre; SEM, scanning electron microscope; UDP, undegraded dietary protein; OM, organic matter; CP, crude protein; EE, ether extract; ADF, acid-detergent fibre.

a

Interaction of dietary NFC/NDF and UDP.

Table 3

Effect of dietary NFC/NDF and UDP on ruminal fermentation parameters in lambs

Item Low NFC/NDF High NFC/NDF SEM p-value



High UDP Low UDP High UDP Low UDP NFC/NDF UDP Interactiona
pH 6.15 6.07 5.87 5.90 0.05 <0.001 0.53 0.34
NH3-N (mg/100 mL) 11.0 16.7 8.6 11.2 1.08 0.008 <0.001 0.005
Total VFA (mmol) 92.7 96.9 103.2 105.7 2.32 <0.001 0.27 0.51
VFA (mol/100 mol)
 Acetate 65.6 65.6 59.9 61.1 0.42 0.007 0.13 0.25
 Propionate 18.1 17.8 21.8 20.4 0.49 <0.001 0.23 0.42
 Butyrate 14.1 14.0 15.6 16.1 0.21 0.003 0.35 0.31
 Isobutyrate 0.65 0.79 0.63 0.64 0.06 0.30 0.16 0.47
 Valerate 0.67 0.79 1.11 0.80 0.03 0.08 0.20 0.17
 Isovalerate 0.93 1.03 1.01 0.94 0.08 0.84 0.54 0.43
Acetate/propionate 3.61 3.65 2.80 3.03 0.10 <0.001 0.37 0.31

NFC, non-fibrous carbohydrates; NDF, neutral detergent fibre; SEM, scanning electron microscope; UDP, undegraded dietary protein; NH3-N, ammonia nitrogen; VFA, volatile fatty acid.

a

Interaction of dietary NFC/NDF and UDP.

Table 4

Effect of dietary NFC/NDF and UDP on duodenal supply and utilisation efficiency of protein in lambs

Item Low NFC/NDF High NFC/NDF SEM p-value



High UDP Low UDP High UDP Low UDP NFC/NDF UDP Interactiona
Duodenal flow (g/d)
 Total NAN 21.92 21.20 23.82 22.88 0.24 0.03 0.12 0.37
 Microbial N 8.08 10.27 10.38 12.14 0.40 0.007 0.03 0.07
 Undegraded dietary N 13.28 10.45 12.96 9.76 0.41 0.43 <0.001 0.45
 Endogenous Nb 0.55 0.48 0.63 0.96 0.032 0.52 0.57 0.55
 Metabolisable Nc 11.62 9.50 13.73 11.78 0.34 0.02 0.04 0.02
Faecal N (g/d) 10.30 11.70 10.10 11.10 0.14 0.49 0.16 0.27
Urinary N (g/d) 10.70 12.99 6.50 7.52 0.62 0.01 0.04 0.45
Metabolisable N/Total NAN (%) 65.5 57.0 69.2 63.4 1.18 0.35 0.02 0.49
Metabolisable N/Digestible N (%) 62.1 47.8 77.8 60.9 4.07 0.02 0.003 0.01
Metabolisable N/N intake (%) 46.7 35.1 57.8 45.1 2.35 0.01 0.006 0.01

NFC, non-fibrous carbohydrates; NDF, neutral detergent fibre; SEM, scanning electron microscope; UDP, undegraded dietary protein; NAN, non-ammonia N.

a

Interaction of dietary NFC/NDF and UDP.

b

Endogenous N were calculated as 2.8 g/kg DMI according to Bartram (1987).

c

Metabolisable N = Duodenal total NAN – Faecal N – endogenous N.