Agroecological Zone-Specific Diet Optimization for Water Buffalo (Bubalus bubalis) through Nutritional and In Vitro Fermentation Studies
by
, ,
Sultan Singh
1,†
,
Pushpendra Koli
1,2,*,†,
B. P. Kushwaha
3,
Uchenna Y. Anele
4,
Sumana Bhattacharya
5 and
Yonglin Ren
2,* 1
ICAR-Indian Grassland and Fodder Research Institute, Jhansi 284 003, India
2
College of Environmental and Life Sciences, Murdoch University, 90 South Street, Murdoch, WA 6150, Australia
3
ICAR-Central Institute for Research on Buffaloes, Hisar 125 001, India
4
Department of Animal Sciences, North Carolina Agricultural and Technical State University, Greensboro, NC 27411, USA
5
Natcom Management Cell, Ministry of Environment and Forests, New Delhi 110 003, India
*
Authors to whom correspondence should be addressed.
†
These authors contributed equally to this work.
Animals 2024, 14(1), 143; https://doi.org/10.3390/ani14010143
Submission received: 23 November 2023
/
Revised: 27 December 2023
/
Accepted: 29 December 2023
/
Published: 31 December 2023
(This article belongs to the Special Issue Water Buffalo Welfare, Strategies to Improve Health, Behavior, Productivity, and Food Quality and Safety)
Abstract
:Simple Summary
This study involves the formulation of distinct diets for water buffalo based on locally available feed resources to specific agroecological zones. The diets were categorized into three groups addressing the maintenance, growth, and lactation/production requirements of buffaloes. This study assessed the chemical composition and in vitro gas and methane emissions of each diet. The implication of this work suggests a promising future for buffalo feeding systems, as it focuses on need-based formulations using specific regional ingredients. This approach may enhance the efficiency and sustainability of buffalo farming in specific zones.
Abstract
The water buffalo faces challenges in optimizing nutrition due to varying local feed resources. In response to this challenge, the current study introduces originality by addressing the lack of region-specific feeding strategies for water buffaloes. This is achieved through the formulation of 30 different diets based on locally available resources, offering a tailored approach to enhance nutritional optimization in diverse agroecological contexts. These diets were segmented into three groups of ten, each catering to the maintenance (MD1 to MD10), growth (GD1 to GD10), and lactation/production (PD1 to PD10) needs of buffaloes. Utilizing local feed ingredients, each diet was assessed for its chemical composition, in vitro gas and methane emissions, and dry matter (DM) disappearance using buffalo rumen liquor. The production diets (127 and 32.2 g/kg DM) had more protein and fats than the maintenance diets (82.0 and 21.0 g/kg DM). There was less (p < 0.05) fiber in the production diets compared to the maintenance ones. Different protein components (PB1, PB2) were lower (p < 0.05) in the maintenance diets compared to the growth and production ones, but other protein fractions (PB3, Pc) were higher (p < 0.05) in the maintenance diet. Furthermore, the growth diets had the highest amount of other protein components (PA), while the maintenance diets had the highest amount of soluble carbohydrates (586 g/kg DM), whereas the carbohydrate fraction (CB1) was highest (p < 0.05) in the production diets (187 g/kg DM), followed by the growth (129 g/kg DM) and maintenance diets (96.1 g/kg DM). On the contrary, the carbohydrate CA fraction was (p < 0.05) higher in the maintenance diets (107 g/kg DM) than in the growth (70.4 g/kg DM) and production diets (44.7 g/kg DM). The in vitro gas production over time (12, 24, and 48 h) was roughly the same for all the diets. Interestingly, certain components (ether extract, lignin, NDIN, ADIN, and PB3 and CC) of the diets seemed to reduce methane production, while others (OM, NPN, SP, PA and PB1, tCHO and CB2) increased it. In simple words, this study reveals that different diets affect gas production during digestion, signifying a significant step towards a promising future for buffalo farming through tailored, region-specific formulations.
1. Introduction
India’s vast agroecological diversity offers a surplus of locally available feed resources. These diverse regions provide an opportunity to create diets specific to the needs of buffaloes, depending on their lifecycle stage, be it maintenance, growth, or lactation. The country’s agricultural backbone stands not just on its crops but, significantly, also on its livestock, with buffaloes playing a pivotal role [1]. The buffalo, often deemed the ‘Black Gold’ of India and Pakistan, is central to the rural economy [2,3]. This is not surprising given that India boasts a multitude of buffalo breeds, each with its unique attributes, suiting the varied climatic and topographical conditions of the country. From the Murrah, known for its high milk yield, to the Bhadawari, appreciated for its adaptability, the diversity is truly expansive [4]. In India, buffalo and cattle farming face challenges with limited feed resources and insufficient farmer knowledge on animal nutrition, impacting dairy animal productivity, which varies across regions due to differences in feed availability, types, and adherence to scientific feeding practices [5]. Livestock is the primary contributor of 50% of the 14.17 Tg methane emission total that comes from the Indian agricultural sector [6]. Methane, an important GHG (greenhouse gas) about 22–25 times more potent than carbon dioxide [7], is produced by ruminants as an end product of microbial digestion [8]. During the fermentation process (digestion and metabolism) of diets in the gastrointestinal tract, between 2 and 12% of dietary gross energy is lost as methane [7]. Several factors, viz., animal species and size, animal physiological stage, feed intake, digestibility, diet composition, etc., influence enteric methane production [9,10]. Diet composition (chemical and physical qualities) and its intake level (quantity consumed) influence methane production due to their effect on the rate of digestion and the rate of passage [11]. Animal species and diet composition play an important role in methane production [7,12,13]. Animals have three main nutritional needs: staying healthy (maintenance), growing, and producing things like milk or offsprings (production). To meet these needs, we created three different diets for each region. These diets were made by combining different amounts of locally available food resources, like dry and green roughages, along with concentrated mixtures. Protein in vitro fermentation has been shown to be associated with lower CH4 production than carbohydrates fermentation [14,15]. Dietary nitrogen (N) concentrations play an important role in influencing rumen methanogenesis [16], specifically where feed N is low [17], leading to the reduced microbial growth of methanogens, which face difficulty competing under low N conditions [18]. The type of carbohydrate being digested, such as cellulose, hemicelluloses, and soluble residue, holds a notable influence over methane production [19,20,21]. Moreover, a strong relationship is observed between CH4 production and digestible neutral detergent fiber (NDF) for cows and calves [22].
The main goal of this study was to develop and evaluate 30 water buffalo diets tailored for various life stages and agroecological zones in India. The assessment involved scrutinizing their nutritional compositions and in vitro methane production. The ultimate aim was to redirect methane emissions into a valuable energy source, thereby improving livestock productivity and simultaneously addressing global environmental concerns.
2. Materials and Methods
2.1. Formulation of Concentrate Mixtures
Local feed ingredients and their use in feeding livestock according to their suitable agroecological regions were considered for the formulation of concentrate mixtures (CM) for different regions of the country. A total of nine CM were prepared using protein and energy sources in different proportion for use in different diets as described in Table 1.
2.2. Preparation Diets/Rations
The nutritional requirements of livestock were classified into three categories based on animals’ functional needs, viz., maintenance, growth, and production. For each category, ten diets/rations were prepared, and, hence, a total of thirty diets were formulated via the uniform mixing of dry and green fodder with concentrate mixtures in different proportions (Table 2).
2.3. Determination of Chemical Composition
The dry matter (930.15), ash (932.05), N (976.05), and ether extract (EE, 920.39) contents of the diets’ samples were estimated following the standard method of the Association of Official Analytical Chemists (AOAC) [23]. The nitrogen values were multiplied by 6.25 to convert them into crude protein (CP) values. Neutral detergent fiber (NDF), acid detergent fiber (ADF), cellulose, and lignin (sa) were estimated as per the sequential method [24] using a fiber analyzer (Fibra Plus FES 6, Pelican, Chennai, India). Both the NDF and the ADF were expressed inclusive of their residual ash. There was no complex plant matrix included in our diet compositions; therefore, heat-stable α-amylase and sodium sulfite were not used in NDF determination. The lignin (sa) was determined by solubilizing cellulose with 72% of sulfuric acid in the ADF residue [24]. The cellulose was calculated as the difference between the ADF and the lignin (sa) in the sequential analysis. The hemicellulose was calculated as the difference between the NDF and ADF contents.
2.4. Estimation of Carbohydrate Fractions
The carbohydrate (CHO) fractions of the different diets samples were estimated as per the Cornell Net Carbohydrate and Protein (CNCP) system [25]. This system classifies CHO fractions into four fractions, as follows: CA indicates rapidly degradable sugars; CB1 classifies intermediately degradable starch and pectin; CB2 includes slowly degradable cell walls; and CC comprises unavailable/lignin-bound cell walls based on their degradation rate. The diets’ total CHO (tCHO; g/kg DM) was determined by subtracting the CP, ether extract (EE), and ash contents from 1000. The structural carbohydrates (SC) were calculated as the difference between the NDF and the neutral detergent-insoluble protein (NDIP), and the non-structural CHO were estimated as the difference between the tCHO and the SC [26]. For the starch estimation, samples were extracted with ethyl alcohol to solubilize free sugars, lipids, pigments, and waxes. The residue rich in starch was solubilized with perchloric acid, and the extract was treated with anthrone–sulfuric acid to determine glucose colorimetrically using a UV spectrophotometer (LABINDIA3000) at 630 nm [27].
