The effect of white-rot basidiomycetes on chemical composition andin Vitro digestibility of wheat straw

Five white-rot basidiomycetes were evaluated for their potential to improve ruminal degradation of wheat straw.Polyorus brumalis, Lyophyllum ulmarium III,Trametes gibbosa, Pleurotus ostreatus, and aPleurotus ostreatus mutant were incubated on wheat straw for 30 d at 28°C. Detergent fiber, crude protein andin vitro dry matter digestibility (IVDMD) were determined. The results showed increasing crude protein and ash contents in fungus-treated straw. IVDMD values were increased in straws treated withP. ostreatus, P. ostreatus mutant andT. gibbosa only. Relative to untreated wheat straw the detergent fiber content—neutral detergent fiber (NDF), and acid detergent fiber (ADF) was reduced in fungus-treated straw and out of three fractions—hemicellulose, cellulose and lignin, hemicellulose showed the largest proportionate loss whereas lignin the smallest one in all 5 samples of fungus treated straw.     

Effect of six species of white-rot basidiomycetes on the chemical composition and rumen degradability of wheat straw

This study was conducted to investigate changes in in vitro dry matter digestibility (IVDMD), volatile fatty acids (VFA) production and cell-wall constituent degradation in wheat straw treated with six white-rot fungi: Daedalea quercina, Hericium clathroides, Phelinus laevigatus, Inonotus andersonii, Inonotus obliquus, and Inonotus dryophilus. The incubation of wheat straw for 30 days at 28 C improved IVDMD from 41.4 (control) to 59.2% for D. quercina, 56.3% for H. clathroides, 50.2% for P. laevigatus, 51.4% for I. andersonii, 52% for I. obliquus, and 55.9% for I. dryophilus. In contrast, the growth of fungi was accompanied by the dry matter loss of wheat straw: 43% for D. quercina, 12% for H. clathroides, and 22-25% for the other fungi. It is evident that the increase in digestibility by D. quercina was not offset by a loss of dry matter. The total VFA production during the rumen fermentation of fungus-treated straw was slightly increased by H. clathroides and I. dryophilus only. Neutral detergent fiber (NDF) and acid detergent fiber (ADF) were reduced in fungus-treated straw. Out of the three fractions (hemicellulose, cellulose, and lignin), hemicellulose and lignin showed the largest proportionate loss after inoculation with the fungi D. quercina, H. clathroides, P. laevigatus, and I. obliquus. The other two fungi showed the largest proportionate loss in cellulose and hemicellulose contents. The results of this study suggest that the digestion enhancement of wheat straw colonized by white-rot fungi is regulated by complex factors including the degradation of structural carbohydrates and lignin.     

Effect of treatment of wheat straw with ammonia and peracetic acid on digestibility in vitro and cell wall composition

Wheat straw was treated with four levels of ammonia (0, 35, 70 and 105 g kg^?1 straw dry matter), allowed to react for five days and then treated with four levels of peracetic acid (0, 40, 80 and 120 k kg^?1 straw dry matter) for five more days. There was a 1.24 percentage unit increase in dry matter digestibility in vitro (IVDMD) with each 10.0 g of ammonia added per kg of straw dry matter. The IVDMD increased 1.01 percentage unit for each 10.0 g of peracetic acid added per kg of straw dry matter. The lignin content of the straw decreased 0.39% with each 10.0 g of peracetic acid added per kg of straw dry matter. The hemicellulose content of the straw decreased 0.82% with the addition of 10.0 g of ammonia per kg of straw dry matter. Cellulose content was not affected by the addition of peracetic acid or ammonia.The development of more economical and safe procedures which combine swelling and delignification would be very beneficial for improving the nutritive value of low quality roughages.     

