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Advances in Animal and Veterinary Sciences

AAVS_7_7_530-536

 

 

Research Article

 

Extracted Saponin from Sapindus rarak and Hibiscus sp. as an Additive in Cassava Leaf Silage: Effects on Chemical Composition, Rumen Fermentation and Microbial Population

 

Pristian Yuliana1, Erika B. Laconi2, Anuraga Jayanegara2, Suminar S. Achmadi3, Anjas A. Samsudin4*

1Graduate School of Nutrition and Feed Science, Faculty of Animal Science, Bogor Agricultural University, Bogor, West Java, Indonesia; 2Department of Nutrition and Feed Technology, Faculty of Animal Science, Bogor Agricultural University, Bogor, West Java, Indonesia; 3Department of Chemistry, Faculty of Mathematics and Natural Sciences, Bogor Agricultural University, Bogor, West Java, Indonesia; 4Department of Animal Science, Faculty of Agriculture, Universiti Putra Malaysia, Serdang, Selangor, Malaysia.

 

Abstract | This study aimed to evaluate the addition of saponin extracts from lerak fruit (Sapindus rarak) or hibiscus leaf (Hibiscus sp.) on chemical composition, in vitro rumen fermentation and microbial population of cassava leaf silage. Lerak and hibiscus extracts were added to cassava leaf by following a factorial design 2 × 3, in which the first factor was saponin source (Sapindus rarak or Hibiscus sp.) and the second factor was addition level (0, 2 or 4% of cassava leaf dry matter). Cassava leaf was then ensiled in a lab-scale silo (1 L capacity) for 30 d under room temperature. The silage was subjected to further chemical composition determination and in vitro rumen fermentation analysis, including rumen microbial population by using real-time PCR. Results showed thatthe chemical composition of cassava leaf silage added with various levels of lerak and hibiscus extracts showed significant differences (P<0.05) for a number of variables such as crude protein, ether extract and saponin. The addition of 4% lerak extract on cassava leaf increased significantly gas production after 24 and 48 h, and organic matter digestibility than that of control. The addition of lerak extract at 2% or 4% hibiscus extract in cassava silage significantly decreased (P<0.05) ruminal ammonia concentration. However, the addition of lerak or hibiscus extract to cassava leaf silage did not alter rumen microbial population. It is concluded that the addition of lerak extract at a level 4% to cassava leaf silage increases gas production, organic matter digestibility, and decrease ruminal ammonia concentration.

 

Keywords | Lerak, Hibiscus, Cassava, Silage, Rumen

 

Received | November 21, 2018; Accepted | March 30, 2019; Published | May 08, 2019

*Correspondence | Anjas A Samsudin, Department of Animal Science, Faculty of Agriculture, Universiti Putra Malaysia, Serdang, Selangor, Malaysia; Email: anjas@upm.edu.my

Citation | Yuliana P, Laconi EB, Jayanegara A, Achmadi SS, Samsudin AA (2019). Extracted saponin from sapindus rarak and hibiscus sp. As an additive in cassava leaf silage: effects on chemical composition, rumen fermentation and microbial population Adv. Anim. Vet. Sci. 7(7): 530-536.

DOI | http://dx.doi.org/10.17582/journal.aavs/2019/7.7.530.536

ISSN (Online) | 2307-8316; ISSN (Print) | 2309-3331

Copyright © 2019 Yuliana et al. This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

 

INTRODUCTION

 

Methane is among the main sources of green house gases in the atmosphere, precisely the second after carbon dioxide. Its global warming potential is more than 25 times greater than carbon dioxide (Tian et al., 2016). Livestock is a major source of methane emission through enteric fermentation, and it may account for 25% of the total methane emission (Hristov, 2003). Besides its effect on global warming, methane emission from ruminants also results in the loss of feed energy that would otherwise be used to support productivity. Enteric methane emission from ruminants represents approximately 5–9 % of dietary gross energy loss (Jeyanathan, 2014).

