Subscribe Now Subscribe Today
Research Article

Chemical Compositions and in vitro Methane Production Potentials of Some Agro-industrial By-products and Crop Residues

Aberra Melesse, Herbert Steingass, Margit Schollenberger and Markus Rodehutscord
Facebook Twitter Digg Reddit Linkedin StumbleUpon E-mail

Background and Objective: Crop production provides a range of agro-industrial by-products and crop residues that have been utilized by ruminants and non-ruminants. However, they are also potential sources of methane emission. Moreover, limited information is available on the methane production profiles of these by-products and crop residues. Thus, this study was conducted to evaluate the chemical, mineral and amino acid compositions and methane production profiles of agro-industrial by-products and crop residues. Materials and Methods: Feed samples of agro-industrial by-products and crop residues were collected and processed and ground to pass 1 mm sieve size. Chemical, mineral and amino acid compositions were analyzed using standard procedures. In vitro gas and methane production profiles were determined according to established procedures. Results: Meat and bone meal (MBM) and fish offal waste (FOW) contained high crude protein (574 and 487 g kg1 DM, respectively). Calcium and phosphorous concentrations in MBM were 67.6 and 36.1 g kg1 DM, respectively. Fat content in FOW was highest followed by MBM. Wheat bran had the highest starch (387 g kg1 DM) and noug seed cake (NSC) the highest iron (4383 g kg1 DM) and manganese (189 g kg1 DM). The NSC contained higher concentrations of arginine, cystein, methionine and histidine than those of wheat bran. Methane production was highest (p<0.05) in wheat bran while it was lowest (p<0.05) in FOW. Conclusion: The FOW and MBM might be used as suitable feed combinations with crop residues to mitigate methane emission from the livestock agriculture.

Related Articles in ASCI
Similar Articles in this Journal
Search in Google Scholar
View Citation
Report Citation

  How to cite this article:

Aberra Melesse, Herbert Steingass, Margit Schollenberger and Markus Rodehutscord, 2019. Chemical Compositions and in vitro Methane Production Potentials of Some Agro-industrial By-products and Crop Residues. Journal of Applied Sciences, 19: 763-770.

DOI: 10.3923/jas.2019.763.770

Received: January 11, 2019; Accepted: February 22, 2019; Published: July 25, 2019

Copyright: © 2019. This is an open access article distributed under the terms of the creative commons attribution License, which permits unrestricted use, distribution and reproduction in any medium, provided the original author and source are credited.


In most developing nations, like Ethiopia, livestock have low productivity because they are fed almost entirely on natural pasture and crop residues. However, crop production provides a range of agro-industrial by-products that have been utilized by ruminants and non-ruminants in urban and peri-urban areas. The most common agro-industrial by-products produced and used widely in Ethiopia are noug seed (Guizotia abyssinica) oil cake, wheat bran and meat and bone meal1. Noug (Guizotia abyssinica) is an oilseed crop mainly cultivated in different parts of Ethiopia and India. It constitutes about 50% of the Ethiopian and 3% of Indian oilseed production2. Fish offal waste has been also considered as another potential animal feed by-product from freshwater lakes3,4. These feed resources have been mainly used in ration formulations for both ruminant and poultry by filling the gap in the feed supply, decrease competition for food between humans and animals, reduce feed cost and contribute to self-sufficiency in nutrients from locally available feed sources. Crop residues also represent the major feed resources in most developing nations. In Ethiopia, straws from teff (Eragrostis teff), wheat, barley and maize stover are the most common crop residues used in livestock feeding1. However, they are considered as potential sources of methane emission if fed to livestock alone leading to increased green house gas emissions5.

