Effect of compounds released during pretreatment of wheat straw on microbial growth and enzymatic hydrolysis rates

In the process of producing ethanol from lignocellulosic materials such as wheat straw, compounds that can act inhibitory to enzymatic hydrolysis and to cellular growth may be generated during the pretreatment. Ethanol production was evaluated on pretreated wheat straw hydrolysate using four different recombinant Saccharomyces cerevisiae strains, CPB.CR4, CPB.CB4, F12, and FLX. The fermentation performance of the four S. cerevisiae strains was tested in hydrolysate of wheat straw that has been pretreated at high dry matter content (220 g/L dry matter). The results clearly showed that F12 was the most robust strain, whereas the other three strains were strongly inhibited when the fraction of hydrolysate in the fermentation medium was higher than 60% (v/v). Furthermore, the impact of different lignin derivatives commonly found in the hydrolysate of pretreated wheat straw, was tested on two different enzyme mixtures, a mixture of Celluclast 1.5 L FG and Novozym 188 (3:1) and one crude enzyme preparation produced from Penicillium brasilianum IBT 20888. From all the potential inhibiting compounds that were tested, formic acid had the most severe influence on the hydrolysis rate resulting in a complete inactivation of the two enzyme mixtures.     

多年生黄精不同龄节物质累积和多糖分布特征

多糖是黄精主要活性成分类型之一.通过对陕南汉中黄精实验基地多年生黄精不同龄节干物质重量、折干率、溶出物量及糖含量等进行测定分析,研究黄精不同龄节干物质累积和多糖分布特征.结果表明,各龄节水溶出物量比相应的醇溶出物量高得多,各龄节多糖含量比相应的醇溶性糖含量高得多.随着生长时间延长,单节干物质重量、水溶出物量、多糖含量等在2-4年龄节间变化最大,生长年限再延长,单节各指标下降明显.1-3年龄节品质稳定,黄精干物质累积总量逐年增多,因此确定当地黄精的最佳采收时间为种后3年.这些结果为当地黄精的规范化生产提供了理论依据.     

Rheological characterization of dilute acid pretreated softwood

Large-scale bioethanol production from lignocellulosic biomass will require high solids loading in the enzymatic hydrolysis step. However, slurries of pretreated lignocelluloses are complex fluids due to the fibrous nature, especially at high concentrations of water insoluble solids (WIS). A prerequisite for dealing with transport issues and for developing efficient full-scale processes is a fundamental understanding of the flow properties of pretreated lignocellulose. A comprehensive rheological characterization of dilute acid pretreated spruce has been carried out in this study, accounting for the effects of WIS concentration, particle size distribution (PSD), and the degree of enzymatic hydrolysis. The rheology of pretreated spruce slurries was found to be strongly dependent on the WIS concentration. The storage modulus (G'(LVR)) and yield stress showed typical power-law dependencies on volume fraction and WIS content. Milling of the pretreated material resulted in significantly higher yield stress and viscosity, likely due to narrower PSD, which suggests that the strength of the network of the coarsest fibers determines the rheology of these materials to a large extent. During enzymatic hydrolysis, yield stress and viscosity decreased dramatically, partly due to decreasing WIS content, but possibly also due to changes in fiber properties such as the chemical composition.     

Organic matter availability during pre- and post-drought periods in a Mediterranean stream