 

Several approaches have been studied to mitigate the enteric methane emission from ruminants by using natural bioactive compounds such as tannin, saponin, and essential oil (Cottle et al., 2011). The effects of plant secondary metabolites on methane emission have been reported previously (Kumar et al., 2014). These natural compounds secondary are preferred (Kondo et al., 2014) since many countries have prohibited the use of antibioticsas feed additives. Plants of tropical origin generally contain high concentration of natural compounds including saponin. Fruit of lerak (Sapindus rarak) and leaf of Hibiscus sp. have been known to contain a considerable amount of saponin. Saponin consists of fat-soluble nucleus with one part of the bond iseither steroid or triterpenoid (Cheok et al., 2014). The structure possesses by saponin has membranolytic activity and also has anti-bacterial, anti-tumor, anti-inflammatory properties in animals (Wojciechowski et al., 2016), and reduces methane emission (Rira et al., 2015). However, to our knowledge, there is no study so far attempted to compare between saponin extracts from both sources, i.e., lerak fruit (Sapindus rarak) and hibiscus leaf (Hibiscus sp.) regarding their effects on silage quality of cassava and rumen fermentation profiles.

 

This study aimed to evaluate the addition of saponin extracts from lerak fruit (Sapindus rarak) or hibiscus leaf (Hibiscus sp.) on chemical composition, in vitro rumen fermentation and microbial population of cassava leaf silage.

 

MATERIALS AND METHODS

 

Sample Preparation

Cassava leaves were collected from field research station of Faculty of Agriculture, Universiti Putra Malaysia, whereas Sapindus rarak fruit and Hibiscus sp. leaves were obtained from Bogor Agricultural University, Indonesia. Extraction of saponin was according to Wina et al. (2005); the extract was subsequently lyophilized to obtain a powdered form. The extracts were added to cassava leaf by following a factorial design 2 × 3, in which the first factor was saponin source (Sapindus rarak or Hibiscus sp.) and the second factor was addition level (0, 2 or 4% of cassava leaf dry matter). Cassava leaves were then ensiled in a lab-scale silo (1 L capacity) for 30 d under room temperature. The silage was subjected to further chemical composition determination and in vitro rumen fermentation analysis.

 

Determination of Chemical Composition

Silage samples were subjected to analysis of crude protein (CP), ether extract (EE) and crude fiber (CF) according to the standard procedures of AOAC (AOAC, 1990). Neutral detergent fiber (NDF) and acid detergent fiber (ADF) were determined according to Van Soest et al. (1994). Measure of total saponin was done in accordance with the method of Hiai and Nakajima (1976) and calibrated against diosgenin standard (Sigma-Aldrich D1634, Sigma Aldrich Chemie GmbH, Steinheim, Germany). A pH meter was used to determine pH value of the silage.

 

In vitro Rumen Fermentation Procedure

Dried and ground forms of cassava leaf samples were incubated in vitro with buffered rumen fluid according to the procedure of Menke and Steingass (1988). The rumen fluid was obtained from two fistulated Brahman-cross cattle prior to morning feed.It was filtered and mixed with buffer solution in a ratio of rumen fluid: buffer 1:4 v/v. The incubation was performed in four replicates by employing a randomized complete block design. Total gas generated was recorded at 0, 3, 6, 9, 12, 24, 30, 36, and 48 h.The kinetic parameters of in vitro cumulative gas produced were estimated as per Ørskov and McDonald (1979). Rumen fluid pH was determined by a pH meter while the ammonia nitrogen (NH3-N) concentration was measured according to Parsons et al. (1984). Volatile fatty acids (VFA) were determined by employing a gas chromatograph (Hewlett Packard 6890 GC system) according to the procedure of Cottyn and Boucque (1968). The amount of methane produced was estimated by employing the stoichiometrical equation of Moss et al. (2000).