Nutritive value of ensiled broiler litter for cattle

Broiler litter, consisting of bedding material (chopped wheat straw or rice hulls), excreta, wasted feed and feathers was ensiled at 40 or 50% moisture for 42 days. Cheddar cheese whey was added to adjust the moisture level in some of the silage. The dry matter digestibility in vitro (IVDMD), after 21 days of ensiling was greater for silage containing the wheat straw base than for that with the rice hull base. Whey improved the IVDMD of the wheat straw base silage but not that of the rice hull base silage. Moisture levels did not influence the IVDMD. In a second trial, broiler litter consisting of chopped wheat straw bedding, excreta, wasted feed and feathers was ensiled for 28 days at approximately 45% dry matter. The litter was ensiled as: (1) litter alone; (2) litter plus Irish potato cannery waste (IPW); (3) litter plus ground maize, and (4) litter plus ground grain sorghum. The materials added supplied 33% of the dry matter of the silages. The pH of the silages 1 and 4 weeks after ensiling was (1) 6.00, 5.83; (2) 5.00, 4.56; (3) 4.96, 4.80; and (4) 4.92, 4.78. Total faecal and urine collection trials were conducted using 12 Holstein steers having an average body weight of 200 kg. Dry matter digestibility was greater (P < 0.01) for silages 2, 3 and 4. Digestible energy and protein were 61.2, 70.6; 65.3, 74.6; 65.2, 71.2; and 68.2, 76.4% for silages 1 through 4.     

Influence of formaldehyde-treated soybean and commercial nutrient supplementation on mushroom (Pleurotus sajor-caju) yield and in-vitro dry matter digestibility of spent substrate

Summary Pleurotus sajor-caju 537 was grown on chopped, pasteurized wheat straw non-supplemented and supplemented with formaldehyde-treated soybean, commercial delayed-release nutrient (SpawnMate II SE) or vegetable oil. Yield was 2.1-fold higher for substrate supplemented (12% dry wt) with low-volume formaldehyde-treated soybean as compared to non-supplemented substrate. Mushroom yield from substrate supplemented with commercial nutrient was 1.7-fold higher than yield from non-supplemented substrate. As the supplement level increased, the mushroom yield response increased. The yield ranged from 3.56 kg/m² for non-supplemented substrate to 7.36 kg/m² for substrate supplemented (12% dry wt) with formaldehyde-treated soybean. The type of supplement affected in vitro dry matter digestibility (IVDMD) of spent substrate; commercial supplement resulted in higher IVDMD compared to formaldehyde-treated substrate. An opportunity exists for commercial development of a nutrient(s) specifically designed for Pleurotus cultivation.     

Influence of nutritional supplementation on solid-substrate fermentation of wheat straw with an alkaliphilic white-rot fungus (Coprinus sp.)

Summary The solid-substrate fermentation of wheat straw with an alkaliphilic white-rot fungus (Coprinus sp.) was found to be influenced by the levels of nitrogen, phosphorus+sulphur and free carbohydrates, in terms of biodegradation of straw ingredients, microbial protein production and changes in in-vitro dry matter digestibility (IVDMD). Nitrogen and Phosphorus+Sulphur compounds favoured the bioconversion and their optimum levels were (g/100 g DM): urea (sterile): 1.5, urea (unsterile): 3.0; superphosphate: 1.0. The addition of free carbohydrates as molasses and whey had detrimental effect on biodegradation of lignin as also on organic matter degradation and digestibility. However, the protein production was enhanced in the supplemented straw. The optimized laboratory fermentation was also extended to 4 kg-(sterile and unsterile) and 50 kg-(unsterile) fermentation.     

Solid-state fermentation,lignin degradation and resulting digestibility of wheat straw fermented by selected white-rot fungi

Summary Lignin biodegradation, carbon loss and in vitro dry matter digestibility (IVDMD) have been investigated during the solid state fermentation of wheat straw by eight previously selected strains of white-rot fungi. A mathematical model of the degradation kinetics is presented. [The time period required to reach maximum rates of ¹⁴CO₂ and unlabeled CO₂ release from (¹⁴C)-lignin-labelled wheat straw and from whole wheat straw, respectively, was generally short (6–10 days).] High rates of ¹⁴C-lignin degradation were achieved by Pycnoporus cinnabarinus (2.9% ¹⁴CO₂ evolved/day), an unidentified strain Nancon (3.0%/day), Sporotrichum pulverulentum Nov. (3.4%/day), Bjerkandera adusta (2.4%/day), and Dichomitus squalens (2.3%). However, only the latter two strains degraded whole wheat straw slowly and Bjerkandera adusta was not able to degrade more than 23% of the ¹⁴C-lignin. Cyathus stercoreus and Dichomitus squalens facilitated the highest improvement in IVDMD (68% against 38% for the sound straw) after 20 and 15 days of cultivation respectively, with low dry matter losses (15–20%). A study of the fate of ¹⁴C-lignin during fermentation using these two fungal strains showed that maximal levels of (¹⁴C)-water-soluble compounds are reached before peak levels of ¹⁴CO₂ evolution suggesting that these compounds are intermediates in lignin degradation. A possible relationship between water-soluble lignins and IVDMD improvement is discussed.     

