The effect of calcium hydroxide treatment on the digestibility of chopped oat straw supplemented with a solution containing urea,calcium, phosphorus,sodium, trace elements and vitamins

In the first of two experiments chopped oat straw was supplemented with 4% of a liquid containing urea, calcium, phosphorus, sodium, trace elements and vitamins, all in solution. The straw treatments were (A) basal diet, (B) basal diet plus 5% Ca(OH)₂ and (C) basal diet plus 5% Ca(OH)₂ and 10% water. Diet B was totally unpalatable. The digestibility of diets A and C was determined with adult ewes. The Ca(OH)₂ reacted with the straw as observed by the physical effects of heating and yellowing of the straw, but did not increase its digestibility.In the second experiment chopped oat straw was treated with either (i) an equal weight of water (100% water), (ii) 100% water plus 5% Ca(OH)₂ or (iii) 60% water plus 5% Ca(OH)₂ and ensiled in 0.5 t capacity insulated silos for 20 weeks. In both the Ca(OH)₂ treated silos the temperature rose to approximately 70°C after 10 days storage. By day 60 all the treatments had extremely heavy mould presence, treatment (i) being most heavily contaminated. The treated materials were completely unsuited for animal feeding.It was concluded that straw treated with 5% Ca(OH)₂ plus 10% water did not improve digestibility. Straw ensiled with 5% Ca(OH)₂ plus either 60% or 100% water did not store sufficiently well to be suitable for animal feeding. Further work is required to find the most effective rates of addition of both water and Ca(OH)₂.     

Supplementation of alkali-treated rice straw

Goats were fed rice straw treated with 0,4 or 8% NaOH, dehydrated palm oil mill effluent (POME) at 20 or 30 g/kg liveweight (LW)/day and Leucaena at 5 or 10 g dry matter (DM)/kg LW/day in Experiment 1, and rice straw treated with 4% NaOH or 4% NH₄OH, POME at 30 g/kg LW/day and either Napier grass or Leucaena at 10 g DM/kg LW/day in Experiment 2. Treatment with 4% NaOH promoted the highest intake of rice straw. 10·3 and 12·4 g DM/kg LW/day respectively in Experiments 1 and 2. Feeding Leucaena at 10 g DM/kg LW/day significantly increased total intake (36·0 g DM/kg LW/day) and DM digestibility (59·0%) in Experiment 1, and supported a LW gain of 63 g/day in Experiment 2. It is concluded that diets comprising 25% NaOH-straw, 50% POME and 25% Leucaena permitted dietary nutrients to be used efficiently and maximised the inclusion of by-products.     

Chemical composition,digestibility and in situ degradability of dried and ensiled apple pomace and maize silage

The nutritive value of the dried and ensiled apple pomace (DAP and EAP), taken from two processing factories in Urmia city, was compared with maize silage (MS). For EAP, 1 tonnes of AP was mixed with 100 kg of wheat straw and 5 kg of urea (on fresh weight basis). The chemical composition of all feedstuffs was determined by laboratory analysis. Additionally, pH and the concentration of ammonia-N and volatile fatty acids (VFA) were measured in the EAP and MS silages. An in vivo digestibility study was undertaken with three Gezel wether sheep to determine the digestible organic matter content in the dry matter (DOMD) and to estimate the metabolisable energy (ME) content. The dry matter (DM) and protein effective degradabilities (ED) of the feedstuffs were assessed using a nylon bag method. The mean values of the DM, OM, CP, acid detergent fibre (ADF), neutral detergent fibre (NDF), lignin and acid detergent insoluble nitrogen (ADIN) were, respectively, 749 g/kg fresh weight, 929, 64, 405, 473, 10 and 5.6 g/kg DM for DAP, 284 g/kg fresh weight, 925, 72, 460, 567, 20 and 6.5 g/kg DM for EAP and 429 g/kg fresh weight, 936, 260, 463, 44 and 4.4 g/kg DM for MS. No butyric acid was found in EAP and MS, which indicate good preservation for these silages. However, ammonia-N was higher in MS than EAP. The DOMD values were 690, 654 and 580 g/kg DM for DAP, MS and EAP, respectively. The DOMD and ME values for DAP and MS were significantly higher than those of EAP. The dry matter ED of EAP was significantly lower than that of DAP and MS and there was a significant difference among all feedstuffs in the protein ED where MS was the highest and EAP the lowest. The nutritive value of AP was reduced by the addition of wheat straw. However, ensiling apple with straw is a practical method to preserve such high moisture by-product.     