2.5. Estimation of Protein Fractions
The CP fractions of the diets were partitioned into five fractions according to the CNCPS, [25] as modified previously [28]. These are the following: fraction PA, indicating non-protein N, estimated as the difference between the total N and the true CP N precipitated with sodium tungstate (0.30 M) and 0.5 M of sulfuric acid; PB1, the buffer-soluble protein calculated as the difference between the true protein and the buffer-insoluble protein, estimated with a boratephosphate buffer (pH 6.7–6.8) and a freshly prepared 0.10 M sodium azide solution; fraction PB2, the neutral detergent-soluble protein, estimated as the buffer-insoluble protein minus the ND-insoluble protein; fraction PB3, the acid detergent-soluble CP, estimated as the difference between the ND-insoluble protein and the acid detergent-insoluble CP; and fraction PC, assumed to be indigestible (protein associated with lignin, tannin–protein complexes, and Maillard products which are unavailable to animals).
2.6. In Vitro Incubation
The in vitro gas production was determined using the pressure transducer technique [29]. Ruminal fluid was collected before feeding from two fistulated adult male Murrah water buffaloes (Bubalus bubalis) fed a wheat straw-concentrate diet (65:35 DM basis). The rumen fluid was filtered through a double layer of cheese cloth and bubbled with CO2 before the commencement of incubation. The incubation medium was prepared by means of the sequential mixing of a buffer solution (NH4HCO3 and NaHCO3), a macro-mineral solution, a micro-mineral solution, and resazurin solution [30]. Samples (1 g) of air-dry green forages were weighed into three serum bottles (150 mL capacity). Three serum bottles without substrate were used as blank cultures. The sample and control serum bottles were gassed briefly with CO2 before adding 65 mL of medium. The bottles were continuously fluxed with CO2, and then 3 mL of reducing solution were added in each bottle. The gassing of bottles with CO2 continued until the pink color turned colorless. Before inoculation, the gas pressure transducer was used to adjust the head-space gas pressure in each bottle (to adjust the zero reading on the LED display). The serum bottles were inoculated with 8 mL of ruminal fluid inoculum using a 10 mL syringe. The inoculated bottles were sealed and incubated at 39 °C. The samples were incubated in triplicates, and the gas production (mL) was measured at 12, 24, and 48 h of incubation. The whole process was repeated on a different day.
2.7. Methane Measurements
The methane (CH4) in the total gas was measured from three bottles incubated for each of the thirty diets at the 12, 24, and 48 h timepoints using gas chromatography (Nucon 5765 microprocessor-controlled gas chromatograph (GC), Okhla, New Delhi, India) equipped with a stainless-steel column packed with Porapak-Q and a flame ionization detector. Gas (1 mL) was sampled from the gas produced using a Hamilton syringe and injected manually (pull and push method of sample injection) into a GC. The GC was calibrated using standard methane and CO2. The methane level was additionally measured in blank samples at different fermentation stages, and these measurements were used to correct for methane produced by the inoculum. The methane measured was related to the total gas to estimate its concentration [31] and converted into energy and mass values using 39.54 kJ/L CH4 and 0.716 mg/mL CH4 factors, respectively [32].
2.8. In Vitro Dry Matter Digestibility (IVDMD) and Energy of Diets
For the determination of the IVDMD for the evaluated diets a standard method was followed [33], wherein a 0.5 g sample was incubated for 48 h and then digested with 0.1 g of pepsin (1:3000 Sisco Research Laboratories, Mumbai, India) and 2 mL of 6N HCl at 39 °C for 24 h. The samples were incubated in triplicate with ruminal inoculum from the two fistulated buffaloes described previously. A provision was also made for the blanks, as described for the in vitro gas production. The digestibility was estimated as the difference between the DM incubated and the residual DM at the end of the second stage of digestion. The gross energy (GE) of the forages was measured with a bomb calorimeter (Toshniwal Brothers CLOI/M2, Bangalore, India) using benzoic acid as the standard.
2.9. Statistical Analysis
The data were subjected to an analysis of variance using the GLM procedure of SAS (2002). The model was the following: Yij = [1] + Fi + Eij, where Yij represents the individual observation of the variable, and Fi is the fixed effect of the ith diet (i = 1–30). The overall mean is expressed as [1], and Eij is the random error associated with Yij, not accounted in the fixed effect. The means were separated using Fisher’s LSD and all the statistical tests were at the p = 0.05 level of significance. The means of cereals, grasses, and legumes were compared using orthogonal contrasts (i.e., cereals vs. grasses, cereals vs. legumes, and grasses vs. legumes). The differences among forage means with p < 0.05 were accepted as statistically significant. A correlation analysis was used to establish relationships between chemical constituents, carbohydrate fractions, protein fractions, and CH4 production. Pearson’s correlation analysis was performed to establish the relationship of chemical composition with methane production, carbohydrate fractions, and protein fractions at level p < 0.05.
3. Results
3.1. Chemical Composition
The crude protein (CP) and ether extract (EE) values were significantly higher (p < 0.05) for the production diets (127 and 32.2) than the maintenance diets (82.0 and 21.0 g/kgDM), respectively. The CP values of all three diets including the MD, the GD, and the PD varied, measuring 69.8–96.1, 106–130, and 103–153 g/kg DM, respectively (Table 3), whereas, the concentrations of NDF, ADF, and cellulose were lower (p < 0.05) in the production diets (546, 333 and 245) than in the maintenance diets (618, 395 and 293 g/kg DM). Interestingly, no significant difference was observed in the lignin contents among all three diets.
3.2. Nitrogen Fractions
The protein fraction values (PB1 and PB2; g/kg DM) followed a lower to higher (p < 0.05) order from the MD (150.2 and 357.3) to the GD (204.7 and 409.7), followed by the PD (217.4 and 412.3), while the mean concentration of the slowly degradable protein fraction (PB3) and the lignin-bound protein fraction (Pc) were higher (p < 0.05) in the maintenance diets (205.6 and 181.3) than in the growth diets (113.9 and 114.8), followed by the production diets (151.5 and 104.0 g/kg DM) (Table 4). The average value of PA (g/kg DM) was significantly higher (p < 0.05) for the growth diets (136.9) than in the production and maintenance diets, which had values of 114.8 and 105.6, respectively. In the maintenance diets, the affinity of protein binding to ADF was observed to be higher than in the growth and production diets, whereas the SP concentration was in the reverse order, meaning that the concentration in the maintenance diets was lower than in the two other diets.
3.3. Carbohydrate Fractions
Among the carbohydrate fractions, no significant difference was observed among all three diets for the total carbohydrate levels (tCHO), while the SC contents were (p < 0.05) higher in the maintenance diets (586.2) than in the production diets (513.0 g/kg DM), respectively. The average value of the rapidly degradable carbohydrate fraction (CB1) differed (p < 0.05) among the diets, being highest in the production diets (187.2), followed by the growth (129.5) and maintenance diets (96.1 g/kg DM; Table 5). The contrary carbohydrate CA fraction was (p < 0.05) higher in the maintenance diets (107.1) than in the growth (70.4) and production diets (944.7 g/kg DM). The carbohydrate fractions CB2 and CC were relatively lower in the production diets than in the maintenance and growth diets.
3.4. Gas and Methane Production Kinetics
The average values (mL/g DM) for the diets’ in vitro gas production were found to have a consistent pattern at 0–12, 12–24, and 24–48 h. The observed values for the maintenance diets were 63.0, 52.0, and 48.15; for the growth diets, they were 63.8, 52.7, and 48.2, and, for the production diets, they were 63.5, 52.5, and 47.2. The cumulative gas production values (48 h) were close and similar 163, 165, and 163 mL/g DM for the maintenance, growth, and production diets, respectively (Table 6). The in vitro methane production mean values at 0–12, 12–24, and 24–48 h and the cumulative values of the maintenance diets tended (p > 0.05) to be lower than those of the growth and maintenance diets, whereas, the cumulative methane production was lower in the maintenance diets (28.4) than in the production diets (33.1 mL/g DM).
3.5. Methane Production and Percentage Loss of Dietary Energy as Methane
The mean values of the in vitro methane production (mL/g DDM, g/kg DM and g/kg DDM) were similar in the diets formulated for maintenance (41.2, 13.3 and 29.5; Table 7), for growth (42.2, 14.3 and 30.2; Table 7), and for production (41.3, 15.9 and 29.6; Table 7). Furthermore, a similar trend was observed for the gross energy from each diet being lost as methane, with comparable values in the maintenance (1.57), growth (1.61), and production diets (1.58 kJ/g DDM), equivalent to 9.09, 9.37, and 9.14% of dietary energy lost as methane, respectively.