Mediterranean streams are characterized by water flow changes caused by floods and droughts. When intermittency occurs in river ecosystems, hydrologic connectivity is interrupted and this affects benthic, hyporheic and flowing water compartments. Organic matter use and transport can be particularly affected during the transition from wet to dry and dry to wet conditions. In order to characterize the changes in benthic organic matter quantity and quality throughout a drying and rewetting process, organic matter, and enzyme activities were analyzed in the benthic accumulated material (biofilms growing on rocks and cobbles, leaves, and sand) and in flowing water (dissolved and particulate fractions). The total polysaccharide, amino acid, and lipid content in the benthic organic matter were on average higher in the drying period than in the rewetting period. However, during the drying period, peptide availability decreased, as indicated by decreases in leucine aminopeptidase activity, as well as amino acid content in the water and benthic material, except leaves; while polysaccharides were actively used, as indicated by an increase in β-glucosidase activity in the benthic substrata and an increase in polysaccharide content of the particulate water fraction and in leaf material. During this process, microbial heterotrophs were constrained to use the organic matter source of the lowest quality (polysaccharides, providing only C), since peptides (providing N and C) were no longer available. During the flow recovery phase, the microbial community rapidly recovered, suggesting the use of refuges and/or adaptation to desiccation during the previous drought period. The scouring during rewetting was responsible for the mobilization of the streambed and loss of benthic material, and the increase in high quality organic matter in transport (at that moment, polysaccharides and amino acids accounted for 30% of the total DOC). The dynamics of progressive and gradual drought effects, as well as the fast recovery after rewetting, might be affected by the interaction of the individual dynamics of each benthic substratum: sand sediments and leaves providing refuge for microorganisms and organic matter storage, while on cobbles, an active bacterial community is developed in the rewetting. Since global climate change may favor a higher intensity and frequency of droughts in streams, understanding the effects of these disturbances on the materials and biota could contribute to reliable resource management. The maintenance of benthic substrata heterogeneity within the stream may be important for stream recovery after droughts.     

Effect of thermal pretreatment on equilibrium moisture content of lignocellulosic biomass

The equilibrium moisture content (EMC) of raw lignocellulosic biomass, along with four samples subjected to thermal pretreatment, was measured at relative humidities ranging from 11% to 97% at a constant temperature of 30 °C. Three samples were prepared by treatment in hot compressed water by a process known as wet torrefaction, at temperatures of 200, 230, and 260 °C. An additional sample was prepared by dry torrefaction at 300 °C. Pretreated biomass shows EMC below that of raw biomass. This indicates that pretreated biomass, both dry and wet torrefied, is more hydrophobic than raw biomass. The EMC results were correlated with a recent model that takes into account additional non-adsorption interactions of water, such as mixing and swelling. The model offers physical insight into the water activity in lignocellulosic biomass.     

Drying of Tribenuron,a Thermosensitive Biochemical

The extension of microwave use in the biochemical industry was explored by drying tribenuron, a thermosensitive biochemical, in a microwave oven and in a thermal vacuum oven. Tribenuron wet cakes, containing a mixture of solvents, methanol and water, were heated at 40 °C in both ovens. Nitrogen purge was used to prevent the decomposition of tribenuron from prolonged heating. Microwave heating dried tribenuron in twenty minutes while the vacuum oven heating required eighteen hours to dry the wet cakes. In addition, the tribenuron quality was maintained under microwave drying, but deteriorated in the thermal vacuum oven. Therefore, microwave technology is more effective in drying tribenuron than conventional vacuum ovens. The results of this study are important for the use of microwave drying on a large scale in biochemical companies.     

Acid hydrolysis of fibers from dairy manure

Concentrated acid hydrolysis of lignocellulosic materials is a conventional treatment process for the production of mono-sugars. However, this method has been proved ineffective and undesirable for the treatment of dairy manure due to the high nitrogen content of dairy manure and the environmental issues caused by the use of highly concentrated acid solution. In an effort to overcome these barriers, a modified acid hydrolysis process with short reaction time was introduced that involved a nitrogen-removing pretreatment followed by decrystallization with concentrated acid and then hydrolysis using dilute acid. The effects of nitrogen, acid concentration, reaction time, and temperature were investigated. A pretreated manure with a low nitrogen content of 1.3% was used as the substrate. The results indicated that the optimal conditions for fiber decrystallization were 75% acid concentration, 3:5 sample to acid ratio (weight basis), and 30 min of reaction time; while the optimal conditions for acid hydrolysis were 12.5% acid and 10% dry sample at 135 degrees C for 10 min. These conditions produced 26 g/L glucose at a yield of 84% and 11 g/L hemicellulose-sugars at a yield of 80%.     