Nutrient composition,digestion and rumen fermentation in sheep of wheat straw treated with calcium oxide,sodium hydroxide and alkaline hydrogen peroxide

This study tested the effect of calcium oxide (CaO), sodium hydroxide (NaOH) and NaOH plus hydrogen peroxide (H₂O₂; AHP) on cell wall composition, digestion and fermentation of wheat straw (straw) in sheep. Treated straws were prepared by mixing straw either with water followed by dusting with CaO at 160 g kg⁻¹ DM or with a NaOH solution alone at 3 l kg⁻¹ DM to supply 80 g NaOH kg⁻¹ DM (Na) or pre-soaked with Na exactly as in the previous treatment for 27 h followed by mixing with 130 g H₂O₂ kg⁻¹ DM (AHP) for 6 h. After 14 days of storage, the treated straws and an untreated straw (U) were fed automatically every 2 h to four individually housed sheep together with a supplement in a 4×4 latin square experiment. Each kilogram supplement DM contained 422 g CP and 10.8 MJ ME. NDF (p<0.001) and hemicellulose (p<0.01) contents were significantly reduced whereas cellulose was increased (p<0.001) in treated compared to untreated straw. ADL was reduced in Ca (p<0.05) but increased (p<0.05) in Na and AHP compared with U. The rumen and total tract digestibility were significantly (p<0.001) greater in sheep fed treated compared with untreated straw. Significant differences (p<0.05) between treatments for pH, NH₃ and VFA were also observed. All treatments improved the nutritive value of straws compared with untreated through modification of cell wall with a subsequent increase in digestibility by sheep. Although the digestibility for Ca was lower than that for Na despite reduction in cell wall, its use to treat straws may be more safe and cost effective than Na. AHP was the most effective and could also improve the energy value of other low quality forages for ruminants. However, the need of AHP for a large amount of NaOH to achieve highly alkaline pH limits its farm scale application. Therefore, further studies should either consider reducing the amount of NaOH or finding alternative alkalis that are cost effective and user-friendly.     

Alkali treatment of straw for ruminants. II. Nutritive value of straw ensiled after alkali treatment

In the first of two experiments barley straw was treated with a 16% solution of $\text{NaOH}\text{t}$ dry matter (DM) and ensiled for one year. It was satisfactorily preserved, having a pH of 10 and counts of 10⁴ mesophilic bacteria and 10³ fungal propagules per g. When this straw was mixed with concentrates (50:50, DM basis) and given to sheep, DM intake and digestibility were 102 g/kg W^0.75 per day and 67.3%. Comparable values for a diet based on freshly-treated straw were 88 g and 66.5%.In the second experiment, a 6-tonne batch of alkali-treated barley straw was ensiled for 2–4 months, then mixed with 40% concentrates and given to 370-kg steers for 66 days. Intake and growth rate were 10.23 and 1.08 kg/d, compared with 9.06 and 1.00 kg/d for steers given a diet based on freshly-treated straw. The latter diet was less digestible (for sheep) than the former.It is concluded that the feeding value of stored straw is as high as that of freshly-treated material.     

Alkali treatment of straw for ruminants. I. Utilization of complete diets containing straw by beef cattle

In the first of two experiments, 40 Friesian steers weighing initially 300 kg were fattened on diets containing barley and soya bean meal alone (C) or with inclusions of 40% untreated straw (WS₄₀) or 40 or 60% alkali-treated straw (AS₄₀ and AS₆₀). The straw was coarsely milled into a horizontal mixer, where sodium hydroxide was applied as a 16% solution providing $\text{80}\text{kg NaOH}\text{t straw dry matter (DM)}$. Intakes of DM (kg/d) were: C, 7.88; AS₄₀, 9.67; AS₆₀, 9.23; WS₄₀, 8.60, and empty body weight gains (kg/d, in the same order) were 1.16, 1.03, 0.82 and 0.78.In the second experiment there were four diets, all containing 60% straw and 40% concentrates. The straw was coarsely milled (M) or chopped by forage harvester (C), and treated with alkali (A) or untreated (U). In a trial of latin square design, intake (kg DM/d) was; MU, 7.77; MA, 10.37; CU, 7.44; CA, 10.12. In a longer trial with five steers per diet, liveweight gains (kg/d, in the same order) were 0.70, 1.09, 0.71 and 1.18. The digestibility of DM for the four diets was 60.0, 72.7, 60.3 and 72.0%.The utilization of the energy of the diets, and the economic value of alkali treatment, are discussed.     