 

Microbial Population Analysis using Real Time PCR

The rumen fluid sample was extracted using a tool kit extractor (Qiagen Inc., Valencia, USA). The target of rumen microbial population, primer sequences of DNA microbial, annealing temperature and references in this study were provided in Table 1. The real time PCR was performed with Bio Rad CFX96 real-time PCR system (Bio Rad, USA) using an optical grade plate. An amount of 25 µl Quanti Fast® SYBR® Green PCR kit (Qiagen Inc., Valencia, USA), which included 12.5 µl of 2x SYBR Green Master Mix, 1 µl of 10 µM forward primer, 2 µl of DNA sample and 8.5 µl nuclease-free water for each reaction were analyzed in duplicate. To prevent contamination for each sample, a number of plate control was established in the real-time PCR amplification to rule. The real-time cycle condition had been set up with annealing temperature of 94oC for 5 min for initial denaturation, then 40 cycles at 94oC for 20 s. The total annealing for total bacteria, methanogen, total protozoa, Fibrobacter succinogenes, Ruminococcus albus, and Ruminococcus flavefacienswas performed at 60oC and extension at 72oC to 20 s (Navidshad et al., 2012).

 

Statistical Analysis

The obtained data were subjected to analysis of variance (Steel and Torrie, 1993). When a parameter exhibited a significance at P<0.05 among the experimental treatments, Duncan’s multiple range test was performed to compare the different treatments. The statistical analysis was determined by using SPSS statistical software version 22.0.

 

Table 1: Sequence of primers used for targeting total bacteria, total protozoa, Fibrobacter succinogenes, Ruminococcus albus, Ruminococcus flavefaciens and methanogen

 

Targeted microbe

Sequence 5’- 3’ Annealing

Temperature (oC)

Reference
Total bacteria

F-CGGCAACGAGCGCAACCC

R-CCATTGTAGCACGTGTGTAGCC

55 Koike and Kobayashi (2001)
Methanogen

F-CCGGAGATGGAACCTGAGAC

R-CGGTCTTTGCCCAGCTCTTATTC

55

Zhou et al. (2009)

Total

protozoa

F-CTTGCCCTCYAATCGTWCT

R-GCTTTCGWTGGTAGTGTATT

55

Sylvester et al. (2004)

F. succinogenes

F-GTTCGGAATTACTGGGCGTAAA

R-CGCCTGCCCTGAACTATC

55 Lane (1991)
R.albus

F-CCCTAAAAGCAGTCTTAGTTCG

R-CCTCCTTGCGGTTAGAACA

55 Koike and Kobayashi (2001)
R. flavefaciens

F-TCTGGAAACGGATGGTA

R-CCTCCTTGCGTTAGAACA

60

Koike and Kobayashi (2001)

 

Table 2: Chemical composition of cassava leaf silage added with saponin extract (% dry matter)

 

Parameter Saponin source Level (% dry matter) SEM

P-value

    0 2 4    
CP Lerak

31.87a

27.81a

32.87a

0.874 <0.001
  Hibiscus

32.41a

28.84a

38.41b

   
EE Lerak

3.33a

5.76c

5.38bc

0.237 0.019
  Hibiscus

4.10ab

5.04bc

5.68bc

   
CF Lerak 14.32 16.61 15.49 0.573 0.363
  Hibiscus 15.68 12.37 15.68    
NDF Lerak 46.69 48.09 40.37 2.120 0.326
  Hibiscus 49.23 54.67 39.40    
ADF Lerak 29.84 30.78

25.49

1.145 0.541
  Hibiscus 32.07 26.34 27.56    
pH Lerak

4.00a

4.48b

4.92c

0.081 0.002
  Hibiscus

4.47a

4.56b

4.51b

   
Saponin Lerak

0.24a

3.10b

6.01c

0.468 <0.001
  Hibiscus

0.17a

0.17a

2.98b

   

 

Different superscripts within the same parameter are significantly different at P<0.05.

CP: crude protein, EE: ether extract,CF: crude fiber, NDF: neutral detergent fiber, ADF: acid detergent fiber, SEM:standard error mean.