金沙江干热河谷人工植被土壤水环境

金沙江干热河谷异常干热的气候特点,普遍存在水分亏缺问题,人工植被土壤水环境问题比其它干旱、半干旱地区更加突出．在干热河谷典型地段——元谋的试验观测表明,现有的乔木林明显表现出“土壤干化”的特点,土壤水分持续长时间亏缺,雨季结束之后的11月份。2m土层内的土壤含水量只有15％(相当于田间持水量的35％)左右,之后持续下降,直到5月份达到最低点(9％左右),几乎接近林木的凋萎湿度(元谋表蚀燥红壤的凋萎湿度为9．O％)．由此而导致林木生长缓慢．车桑子(Radonaea wiscosa)灌木林同层土壤含水率相对比乔木林高42．68％,自然草坡的土壤水分明显优于乔木和灌木林,分别比乔木林和灌木林高34．36％和22．22％．这种人工乔木林的“土壤干化”问题在干热河谷地区的植被恢复中还没有引起重视,将极大地制约人工植被的可持续发展．     

Rates of Respiration and of Increase in Structural Dry Matter in Young Wheat, Ryegrass and Maize Plants in Relation to Temperature, to Water Stress and to Their Sugar Content

A method to determine the rate of conversion of reserve materialsinto structural dry matter in living, whole plants is presented.It is based on a brief measurement of plant respiration. Therate of increase in structural dry matter and of decrease ofreserve materials is calculated by subtracting the maintenancerespiration component from the total respiration. The remainder,the growth respiration rate, is multiplied by a factor thatis derived from the biochemical composition of the structuraldry matter formed. This method is applied to determine the relations of the rateof conversion of reserve material into structural dry matterto temperature, water stress and the level of reserve carbohydratesin plants of three species. The weakest part of the method is in the determination of therate of maintenance respiration. Consequences of different assumptionsconcerning the rate of adjustment of this respiration componentto modified environmental conditions are discussed. Lolium perenne L, Triticum aestivum L, Zea mays L, ryegrass, wheat, maize, respiration, maintenance respiration, water stress, sugar content, structured dry matter     

Changes in root hydraulic conductivity for two tropical epiphytic cacti as soil moisture varies

The tropical epiphytic cacti Epiphyllum phyllanthus and Rhipsalis baccifera experience extreme variations in soil moisture due to limited soil volumes and episodic rainfalls. To examine possible root rectification, whereby water uptake from a wet soil occurs readily but water loss to a dry soil is minimal, responses of root hydraulic conductivity (L_p) to soil drying and rewetting were investigated along with the underlying anatomical changes. After 30 d of soil drying, L_p decreased 50%–70% for roots of both species, primarily because increased suberization of the periderm reduced radial conductivity. Sheaths composed of soil particles, root hairs, and mucilage covered young roots and helped reduce root desiccation. Axial (xylem) conductance increased during drying due to vessel differentiation and maturation, and drought-induced embolism was relatively low. Within 4 d of rewetting, L_p for roots of both species attained predrought values; radial conductivity increased for young roots due to the growth of new branch roots initiated during drying and for older roots due to the development of radial breaks in the periderm. The decreases in L_p during drought reduced plant water loss to a dry soil, and yet maximal water uptake and transpiration occurred within a few days of rewetting, helping these epiphytes to take advantage of episodic rainfalls in a moist tropical forest.     

Effects of oven- or freeze-drying on chemical composition and NIR spectra of pasture silage