Ensiled alkali-treated straw. II. The nutritive value for young beef cattle of mixtures of ensiled or frozen alkali-treated straw and ryegrass silage

Ensiled or frozen barley straw, treated with 7.5 g NaOH and 120 ml solution per 100 g DM prior to storage, was given in mixtures with ryegrass silage to young calves, initially 100 kg live weight. Urea was added to the straw at feeding at 2.5% of the dry matter (DM) and soya bean meal was given at 0.3% live weight per day in all treatments. Voluntary intake, digestibility and live-weight gain were similar for the two types of treated straw. Intake of metabolisable energy and weight gain decreased with increasing level of straw in the diet, averaging 889 g per head per day for a control diet of grass silage (91.7% of total diet DM), and 749, 550 and 150 g per head per day when the proportion of straw DM to grass silage DM was 33: 66, 66 : 33 and 100 : 0, respectively. Whilst alkali-treated straw cannot replace high quality grass silage with the same nutritional efficiency, weight gains in excess of 500 g/day can be reached if the proportion of straw is less than half the total DM.     

Changes during aerobic exposure of wheat silages

Aerobic stability is an important characteristic of silages because they are exposed to air during storage and feedout. The objective of the current study was to investigate changes that occur in wheat silages during aerobic exposure. Silages of whole crop wheat harvested at the flowering, milk and dough stages of maturity were prepared in 1.5 L anaerobic glass jars. Three months after ensiling, silages were subjected to a 7-day aerobic stability test. The silages of wheat harvested at the flowering stage were the most stable upon aerobic exposure, but had the largest fermentation losses. Silages of milk-stage wheat were unstable upon aerobic exposure, and had large amounts of CO₂ and heating, large yeast populations, decreased amounts of fermentation products and decreased dry matter (DM) and neutral detergent fiber (NDF) digestibility (from 667 to 572 g/kg DM and from 597 to 558 g/kg DM, following 7-day aerobic exposure, respectively). Silages of dough-stage wheat had relatively low fermentation losses and were quite stable for at least 4 days of aerobic exposure. Silage samples from the center of commercial bunker silos, and from areas adjacent to the walls of the silos, were judged to be of good quality. Samples from the shoulders of bunker silos were spoiled with higher pH (P<0.05), higher ash content and lower DM and NDF digestibility compared with samples from the center of the silos and areas near the walls (6.8 vs. 4.0, 19.0 vs. 7.8, 477 g/kg DM vs. 634 g/kg DM and 230 g/kg DM vs. 487 g/kg DM, respectively).     

Simplified method for alkali treatment of low-quality roughages for use by small-holders in developing countries

The method described is a modification of the soaking procedure of Beckmann and of Torgrimsby. As the effluent NaOH solution is successively replenished and re-used many times before being discarded, pollution is minimised. Furthermore, the amounts of water and alkali consumed are smaller than with the Beckmann method, and the same container is used for all treatments and washing. The method is adaptable to small-scale farming.In Experiment 1, Cynodon hay was treated with 0, 50 or 100 kg NaOH/tonne dry matter (DM), by a modification of the Beckmann method. Significant (P < 0.01) improvements in digestibility of dry matter (DM), organic matter (OM), and cell wall constituents (CWC) were obtained, and voluntary feed intake was raised significantly (P < 0.01).In Experiment 2, both NaOH and Ca(OH)₂ treatments at 0, 50, 100 and 150 kg alkali/tonne DM of maize stover, significantly (P < 0.01) increased DM and OM digestibility, but the response was greater with NaOH. A combination of NaOH and Ca(OH)₂ treatments had no consistent effect on digestibility, but the trend was a decline in digestibility when Ca(OH)₂ was applied at high rates of 100 and 150 kg Ca(OH)₂/tonne DM. The recovery of DM increased with Ca(OH)₂ treatment, but decreased with NaOH.In Experiment 3, the treatment of maize stover with 0, 25 or 50 kg Ca(OH)₂/tonne DM, in combination with 0, 100 or 150 kg NaOH/tonne DM, significantly (P < 0.01) decreased DM, OM, and CWC digestibility below that achieved by NaOH alone.It is concluded that with the modified method an initial allowance of 100–150 kg NaOH/tonne DM of stover and replenishment of 40–60 kg NaOH/tonne DM is optimal.     