 

Table 3: The effect of saponin extract addition on in vitro gas production and digestibility of cassava leaf silage

 

Parameter Saponin source Level (% dry matter) SEM

P-value

    0 2 4    
Gas 24 h (ml) Lerak

24.53b

21.19a

27.01c

0.589 0.002
  Hibiscus

24.63b

22.32a

26.86b

   
Gas 48 (ml) Lerak

29.60b

23.72a

32.93c

0.722 0.002
  Hibiscus

29.20b

29.16b

29.62b

   
b (ml) Lerak

34.17b

28.32a

32.83b

0.589 0.056
  Hibiscus

32.30b

32.54b

34.24b

   
c (/ml) Lerak 0.07 0.07 0.07 0.722 0.354
  Hibiscus 0.06 0.06 0.85    
IVOMD (%) Lerak

54.45b

49.76a

59.21c

0.603 <0.001
  Hibiscus

54.17b

50.49a

55.81b

   

 

Different superscripts within the same parameter are significantly different at P<0.05.

b: Potential gas production, c: Gas production rate constant, IVOMD:in vitro organic matter digestibility, SEM:standard error mean.

 

Table 4: The effect of saponin extract addition on ruminal volatile fatty acid profile of cassava leaf silage

 

Parameter Saponin source Level (% dry matter) SEM

P-value

 
    0 2 4    
TVFA Lerak 53.84 52.59 56.71 2.098 0.798
(mM) Hibiscus 56.74 49.69 54.00    

C2 (%)

Lerak

67.88a

69.70c

66.86a

0.264 <0.001
  Hibiscus

68.32b

70.16c

69.02b

   

C3 (%)

Lerak

18.13c

17.43b

17.62b

0.141 0.035
  Hibiscus

18.16c

17.15a

17.30a

   

IsoC4 (%)

Lerak

1.46b

1.36a

1.53b

0.024 0.022
  Hibiscus

1.46b

1.29a

1.53b

   

C4 (%)

Lerak

8.65a

8.10a

9.86b

0.172 0.007
  Hibiscus

8.27a

8.17a

8.17a

   

IsoC5 (%)

Lerak

2.64b

2.33a

2.81b

0.062 0.012
  Hibiscus

2.65b

2.19a

2.72b

   

C5 (%)

Lerak

1.21b

1.06b

1.30c

0.031 0.017
  Hibiscus

1.12b

1.02a

1.24b

   

 

Different superscripts within the same parameter are significantly different at P<0.05.

TVFA: total volatile fatty acid, C2: acetate, C3: propionate,IsoC4: isobutyrate, C4: butyrate, IsoC5: isovalerate, C5:valerate, SEM:standard error mean.

 

Table 5: The effect of saponin extract addition on ruminal pH, ammonia, and methane formation of cassava leaf silage

 

Parameter Saponin source Level (% dry matter) SEM

P-value

    0 2 4    
pH Lerak

7.3a

7.5b

7.5b

0.043 0.007
  Hibiscus

7.4a

7.5b

7.5b

   

NH3 (mM)

Lerak

17.3b

17.8b

14.2a

0.369 0.007
  Hibiscus

17.3b

15.3a

16.9b

   

CH4

Lerak

22.65a

22.98b

22.64a

0.069 0.002
(%TVFA) Hibiscus

22.66a

23.07b

22.90b

   

 

Different superscripts within the same parameter are significantly different at P<0.05.

NH3: ammonia, CH4: methane, TVFA: total volatile fatty acid, SEM: standard error mean.