Even though feeding animal origin feeds (meat and bone meal) to farm animals is prohibited in most developed nations, such feed ingredients are still playing a major role in the nutrition of livestock in most developing nations6. Dumping or burning agro-industrial by-products, particularly those from animal products processing industries, present potential air and water pollution problems in developing nations. However, they can be beneficial in enhancing the nutritional status of different forms of rations and feeds of livestock as these contain various amounts of macro and micro-nutrients that are essential for body growth and productivity7. Moreover, these feed resources could be used as potential nutrient supplements to improve the quality of crop residues in the livestock agriculture. Although the nutritive values of agro-industrial by-products and crop residues have been reported by previous scholars, the results were highly variable and inconsistent. A full-fledged data on both macro and trace minerals as well as amino acid profiles for most agro-industrial by-products and crop residues are also scanty6,8,9. Moreover, limited data are available in the literature on the methane production profiles of these by-products and crop residues. Thus, the specific objectives of this study were to evaluate the chemical, mineral and amino acid compositions, in vitro gas production characteristics and methane production profiles of some tropical agro-industrial by-products and crop residues.


Feed sample collection and processing: Samples of wheat bran and noug seed (Guizotia abyssinica) cake (NSC) were purchased from Flour and Oil Factories, respectively. Meat and bone meal (MBM) sample was purchased from local Abattoir Enterprise. The local concentrate was obtained from Animal Feed Processing Section of Hawassa University. Sample of fish offal waste (FOW) was collected from the lake Hawassa. The FOW included the gut, head, skin, scale, gills and gonads of tilapia (Oreochromis niloticus). The waste was then chopped into smaller pieces using a knife and cooked in boiled water for 17 min. After cooling, the cooked offal was gently removed and thinly spread on plastic sheet and sun-dried.

Samples of maize stovers and straws from wheat, barley and teff (Eragrostis teff) were collected after grain harvesting. Crop residues were first chopped to reduce the sizes of the feed material at the site of collection and then sun-dried on plastic sheets. All dried samples were then ground to pass 1 mm sieve size and stored in labelled air-tight plastic bags until analysis. The experiment was conducted from June, 2013 to November 2014 at the Institute of Animal Nutrition, University of Hohenheim, Germany.

Chemical analyses: Analyses of proximate nutrients and fiber fractions were performed as outlined by VDLUFA10 at the Institute of Animal Science, University of Hohenheim, Germany. The samples were analyzed for DM (method 3.1), ash (method 8.1), crude protein (CP, method 4.1.1), petroleum ether extract (EE, method 5.1.1) and crude fiber (CF, method 6.1.1). Neutral detergent fiber (aNDFom) was assayed on organic matter basis after amylase treatment and acid detergent fiber (ADFom) on organic matter basis (methods 6.5.1 and 6.5.2, respectively). Acid detergent lignin (ADL) was analyzed according to method 6.5.3. Starch was analyzed polarimetrically (method 7.2.1) and sugar was determined according to method 7.1.2 and expressed as sucrose equivalents. Minerals were determined according to methods 10 and 11 using an Inductively Coupled Plasma spectrometer (ICP-OES).

Analysis of amino acids was only performed on feed samples of wheat bran and noug seed cake due to their frequent usage in the nutrition of non-ruminant animals such as poultry. Amino acid contents were measured by ion-exchange chromatography using an amino acid analyzer L8900 (VWR/Hitachi, Darmstadt, Germany). After a performic acid oxidation step, protein was hydrolyzed with 6 M HCl for 24 h at 113°C. The amino acids were separated on a cation exchange resin and detected after post column derivatization with ninhydrin reagent using visible spectrophotometer (VIS) detection at 570 nm (440 nm for proline). All analyses were run in duplicate and were averaged. If deviation between duplicates was below the level specified for each analysis, the analysis was repeated.

In vitro gas production
Gas production protocols: Gas production (GP) was determined according to the procedure of VDLUFA10 official method (method No. 25.1). About 200 mg of feed sample was weighed and transferred into 100 mL calibrated glass syringes, fitted with white Vaseline lubricated glass-made plungers. Three syringes with only buffered rumen fluid, termed as blanks (rumen fluid without feed sample), three syringes with hay standard and three with concentrate standard with known GP were included along with each run. Six independent runs were performed for each feed material and standards. Moreover, three replicates per run were used for standards (hay and concentrate) and blanks. The standards of hay and concentrate were used for estimation of metabolizable energy (ME) and organic matter digestibility (OMD) as suggested by Menke and Steingass11 and Menke et al.12. The GP of samples, blanks and standards was recorded at 2, 4, 6, 8, 12, 24, 32, 48, 72 and 96 h incubation.