Bioconversion of wheat straw to ethanol: Chemical modification,enzymatic hydrolysis,and fermentation

Native wheat straw (WS) was pretreated with various concentrations of H₂SO₄ and NaOH followed by secondary treatments with ethylene diamine (EDA) and NH₄OH prior to enzymatic saccharification. Conversion of the cellulosic component to sugar varied with the chemical modification steps. Treatment solely with alkali yield 51–75% conversion, depending on temperature. Acid treatment at elevated tempeatures showed a substantial decrease in the hemicellulose component, whereas EDA-treated WS (acid pretreated) showed a 69–75% decrease in the lignin component. Acid-pretreated EDA-treated straw yielded a 98% conversion rate, followed by 83% for alkali–NH₄OH treated straws. In other experiments, WS was pretreated with varying concentration of H₂SO₄ or NaOh followed by NH₄OH treatment prior to enzymatic hydrolysis. Pretreatment of straw with 2% NaOH for 4 h coupled to enzymatic hydrolysis yield a 76% conversion of the cellulosic component. Acid–base combination pretreatment yielded only 43% conversions. A reactor column was subsequently used to measure modification–saccharification–fermentation for wheat straw conversion on a larger scale. Thirty percent conversions of wheat straw cellulosics to sugar were observed with subsequent fermentation to alcohol. The crude cellulase preparation yielded considerable quantities of xylose in addition to the glucose. Saccharified materials were fermented directly with actively proliferating proliferating yeast cells without concentration of the sugars.     

Utilization of alkali-treated and neutralized wheat straw-based rations for growing goat kids

Six groups of six goat kids were fed individually for 168 days with wheat straw given various treatments: (1) control; (2) 33 g NaOH/kg straw; (3) 80 g NaOH/kg, partly neutralized with mineral acids; (4) mineral control for 80 g NaOH/kg; (5) 120 g NaOH/kg, partly neutralized with mineral acids, and (6) mineral control for 120 g NaOH/kg straw. The average weight gain was significantly superior (P< 0.05) and the efficiency of dry matter (DM) and energy utilization was the highest with the 80 g NaOH/kg straw treatment. This treatment also gave significantly higher (P<0.05) digestibility of DM, organic matter (OM), neutral detergent fibre (NDF), acid detergent fibre (ADF), nitrogen-free extract (NFE) and hemicellulose than the control and 33 g NaOH/kg straw treatments. Increasing levels of alkali decreased (P<0.05) the digestibility of crude protein (CP) and ether extract (EE). Digestible energy and nitrogen-corrected metabolisable energy (ME_n) (as a percentage of gross energy (GE)) were maximal with 80 g NaOH/kg. The pH value of rumen liquor was the same for the control and the 33 g NaOH/kg and 80 g NaOH/kg treatments, but significantly increased (P<0.05) with the 120 g NaOH/kg straw treatment. The mean values for rumen ammonia nitrogen (NH₃ -N) were the same for the control, the 33 g NaOH/kg, and mineral controls for 80 and 120 g NaOH/kg treatments, but 80 g NaOH and 120 g NaOH/kg straw gave significantly lower values. It is suggested that by partially neutralizing the residual alkali, 80 g NaOH/kg straw can give higher efficiency of energy utilization for growth and digestibility of nutrients compared with 33 g NaOH/kg or the untreated control group, and the extensive use of treated straw in the diets of animals of which a rapid rate of production is not demanded, may be advantageous.     

Methods of improving the utilization of cereal straw by ruminants. III. A note on the effect of ensiling straw treated with urea

Straw treated with urea was offered to lambs either freshly prepared (EN₀) or after ensiling with urea for 30 days (EN₃₀). The lambs also received 10 g dry matter (DM) of shredded, artificially dried grass per day per kg of metabolic liveweight. Ensiling straw significantly increased its intake from 32 to 41 g DM per day per kg of metabolic liveweight, and its DM digestibility from 375 to 450 g per kg.     