 

Table 6: The effect of saponin extract addition on ruminalmicrobial population of cassava leaf silage (log cell/ml)

 

Parameter Saponin source Level (% dry matter) SEM

P-value

    0 2 4    
Total bacteria Lerak 10.6 10.5 10.6 0.042 0.699
  Hibiscus 10.4 10.4 10.5    
R. flavefaciens Lerak 4.62 4.89 4.91 0.070 0.437
  Hibiscus 4.52 4.78 4.76    
R. albus Lerak 6.47 6.39 6.30 0.193 0.844
  Hibiscus 6.36 5.76 6.34    
F. succinogenes Lerak 6.69 6.47 6.81 0.121 0.659
  Hibiscus 6.72 6.78 6.27    
Total protozoa Lerak

5.02

5.75 6.03 0.166 0.141
  Hibiscus 5.07 5.02 5.34    
Methanogen Lerak 6.70 6.61 6.65 0.037 0.630
  Hibiscus 6.56 6.48 6.56    

 

Different superscripts within the same parameter are significantly different at P<0.05.

SEM: standard error mean.

 

RESULTS AND DISCUSSION

 

The chemical composition of cassava leaf silage added with various levels of lerak and hibiscus extracts showed significant differences (P<0.05) for a number of variables such as CP, EE and saponin (Table 2). The nutrient contents of the experimental silages were quite diverse due to different saponin level addition. All silages in this study had higher CP content than the minimum 6-7% as required for effective rumen function (Milford & Haydock, 1965). The increase in CP content of cassava leaf silage after adding lerak extract was expected because the lerak extract contained a small amount of protein and fat. Higher level of saponin in the cassava leaf silage added with lerak extract was expected due to the high content of saponin present in lerak. This is in agreement with Wina et al. (2005) who observed that lerak fruit extract contained 48-87% saponin. This also indicates that saponin isrelatively resistant to degradation during the ensiling process.

 

The addition of 4% lerak extract on cassava leaf significantly increased (P<0.05) gas production after 24 and 48 h as compared to the control (Table 3). The addition of 4% lerak extract also, siginificantly increased the organic matter digestibility of cassava leaf silage than that of control. Total gas production in all treatments increased with the increasing incubation time. Gas production will continue to increase as long as the microbial substrate is still available. The gas production during in vitro rumen incubation is a product of microbial metabolism in degrading feed, and in addition, it isalso as a result of the buffering effect of artificial saliva (buffer solution) when VFA is produced (Getachew et al., 1998). The increase in gas production after the addition of lerak extract is possiblesince some saponin is cleaved to aglycon and glycon (sugar) component, and then the sugar component is metabolized by the microbes to generate gas (Patra et al., 2010). Gas production is positively correlated with organic matter digestibility because both parameters reflect the level of feed degradation in the rumen (Jayanegara et al., 2016).

 

Addition of lerak extract did not increase propionate proportion of cassava leaf silage (Table 4). This was in contrast to some other related studies which an increase in propionate proportion from the total SCFA production with increasing levels of the saponins (Jayanegara et al., 2014), that saponin generally increases propionate in the rumen. Propionate is related to methane emission since both products require H2 for their synthesis in the rumen system, and hence compete for similar substrate. Methane was also did not decrease by addition of lerak or hibiscus extract (Table 5). Methane is produced in the rumen by methanogen which possesses enzyme system to use H2 and combined with CO2 to form methane (Morgavi et al., 2011). Saponin addition has been known to increase proportion of propionate and its respective ratio to total VFA in the rumen particularly when saponin is given in high concentration (Goel et al., 2008). The CO2, CH4, and volatile fatty acids (VFA) are the final products of rumen fermentation, and the VFA is a major energy source for ruminant (Banik et al., 2013).

 

The addition of lerak extract at a level 4% or 2% hibiscus extract in cassava silage significantly decreased (P<0.05) ruminal ammonia concentration. Ammonia concentration produced from all treatments ranged between 14.2 and 17.8 mM and these values are considered to be satisfactory for rumen microbial growth. McDonald et al. (2002) stated that the optimum ammonia concentration to support microbial protein synthesis in rumen fluid varies widely, ranging from 6 to 21 mM. A common observation about saponin is its typical effect to decrease NH3 concentration in the rumen (Goel et al., 2008). Supporting the current finding, Lila et al. (2005) observed that the administration of saponin reduced NH3 concentration and accompanied with an increase of total VFA and propionate concentration. Hu et al. (2005) also observed a decrease of 27% NH3 proportion and an increase proportion of propionate by giving saponin from tea at 8 mg/200 g of feed under in vitro rumen fermentation.