Parameter estimation: Estimation of ME and OMD was computed from the corrected 24 h GP as described:

ME (MJ kg1 DM) = 1.68+0.1418*GP+0.0073*CP+0.0217*XL- 0.0028 XA

OMD (%) = 14.88+0.889*GP+0.0448*CP+0.0651*XA

where, GP, CP, XL and XA are 24 h gas production (mL/200 mg DM), crude protein, crude fat and ash (g kg1 DM) of the incubated feed samples, respectively.

Describing the gas production kinetics: The corrected GP recorded between 2 and 96 h of incubation and the kinetics of GP were described by using the exponential equation:

y = b*(1e(-c(t-lag)))

which assumed one pool of asymptotic GP (b, mL/200 mg DM) with a constant fractional rate of GP (c, per h) with a lag phase (colonization time, hour) in the onset of GP and parameter “y” is GP at time “t”13.

Methane production: For CH4 determination, five separate in vitro runs were performed. The quantity of each feed sample to be incubated for 24 h without removing the produced gas in the syringes during the incubation period was calculated based on the previous in vitro GP results. After 24 h of incubation, the total gas production was recorded and the incubation liquid was carefully decanted while leaving the gas inside the syringes. The CH4 content of the total gas in the syringes was then analyzed using an infrared methane analyzer (Pronova Analysentechnik, Berlin, Germany) calibrated with a reference gas (13.0 vol. (%) CH4, Westfalen AG, Münster; Germany). Syringes were directly connected to the analyzer and about 20 mL of gas was injected for about 20 sec until the displayed CH4 concentration was constant. The CH4 produced by each sample was corrected by the amount of CH4 produced by blank syringes (containing only the rumen fluid) and by the factors of reference hay and concentrate feed which were included in each run.

Statistical analyses: Results of chemical and mineral compositions are expressed as means for duplicate analysis of a bulked sample. To describe the in vitro gas production kinetics, data were fitted to non-linear regression model by using GraphPad Prism 5.0 (2007) for Windows (GraphPad Software, Inc. La Jolla, CA., USA). Data on ME, OMD, GP and CH4 production were analyzed by one-way ANOVA at p<0.05 using the GLM procedure of the Statistical Analysis System14. Mean comparisons were performed with the Duncan’s multiple range tests.


Chemical compositions: The chemical composition of the main agro-industrial by-products and crop residues is presented in Table 1. Both MBM and FOW contained high levels of total ash and CP followed by NSC. The highest fat content was observed in FOW followed by MBM. Noug seed cake had the highest structured carbohydrates (CF, NDF, ADF and ADL) while FOW the lowest. The sugar content was higher in wheat bran than other by-products. Noug seed cake also contained appreciable amounts of sugar.

Table 1: Chemical compositions of some tropical agro-industrial by-products and crop residues (g kg1 DM)
Image for - Chemical Compositions and in vitro Methane Production Potentials of Some Agro-industrial By-products and Crop Residues
aGuizotia abyssinica, NSC: Noug seed cake, MBM: Meat and bone meal, FOW: Fish offal waste, CP: Crude protein, EE: Ether extract, CF: Crude fiber, aNDFom: Neutral detergent fiber on organic matter basis after amylase treatment, ADFom: Acid detergent fiber on organic matter basis, ADL: Acid detergent lignin, ND: Not determined

Table 2: Compositions of major and trace minerals in some agro-industrial by-products and crop residues
Image for - Chemical Compositions and in vitro Methane Production Potentials of Some Agro-industrial By-products and Crop Residues
aGuizotia abyssinica, Ca: Calcium, P: Phosphorous, Mg: Magnesium, K: Potassium, Na: Sodium, Fe: Iron, Cu: Copper, Mn: Manganese, Zn: Zinc

Table 3:
Amino acid concentrations in wheat bran and noug seed cake collected from Ethiopian agro-industrial feed processing plants
Image for - Chemical Compositions and in vitro Methane Production Potentials of Some Agro-industrial By-products and Crop Residues
aGuizotia abyssinica

The highest and lowest ash values were observed in barely and teff straws, respectively (Table 1). The CP content was low in all crop residues. The fat content in crop residues ranged from 0.87-3.88 g kg1 DM. High ADFom and ADL values were observed in wheat and barley straws.