3.6. Correlation between Chemical Constituents and Methane Production
Among the proximate constituents, the EE and lignin were significantly (p < 0.05) negatively associated (r = −0.422 ** and r = −0.365 **) with dietary methane production, while the OM contents of the diets were positively (p < 0.05 r = 0.266 *) correlated with methane production (Table 8). The protein fractions NDIP, ADIP, and PB3 of the diets were negatively associated with CH4 production (r = −0.448 **, r = −0.272 **, and r = −0.341 **). On the other hand, the N fraction, the NPN, the SP, the PA, and the PB1 fraction of the diets were positively associated (r = 0.450 **, 0.387 **, r = 0.412 **, and r = 0.284 **) with the in vitro CH4 production. Among the diets, the tCHO and carbohydrate fraction CB2 contents were positively associated (r = 0.353 ** and 0.278 **) with the in vitro CH4 production, while the carbohydrate fraction CC DM was negatively associated (r = −0.365 **) with CH4 production.
4. Discussion
4.1. Chemical Composition
All three diet categories including maintenance, growth, and production showed crude protein (CP) levels equal to or exceeding the minimum required for microbial growth. A minimum of 7.0% CP is essential to optimize the growth and functionality of rumen microbes [34]. The reason for higher CP contents in the production diets (127) than in the growth (112) and maintenance diets (82.0 g/kg DM) may be due to the inclusion of a protein-rich concentrate mixture in the production diets. These values of CP were within the range (64.4 to 150.4 g/kg DM) of values reported for 45 rations [35]. Additionally, the higher values of NDF, ADF, and cellulose contents in the maintenance diets may be due to the sole roughage ingredients in its compositions. Further, the variability in the cell wall constituents of the maintenance, growth, and production diets may be attributed to the composition and level of diverse sources of dry, green, and concentrate mixtures. The average value of the CP and hemicelluloses obtained from the growth and production diets were in similar to the value reported in a combined mixed-diet ration containing low-protein and high-protein rations [36]. The OM contents of the maintenance, growth, and production diets evaluated in the present study were within the range of OM values observed in an experiment involving seven diets [37] and utilizing local-based feed resources and tropical grass pastures [38,39].
4.2. Carbohydrate and Protein Fractions
Carbohydrates and proteins are the two most important constituents of diets required for the different physiological functions of animals, viz., maintenance, growth, and production. The total carbohydrate (tCHO) and NSC content of the maintenance, growth, and production diets recorded in the present study were aligned within the range (773.3–859.4 and 95.1–335.6 g/kg DM) of values reported for 45 rations of different roughage and concentrate feed ratios formulated using different roughage and concentrate feed types [35]. A previous study conducted on top foliage [40] and concentrate feed [10] observed values within a similar range and following a comparable trend. The maintenance, growth, and production diets had the highest contents of carbohydrate fraction CB2 (429, 400, and 364 g/kg DM, respectively), following a similar pattern to that of the 45 rations reported by Dong and Zhao [35]; also, our diets’ CB2 contents were within the range (344.8–588.2 g/kg DM) of values reported in the above-mentioned study. The variations in the concentration of the CA, CB1, CB2, and CC carbohydrate fractions of the maintenance, growth, and production diet are similar to those observed for the 45 rations reported in the earlier study mentioned previously [35]. The carbohydrate fractions CB2 and CB1’s contents in most of our growth and production diets were within the range of values reported for six farm diets in a previous study [41]: the observed lower content of CC fraction in the above-mentioned study can likely be attributed to the elevated lignin levels in the diets analyzed in our study. The higher lignin content may hinder the release or accessibility of cellulose and hemicellulose, resulting in reduced CC fraction values. This phenomenon suggests a potential influence of diet composition on the structural components of plant material, with a higher lignin content acting as a limiting factor for the measured CC fraction. Further, the tCHO values of the growth and production diets were similar to the tCHO values of the diets reported in the above-mentioned study [41], while their NSC contents were relatively higher than our values. The difference in the protein/nitrogen fractions of the maintenance, growth, and production/lactation diets may be attributed to the differences in the proportion of different dietary ingredients and their chemical constituents.
4.3. Gas and Methane Production and Loss of Energy as Methane
The average values of the gas production kinetics at three time intervals (12, 24, and 48 h) and the cumulative gas production (mL/g DM) from the high-protein and low-protein diets showed values higher than the gas production values in the maintenance, growth, and production diets in our study [36]. The gas production from the total mixed rations collected from seven dairies ranged between 211 and 256 mL/g DM after 48 h, which was higher than our gas production values. This variation in gas production may be due to differences in the chemical constituents, mainly the cell wall fractions and the carbohydrate and protein fractions, and their degradability. The availability of nutrients to microbes influences gas production from any feed/diet [42,43]. The total gas production (mL/g DM) from 45 rations of various concentrate to roughage ratios ranged between 165 and 281 [35], which partially agrees with our gas production values. The relatively higher cumulative methane production (mL/g DM) at the 48 h timepoint in the lactation diets (33.1) compared to the maintenance diets (28.4) may be due to the higher digestibility of the production diets, as the degradability of a substrate influences both gas and methane production. In a previous study conducted on lactating cows’ diets, the methane production (mL/200 g) reported was higher in the lactating ration (8.85) than in the dry ration (7.24), which substantiates our observations [44]. Further, in same study [44], they recorded higher gas production values in the lactation ration (54.4) than in the dry ration (43.0 mL/200 g). The methane production of 45 rations with varied roughage was the following: the concentrate ration ranged from 30 to 51 mL/g DM after 48 h of fermentation [35], which partially agreed with our results. A similar trend of methane production was observed in a study [45] where goats were fed three diets of different roughage to concentrate ratios (25:75, 50:50 and 73:27), and the values were 37.1, 36.4, and 34.5 g/kg DDM, respectively. Further, the CH4 (%GE) for these three diets (8.6, 7.3, and 6.0%) differed significantly (p < 0.05), which agreed with our observations that the level of concentrate and the dietary ingredients’ composition influences methane production. The percentages of CH4 and GE were lower in the above-mentioned study than our average values in the maintenance, growth, and production diets.
4.4. Correlation between Methane Production and Chemical Constituents (Proximate Constituents, Carbohydrate Fractions, and Protein Fractions)
The correlations studies between chemical constituents and CH4 production of forages and concentrate feeds are crucial for optimizing animal nutrition, reducing environmental impact, and improving overall feed efficiency in livestock production [34,46,47]. However, the information on the correlation between methane production and diets/rations’ chemical constituents is limited. In this study, the EE and lignin from the proximate constituents and the NDIP and ADIP protein fractions were negatively associated with methane production. Similar to our observations, earlier studies [48,49,50] reported that EE, lignin, NDIP, and ADIP were negatively associated with methane production. Contrary, a positive correlation between EE and methane production was recorded by Ellis et al. [51]. Information on diets/rations’ carbohydrate and/or protein fractions’ relationship with in vitro methane production is scarce. In a study of 45 rations, a relationship between CNCPS carbohydrate fractions and methane production was reported [35]. They also reported that the carbohydrate fractions CA, CB1, and CB2 were positively related to methane production, and this agrees of our correlation results. In our study, CC was negatively related to methane production, and this could be due to the unavailability of lignin-bound carbohydrates for digestion. The evaluated diets’ soluble protein, NPN, PA, and PB1 were positively associated with methane production. This is probably due to the ready availability of these more degradable protein fractions to microbial fermentation.
This study effectively created diets for water buffaloes, but it has limitations. It mainly looks at diet composition and gas emissions; therefore, future research should explore the diets’ long-term effects on buffalo health, practical use on farms, and economic factors to get a fuller picture of their feasibility in real-world farming.
5. Conclusions
This study highlighted key findings on three categories (maintenance, growth, and production/lactation) of thirty different diet compositions for water buffaloes based on local resources, addressing the need for region-specific feeding strategies. The production diets exhibited higher crude protein contents, while the maintenance diets had more fiber. The soluble protein fractions (PB1 and PB2) were more present in the production and growth diets and the indigestible fraction (PC) in the maintenance diets. The higher levels of non-structural carbohydrates in the production diets suggest dietary optimization possibilities. The loss of energy as CH4 from the diets/feeding systems varied from 6.48% to 12.56 for the buffalos observed. Amongst the agroecological regions studied (AERs), the livestock from the AER-2 and AER-10 regions emitted the lowest CH4. The diets in the AER-2 and AER-10 regions consisting of tree leaves as the green fodder source produced less CH4, with lower losses of dietary energy as methane. The AER-10 diets supplemented with coconut cake as the protein source emitted less CH4. These findings emphasize the importance of tailoring diets to meet the nutritional needs of buffaloes, marking a significant step forward in optimizing buffalo farming practices. Future implications involve refining agroecological regional feeding practices and considering correlations for a targeted and sustainable diet selection process, promoting both livestock health and environmental stewardship.
Author Contributions
Conceptualization, S.S., B.P.K., P.K., and Y.R.; methodology, S.S., B.P.K., P.K., U.Y.A., S.B., and P.K.; formal analysis, S.S., B.P.K., and P.K.; investigation, S.S., P.K., and B.P.K.; writing—original draft preparation, S.S., B.P.K., P.K., and Y.R.; writing—review and editing, S.S., P.K., U.Y.A., and Y.R.; visualization, S.S., P.K., and Y.R.; supervision, S.S., B.P.K., and Y.R.; project administration, S.S. All authors have read and agreed to the published version of the manuscript.
Funding
This research received no external funding.
Institutional Review Board Statement
The study was conducted according to the guidelines of animal welfare (animal ethics) being adopted by Indian Council of Agricultural Research (ICAR) institutes and approved by the Institutional Review Board of ICAR-Indian Grassland and Fodder Research Institute (2018).