The effect of silage additives containing formaldehyde on the fermentation of ryegrass ensiled at different dry matter levels and on the nutritive value of direct-cut silage

Ryegrass, harvested at the pre-ear emergence stage of growth, was ensiled in laboratory silos, either fresh (175 g dry matter kg^?1) or wilted to five DM levels ranging from 216–432 g DM kg^?1, with and without additive treatment. The additives used were “Sylade” containing sulphuric acid (15%) and formaldehyde (23%) applied at 4.6 l t^?1 and an “ADD-F” $\text{(85\%}\text{formic acid}\text{)}\text{formalin}$ mixture (7:3 by volume) applied at a similar rate (4.8 l t^?1). An additional treatment included application of the mixture at a constant rate related to the DM content of the ensiled crop (25 l t^?1 DM).In the untreated silages, the water-soluble carbohydrates (WSC) varied, respectively (over the DM range 175–432), from 0–32 g kg^?1 DM compared with 197-6 g kg^?1 DM for the “Sylade” treated silages and 256-50 g kg^?1 DM for the formic acid/formalin silages treated at an additive rate of 4.8 l t^?1. Corresponding ranges of protein N for the control and treatments (expressed as g kg^?1 total N) were 302–447, 624-502 and 620-505, respectively. When the formic acid/formalin additive was applied at a constant level related to the DM content of the crop, although the WSC content decreased with increasing DM (247-158 g kg^?1 DM), the protein N content (612 g kg^?1 total N) remained constant.Grass from the same field was ensiled fresh, treated with “ADD-F” at the rate of 3.4 l t^?1 fresh grass, $\text{“}\text{ADD-F}\text{”}\text{formalin}$ at the rate of 4.8 l t^?1 fresh grass and “Sylade” at the rate of 4.6 l t^?1 fresh grass. The silages were given to Suffolk-cross wether lambs in digestibility and intake trials. Digestibility coefficients of DM and energy of the silage treated with “Sylade” were significantly lower (P < 0.05) than those of the other three silages. The DM intakes of all the silages were high, ranging from 27.7 g kg^?1 live weight for the “Sylade” silage to 30.7 g kg^?1 live weight for the silage treated with $\text{“}\text{ADD-F}\text{”}\text{formalin}$. Live weight gains ranged from 200 g/day for the control silage to 267 g/day for the $\text{“}\text{ADD-F}\text{”}\text{formalin}$ silage.     

Fermentation characteristics and feeding value of ensiled poultry litter containing wheat straw,bagasse or sawdust

Poultry excreta substantially increased the crude protein (CP) content and the calcium and phosporus content of the base bedding materials. The crude fibre (CF) content of sawdust (52.3%) was higher than that of wheat straw (38.9%) and bagasse (30.2%). Dry matter digestibility in vitro (IVDMD) of wheat straw, bagasse and sawdust poultry litters (PL) was 65.4, 64.5 and 48.1%, respectively. Green sorghum fodder when ensiled alone or with 20% wheat straw PL, sawdust PL or bagasse PL on fresh basis contained 4.67, 7.80, 10.00 and 7.55% CP, respectively. Nitrogen-free extract (NFE) content of PL silages was lower than that of the control. Apart from wheat straw PL, all silages accumulated considerable amounts of lactic acid. The total volatile fatty acids (TVFA) concentrations were similar for all silages. The addition of PL caused an increase in the proportion of ammonia nitrogen. A feeding trial with crossbred adult male cattle revealed no significant difference in dry matter (DM), CP and ether extract (EE) digestibility of wheat straw and bagasse PL silages. The CF digestibility was similar for all the silages. Sawdust PL silage, however, was significantly lower (P < 0.05) in digestibility of DM, EE and NFE compared to other PL based silages. The DCP and TDN values for the control, wheat straw, bagasse and sawdust PL silages were 2.0, 60.1; 4.3, 45.3; 6.1, 50.3 and 2.9, 41.9 kg/100 kg DM, respectively.     