As shown in Table 2, FOW contained 63.5 and 33.2 g kg1 DM Ca and P, respectively, values being comparable with those observed in MBM. Although relatively deficient in Ca, wheat bran contained considerable concentration of P. Noug seed cake had the highest concentration of Fe and Mn. Both wheat bran and NSC were deficient in Na.

Wheat straw had comparatively lower Ca, Mg, Cu and Zn concentrations. The Ca, Fe and Mn values were highest in barely straw. The highest P, Mg and Zn concentrations were observed in maize stover. Teff straw was rich in Cu. As presented in Table 3, the concentrations of essential amino acids arginine, isoleucine, leucine, methionine, phenylalanine and valine were generally higher in NSC than in wheat bran.

Kinetics of in vitro gas production and estimated parameters: As presented in Fig. 1, the highest GP was observed in wheat bran followed by local concentrate while FOW and MBM had the lowest gas. Values for the asymptotic GP (parameter b) and rate of GP (parameter c) were highest in wheat bran and local concentrate and differed from (p<0.05) the other by-products. The lag time was positive for wheat bran and local concentrate while it was negative for the other feed materials being the lowest in FOW.

Table 4:
In vitro estimates of metabolizable energy (ME, MJ kg1 DM) organic matter digestibility (OMD, %) and gas production kinetics in some tropical agro-industrial by-products and crop residues
Image for - Chemical Compositions and in vitro Methane Production Potentials of Some Agro-industrial By-products and Crop Residues
a-cColumn means with different superscript letters differ significantly at p<0.05. *Guizotia abyssinica, b: Asymptotic gas production (mL g1 DM), c: Constant fractional rate of gas production (per h) with a lag time (colonization time, h) in the onset of gas production, SEM: Standard error of the mean

Image for - Chemical Compositions and in vitro Methane Production Potentials of Some Agro-industrial By-products and Crop Residues
Fig. 1:
Patterns of in vitro gas production in tropical agro-industrial feed processing by-products and local concentrate

The highest ME (12.3 MJ kg1 DM) and OMD (81%) values were observed in wheat bran (Table 4). Fish offal waste had the lowest NGP and OMD values.

As shown in Fig. 2, except in maize stover, other crop residues demonstrated similar GP trends during the first 36 h of incubation after which the pattern for teff straw increased considerably. The highest asymptotic GP (parameter b) and rate of GP (parameter c) were observed in teff and barley straws, respectively. The highest ME and OMD values were obtained from maize stover (Table 4).

Methane production: As shown in Table 5, the lowest CH4 (1.70 mL g1 DM) was observed in FOW, which differed (p<0.05) from other feed materials.

Image for - Chemical Compositions and in vitro Methane Production Potentials of Some Agro-industrial By-products and Crop Residues
Fig. 2:Pattern of in vitro gas production of crop residues of major crops

Meat and bone meal (8.60 mL g1 DM) produced lower (p<0.05) CH4 than the other by-products. However, the percentile CH4 was higher (p<0.05) in NSC (16.8%) as compared to other feed by-products. The values for absolute and percentile CH4 as well as NGP for wheat bran were also higher (p<0.05) than those of the other agro-industrial by-products. No differences (p>0.05) were observed between the crop residues in absolute CH4, GP and percentile CH4 (Table 5).


The nature of the raw materials as well as the processing methods used to produce MBM may result in a highly variable product in terms of chemical composition including the protein quality.