 

Addition of lerak or hibiscus extract to cassava leaf silage in the present study did not alter microbial population in the rumen in vitro, i.e. total bacteria, R. flavefaciens, R. Albus, F. succinogenes, total protozoa and methanogen (Table 6). This is in contrast to some other findings that saponin or plant extract rich in saponin generally has a defaunation activity against protozoa and affects the H2 pathway so that it could not be used by methanogen (Johnson & Johnson, 1995). Saponins has the capability to bind the sterol component found in the protozoa cell membrane and may cause cell lysis (Wina et al., 2005). Supplementation of Sesbania sesban leaves that rich in saponin was able to increase the flow of protein from rumen by pressing the existing protozoa (Newbold et al., 1997). Methane production in the rumen is very dependent on the interaction level among methanogens and rumen protozoa, as well as the methane production level per methanogen cell (Machmuller et al., 2003). Methane can also be influenced by saponin as a result of a decrease in the rate of methanogenesis with decreasing methane-producing gene activity without changing the total population of methanogen (Hess et al., 2003).

 

CONCLUSION

 

Addition of lerak extract at a level 4% to cassava leaf silage can increase gas production, organic matter digestibility, and decrease ruminal ammonia concentration.

 

ACKNOWLEDGMENTS

 

The authors are grateful to the Department of Animal Science, Faculty of Agriculture, Universiti Putra Malaysia for the facilitation of this study through Research Attachment Program. The first author is grateful to the Indonesian Ministry of Education and Culture (Kemendikbud) for the Doctoral Scholarship award.

 

CONFLICT OF INTEREST

 

The authors declare that there is no conflict of interest.

 

AUTHORS CONTRIBUTION

 

Pristian Yuliana conducted research, analyzed the data and wrote the manuscript. Erika B. Laconi supervised the experiment, Anuraga Jayanegara supervised the experiment, analyzed the data and revisedthe manuscript, Suminar S. Achmadi revised the manuscript. Anjas A. Samsudin supervised the analysis of rumen microbial population using Real Time PCR and revised the manuscript.

 

REFERENCES

 