Effects of high‐ and low‐fiber diets on fecal fermentation and fecal microbial populations of captive chimpanzees

We examined fiber fermentation capacity of captive chimpanzee fecal microflora from animals (n=2) eating low‐fiber diets (LFDs; 14% neutral detergent fiber (NDF) and 5% of cellulose) and high‐fiber diets (HFDs; 26% NDF and 15% of cellulose), using barley grain, meadow hay, wheat straw, and amorphous cellulose as substrates for in vitro gas production of feces. We also examined the effects of LFD or HFD on populations of eubacteria and archaea in chimpanzee feces. Fecal inoculum fermentation from the LFD animals resulted in a higher in vitro dry matter digestibility (IVDMD) and gas production than from the HFD animals. However, there was an interaction between different inocula and substrates on IVDMD, gas and methane production, and hydrogen recovery (P<0.001). On the other hand, HFD inoculum increased the production of total short‐chain fatty acids (SCFAs), acetate, and propionate with all tested substrates. The effect of the interaction between the inoculum and substrate on total SCFAs was not observed. Changes in fermentation activities were associated with changes in bacterial populations. DGGE of bacterial DNA revealed shift in population of both archaeal and eubacterial communities. However, a much more complex eubacterial population structure represented by many bands was observed compared with the less variable archaeal population in both diets. Some archaeal bands were related to the uncultured archaea from gastrointestinal tracts of homeothermic animals. Genomic DNA in the dominant eubacterial band in the HFD inoculum was confirmed to be closely related to DNA from Eubacterium biforme. Interestingly, the predominant band in the LFD inoculum represented DNA of probably new or yet‐to‐be‐sequenced species belonging to mycoplasms. Collectively, our results indicated that fecal microbial populations of the captive chimpanzees are not capable of extensive fiber fermentation; however, there was a positive effect of fiber content on SCFA production. Am. J. Primatol. 71:548–557, 2009. © 2009 Wiley‐Liss, Inc.     

Dilute acid pretreatment, enzymatic saccharification and fermentation of wheat straw to ethanol

Wheat straw consists of 48.57 ± 0.30% cellulose and 27.70 ± 0.12% hemicellulose on dry solid (DS) basis and has the potential to serve as a low cost feedstock for production of ethanol. Dilute acid pretreatment at varied temperature and enzymatic saccharification were evaluated for conversion of wheat straw cellulose and hemicellulose to monomeric sugars. The maximum yield of monomeric sugars from wheat straw (7.83%, w/v, DS) by dilute H₂SO₄ (0.75%, v/v) pretreatment and enzymatic saccharification (45 °C, pH 5.0, 72 h) using cellulase, β-glucosidase, xylanase and esterase was 565 ± 10 mg/g. Under this condition, no measurable quantities of furfural and hydroxymethyl furfural were produced. The yield of ethanol (per litre) from acid pretreated enzyme saccharified wheat straw (78.3 g) hydrolyzate by recombinant Escherichia coli strain FBR5 was 19 ± 1 g with a yield of 0.24 g/g DS. Detoxification of the acid and enzyme treated wheat straw hydrolyzate by overliming reduced the fermentation time from 118 to 39 h in the case of separate hydrolysis and fermentation (35 °C, pH 6.5), and increased the ethanol yield from 13 ± 2 to 17 ± 0 g/l and decreased the fermentation time from 136 to 112 h in the case of simultaneous saccharification and fermentation (35 °C, pH 6.0).     