Table 5:
In vitro methane and net gas production (mL g1 DM) potentials of tropical agro-industrial by-products and crop residues
Image for - Chemical Compositions and in vitro Methane Production Potentials of Some Agro-industrial By-products and Crop Residues
a-eColumn means with different superscript letters differ significantly at p<0.05 *Guizotia abyssinica, CH4: Methane, NGP: Net gas production at 24 h feed sample incubation, SEM: Standard error of the mean

Kassahun et al.15 reported 185 and 303 g kg1 DM of CP for wheat bran and NSC, respectively, which are comparable to the current findings. Consistent to the current findings, Hagos and Melaku16 reported 168 and 317 g kg1 DM of NDF and CP, respectively for wheat bran. Hendriks et al.17 and Adedokun and Adeola18 reported CP value of 568 and 547 g kg1 DM in MBM, respectively, which are in agreement with the present findings. Dale19 reported 9.60 and 11.2 MJ kg1 DM ME for MBM from beef and pork, respectively. These values are generally higher than observed in the current study.

The concentration of essential amino acids arginine, cystein and methionine in NSC are higher than those found in soybean oil meal reported by Hossain and Becker20. Moreover, NSC contained comparable concentrations of valine, threonine and phenylalanine to that of soybean oil meal. However, NSC is found to be low in lysine, a very important essential amino acid in the nutrition of poultry. Although wheat bran is deficient in lysine, isoleucine and arginine, it contained higher concentrations of cystein and methionine than soybean oil meal observed by Hossain and Becker20. Mineral concentrations in crop residues might be influenced by a number of factors such as intensity of agriculture system, agro-climatic environments, stage of growth and harvest, soil type and intensity of fertilizer application21.

In general, the low CP and high cell wall contents implicated the low nutritive value of crop residues. Singh et al.22 reported slightly lower CP but much higher crude fat contents in maize stover than observed in the current study. Melaku et al.23 reported higher ash, CP and low ADF values for teff straw. The variation might be due to differences in the variety of teff and soil type in which the plant was grown.

The CP content of the investigated dry roughages (except maize stover) was below the ruminant maintenance requirement24. Paterson et al.25 suggested that basal feed resources with a CP content of less than 70 g kg1 DM (like teff straw, wheat straw, stover) require protein supplementation. In this regard, fish offal wastes and noug seed oil cakes which had high CP and ME contents could be used as alternative feed supplements to offset limitations on voluntary feed intake of crop residues25.

The Ca concentrations in maize stover (307 mg kg1 DM) and in barely (398 mg kg1 DM) should fulfill the maintenance requirements of ruminants (270 mg kg1)24. Moreover, the Mg concentrations (196 mg kg1) in maize stover can meet the recommended maintenance requirements of ruminant animals (120-220 mg kg1). However, the Ca concentrations in teff and wheat straws are unable to meet even the critical levels recommended for ruminants. The P concentrations in all crop residues were low (50 and 115 mg kg1) and is unable to meet the levels (220 mg kg1) recommended for ruminants. The low concentrations of many minerals in straws and stovers are probably due to maturity and possible transfer of nutrients to seeds21.

Consistent with the current results for local concentrate, Getachew et al.26 reported between 6.3 and 7.6 mL/200 mg DM CH4 production from commercial total mixed rations for lactating dairy cows. The current results for asymptotic GP are only slightly higher (46.8 mL/200 mg DM) than those reported by Getachew et al.26 (40.8 mL/200 mg DM) for lactating cows. In tropical regions, CH4 emissions from ruminants are mainly caused by poor feed resources that are characterized by high fibrous materials. A suppressing influence of ration with high fat content on CH4 production has been documented in the literature27-30. Recent findings have indicated that fish fat had higher inhibition potential of CH4 production when combined with concentrate and grass silage than with maize silage31. Inthapanya and Preston27 also reported that CH4 production was reduced when the CP source was fish meal.