In order to assess effects of drying method on chemical composition and NIR spectra of pasture silage, 20 samples of silages from permanent pastures of different qualities were subsampled and dried either by forced draught oven at 65°C or freeze-dried. Samples were analysed for crude protein (CP), crude fibre (CF), neutral detergent fibre (NDF), acid detergent fibre (ADF), gross energy (GE) and in vitro digestible organic matter in the dry matter (DOMD) and composition expressed on a dry-matter (DM) basis, either obtained as oven 105°C DM (DM_105°) or toluene DM (DM_tol). Effects of the drying method on chemical composition were estimated by paired comparisons. Near-infrared reflectance (NIR) spectra were taken and the difference spectra between treatments for each sample were plotted in order to visually inspect effects of treatments, either as log 1/R or transformed by their first derivative. Principal components explaining spectral variability were computed and samples graphically displayed according to the eigenvalues of the first (1 and 2), or second (2 and 3) pairs of principal components. Oven-drying resulted in a reduction in CP (p<0.02) content and an increase in CF (p<0.1), NDF (p<0.001) and ADF (p<0.06) content of silages, when expressed on a DM_105° basis. When expressed on a DM_tol basis, a reduction in CP (p<0.02) and DOMD (p<0.06) content was observed with oven drying, but fibre fractions were not affected (p>0.1). Effects of the drying treatment were visually apparent on NIR spectra when plotted as log 1/R against wavelengths, mainly as a baseline shift. Difference spectra (OD − FD), both as log 1/R and its first derivative, showed consistent absorption bands, indicative of different molecular responses of OD and FD silages to incident light. Plotting samples according to eigenvalues of the first two or second two principal components suggests that drying methods affect the distribution of samples. This is also indicative of an effect of drying treatment on spectral features and reinforces the general advice that sample processing should be consistent in order to avoid adding errors to NIR analysis.     

Biomass‐water interactions correlate to recalcitrance and are intensified by pretreatment: An investigation of water constraint and retention in pretreated spruce using low field NMR and water retention value techniques

The underlying mechanisms of the recalcitrance of biomass to enzymatic deconstruction are still not fully understood, and this hampers the development of biomass based fuels and chemicals. With water being necessary for most biological processes, it is suggested that interactions between water and biomass may be key to understanding and controlling biomass recalcitrance. This study investigates the correlation between biomass recalcitrance and the constraint and retention of water by the biomass, using SO₂ pretreated spruce, a common feedstock for lignocellulosic biofuel production, as a substrate to evaluate this relationship. The water retention value (WRV) of the pretreated materials was measured, and water constraint was assessed using time domain Low Field Nuclear Magnetic Resonance (LFNMR) relaxometry. WRV increased with pretreatment severity, correlating to reduced recalcitrance, as measured by hydrolysis of cellulose using commercial enzyme preparations. Water constraint increased with pretreatment severity, suggesting that a higher level of biomass‐water interaction is indicative of reduced recalcitrance in pretreated materials. Both WRV and water constraint increased significantly with reductions in particle size when pretreated materials were further milled, suggesting that particle size plays an important role in biomass water interactions. It is suggested that WRV may be a simple and effective method for measuring and comparing biomass recalcitrance. © 2016 American Institute of Chemical Engineers Biotechnol. Prog., 33:146–153, 2017     

Spore survival during batch dry rendering of abattoir waste.

Normal batch dry rendering practice does not ensure sterile products, because bacterial spores are protected against thermal denaturation by the high fat-low water content environment which results from drying the materials at temperatures below those required for sterilization.     

Spore survival during batch dry rendering of abattoir waste.

Normal batch dry rendering practice does not ensure sterile products, because bacterial spores are protected against thermal denaturation by the high fat-low water content environment which results from drying the materials at temperatures below those required for sterilization.     

A rapid method for the determination of microbial biomass by dry weight using a moisture analyser with an infrared heating source and an analytical balance

Aims: Microbial biomass is an important biotechnological parameter. The traditional method for its determination involves an oven‐drying step and equilibration to room temperature before weighing, and it is tedious and time consuming. This work studied the utilisation of a moisture analyser consisting of an efficient infrared‐heating module and an analytical balance for the determination of microbial biomass by dry weight. Methods and Results: The method duration depended on the sample volume and was between 7 and 40 min for sample volumes of 1–10 ml. The method precision depended on the total dry weight analysed – 10 mg of total dry weight being sufficient to achieve coefficients of variation of 5% or less. Comparison with the conventional oven method provided a correlation coefficient r² of 0·99. The recovery of an internal standard ranged between 94·2 and 106·4% with a precision of 1·39–4·53%CV. Conclusions: Validation revealed sufficient method accuracy, precision and robustness and was successfully applied to the study of yeast and bacterial growth kinetics. Techniques are discussed that allow for increased method precision at low biomass concentrations, and equations are provided to estimate required drying time and method precision based on sample volume and total sample dry weight, respectively. Significance and Impact of the Study: This work presents a rapid method for the determination of microbial biomass, allowing for the timely implementation of biomass‐based information in biotechnological and laboratory protocols.     