Comparative ligninolytic and polysaccharolytic potentials of an alkaliphilic basidiomycete on native ligninocellulose

A comparison of the ligninolytic, cellulolytic and hemicellulolytic abilities of an alkaliphilic white-rot fungus. Coprinus fimetarius, on wheat straw under varying conditions of solid-substrate fermentation is presented. The extent of fractional degradation (percentage of the original dry weight of the fraction) of straw under an optimized set of cultural conditions (pH 9·0, moisture 65%, temperature 37°C, period 21 days) was in the following order: lignin (45%), cellulose (42%), hemicellulose (27%). Urea nitrogen favoured the degradation of lignin as well as cellulose and hemicellulose up to a certain level (1·5% sterile urea or 3% unsterile urea on a dry weight basis) beyond which the degradation of lignin was relatively more adversely affected than cellulose. The addition of phosphorus and sulphur was found essential for selective lignin removal. Increasing the C:N ratio by addition of free carbohydrates resulted in an overall decrease in the degradation wherein cellulose utilization was the most affected event. The pre-treatment (physical or chemical) of the substrate caused a general increase in biodegradation of lignin, cellulose and hemicellulose. The degrading activity of the fungus declined with the scaling-up of the fermentation particularly under non-sterile conditions.     

Oyster mushroom cultivation with rice and wheat straw

Cultivation of the oyster mushroom, Pleurotus sajor-caju, on rice and wheat straw without nutrient supplementation was investigated. The effects of straw size reduction method and particle size, spawn inoculation level, and type of substrate (rice straw versus wheat straw) on mushroom yield, biological efficiency, bioconversion efficiency, and substrate degradation were determined. Two size reduction methods, grinding and chopping, were compared. The ground straw yielded higher mushroom growth rate and yield than the chopped straw. The growth cycles of mushrooms with the ground substrate were five days shorter than with the chopped straw for a similar particle size. However, it was found that when the straw was ground into particles that were too small, the mushroom yield decreased. With the three spawn levels tested (12%, 16% and 18%), the 12% level resulted in significantly lower mushroom yield than the other two levels. Comparing rice straw with wheat straw, rice straw yielded about 10% more mushrooms than wheat straw under the same cultivation conditions. The dry matter loss of the substrate after mushroom growth varied from 30.1% to 44.3%. The straw fiber remaining after fungal utilization was not as degradable as the original straw fiber, indicating that the fungal fermentation did not improve the feed value of the straw.     

Digestibility of diets containing increasing levels of NaOH-treated or untreated wheat straw

Sodium hydroxide-treated or untreated wheat straw was included in a basal alfalfamaize diet at 0, 10, 20 and 40%. As the level of straw increased, the apparent digestibility of dry matter (DM) and organic matter (OM) by sheep, decreased linearly (P < 0.01), with a faster decrease (P < 0.05) for diets containing untreated straw. The digestibility of DM decreased by 0.22 and 0.41% and OM by 0.24 and 0.42% for treated and untreated straw diets, respectively, with each 1% increase of straw in the diets.Addition of treated straw increased (P < 0.05) digestibility of cell wall constituents (CWC), acid detergent fibre (ADF) and hemicellulose (HC). However, when untreated straw was added, the digestibility of HC was reduced, whereas the digestibility of CWC and ADF was dependent on the level of straw added. Increasing levels of NaOH-treated straw in the diets produced linear increases (P < 0.05) in digestibility of CWC, ADF and HC. However, significant (P < 0.05) linear or quadratic responses were not noted in the digestibility of CWC, ADF and HC with increasing levels of untreated straw in the diet. Apparent digestibility of crude protein was not affected by addition of either NaOH-treated or untreated straw to the diet.In general, although changes in nutrient digestibility of the basal component small, large changes in the digestibility of nutrients in the straw component were apparent and accounted for the major differences in digestibility of the diets. The absence of curvilinearity in the regression equations suggested that there were no associative effects.     