From the current study, FOW contained high levels of fat (about 25% on DM basis) and thus feeding it to ruminants in combination with grass silages or crop residues would be an effective strategy to mitigate CH4 production without affecting productivity. An appealing finding in the current study might be that the investigated agro-industrial by-products which had a negative lag time produced less CH4 compared to those with positive lag time that emitted comparatively high methane. Fish offal waste, NSC and MBM had negative lag time and produced the lowest CH4. Similar trends have been also observed in leaves of multi-purpose trees and forage crops in an in vitro study32,33. Thus, it appears that those feed materials with reduced lag time might have a direct association with low CH4 production.

The in vitro GP of crop residues increased considerably with incubation time and so did CH4 production. In agreement with the current observation, Blummel et al.34 reported a highly positively association of CH4 production with GP. Getachew et al.26 reported a proportional increase of CH4 with the incubation time suggesting that the slowly digestible fraction of feed (i.e., structural fiber) could be associated with higher CH4 production.

Energy density of roughages is particularly a primary parameter influencing animal productivity. Except noug seed cake, all other agro-industrial by-products contained adequate energy (ME 2.56-2.94 kcal g1 DM) to meet the maintenance requirement of livestock (ME 2.0 kcal g1 DM)24. Nevertheless, all crop residues had lower energy (ME 1.55-1.85 kcal g1 DM) and cannot meet the maintenance requirement of livestock (ME 2.0 kcal g1 DM) recommended for ruminants by NRC24. Moreover, the major part of the protein in crop residues is most likely associated with the cell-walls which are known to have low digestibility. Thus, feeding of crop residues in combination with agro-industrial by-products would be a viable feeding strategy to mitigate the enteric methane emission from tropical livestock.


Noug seed cake contained high concentrations of arginine, cystein, methionine and histidine. However, it had high structured carbohydrates and thus special care should be taken in its inclusion in broilers’ ration. The lowest methane was obtained from fish offal waste followed by meat and bone meal. Thus, these by-products could be combined with crop residues or other forages as CH4 mitigation strategy while maintaining improved animal productivity under smallholder livestock production system. Animal based experiments are recommended to validate the in vitro findings by combining crop residues with those methane reducing by-products.


This study discovered the nutritive values and methane production potentials of agro-industrial and crop residues that can be beneficial for mitigating enteric methane emission from the livestock agriculture. This study will help the researchers to uncover the critical areas of promoting those identified methane reducing feed resources as viable option in combination with those poor quality crop residues in ruminant nutrition. Thus, this study signifies the development of a strategy on the effective utilization of by-products and crop residues in livestock nutrition aiming at the reduction of methane emission from the livestock agriculture.


This research work was fully sponsored by Alexander von Humboldt Foundation (Germany) under grant category ‘Research Fellowship for Experienced Researchers’ for which authors are highly grateful. The authors very much appreciate Sibylle Rupp and Julia Holstein for their excellent technical support in chemical and methane analyses, respectively.

1:  Tolera, A., 2008. Feed resources and feeding management: A manual for feedlot operators and development workers. Ethiopia Sanitary & Phytosanitary Standards and Livestock & Meat Marketing Program (SPS-LMM) Report, September 2008, Addis Ababa, Ethiopia, pp: 7-11.

2:  Syume, M. and B.S. Chandravanshi, 2015. Nutrient composition of Niger seed (Guizotia abyssinica (L. f.) Cass.) cultivated in different parts of Ethiopia. Bull. Chem. Soc. Ethiop., 29: 341-355.
CrossRef  |  Direct Link  |  

3:  Tera, A., T. Neggese and A. Melesse, 2009. The effect of partial substitution of plant protein by fishmeal prepared out of cooked and sun dried fish offal on feed intake and carcass traits of Rhode Island Red chicks. Ethiop. J. Sci., 32: 75-80.
Direct Link  |  

4:  Negesse, T. and A. Tera, 2010. Effects of feeding different levels of cooked and sun dried fish offal on carcass traits of growing Rhode Island Red chicks. Trop. Anim. Health Prod., 42: 45-54.
CrossRef  |  PubMed  |  Direct Link  |  

5:  Yanti, Y. and M. Yayota, 2017. Agricultural by-products as feed for ruminants in tropical area: Nutritive value and mitigating methane emission. Rev. Agric. Sci., 5: 65-76.
CrossRef  |  Direct Link  |  