Informed Consent Statement
Plant-Animal Relationship Division at ICAR-Indian Grassland and Fodder Research Institute, Jhansi, India, maintains fistulated/intact animals for in vitro and in sacco feed and fodder fermentation and degradability studies. The in-house and externally funded projects are presented in the Institute Research Committee (IRC), and the technical programs, including the requirements of animals and feeds/fodders, are approved in this house. The requirement/proposal is reviewed by the Head of the Division, who then approves the proposal to use fistulated buffaloes maintained at the experimental farm to collect rumen liquor for in vitro fermentation studies.
Data Availability Statement
Data are contained within the article.
Acknowledgments
The authors are thankful to Director IGFRI for providing financial support and to the Head Plant Animal Relationship Division for providing the laboratory and animal facilities required to carry out this research.
Conflicts of Interest
The authors have no conflicts of interest.
References
- Nanda, A.S.; Nakao, T. Role of buffalo in the socioeconomic development of rural Asia: Current status and future prospectus. Anim. Sci. J. 2003, 74, 443–455. [Google Scholar] [CrossRef]
- Bilal, M.; Suleman, M.; Raziq, A. Buffalo: Black gold of Pakistan. Livest. Res. Rural Dev. 2006, 18, 140–151. [Google Scholar]
- Singh, P.K.; Kamboj, M.; Kumar, N. Effect of dummy calf, weaning and suckling on the reproductive performance of post-partum Murrah buffaloes. Indian J. Anim. Res. 2016, 50, 265–267. [Google Scholar] [CrossRef]
- Das, M.; Kundu, S.; Kushwaha, B. Comparative Nutrient Utilization in Murrah and Bhadawari Lactating Buffaloes Fed Barley Straw Based Ration. Indian J. Anim. Nutr. 2013, 30, 1–4. [Google Scholar]
- Kumar, M.; Dahiya, S.; Ratwan, P.; Kumar, S.; Chitra, A. Status, constraints and future prospects of Murrah buffaloes in India. Indian J. Anim. Sci. 2019, 89, 1291–1302. [Google Scholar] [CrossRef]
- Singh, S.; Kushwaha, B.; Nag, S.; Bhattacharya, S.; Gupta, P.; Mishra, A.; Singh, A. Assessment of enteric methane emission of Indian livestock in different agro-ecological regions. Curr. Sci. 2012, 102, 1017–1027. [Google Scholar]
- Johnson, K.A.; Johnson, D.E. Methane emissions from cattle. J. Anim. Sci. 1995, 73, 2483–2492. [Google Scholar] [CrossRef] [PubMed]
- McAllister, T.; Cheng, K.-J.; Okine, E.; Mathison, G. Dietary, environmental and microbiological aspects of methane production in ruminants. Can. J. Anim. Sci. 1996, 76, 231–243. [Google Scholar] [CrossRef]
- Lata, S.; Koli, P.; Singh, S.; Bhadoria, B.; Chand, U.; Ren, Y. The study of structure and effects of two new proanthocyanidins from Anogeissus pendula leaves on rumen enzyme activities. Front. Vet. Sci. 2023, 10, 1163197. [Google Scholar] [CrossRef]
- Singh, S.; Koli, P.; Bhadoria, B.K.; Singh, A. Nutritional composition, In vitro fermentation and methane production potential of tropical feed ingredients used in ruminants feeding. Anim. Nutr. Feed Technol. 2023, 23, 345–359. [Google Scholar] [CrossRef]
- Van Soest, P. Nutritional Ecology of the Ruminant; O and B Books; Cornell University: Ithaca, NY, USA, 1982. [Google Scholar]
- Chianese, D.S.; Rotz, C.A.; Richard, T.L. Whole-farm greenhouse gas emissions: A review with application to a Pennsylvania dairy farm. Appl. Eng. Agric. 2009, 25, 431–442. [Google Scholar] [CrossRef]
- Shibata, M.; Terada, F. Factors affecting methane production and mitigation in ruminants. Anim. Sci. J. 2010, 81, 2–10. [Google Scholar] [CrossRef] [PubMed]
- Demeyer, D.; Van Nevel, C. Protein fermentation and growth by rumen microbes. Ann. Rech. Vet. 1979, 10, 277–279. [Google Scholar]
- Cone, J.W.; van Gelder, A.H. Influence of protein fermentation on gas production profiles. Anim. Feed Sci. Technol. 1999, 76, 251–264. [Google Scholar] [CrossRef]
- Kurihara, M.; Magner, T.; Hunter, R.; McCrabb, G. Methane production and energy partition of cattle in the tropics. Br. J. Nutr. 1999, 81, 227–234. [Google Scholar] [CrossRef]
- Kirchgessner, M.; Windisch, W.; Müller, H.; Kreuzer, M. Release of methane and of carbon dioxide by dairy cattle. Agribiol. Res. 1991, 44, 91–102. [Google Scholar]
- Moss, A.R. Methane: Global Warming and Production by Animals; Chalcombe Publications: Welton, UK, 1993. [Google Scholar]
- Moe, P.; Tyrrell, H. Methane production in dairy cows. J. Dairy Sci. 1979, 62, 1583–1586. [Google Scholar] [CrossRef]
- Santoso, B.; Kume, S.; Nonaka, K.; Kimura, K.; Mizukoshi, H.; Gamo, Y.; Takahashi, J. Methane emission, nutrient digestibility, energy metabolism and blood metabolites in dairy cows fed silages with and without galacto-oligosaccharides supplementation. Asian-Australas. J. Anim. Sci. 2003, 16, 534–540. [Google Scholar] [CrossRef]
- Takahashi, J. Nutritional manipulation of methanogenesis in ruminants. Asian-Australas. J. Anim. Sci. 2001, 14, 131–135. [Google Scholar]
- Estermann, B.; Sutter, F.; Schlegel, P.; Erdin, D.; Wettstein, H.; Kreuzer, M. Effect of calf age and dam breed on intake, energy expenditure, and excretion of nitrogen, phosphorus, and methane of beef cows with calves. J. Anim. Sci. 2002, 80, 1124–1134. [Google Scholar] [CrossRef]
- AOAC. Official Methods of Analysis, Association of Official Analytical Chemists; AOAC: Washington, DC, USA, 1994. [Google Scholar]
- Van Soest, P.; Robertson, J.; Lewis, B. Symposium: Carbohydrate methodology, metabolism, and nutritional implications in dairy cattle. J. Dairy Sci. 1991, 74, 3583–3597. [Google Scholar] [CrossRef] [PubMed]
- Sniffen, C.J.; O’Connor, J.D.; Van Soest, P.J.; Fox, D.G.; Russell, J.B. A net carbohydrate and protein system for evaluating cattle diets: II. Carbohydrate and protein availability. J. Anim. Sci. 1992, 70, 3562–3577. [Google Scholar] [CrossRef] [PubMed]
- Caballero, R.; Alzueta, C.; Ortiz, L.T.; Rodríguez, M.L.; Barro, C.; Rebolé, A. Carbohydrate and protein fractions of fresh and dried common vetch at three maturity stages. Agron. J. 2001, 93, 1006–1013. [Google Scholar] [CrossRef]
- Sastry, V.; Kamra, D.; Pathak, N. Laboratory manual of animal nutrition. Indian Vet. Res. Inst. Izatnagar India 1999, 1–266. [Google Scholar]
- Licitra, G.; Hernandez, T.; Van Soest, P. Standardization of procedures for nitrogen fractionation of ruminant feeds. Anim. Feed Sci. Technol. 1996, 57, 347–358. [Google Scholar] [CrossRef]
- Theodorou, M.K.; Williams, B.A.; Dhanoa, M.S.; McAllan, A.B.; France, J. A simple gas production method using a pressure transducer to determine the fermentation kinetics of ruminant feeds. Anim. Feed Sci. Technol. 1994, 48, 185–197. [Google Scholar] [CrossRef]
- Kh, M. Estimation of the energetic feed value obtained from chemical analysis and in vitro gas production using rumen fluid. Anim. Res. Dev. 1988, 28, 7–55. [Google Scholar]
- Tavendale, M.H.; Meagher, L.P.; Pacheco, D.; Walker, N.; Attwood, G.T.; Sivakumaran, S. Methane production from in vitro rumen incubations with Lotus pedunculatus and Medicago sativa, and effects of extractable condensed tannin fractions on methanogenesis. Anim. Feed Sci. Technol. 2005, 123, 403–419. [Google Scholar] [CrossRef]