木质纤维素的定量测定及降解规律的初步研究

为了准确地测定稻草及其发酵物中纤维素、半纤维素、木质素的含量,通过差重法进行定量测定,并以此评价白腐菌株Pleurotus sapidus对稻草秸秆的降解状况,结果表明：利用差重法测定稻草发酵物中纤维素、半纤维索、木质素的百分含量是可行的,并能很好地评价白腐菌对稻草的降解规律,即降解过程中纤维素、半纤维素、本质素在前20d降解的很快,之后降解减缓,在50d内,纤维素被降解34．02％,半纤维素被降解56．29％,木质素被降解61．65％。     

Studies on ammonia-treated straw. I. The effects of type and level of ammonia,moisture content and treatment time on the digestibility in vitro and enzyme soluble organic matter of oat straw

Oat straw containing 2.5, 5.0, 7.5 and 10.0% moisture was treated with anhydrous or aqueous ammonia at 20 and 40 g NH₃/kg dry matter for 3 and 6 weeks at room temperature (17–20° C). Samples were milled and used for determinations of digestibility of dry matter in vitro (IVDMD) and of organic matter (IVOMD) and also enzyme solubility (ESOM).The moisture contents of the straw after treatment corresponded fairly well with those planned. Both types of ammonia improved the IVDMD, IVOMD and ESOM of the straw as compared with the untreated samples. However, aqueous ammonia caused significantly higher improvements than did anhydrous ammonia. The averages of IVDMD, IVOMD and ESOM of the straw were 61.9, 64.2 and 25.6 with aqueous ammonia, and 54.7, 57.4 and 18.9 with anhydrous ammonia.The 40 g kg^?1 level of ammonia was more effective than the 20 g kg^?1 level; this trend was more clear with aqueous than with anhydrous ammonia. The effects of both types of ammonia were more pronounced at 6 weeks than at 3 weeks.The results showed that treatment with 40 g kg^?1 aqueous ammonia for 6 weeks improved the IVDMD, IVOMD and ESOM to 69.4, 71.7 and 33.4, respectively. However, anhydrous ammonia in the same conditions gave values of 58.3, 61.2 and 22.2, respectively. The ammonia treatment was less effective at low than at higher moisture contents, particularly with anhydrous ammonia.It was concluded that maximal improvement in the nutritive value of the oat straw was obtained when straw containing 7.5% moisture was treated with 40 g kg^?1 aqueous ammonia for 6 weeks. With this treatment values for IVDMD, IVOMD and ESOM of oat straw were 72.5, 74.5 and 35.5, respectively.     

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.     

Cultivation of oyster mushrooms on wheat straw and bagasse substrate amended with distillery effluent

Summary Molasses-based distilleries produce large quantities of dark coloured effluent, which is a major cause of environmental pollution. An experiment was conducted to investigate the efficacy of distillery effluent amendment for edible mushroom production. Three species of oyster mushroom, namely Pleurotus florida Eger (EM 1303), Pleurotus pulmonarius (Fries) Quelet (EM 1302) and Pleurotus sajor-caju (Fries) Singer (EM 1304) were grown on wheat straw (variety UP 2338) and bagasse amended with post-anaerobic distillery effluent, a high organic load wastewater with high biochemical oxygen demand and chemical oxygen demand. Three different levels of effluent treatment were applied to bagasse and wheat straw. Wheat straw was found to be the preferred substrate and showed better results than bagasse in all treatments with respect to yield, biological efficiency (BE) and dry matter loss. P. florida (EM 1303) and P. pulmonarius (EM 1302) gave significantly enhanced yield with increasing levels of effluent, with BE reaching highest at 238.6% for P. florida (EM 1303). Using bagasse as a substrate, P. sajor-caju (EM 1304) and P.␣pulmonarius (EM 1302) exhibited a decreasing trend as compared to control. However, the effect of effluent concentrations did not influence yield and BE significantly in case of bagasse. The dry matter loss of the substrate varied from 9.4% to 53.4% in wheat straw and 17.5% to 45.2% in bagasse respectively.     

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.     