6:  Castellanos-Navarrete, A., P. Tittonell, M.C. Rufino and K.E. Giller, 2015. Feeding, crop residue and manure management for integrated soil fertility management-a case study from Kenya. Agric. Syst., 134: 24-35.
CrossRef  |  Direct Link  |  

7:  Shamsi, I.H., N. Hussain and L. Jiang, 2012. Agro-Industrial By-Products Utilization in Animal Nutrition. In: Technological Innovations in Major World Oil Crops, Volume 2: Perspectives, Gupta, S.K. (Ed.). Springer, New York, USA., ISBN: 978-1-4614-0826-0, pp: 209-220.

8:  Tolera, A., T. Berg and F. Sundstol, 1999. The effect of variety on maize grain and crop residue yield and nutritive value of the stover. Anim. Feed Sci. Technol., 79: 165-177.
CrossRef  |  Direct Link  |  

9:  Negesse, T., H.P.S. Makkar and K. Becker, 2009. Nutritive value of some non-conventional feed resources of Ethiopia determined by chemical analyses and an in vitro gas method. Anim. Feed Sci. Technol., 154: 204-217.
CrossRef  |  Direct Link  |  

10:  VDLUFA., 2007. Methodenbuch Band III: Die Chemische Untersuchung von Futtermitteln. Verband Deutscher Landwirtschaftlicher Untersuchungs-und Forschungsanstalten (VDLUFA)-Verlag, Darmstadt, Germany.

11:  Menke, K.H. and H. Steingass, 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.
Direct Link  |  

12:  Menke, K.H., L. Raab, A. Salewski, H. Steingass, D. Fritz and W. Schneider, 1979. The estimation of the digestibility and metabolizable energy content of ruminant feedingstuffs from the gas production when they are incubated with rumen liquor in vitro. J. Agric. Sci., 93: 217-222.
CrossRef  |  Direct Link  |  

13:  Blummel, M., E. Zerbini, B.V.S. Reddy, C.T. Hash, F. Bidinger and D. Ravi, 2003. Improving the production and utilization of sorghum and pearl millet as livestock feed: Methodological problems and possible solutions. Field Crops Res., 84: 123-142.
CrossRef  |  Direct Link  |  

14:  SAS., 2012. SAS User's Guide. Version 9.4, SAS Institute Inc., Cary, NC., USA.

15:  2012. Proximate composition of selected potential feedstuffs for small-scale aquaculture in Ethiopia. Livest. Res. Rural Dev., Vol. 24, No. 6.

16:  Hagos, T. and S. Melaku, 2009. Feed intake, digestibility, body weight and carcass parameters of Afar rams fed tef (Eragrostis tef) straw supplemented with graded levels of concentrate mix. Trop. Anim. Health Prod., 41: 599-606.
CrossRef  |  Direct Link  |  

17:  Hendriks, W.H., C.A. Butts, D.V. Thomas, K.A.C. James, P.C.A. Morel and M.W.A. Verstegen, 2002. Nutritional quality and variation of meat and bone meal. Asian-Australas. J. Anim. Sci., 15: 1507-1516.
CrossRef  |  Direct Link  |  

18:  Adedokun, S.A. and O. Adeola, 2005. Metabolizable energy value of meat and bone meal for pigs. J. Anim. Sci., 83: 2519-2526.
CrossRef  |  Direct Link  |  

19:  Dale, N., 1997. Metabolizable energy of meat and bone meal. J. Applied Poult. Res., 6: 169-173.
CrossRef  |  Direct Link  |  

20:  Hossain, M.A. and K. Becker, 2001. Nutritive value and antinutritional factors in different varieties of Sesbania seeds and their morphological fractions. Food Chem., 73: 421-431.
CrossRef  |  Direct Link  |  

21:  Singh, S., B.V. Bhat, G.P. Shukla, K.K. Singh and D. Gehrana, 2018. Variation in carbohydrate and protein fractions, energy, digestibility and mineral concentrations in stover of sorghum cultivars. Trop. Grasslands, 6: 42-52.
CrossRef  |  Direct Link  |  