- Santoso, B.; Mwenya, B.; Sar, C.; Takahashi, J. Methane production and energy partition in sheep fed timothy silage-or hay-based diets. J. Ilmu Ternak Dan Vet. 2007, 12, 27–33. [Google Scholar]
- Tilley, J.; Terry, D.R. A two-stage technique for the in vitro digestion of forage crops. Grass Forage Sci. 1963, 18, 104–111. [Google Scholar] [CrossRef]
- Hariadi, B.T.; Santoso, B. Evaluation of tropical plants containing tannin on in vitro methanogenesis and fermentation parameters using rumen fluid. J. Sci. Food Agric. 2010, 90, 456–461. [Google Scholar] [CrossRef] [PubMed]
- Dong, R.; Zhao, G. Relationship between the methane production and the CNCPS carbohydrate fractions of rations with various concentrate/roughage ratios evaluated using in vitro incubation technique. Asian-Australas. J. Anim. Sci. 2013, 26, 1708. [Google Scholar] [CrossRef] [PubMed]
- Elghandour, M.; Vázquez, J.; Salem, A.; Kholif, A.; Cipriano, M.; Camacho, L.; Márquez, O. In vitro gas and methane production of two mixed rations influenced by three different cultures of Saccharomyces cerevisiae. J. Appl. Anim. Res. 2017, 45, 389–395. [Google Scholar] [CrossRef]
- Getachew, G.; Robinson, P.; DePeters, E.; Taylor, S.; Gisi, D.; Higginbotham, G.; Riordan, T. Methane production from commercial dairy rations estimated using an in vitro gas technique. Anim. Feed Sci. Technol. 2005, 123, 391–402. [Google Scholar] [CrossRef]
- Detmann, E.; Valente, É.E.; Batista, E.D.; Huhtanen, P. An evaluation of the performance and efficiency of nitrogen utilization in cattle fed tropical grass pastures with supplementation. Livest. Sci. 2014, 162, 141–153. [Google Scholar] [CrossRef]
- Mayulu, H.; Daru, T.P.; Tricahyadinata, I. In vitro evaluation of ruminal digestibility and fermentation characteristics of local feedstuff-based beef cattle ration. F1000Research 2023, 11, 834. [Google Scholar] [CrossRef]
- Singh, S.; Bhadoria, B.K.; Koli, P.; Lata, S. Seasonal variation in chemical and biochemical constituents of tropical top feed species: Components in silvipasture system. Range Manag. Agrofor. 2021, 42, 312–319. [Google Scholar]
- Calabro, S.; Piccolo, V.; Infascelli, F. Evaluation of diet for buffalo dairy cows using the Cornell Net Carbohydrate and Protein System. Asian-Australas. J. Anim. Sci. 2003, 16, 1475–1481. [Google Scholar] [CrossRef]
- Elghandour, M.M.; Chagoyán, J.C.V.; Salem, A.Z.; Kholif, A.E.; Castañeda, J.S.M.; Camacho, L.M.; Cerrillo-Soto, M.A. Effects of Saccharomyces cerevisiae at direct addition or pre-incubation on in vitro gas production kinetics and degradability of four fibrous feeds. Ital. J. Anim. Sci. 2014, 13, 3075. [Google Scholar] [CrossRef]
- Phesatcha, K.; Phesatcha, B.; Wanapat, M.; Cherdthong, A. Mitragyna speciosa korth leaves supplementation on feed utilization, rumen fermentation efficiency, microbial population, and methane production in vitro. Fermentation 2021, 8, 8. [Google Scholar] [CrossRef]
- Pirondini, M.; Malagutti, L.; Colombini, S.; Amodeo, P.; Crovetto, G.M. Methane yield from dry and lactating cows diets in the Po Plain (Italy) using an in vitro gas production technique. Ital. J. Anim. Sci. 2012, 11, e61. [Google Scholar] [CrossRef]
- Na, Y.; Li, D.H.; Lee, S.R. Effects of dietary forage-to-concentrate ratio on nutrient digestibility and enteric methane production in growing goats (Capra hircus hircus) and Sika deer (Cervus nippon hortulorum). Asian-Australas. J. Anim. Sci. 2017, 30, 967. [Google Scholar] [CrossRef] [PubMed]
- Kulivand, M.; Kafilzadeh, F. Correlation between chemical composition, kinetics of fermentation and methane production of eight pasture grasses. Acta Scientiarum. Anim. Sci. 2015, 37, 9–14. [Google Scholar] [CrossRef]
- Chino Velasquez, L.B.; Molina-Botero, I.C.; Moscoso Muñoz, J.E.; Gómez Bravo, C. Relationship between Chemical Composition and In Vitro Methane Production of High Andean Grasses. Animals 2022, 12, 2348. [Google Scholar] [CrossRef] [PubMed]
- Gemeda, B.S.; Hassen, A. In vitro fermentation, digestibility and methane production of tropical perennial grass species. Crop Pasture Sci. 2014, 65, 479–488. [Google Scholar] [CrossRef]
- Yan, T.; Porter, M.; Mayne, C. Prediction of methane emission from beef cattle using data measured in indirect open-circuit respiration calorimeters. Animal 2009, 3, 1455–1462. [Google Scholar] [CrossRef]
- Chen, C.-N.; Lee, T.-T.; Yu, B. Improving the Prediction of Methane Production Determined by in Vitro Gas Production Technique for Ruminants. Ann. Anim. Sci. 2016, 16, 565–584. [Google Scholar] [CrossRef]
- Ellis, J.; Kebreab, E.; Odongo, N.; McBride, B.; Okine, E.; France, J. Prediction of methane production from dairy and beef cattle. J. Dairy Sci. 2007, 90, 3456–3466. [Google Scholar] [CrossRef]
Table 1.
Proportion (%) and composition of ingredients in different concentrate mixtures.
| Ingredients | CM1 | CM2 | CM3 | CM4 | CM5 | CM6 | CM7 | CM8 | CM9 |
|---|---|---|---|---|---|---|---|---|---|
| Mustard seed cake | 35 | 40 | - | - | - | - | 40 | 45 | - |
| Wheat bran | 25 | - | 25 | - | 25 | - | - | - | - |
| Maize grain | 40 | - | - | 60 | - | - | 20 | - | 40 |
| Cotton seed cake | - | - | 35 | 40 | - | - | - | - | 45 |
| Oat grain | - | - | 40 | - | - | 60 | - | - | - |
| Barley grain | - | 60 | - | - | 40 | - | - | - | - |
| Groundnut cake | - | - | - | - | 35 | 40 | - | - | - |
| Rice bran | - | - | - | - | - | - | 40 | 55 | 15 |
CM: Concentrate mixture.
Table 2.
Composition of diets (ingredients and their proportions).
| AER No. | Region | Maintenance | Growth | Production | ||||||
|---|---|---|---|---|---|---|---|---|---|---|
| Diet | Composition | Proportions | Diet | Composition | Proportions | Diet | Composition | Proportions | ||
| 1 | Western Himalayan region | MD1 | Grass: GOL | 65:35 | GD1 | SST:L:CM2 | 60:30:10 | PD1 | WS:B:CM2 | 30:40:30 |
| 2 | Eastern Himalayan region | MD2 | Grass:LL | 75:25 | GD2 | RS:LL:CM1 | 50:35:15 | PD2 | Grass: LL:CM1 | 35:40:25 |
| 3 | Eastern plateau and plains region | MD3 | RS:MG | 20:80 | GD3 | RS:NG:CM7 | 30:50: 20 | PD3 | MST:NG:CM7 | 20:45:35 |
| 4 | Middle Gangetic plain | MD4 | WS:MG | 50:50 | GD4 | RS:B | 40:60 | PD4 | MST:CM6 | 60:40 |
| 5 | Trans and Upper Gangetic plain | MD5 | WS:B | 70:30 | GD5 | SST:B:CM2 | 60:25:15 | PD5 | WS:B:CM3 | 30:40:30 |
| 6 | Central plateau and hills | MD6 | LS | 100 | GD6 | GS:CM2 | 80:20 | PD6 | LS:CM5 | 60:40 |
| 7 | Western plateau and hills | MD7 | WS:SG | 50:50 | GD7 | SST/L/B | 55:45 | PD7 | WS:B:CM4 | 35:35:30 |
| 8 | Southern plateau and hills region | MD8 | RS:L | 65:35 | GD8 | SST:ST:CM7 | 40:40:20 | PD8 | SST:CM8 | 60:40 |
| 9 | Western dry zone | MD9 | PST:LL | 75:25 | GD9 | PST: LL:CM2 | 55:30:15 | PD9 | PST:CM2 | 60:40 |
| 10 | Coastal and island region | MD10 | RS:LL | 65:35 | GD10 | RS:LL:CM9 | 45:40:15 | PD10 | RS:LL:CM9 | 30:35:35 |
AER: Agroecological regions; CM: Concentrate mixture; MD: Maintenance diet; GD: Growth diet; PD: Production diet; GOL: Grewia optiva leaves; LL: Leucaena leucocephala leaves; MG: Maize green; RS: Rice straw; SST: Sorghum stover; L: Lucerne; WS: Wheat straw; B: Berseem; LS: Lentil straw; SG: sorghum green; PST: Pearl millet stover; NG: Napier grass; MST: Maize stover.
Table 3.