Optimization of cultivation and nutrition conditions and substrate pretreatment for solid-substrate fermentation of wheat straw byCoriolus versicolor

Bioconversion of wheat straw by solid-substrate fermentation (SSF) withCoriolus versicolor was optimized by varying its physiological parameters. Selective delignification (more lignin than holocellulose degradation) and increases in crude protein (CP) content andin vitro dry matter digestibility (IVDMD) were taken as the criteria to select optimum levels of these parameters. The fungus behaved optimally under the following set of cultural and nutritional conditions: pH 5.5, moisture level 55%, temperature 30 °C, duration of fermentation 21 d, form of inoculum—grain culture, turning frequency—once at mid-incubation, urea (nitrogen source) 1.5% (sterile) or 3.0% (nonsterile), single superphosphate (phosphorus+sulfur source) 1.0%, no addition of free polysaccharides (as whey or molasses). A maximum of 17.5% increase in IVDMD involving 4.3% degradation of lignin, was attained in the optimized SSF under laboratory conditions. The digestibility improvement could be further increased by using a substrate preteatment (physical/chemical/biological) in the following order of preference: NaOH treatment, urea or urine treatment, ensiling, steaming, grinding. For practical farm applications, urea treatment and ensiling appeared most feasible. The laboratory optimized process was also scaled up to 4 kg (sterile and unsterile) and 50 kg (unsterile) fermentations.     

Ammoniation of wheat straw and native grass hay during baling of large round bales

Wheat straw and native grass hay were treated with anhydrous ammonia during baling with a large round baler. In Experiment 1, ammonia (3.2 and 7.1% w/w of straw DM) was applied by use of a Cold-flow Converter to wheat straw that either had not been sprayed or had been sprayed with one of two rates of water as it passed over the pick-up frame of the baler. Straw water concentrations immediately after baling were 13.8 and 23.8%, respectively, for the low and high rates of water application. Straw water concentrations were about 12 percentage units lower than anticipated, and indicate that water penetration of the hard cuticular surface of the straw was low. Treatment with 3.2% ammonia of straw not sprayed with water increased the crude protein content from 3.2 to 5.7% immediately after baling. However, none of the ammonia-nitrogen (NH₃-N) was retained 45 days after baling, and dry matter digestibility in vitro (IVDMD) of the straw was not increased. Straw that was treated with low levels of both ammonia and water contained 6.0% crude protein after storage, and IVDMD increased 27% (i.e., 36.7 vs. 28.9%; P < 0.001). Retention of NH₃-N after storage ranged from ?1.4 (low level of ammonia and no added water) to 14.8% (low level of both ammonia and water) and was increased (P < 0.001) by added water at the low level of ammonia application.The effects of crimping wheat straw during baling and addition of a surfactant (0.2% v/v) to aqua-ammonia on crude protein content, retention of NH₃-N and the IVDMD of straw were studied in Experiment 2. Water content of ammoniated straw in Experiment 2 (ca.14%) was similar to that of straw sprayed with the low level of water in Experiment 1. Crimping did not visibly disrupt the surface of the straw, nor affect crude protein content or IVDMD. Addition of surfactant to the aqua-ammonia increased (P < 0.01) the crude protein content after storage of non-crimped and crimped straw, respectively, by 0.3 and 1.5 percentage units (P < 0.05 for crimping by surfactant interaction). Straw IVDMD was not increased by either crimping or addition of surfactant to the aqua-ammonia. Retention of NH₃-N after storage, which ranged from 26 to 49%, was greater than that of Experiment 1, and was attributed to the lower level of ammonia application (1.7% of straw DM). Native grass hay readily adsorbed aqua-ammonia. Water content of the hay was increased from 12.2 to 28.7%, and the crude protein content was increased from 4.4 to 13.9% by ammoniation. The studies indicate that while ammoniation of crop residues during the baling operation is a possible means of treatment, low retention of NH₃-N remains a problem. Disruption of the hard cuticular surface of residues such as wheat straw may improve penetration of aqua-ammonia and therefore the effectiveness of treatment.     

Delignification of Wheat Straw by Pleurotus spp. under Mushroom-Growing Conditions

Pleurotus sajor-caju, P. sapidus, P. cornucopiae, and P. ostreatus mushrooms were produced on unsupplemented wheat straw. The yield of mushrooms averaged 3.6% (dry-weight basis), with an average 18% straw weight loss. Lignin losses (average, 11%) were lower than cellulose (20%) and hemicellulose (50%) losses. The cellulase digestibility of the residual straw after mushroom harvest was generally lower than that of the original straw. It does not appear feasible to simultaneously produce Pleurotus mushrooms and a highly delignified residue from wheat straw.