In vitro and in sacco digestibility of wheat straw treated with calcium oxide and sodium hydroxide alone or with hydrogen peroxide

A series of five factorial experiments examined the effects of sodium hydroxide (NaOH) and calcium oxide (CaO) alone or together with hydrogen peroxide (H₂O₂, 27.5% w/w) at pH of about 11.5 (AHP) on in vitro (IVDMD) and in sacco (ISDMD) dry matter digestibility of wheat straw. The effects of different temperatures (20°C, 40°C and 60°C), various times (2, 3, 4, 6 and 27 h), pre-soaking, filtration and washing on the efficacy of the above levels of chemicals in improving IVDMD and ISDMD were tested in separate experiments. AHP improved IVDMD (P<0.001) of straws when pH was regulated to around 11.5 using NaOH. In contrast, AHP was ineffective or depressive (P<0.001) when CaO was used to regulate pH to around 11.5. However, CaO alone increased IVDMD to a similar extent as did NaOH. Washing, filtration and temperature were ineffective in improving the IVDMD of CaO-treated straw. AHP was most effective when 130 g H₂O₂ was applied to each kg DM of straw after soaking it with 3 l solution containing 80 g NaOH for a period of 27 h. The nutritional value of low quality forages can be enhanced for ruminants by using alkalis provided conditions as described above are maintained during alkali treatments.     

Review article: The alkali treatment of straws

The Beckmann method of alkali treatment consists of soaking straw in dilute alkali solutions for 24 hours and then washing it with clean water. Straw digestibility is increased from about 40 to about 70%. While this process has been known for 50 years, it has not been much used because treatment costs are too high. Also, it cannot be industrialised. The spray process, in which the straw is wetted with an alkali solution (Wilson and Pigden, 1964) is an improvement from both points of view, but poses nutritional problems since straw is not washed after treatment. So great is the potential, however, that within the last seven years nearly 100 research reports have been published on the production and use of spray-treated straw. These reports are reviewed in this article.Straws are poorly digested by ruminants because of their high cell-wall content. Alkali treatment disrupts the cell-wall by dissolving hemicellulose, lignin and silica, by hydrolysing uronic and acetic acid esters and by swelling cellulose. Digestibility in vitro increases from about 40 to about 80% with $\text{10}\text{g NaOH}\text{100}\text{g straw}$. Equally large increases are not, however, obtained in vivo because of unreacted alkali and/or high sodium concentration. Several hypotheses concerning the depression of digestibility in vivo are reviewed. In general $\text{3–6}\text{g NaOH}\text{100}\text{g straw}$ is the optimum. For maximum effectiveness the volume of the alkali solution must be between 50 and $\text{200}\text{ml}\text{100}\text{g straw}$. The usefulness of neutralising unreacted alkali has not yet been determined. Crop and industrial residues with lower initial digestibility than straw (e.g. paddy hulls, bagasse and some types of sawdust) are usually still too poor after treatment (digestibility 30–50%) to be useful feeds. Pressure and temperature increase the effectiveness of alkali, but add to the cost of treatment. The pelleting of treated straws probably increases the effectiveness of alkali treatment. The length of time treated straw is allowed to “cure” before being fed does not affect its digestibility. Chemicals other than NaOH, like chlorine, ammonia and peroxides, are also effective in treating straws but are more expensive and/or more difficult to apply.Animal feeding experiments with sprayed straw have shown its utility for livestock normally fed poor straw diets, in high concentrate diets for growing, finishing and milking stock, and as an extender of silage. The factors affecting the degree of improvement to be expected in digestibility, growth and production from the treatment of straw need to be identified and studied.In spite of its high pH and Na content, sprayed straw has not been found to cause any health problems in livestock when treatment is in the range of 3–8 g NaOH/100 g straw. The extra sodium is excreted in the urine. Water intake and urine volume increase. Milk composition is unaffected.Several factories producing alkali spray-treated straw-based diets in pelleted form are already in operation in Europe. The process is briefly described.     

Effects of nitrogen and glucose on saprophytic survival of Ophiobolus graminis in buried straw

Calcium nitrate prolonged the saprophytic survival of Ophiobolus graminis (Sacc.) Sacc. in artificially colonized straws buried in soil in the laboratory, whether supplied to the soil (at 12·5 or 100 mg nitrogen/100 g soil) or to the straws before colonization (at 0·5 or 1·0 g nitrogen/100 g straw). Glucose (at 2·5 g/100 g soil, and at 10 g/100 g straw) shortened survival. When straws colonized in the presence of 0·5 g nitrogen/100 g straw were buried in soil supplied with 14·1 mg nitrogen/100 g soil, the level of soluble soil nitrogen reached equilibrium at 2–4mg/100g soil; this allowed rapid straw decomposition and, although the added soil nitrogen prolonged survival in straws that remained undecomposed, it also accelerated substrate exhaustion. Addition of 100 mg nitrogen/100 g soil was supra-optimal for survival: although some nitrogen was necessary for maximum survival, the equilibrium concentration of soluble nitrogen (24–56 mg/100 g soil) was high enough in this case to have an inhibitory effect in addition.     