Chemical composition of the maintenance diets (g/kg DM) *.
| Diet | CP | OM | EE | NDF | ADF | Cellulose | H cellulose | Lignin |
| MD1 | 76.0 cd | 876 cd | 32.1 a | 646 c | 453 a | 298 c | 193 de | 93.4 b |
| MD2 | 93.3 a | 871 c | 27.5 b | 678 b | 456 a | 274 d | 222 c | 109 a |
| MD3 | 84.3 b | 923 a | 17.8 d | 668 bc | 361 d | 309 b | 306 a | 49.6 de |
| MD4 | 69.8 de | 903 b | 14.4 e | 651 c | 379 c | 318 b | 271 b | 45.7 ef |
| MD5 | 96.1 a | 884 c | 18.1 d | 573 e | 386 c | 301 c | 187 e | 49.7 de |
| MD6 | 76.9 cd | 914 a | 13.4 e | 537 f | 386 c | 283 d | 151 f | 93.9 b |
| MD7 | 68.0 e | 920 a | 20.7 cd | 713 a | 406 b | 345 a | 307 a | 42.6 f |
| MD8 | 77.8 bc | 857 e | 26.4 b | 591 d | 391 bc | 272 d | 200 d | 55.8 cd |
| MD9 | 81.8 bc | 920 a | 21.5 c | 545 f | 344 e | 256 e | 201 d | 62.5 c |
| MD10 | 95.5 a | 852 e | 17.9 d | 575 e | 392 bc | 274 d | 184 e | 53.7 d |
| LSD | 7.12 | 10.20 | 3.17 | 12.96 | 15.62 | 15.07 | 9.17 | 6.84 |
| Diet | CP | OM | EE | NDF | ADF | Cellulose | H cellulose | Lignin |
| GD1 | 121 ab | 917 ab | 19.7 de | 610 b | 411 b | 311 b | 199 cde | 80.7 b |
| GD2 | 116 bcd | 874 d | 32.4 a | 527 e | 341 e | 231 c | 186 e | 55.4 fg |
| GD3 | 88.7 e | 856 e | 24.7 bc | 676 a | 392 cd | 334 a | 284 a | 55.9 fg |
| GD4 | 111 bcd | 864 de | 18.6 e | 619 b | 411 bc | 311 b | 209 cd | 52.0 g |
| GD5 | 117 bc | 922 a | 26.7 b | 610 b | 391 d | 303 b | 219 c | 64.2 de |
| GD6 | 110 cd | 909 bc | 18.4 e | 546 d | 412 b | 306 b | 134 f | 92.5 a |
| GD7 | 106 d | 899 c | 17.7 e | 584 c | 389 d | 306 b | 195 de | 71.6 cd |
| GD8 | 111 bcd | 916 ab | 18.1 e | 690 a | 438 a | 329 a | 252 b | 75.5 bc |
| GD9 | 111 bcd | 917 ab | 23.1 e | 493 f | 300 f | 213 d | 193 de | 62.5 ef |
| GD10 | 130 a | 872 d | 35.5 a | 512 e | 328 e | 220 d | 183 e | 52.0 g |
| LSD | 10.87 | 10.29 | 3.35 | 18.25 | 18.32 | 11.30 | 22.70 | 7.90 |
| Diet | CP | OM | EE | NDF | ADF | Cellulose | H cellulose | Lignin |
| PD1 | 130 bc | 901 c | 18.9 de | 491 e | 345 b | 262 c | 146 f | 54.4 d |
| PD2 | 153 a | 899 c | 39.4 b | 537 c | 292 d | 177 g | 245 b | 79.4 b |
| PD3 | 103 e | 882 d | 33.6 cd | 633 a | 360 b | 311 a | 273 a | 45.0 e |
| PD4 | 116 d | 912 ab | 30.7 e | 589 b | 350 b | 249 de | 239 bc | 68.1 c |
| PD5 | 137 b | 904 bc | 26.3 f | 529 cd | 326 c | 253 cd | 203 d | 49.7 de |
| PD6 | 121 cd | 918 a | 32.8 de | 453 f | 288 d | 203 f | 165 e | 74.3 b |
| PD7 | 121 cd | 917 a | 33.4 cd | 549 c | 318 c | 251 d | 231 bc | 51.1 d |
| PD8 | 121 cd | 902 c | 35.7 c | 634 a | 455 a | 301 b | 179 e | 98.0 a |
| PD9 | 116 d | 916 a | 21.7 g | 539 c | 310 c | 240 e | 229 bc | 49.3 de |
| PD10 | 149 a | 886 d | 49.3 a | 508 de | 283 d | 200 f | 225 c | 50.9 d |
| LSD | 9.82 | 7.95 | 2.68 | 22.11 | 16.41 | 10.41 | 18.67 | 5.68 |
MD, maintenance diets; GD, growth diets; PD, production diets; CP, crude protein; OM, organic matter; EE, ether extract; NDF, neutral detergent fiber; ADF, acid detergent fiber; H cellulose, hemi cellulose; LSD, least significant difference at p value < 0.0001; different superscript letters within a column in the table signify statistical differences among the corresponding values; *, each value is a mean of four observations.
Table 4.
Protein fractions of the diets (g/kg CP) *.
| Maintenance | Growth | Production | |||||||||||||||
|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
| Diet | PA | PB1 | PB2 | PB3 | PC | Diet | PA | PB1 | PB2 | PB3 | PC | Diet | PA | PB1 | PB2 | PB3 | PC |
| MD1 | 35.6 de | 101 f | 358 cd | 237 cd | 268 a | GD1 | 310 a | 213 b | 228 f | 125 cd | 123 abc | PD1 | 124 d | 242 bcd | 423 c | 95.2 ef | 116 b |
| MD2 | 18.1 e | 95.3 f | 287 de | 301 b | 299 a | GD2 | 27.8 fg | 85.4 d | 547 a | 194 a | 146 a | PD2 | 49.4 g | 146 fg | 364 d | 291 b | 148 a |
| MD3 | 194 a | 195 ab | 233 e | 157 e | 220 b | GD3 | 171 c | 213 b | 359 de | 138 bcd | 118 abcd | PD3 | 249 a | 279 ab | 175 f | 187 c | 110 bc |
| MD4 | 187 a | 185 bc | 327 d | 88.8 f | 211 bc | GD4 | 172 c | 202 b | 385 cde | 155 b | 85.7 e | PD4 | 158 b | 296 a | 304 e | 133 d | 108 bc |
| MD5 | 173 a | 213 a | 429 bc | 48.9 f | 135 def | GD5 | 167 c | 295 a | 336 e | 114 de | 87.2 de | PD5 | 134 cd | 259 abc | 464 e | 55.5 h | 87.4 cd |
| MD6 | 123 b | 130 e | 576 a | 70.9 f | 99.6 f | GD6 | 141 d | 292 a | 429 bc | 28.4 f | 110 bcde | PD6 | 96.9 e | 208 ed | 508 bc | 113 de | 73.4 d |
| MD7 | 188 a | 218 a | 24.3 f | 425 a | 145 de | GD7 | 203 b | 192 b | 357 de | 100 e | 147 a | PD7 | 71.3 f | 171 ef | 595 a | 72.1 fgh | 90.4 cd |
| MD8 | 14.9 e | 67.8 g | 485 b | 257 bc | 175 cd | GD8 | 109 e | 218 b | 416 cd | 146 bc | 110 bcde | PD8 | 101 e | 223 cd | 492 b | 65.6 gh | 117 b |
| MD9 | 74.4 c | 159 cd | 412 bc | 209 d | 145 de | GD9 | 50.8 f | 188 b | 490 ab | 142 bc | 129 ab | PD9 | 143 c | 228 cd | 431 c | 88.3 efg | 108 bc |
| MD10 | 47.7 d | 138 de | 440 b | 261 bc | 114 ef | GD10 | 15.9 g | 147 c | 550 a | 195 a | 91.4 cde | PD10 | 20.2 h | 120 g | 364 d | 413 a | 82.3 d |
| LSD | 22.84 | 27.36 | 78.36 | 47.84 | 40.64 | LSD | 23.03 | 31.46 | 64.18 | 24.93 | 32.45 | LSD | 14.29 | 39.28 | 57.32 | 26.78 | 22.65 |
MD, maintenance diets; GD, growth diets; PD, production diets; PA, non-protein nitrogen; PB1, buffer-soluble protein; PB2, neutral detergent-soluble protein; PB3, acid detergent-soluble protein; PC, indigestible protein; LSD, least significant difference at p value < 0.0001; different superscript letters within a column in the table signify statistical differences among the corresponding values; *, each value is a mean of four observations.
Table 5.
Carbohydrate fractions of maintenance diets (g/kg DM) *.