  • Association of Official Analytical Chemists (AOAC), (1990). Association of Official Methods of Analysis. AOAC, Arlington, VA, USA.
  • AOAC (2005). Official Methods of Analysis of AOAC International. 18th ed. Arlington. Assoc. Off Anal Chem. Arlington.
  • Banik BK, Durmic Z, Erskine W, Nichols P, Ghamkhar K, Vercoe P (2013). Variability of in vitro ruminal fermentation and methanogenic potential in the pasture legume biserrula (Biserrulapelecinus L.). Crop. Pasture. Sci. 64: 409. https://doi.org/10.1071/CP13073
  • Cheok CY, Salman HAK, Sulaiman R (2014). Extraction and quantification of saponins: a review. Food Res. Int. 59: 16–40. https://doi.org/10.1016/j.foodres.2014.01.057
  • Cottle DJ, Nolan JV, Wiedemann SG (2011). Ruminant enteric methane mitigation: a review. Anim. Prod. Sci. 51: 491-514.
  • Cottyn B, Bouque CV (1968). Rapid method for gas-chromatographic determination of volatile fatty acids in rumen fluid. J. Agric. Food Chem. 16: 105-107. https://doi.org/10.1021/jf60155a002
  • Getachew G, Blummel M, Makkar HPS, Becker K (1998). In vitro gas measuring technique for assessment of nutritional quality of feeds: a review. Anim. Feed Sci. Technol. 72: 261-281. https://doi.org/10.1016/S0377-8401(97)00189-2
  • Goel G, Makkar HPS, Becker K (2008). Changes in microbial community structure, methanogenesis and rumen fermentation in response to saponin-rich fractions from different plant materials. J. Appl. Microbiol. 105: 770-777. https://doi.org/10.1111/j.1365-2672.2008.03818.x
  • Jayanegara A, Wina E, Takahashi J (2014). Meta-analysis on methane mitigating properties of saponin-rich sources in the rumen:influence of addition levels and plants sources. Asian-Aust J. Anim. Sci. 10: 1426-1435. https://doi.org/10.5713/ajas.2014.14086
  • Jayanegara A, Dewi SP, Laylli N, Laconi EB, Nahrowi, Ridla M (2016). Determination of cell wall protein from selected feedstuffs and its relationship with ruminal protein digestibility in vitro. Media Peternak. 39: 134-140. https://doi.org/10.5398/medpet.2016.39.2.134
  • Jeyanathan J, Martin C, Morgavi, D (2014). The use directed-fed microbial for mitigation of ruminant methane emissions: a review. Animal. 8: 250-261. https://doi.org/10.1017/S1751731113002085
  • Johnson KA, Johnson DE (1995). Methane emissions from cattle. J. Anim. Sci. 73: 2483-2492. https://doi.org/10.2527/1995.7382483x
  • Hiai S Oura. H, Nakajima T (1976). Color Reaction of some sapogenins and saponins with vanillin and sulfuric acid. Planta Med. 29: 116-122. https://doi.org/10.1055/s-0028-1097639
  • Hess HD, Monsalve LM, Lascano CE, Carulla JE, Diaz TE, Kreuzer M (2003). Supplementation of a tropical grass diet with forage legumes and Sapindus saponaria fruits: effects on in vitro ruminal nitrogen turnover and methanogenesis. Aust. J. Agric. Res. 54: 703–713. https://doi.org/10.1071/AR02241
  • Hristov AN, Oh J, Giallongo F, Freederick WT, Harper TM, Weeks LH, Branco FA, Moate JP, Deighton HM, Williams OR, Kinderman M, Duval S (2017). An inhibitor persistently decreased enteric methane emission from dairy cows with no negative effect on milk production. PNAS. 112: 10663-10668. https://doi.org/10.1073/pnas.1504124112
  • Hu WL, Yue-Ming W, Jian-Xin L, Yan-Qiu G, Jun-An Y (2005). Tea Saponins Affect In Vitro Fermentation And Methanogenesis In Faunated and Defaunated Rumen Fluid. Zhejiang Univ. Sci. 6b: 787-792.S https://doi.org/10.1631/jzus.2005.B0787
  • Kondo M, Hirano Y, Ikai N, Kita K, Jayanegara A, Yokota HO (2014). Assessment of anti-nutritive activity of tannins in tea by-products based on in vitro rumen fermentation. Asian Australas. J. Anim. Sci. 27: 1571-1576. https://doi.org/10.5713/ajas.2014.14204
  • Kumar S, Choudhury PK, Carro, MD, Griffith GW, Dagar S, Puniya M, Calabro S, Ravella SR, Dhewa T, Upadhyay RC, Sirohi SK, Kundu SS, Wanapat M, Puniya K (2014). New aspects and strategies for methane mitigation from ruminants. Appl. Microbiol. Biotechnol. 98: 31-44. https://doi.org/10.1007/s00253-013-5365-0