Studies on ammonia-treated straw. II. Fixation of ammonia in treated straw by spraying with acids

Ammonia-treated barley straw (NH₃ straw) was sprayed with either formic, acetic or phosphoric acid immediately after opening the stack in order to capture the excess ammonia. The amount of acid applied was estimated to neutralize 100% of the ammonia added to the straw (30 kg NH₃/t straw). After spraying with acid the straw was stored in plastic bags for about 8 weeks at room temperature (15–20° C). When bags of NH₃ straw treated with acids were opened, there was very little smell of ammonia whereas there was a very strong smell from the bag of NH₃ straw without acid added.The nitrogen content of the straw (g/100 g DM) was for untreated straw, 0.88, NH₃ straw without acid, 2.50, and NH₃ straw with added formic acid, 3.49, acetic acid, 3.81, and phosphoric acid, 2.27. The digestibility of organic matter determined in sheep was 47.3, 60.5, 59.0, 60.4 and 51.3 following the same order as above.It is concluded that spraying NH₃ straw with organic acids effectively reduces the loss of ammonia and increases the nitrogen content of the straw. Another advantage of this is that the air pollution with ammonia which may occur in the barn when the straw is not well aired is effectively prevented.Spraying with organic acids had no negative effect on the digestibility of the straw. The nitrogen supply and the digestibility of nitrogen in the animal seemed to be markedly improved.     

Different sources of ammonia for improving the nutritive value of low quality roughages

The study was undertaken to investigate the effectiveness of anhydrous NH₃, aqueous NH₄OH and urea + urease as sources of ammonia for treating maize stover, rice and wheat straws at graded treatment rates of 0, 25 and 50 g NH₃/kg DM of roughage and at two moisture levels of 20 and 40% in all combinations in improving dry matter digestibility in vitro (IVDMD), organic matter digestibility in vitro (IVOMD) and crude protein (CP) contents when allowed to react for 15 or 30 days.Rate of ammonia was the most important factor in enhancing IVDMD, IVOMD and CP. Moisture level and days of reaction had a less important influence on the parameters measured. While anhydrous NH₃ was most effective in improving IVDMD and IVOMD of maize stover, aqueous NH₄OH had a similar effect in increasing IVDMD and IVOMD of rice and wheat straws and urea + urease was the least effective but promising. Highest responses in IVDMD and IVOMD were obtained with rice straw, followed by wheat straw and, lastly, maize stover.In a second experiment maize stover which was treated with aqueous NH₄OH at 0, 25 and 50 g NH₃/kg DM at two moisture levels of 20 and 40% was given to Black Headed Persian rams. Digestibility of DM and OM and voluntary feed intake were improved significantly (P < 0.01) by ammonia treatment and there was also a significant (P < 0.01) response to increasing moisture levels.     

The effect of an inoculant and enzymes on fermentation and nutritive value of sorghum straw silages

The objectives of this study were to determine the effect of inoculant, enzymes and inoculant-enzymes mixture on fermentation quality, nutritive value, and microbial changes of sorghum straw silage. Sorghum straws were collected and treated with distilled water (control), inoculant, enzymes and inoculant+enzymes prior to ensiling. Three bag silos for each silage (denoted C, I, E and I+E, respectively) were opened after 3, 7, 11, 15, 30 and 60 days for chemical and microbial analyses. For all the silages, there was a rapid decline in pH during the first 3 days of ensiling. Relative to silage C, all the treatment (I, E and I+E) had higher (P<0.05) lactic acid concentration at all ensiling periods. Population of LAB during all ensiling time was numerically greater for treated than control silages. Separate addition of two additives, especially for enzymes, can effectively (P<0.05) decrease aNDF and ADF concentration. Treatments with enzymes (E, I+E) can also improve significantly silage IVDMD and IVNDFD concentration. These results indicated that the addition of additives can improve the sorghum straw silage fermentation quality at different extent.