| Diet | tCHO | NSC | SC | CC | CB2 | CB1 | CA |
| MD1 | 768 c | 161 d | 607 c | 224 b | 383 e | 20.3 g | 140 b |
| MD2 | 751 d | 128 e | 622 bc | 262 a | 360 f | 95.6 cde | 32.9 d |
| MD3 | 821 ab | 185 c | 636 b | 119 de | 517 b | 74.5 ef | 110 b |
| MD4 | 818 ab | 189 c | 630 b | 110 ef | 520 b | 87.6 def | 101 c |
| MD5 | 770 c | 215 b | 555 d | 119 de | 436 c | 120 bc | 94.8 c |
| MD6 | 824 ab | 300 a | 523 f | 225 b | 298 g | 178 a | 122 b |
| MD7 | 832 a | 157 d | 674 a | 102 f | 572 a | 114 bcd | 43 d |
| MD8 | 753 d | 196 c | 557 d | 134 cd | 423 cd | 135 b | 60.4 d |
| MD9 | 817 b | 300 a | 516 f | 150 c | 366 ef | 58.4 f | 242 a |
| MD10 | 739 d | 199 c | 540 e | 129 d | 411 d | 76.8 ef | 123 b |
| LSD | 14.23 | 15.14 | 14.70 | 16.43 | 18.56 | 30.53 | 31.46 |
| Diet | tCHO | NSC | SC | CC | CB2 | CB1 | CA |
| GD1 | 776 a | 196 d | 580 b | 194 b | 386 d | 144 cd | 51.9 def |
| GD2 | 726 c | 238 b | 488 e | 133 fg | 355 e | 175 bc | 62.9 cde |
| GD3 | 743 b | 88.9 f | 654 a | 134 fg | 520 a | 59.2 g | 29.8 fg |
| GD4 | 735 bc | 142 e | 593 b | 125 g | 468 b | 59.4 g | 82.5 c |
| GD5 | 779 a | 192 d | 586 b | 154 de | 433 c | 155 bc | 37.3 efg |
| GD6 | 780 a | 248 b | 532 d | 222 a | 310 f | 179 ab | 68.7 cd |
| GD7 | 776 a | 218 c | 558 c | 172 cd | 386 d | 86.1 fg | 132 b |
| GD8 | 786 a | 125 e | 662 a | 181 bc | 480 b | 108 ef | 16.6 g |
| GD9 | 783 a | 320 a | 463 f | 150 ef | 313 f | 121 de | 199 a |
| GD10 | 707 d | 232 bc | 475 ef | 125 g | 350 e | 208 a | 23.5 fg |
| LSD | 15.52 | 19.72 | 17.94 | 18.97 | 28.14 | 31.11 | 29.1 |
| Diet | tCHO | NSC | SC | CC | CB2 | CB1 | CA |
| PD1 | 752 bc | 288 b | 464 d | 131 d | 333 d | 239 b | 49.4 bc |
| PD2 | 707 d | 237 d | 470 d | 190 b | 280 f | 194 d | 43.1 c |
| PD3 | 746 c | 143 f | 602 a | 108 e | 494 a | 103 g | 40.2 c |
| PD4 | 765 ab | 203 e | 562 b | 163 c | 398 b | 169 e | 34.1 cd |
| PD5 | 741 c | 231 e | 509 c | 119 de | 390 bc | 133 f | 98.0 a |
| PD6 | 764 b | 333 a | 431 e | 178 b | 252 g | 302 a | 31.7 cd |
| PD7 | 762 b | 233 d | 529 c | 122 d | 407 b | 217 bcd | 16.1 d |
| PD8 | 745 c | 133 f | 612 a | 235 a | 376 c | 97.8 g | 35.2 cd |
| PD9 | 779 a | 262 c | 516 c | 118 de | 398 b | 197 cd | 65.4 b |
| PD10 | 687 e | 253 cd | 434 e | 122 d | 312 e | 219 bc | 34.1 cd |
| LSD | 13.55 | 22.04 | 22.31 | 13.64 | 19.94 | 24.31 | 19.49 |
MD, maintenance diets; GD, growth diets; PD, production diets; tCHO, total carbohydrates; NSC, non-structural carbohydrates; SC, structural carbohydrates; CC, unavailable/lignin-bound cell wall; CB2, slowly degradable cell wall; CB1, intermediately degradable starch and pectin; CA, rapidly degradable CHO, including sugars; LSD, least significant difference at p value < 0.0001; different superscript letters within a column in the table signify statistical differences among the corresponding values; *, each value is a mean of four observations.
Table 6.
Gas and methane production kinetics from the maintenance diets fermented in buffalo inoculums *.
Table 6.
Gas and methane production kinetics from the maintenance diets fermented in buffalo inoculums *.
| Diets/Rations | Gas (mL/g) | Methane (mL/g) | ||||||
| 0–12 h | 12–24 h | 24–48 h | Cumulative | 0–12 h | 12–24 h | 24–48 h | Cumulative | |
| MD1 | 64.3 c | 50.0 e | 50.0 b | 164 c | 9.83 d | 5.77 f | 5.08 h | 20.7 g |
| MD2 | 58.5 h | 51.0 d | 44.3 f | 154 e | 6.57 f | 5.56 f | 11.3 b | 23.4 e |
| MD3 | 59.5 gh | 55.8 b | 47.6 d | 163 c | 11.2 c | 12.3 a | 16.3 a | 39.8 a |
| MD4 | 63.6 cd | 54.3 c | 50.0 b | 168 b | 12.6 b | 11.2 b | 17.0 a | 40.4 a |
| MD5 | 66.0 b | 53.7 c | 45.3 e | 164 c | 11.2 c | 8.77 c | 5.66 g | 25.7 d |
| MD6 | 62.3 de | 49.2 e | 47.9 d | 160 d | 15.1 a | 8.63 c | 9.56 d | 33.3 b |
| MD7 | 69.8 a | 58.5 a | 48.3 cd | 178 a | 12.1 b | 7.89 d | 8.32 e | 28.3 c |
| MD8 | 63.8 cd | 54.5 c | 46.1 e | 164 c | 8.72 e | 6.68 e | 7.02 f | 22.4 f |
| MD9 | 61.8 ef | 44.5 g | 49.3 c | 156 e | 9.03 de | 6.67 e | 8.21 e | 23.9 e |
| MD10 | 60.5 fg | 47.8 f | 52.6 a | 160 d | 7.12 f | 7.98 d | 10.8 c | 25.9 d |
| LSD | 1.535 | 1.038 | 0.960 | 2.245 | 0.829 | 0.528 | 0.359 | 1.348 |
| Diets/Rations | Gas (mL/g) | Methane (mL/g) | ||||||
| 0–12 h | 12–24 h | 24–48 h | Cumulative | 0–12 h | 12–24 h | 24–48 h | Cumulative | |
| GD1 | 65.0 b | 50.3 f | 48.8 cd | 164 c | 12.8 c | 5.74 h | 3.95 i | 22.5 gh |
| GD2 | 59.5 d | 55.8 b | 46.8 e | 162 de | 8.20 ef | 10.1 b | 15.3 c | 33.6 c |
| GD3 | 62.4 c | 55.2 bc | 49.2 bc | 167 b | 10.5 d | 10.6 a | 15.8 b | 36.9 b |
| GD4 | 64.8 b | 52.6 e | 48.8 cd | 166 b | 15.5 a | 10.9 a | 16.2 a | 42.6 a |
| GD5 | 65.8 b | 51.8 e | 45.6 f | 163 cd | 13.2 c | 7.39 f | 6.40 g | 26.96 f |
| GD6 | 67.3 a | 54.5 cd | 44.3 g | 166 b | 10.9 d | 7.96 e | 4.73 h | 23.6 g |
| GD7 | 67.8 a | 57.0 a | 48.3 d | 173 a | 14.5 b | 9.49 c | 8.22 f | 32.2 d |
| GD8 | 62.8 c | 54.0 d | 49.8 b | 167 b | 9.09 e | 6.07 g | 6.40 g | 21.6 h |
| GD9 | 63.5 c | 46.3 g | 49.6 b | 159 f | 11.1 d | 8.48 d | 9.67 e | 29.2 e |
| GD10 | 59.5 d | 50.0 f | 51.0 a | 161 ef | 7.87 f | 8.50 d | 10.27 d | 26.6 f |
| LSD | 1.136 | 0.844 | 0.729 | 1.836 | 0.906 | 0.300 | 0.357 | 1.175 |
| Diets/Rations | Gas (mL/g) | Methane (mL/g) | ||||||
| 0–12 h | 12–24 h | 24–48 h | Cumulative | 0–12 h | 12–24 h | 24–48 h | Cumulative | |
| PD1 | 62.8 e | 54.3 cd | 44.0 g | 161 d | 13.9 b | 12.7 a | 14.5 b | 41.1 a |
| PD2 | 62.6 e | 53.0 e | 46.8 e | 162 d | 11.1 d | 9.02 de | 14.2 b | 34.3 cd |
| PD3 | 61.0 f | 54.6 bc | 48.8 cd | 164 c | 10.9 d | 11.2 bc | 16.0 a | 38.1 b |
| PD4 | 64.3 d | 54.0 d | 50.0 ab | 168 b | 14.0 b | 11.0 bc | 15.9 a | 40.9 a |
| PD5 | 67.6 a | 55.0 b | 45.0 f | 168 b | 15.6 a | 11.1 bc | 8.03 d | 34.7 c |
| PD6 | 66.3 b | 54.8 bc | 44.1 g | 165 c | 15.0 a | 11.4 b | 6.94 e | 33.4 cd |
| PD7 | 66.0 b | 58.6 a | 45.3 f | 170 a | 13.0 c | 10.5 c | 6.94 e | 30.4 e |
| PD8 | 60.5 f | 43.8 h | 48.3 d | 153 f | 6.42 f | 5.68 f | 6.56 e | 18.6 g |
| PD9 | 65.0 c | 47.5 g | 49.4 bc | 162 d | 13.5 bc | 9.41 d | 9.75 c | 32.7 d |
| PD10 | 59.0 g | 49.7 f | 50.4 a | 159 e | 8.28 e | 8.63 e | 10.11 c | 27.0 f |
| LSD | 0.663 | 0.557 | 0.796 | 1.278 | 0.883 | 0.741 | 0.786 | 1.970 |
MD, maintenance diets; GD, growth diets; PD, production diets; LSD, least significant difference at p value < 0.0001; different superscript letters within a column in the table signify statistical differences among the corresponding values; *, each value is a mean of four observations.
Table 7.