  • Lila ZA, Mohammed N, Kanda S, Kurihara M, Itabashi H (2005). Sarsaponin effects on ruminal fermentation and microbes, methane production, digestibility and blood metabolites in steers. Asian-Aust. J. Anim. Sci. 18: 1746-1751. https://doi.org/10.5713/ajas.2005.1746
  • Machmuller A, Soliva CR, Kreuze M (2003). Effect of coconut oil and defaunation treatment on methanogenesis in sheep. Reprod. Nutr. Dev 43: 41–55. https://doi.org/10.1051/rnd:2003005
  • McDonald P, Edwards R, Greenhalgh J (2002). Animal Nutrition. 6th Edition. New York.
  • Menke KH, Steingass H (1988). Estimation of the energetic feed value obtained from chemical analysis and in vitro gas production using rumen fluid. Anim. Res. Dev. 28: 7–55.
  • Milford R, Haydock KPH (1965). The nutritive value of protein in subtropical pasture species grown in southeast Queensland. Aust. J. Exp. Agric. Anim. Husb. 5: 13-17. https://doi.org/10.1071/EA9650013
  • Morgavi DP, Martin C, Jouany JP, Ranilla MJ (2011). Rumen protozoa and methanogenesis: not a simple cause–effect relationship. Br. J. Nutr. 107: 388-397. https://doi.org/10.1017/S0007114511002935
  • Moss AR, Jouany JP, Newbold J (2000). Methane production by ruminants: its contribution to global warming. Ann. Zootech. 49: 231-253. https://doi.org/10.1051/animres:2000119
  • Navidshad B, Liang JB, Jahromi MF (2012). Correlation coefficients between different methods of expressing bacterial quantification using real time PCR. Int. J. Mol. Sci. 13: 2119-2132. https://doi.org/10.3390/ijms13022119
  • Newbold CJ, El Hassan SM, Wang J, Ortega ME, Wallace RJ (1997). Influence of foliage from African multipurpose trees on activity of rumen protozoa and bacteria. Br. J. Nutr. 78: 237–249. https://doi.org/10.1079/BJN19970143
  • Ørskov ER, McDonald P (1979). The estimation of protein degradability in the rumen from incubation measurements weighed according to rate of passage. J. Agric. Sci. 92: 499–503. https://doi.org/10.1017/S0021859600063048
  • Parsons TR, Maita Y, Lalli CM (1984). A Manual of Chemical and Biological Methods for Seawater Analysis. Elmsford, NY: Pergamon Press.
  • Patra AK, Saxena J (2010). A new perspective on the use of plant secondary metabolites to inhibit methanogenesis in the rumen. Phytochemistry. 71: 1198– 1222. https://doi.org/10.1016/j.phytochem.2010.05.010
  • Rira M, Chentli A, Boufenera S, Bousseboua H (2015). Effects of plants containing secondary metabolites on ruminal methanogenesis of Sheep in vitro. Energy Procedia. 74: 15–24. https://doi.org/10.1016/j.egypro.2015.07.513
  • Steel RGD, Torrie JH (1980). Prinsip dan Prosedur Statistika. Suatu Pendekatan Biometrik. Terjemahan: B. Sumantri. PT Gramedia Pustaka Utama, Jakarta.
  • Tian H, Lu C, Ciais P, Michalak AM, Canadell JG, Saikawa E, Huntzinger DN, Gurney KR, Sitch S, Zhang B (2016). The terrestrial biosphere as a net source of greenhouse gases to the atmosphere. Nature. 531: 225–228. https://doi.org/10.1038/nature16946
  • Van Soest PJ (1994). Nutritional Ecology of the ruminant, 2nd ed. Cornell University Press, USA.
  • Wina E, Muetzel S, Hoffmann EM, Makkar HPS, Becker K (2005). Saponins containing methanol extract of Sapindus rarak affect microbial fermentation, microbial activity and microbial community structure in vitro. Anim. Feed. Sci. Technol.121: 59-174. https://doi.org/10.1016/j.anifeedsci.2005.02.016
  • Wojciechowski K, Orczyk M, Gutberlet T, Geue T (2016). Complexation of phospholipids and cholesterol by triterpenic saponins in bulk and in monolayers. Biochim. Biophys. Acta. 1858: 363–373. https://doi.org/10.1016/j.bbamem.2015.12.001
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    Advances in Animal and Veterinary Sciences

    November

    Vol. 12, Iss. 11, pp. 2062-2300

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