22:  Singh, S., B.P. Kushwaha, S.K. Nag, A.K. Mishra, S. Bhattacharya, P.K. Gupta and A. Singh, 2011. In vitro methane emission from Indian dry roughages in relation to chemical composition. Curr. Sci., 101: 57-65.
Direct Link  |  

23:  Melaku, S., K.J. Peters and A. Tegegne, 2003. In vitro and in situ evaluation of selected multipurpose trees, wheat bran and Lablab purpureus as potential feed supplements to tef (Eragrostis tef) straw. Anim. Feed Sci. Technol., 108: 159-179.
CrossRef  |  Direct Link  |  

24:  NRC., 2001. Nutrient Requirements of Beef Cattle. 7th Rev. Edn., National Academy Press, Washington, DC., USA., ISBN-13: 9780309069977, 405.

25:  Paterson, J.A., R.C. Cochran and T.J. Klopfensteinm, 1996. Degradable and undegradable protein responses of cattle consuming forage-based diets. Proceedings of the 3rd Grazing Livestock Nutrition Conference, Volume 47, July 18-19, 1996, Custer State Park, South Dakota, pp: 94-103.

26:  Getachew, G., P.H. Robinson, E.J. DePeters, S.J. Taylor, D.D. Gisi, G.E. Higginbotham and T.J. Riordan, 2005. Methane production from commercial dairy rations estimated using an in vitro gas technique. Anim. Feed Sci. Technol., 123-124: 391-402.
CrossRef  |  Direct Link  |  

27:  2014. Methane production from urea-treated rice straw is reduced when the protein supplement is cassava leaf meal or fish meal compared with water spinach meal in a rumen in vitro fermentation. Livest. Res. Rural Dev., Vol. 26, No. 9.

28:  Melesse, A., H. Steingass, M. Schollenberger and M. Rodehutscord, 2018. Component composition, in vitro gas and methane production profiles of fruit by-products and leaves of root crops. J. Agric. Sci., 156: 949-958.
CrossRef  |  Direct Link  |  

29:  Sauer, F.D., V. Fellner, R. Kinsman, J.K. Kramer, H.A. Jackson, A.J. Lee and S. Chen, 1998. Methane output and lactation response in Holstein cattle with monensin or unsaturated fat added to the diet. J. Anim. Sci., 76: 906-914.
CrossRef  |  Direct Link  |  

30:  Dohme, F., A. Machmuller, A. Wasserfallen and M. Kreuzer, 2001. Ruminal methanogenesis as influenced by individual fatty acids supplemented to complete ruminant diets. Lett. Applied Microbiol., 32: 47-51.
CrossRef  |  PubMed  |  Direct Link  |  

31:  Castro-Montoya, J., S. de Campeneere, G. van Ranst and V. Fievez, 2012. Interactions between methane mitigation additives and basal substrates on in vitro methane and VFA production. Anim. Feed Sci. Technol., 176: 47-60.
CrossRef  |  Direct Link  |  

32:  Melesse, A., H. Steingass, M. Schollenberger, J. Holstein and M. Rodehutscord, 2017. Nutrient compositions and in vitro methane production profiles of leaves and whole pods of twelve tropical multipurpose tree species cultivated in Ethiopia. Agrofor. Syst., 93: 135-147.
CrossRef  |  Direct Link  |  

33:  Melesse, A., H. Steingass, M. Schollenberger and M. Rodehutscord, 2017. Screening of common tropical grass and legume forages in Ethiopia for their nutrient composition and methane production profile in vitro. Trop. Grasslands, 5: 163-175.
CrossRef  |  Direct Link  |  

34:  Blummel, M., D.I. Givens and A.R. Moss, 2005. Comparison of methane produced by straw fed sheep in open-circuit respiration with methane predicted by fermentation characteristics measured by an in vitro gas procedure. Anim. Feed Sci. Technol., 123: 379-390.
CrossRef  |  Direct Link  |  

©  2021 Science Alert. All Rights Reserved