Methane production and loss of dietary energy as methane from the maintenance diets *.
| Diets/Rations | IVDMD g/kg DM | CH4 mL/g DDM 24h | CH4 g/kg DM | CH4 g/kg DDM | GE kJ/g | GE in CH4 g DDM | CH4 %GE DDM |
| MD1 | 422 bc | 37.2 f | 11.2 c | 26.7 ef | 16.9 cd | 1.42 ef | 8.45 ef |
| MD2 | 402 c | 30.4 g | 8.70 d | 21.7 g | 18.0 ab | 1.16 g | 6.46 g |
| MD3 | 482 b | 48.9 a | 16.9 a | 35.0 a | 17.5 bc | 1.87 a | 10.7 ab |
| MD4 | 468 b | 49.4 a | 17.1 a | 35.4 a | 16.3 d | 1.89 a | 11.6 a |
| MD5 | 468 b | 42.5 bcd | 14.3 b | 30.5 bcd | 17.5 bc | 1.63 bcd | 9.31 cde |
| MD6 | 584 a | 43.2 bc | 17.0 a | 31.0 bc | 18.7 a | 1.66 bc | 8.87 de |
| MD7 | 417 bc | 47.0 ab | 14.4 b | 33.7 ab | 17.4 bc | 1.80 ab | 10.3 bc |
| MD8 | 367 e | 41.5 cde | 11.0 c | 29.8 cde | 16.2 d | 1.59 cde | 9.8 bcd |
| MD9 | 474 bc | 33.5 fg | 11.3 c | 24.1 fg | 17.6 bc | 1.28 fg | 7.31 fg |
| MD10 | 389 de | 38.5 de | 10.8 c | 27.6 de | 17.2 c | 1.47 de | 8.56 e |
| LSD | 43.58 | 4.64 | 0.81 | 3.33 | 0.768 | 0.178 | 1.14 |
| Diets/Rations | IVDMD g/kg DM | CH4 mL/g DDM 24 h | CH4 g/kg DM | CH4 g/kg DDM | GE kJ/g | GE in CH4 g DDM | CH4 %GE DDM |
| GD1 | 450 d | 41.3 bc | 13.27 e | 29.6 bc | 16.9 cd | 1.57 bc | 9.29 bc |
| GD2 | 496 bc | 37.0 de | 13.14 e | 26.5 de | 17.5 bc | 1.41 de | 8.06 e |
| GD3 | 530 b | 39.9 cd | 15.13 c | 28.6 cd | 16.9 cd | 1.53 cd | 9.07 cd |
| GD4 | 628 a | 42.1 bc | 18.94 a | 30.2 bc | 17.0 cd | 1.61 bc | 9.49 bc |
| GD5 | 466 cd | 44.3 b | 14.74 c | 31.8 b | 16.9 cd | 1.7 b | 10.0 b |
| GD6 | 530 b | 35.7 e | 13.55 de | 25.6 e | 16.6 d | 1.37 e | 8.21 de |
| GD7 | 409 e | 58.7 a | 17.21 b | 42.1 a | 17.9 ab | 2.24 a | 12.5 a |
| GD8 | 372 f | 40.9 bc | 10.87 g | 29.3 bc | 16.7 d | 1.57 bc | 9.43 bc |
| GD9 | 469 cd | 41.9 bc | 14.01 d | 30.0 bc | 18.3 a | 1.61 bc | 8.82 cde |
| GD10 | 408 e | 40.1 cd | 11.74 f | 28.8 cd | 17.4 bc | 1.53 cd | 8.83 cde |
| LSD | 35.36 | 3.88 | 0.686 | 2.78 | 0.614 | 0.148 | 0.865 |
| Diets/Rations | IVDMD g/kg DM | CH4 mL/g DDM 24h | CH4 g/kg DM | CH4 g/kg DDM | GE kJ/g | GE in CH4 g DDM | CH4 %GE DDM |
| PD1 | 621 a | 42.9 c | 19.06 a | 30.7 c | 17.5 bcd | 1.66 c | 9.48 cd |
| PD2 | 605 a | 33.2 de | 14.39 d | 23.8 de | 17.7 abc | 1.28 de | 7.24 e |
| PD3 | 600 ab | 36.9 d | 15.82 c | 26.5 d | 16.8 ef | 1.41 d | 8.40 d |
| PD4 | 523 cd | 47.9 ab | 17.92 b | 34.3 ab | 16.9 def | 1.82 ab | 10.8 ab |
| PD5 | 520 d | 51.5 a | 19.11 a | 36.9 a | 17.4 bcd | 1.99 a | 11.4 a |
| PD6 | 563 bc | 47.0 bc | 18.96 a | 33.7 ab | 16.7 f | 1.78 bc | 10.7 ab |
| PD7 | 496 d | 47.4 ab | 16.82 c | 34.0 ab | 18.1 a | 1.82 ab | 10.1 bc |
| PD8 | 391 e | 31.1 e | 8.68 f | 22.3 e | 17.2 cdef | 1.20 e | 6.92 e |
| PD9 | 534 cd | 43.1 c | 16.4 c | 30.9 c | 17.3 bcde | 1.66 c | 9.59 c |
| PD10 | 533 cd | 31.8 e | 12.1 e | 22.8 e | 17.8 ab | 1.20 e | 6.84 e |
| LSD | 40.91 | 4.21 | 1.003 | 3.02 | 0.575 | 0.161 | 1.029 |
MD, maintenance diets; GD, growth diets; PD, production diets; IVDM, in vitro dry matter digestibility; GE, gross energy; LSD, least significant difference at p value < 0.0001; different superscript letters within a column in the table signify statistical differences among the corresponding values; *, each value is a mean of four observations.
Table 8.
Correlation between in vitro methane production and chemical constituents of the diets/rations.
Table 8.
Correlation between in vitro methane production and chemical constituents of the diets/rations.
| Chemical Constituents | CH4 g/g DDM | Protein Fractions | CH4 g/g DDM | CHO Fractions | CH4 g/g DDM |
|---|---|---|---|---|---|
| CP | −0.134 | NDIP | −0.448 (**) | tCHO | 0.353 (**) |
| OM | 0.266 (**) | ADIP | −0.272 (**) | NSC | 0.115 |
| EE | −0.422 (**) | SP | 0.387 (**) | SC | 0.083 |
| NDF | −0.009 | NPN | 0.450 (**) | Starch % NSC | −0.104 |
| ADF | −0.127 | PA | 0.412 (**) | CC DM | −0.365 (**) |
| Cellulose | −0.073 | PB1 | 0.284 (**) | CB2DM | 0.278 (**) |
| Hemi cellulose | 0.130 | PB2 | −0.053 | CB1DM | 0.031 |
| Lignin | −0.365 (**) | PB3 | −0.341 (**) | CADM | 0.091 |
| Energy | −0.032 | PC | −0.145 |
CP, crude protein; OM, organic matter; EE, ether extract; NDF, neutral detergent fiber; ADF, acid detergent fiber; NDIP, neutral detergent-insoluble protein; ADIP, acid detergent-insoluble protein; SP, soluble protein; PA, non-protein nitrogen; PB1, buffer-soluble protein; PB2, neutral detergent-soluble protein; PB3, acid detergent-soluble protein; PC, indigestible protein; tCHO, total carbohydrates; NSC, non-structural carbohydrates; SC, structural carbohydrates; CC, unavailable/lignin-bound cell wall; CB2, slowly degradable cell wall; CB1, intermediately degradable starch and pectin; CA, rapidly degradable CHO, including sugars; DM, dry matter; DDM, digestible dry matter; **, statistically significant.
Disclaimer/Publisher’s Note: The statements, opinions and data contained in all publications are solely those of the individual author(s) and contributor(s) and not of MDPI and/or the editor(s). MDPI and/or the editor(s) disclaim responsibility for any injury to people or property resulting from any ideas, methods, instructions or products referred to in the content. |
© 2023 by the authors. Licensee MDPI, Basel, Switzerland. This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution (CC BY) license (https://creativecommons.org/licenses/by/4.0/).
Share and Cite
MDPI and ACS Style
Singh, S.; Koli, P.; Kushwaha, B.P.; Anele, U.Y.; Bhattacharya, S.; Ren, Y. Agroecological Zone-Specific Diet Optimization for Water Buffalo (Bubalus bubalis) through Nutritional and In Vitro Fermentation Studies. Animals 2024, 14, 143. https://doi.org/10.3390/ani14010143
AMA Style
Singh S, Koli P, Kushwaha BP, Anele UY, Bhattacharya S, Ren Y. Agroecological Zone-Specific Diet Optimization for Water Buffalo (Bubalus bubalis) through Nutritional and In Vitro Fermentation Studies. Animals. 2024; 14(1):143. https://doi.org/10.3390/ani14010143
Chicago/Turabian StyleSingh, Sultan, Pushpendra Koli, B. P. Kushwaha, Uchenna Y. Anele, Sumana Bhattacharya, and Yonglin Ren. 2024. "Agroecological Zone-Specific Diet Optimization for Water Buffalo (Bubalus bubalis) through Nutritional and In Vitro Fermentation Studies" Animals 14, no. 1: 143. https://doi.org/10.3390/ani14010143
Note that from the first issue of 2016, this journal uses article numbers instead of page numbers. See further details here.