Minimizing Ergosterol Loss during Preanalytical Handling and Shipping of Samples of Plant Litter

Common preliminary treatments of samples of decaying material can involve changes in water content (e.g., via storage in relatively dry air or rinsing) that could conceivably result in loss or gain of fungal membranes and, consequently, ergosterol. A related problem is that collecting of ergosterol content data from widely distributed locales by shipment of samples ideally requires an inexpensive, safe alternative to submerging the samples in methanol for prevention of ergosterol loss. Experimental testing showed that fungal occupants of decaying salt marsh grass leaves did not exhibit loss or gain of ergosterol during air drying (to a water potential of <-8 MPa) or rewetting (to -0.8 MPa). Wet leaves of one grass species (Juncus roemerianus, black needlerush) could be fixed and dried for shipment by microwaving, or by fully drying after alcoholic or pentane fixation, without ergosterol loss, but those of smooth cordgrass (Spartina alterniflora) lost about 40% of their ergosterol content by all three of these drying methods. Ergosterol content of wet leaves of cordgrass could be maintained by alcoholic fixation and subsequent drying down to a thin film of alcohol.     

Survival of alginate-entrapped cells of Azospirillum lipoferum during dehydration and storage in relation to water properties

Survival of alginate-entrapped cells of Azospirillum lipoferum was studied during dehydration using a dry air stream and during prolonged storage at various constant water activity values (a_w). During the drying operation, the viability loss remained almost constant from the initial water content to 0.35 g water/g dry weight (DW) corresponding to a 98.5% water removal, strongly increased until a water content of 0.25 g/g DW and then stopped until the end of the drying operational (final a_w 0.18). A water content of 0.25 g/g DW (a_w=0.55) corresponded to the critical point of the moisture sorption isotherm curve from which water became restricted to the dry material. A high drying rate (5 g/g DW per hour) was shown to be more detrimental for cell viability than a low drying rate (1.18 g/g DW per hour). When the product was stored in a closed chamber with a regulated a_w (0.23), the number of living cells decreased during a short period (less than 15 days) corresponding to the product a_w stabilization, and then remained constant for more than 150 days. In addition, cell survival during storage was not affected by a_w values in the range 0–0.55. Above a_w=0.55, the higher the a_w and the storage duration, the lower the residual survival percentage. The influence of the drying and storage conditions on the cell death rate are discussed with regard to both the mechanisms generally involved in viability loss and the hydration properties of water. Correspondence to: A. Pareilleux     

Evaluation of a rotary drum drier processing pre-dried chicken manure

Pre-dried manure from laying hens was processed discontinuously in a rotary drum drier. During 6 drying experiments the technical performance and the operation were investigated. Special attention was given to the environmental aspects of the drying process.The dried end-product with a 90% dry matter content qualified as a completely sanitized organic fertilizer of high value. About 10 tonnes of fresh material with 35% dry matter could be processed in one drying cycle of about 20 h, including 2 h for filling and emptying. The installation was safe and operated fully automatically. A high thermal efficiency of ca. 85% was noted.Chemical and sensory analyses were performed on the rotary drier emissions. The characteristics of the emissions met the regulations concerning the maximum allowable concentrations as stated in the West German legislation.Preliminary economic evaluations indicated that the feasibility of drying chicken manure was determined by the dry matter content of the fresh manure, the price of this manure, the utilized capacity of the drier and the price of the end-product.     

Limitations of using the D-glucose oxidase peroxidase method for measuring glucose derived from lignocellulosic substrates

Summary The reproducibility of the glucose oxidase peroxidase method for assaying for -glucosidase activity was shown to be influenced by the nature of the lignocellulosic substrate on which the cellulolytic fungi was grown. When culture filtrates from various pretreated aspenwood and wheat straw fractions were added to the glucose oxidase assay they all decreased the detected glucose values. It appears that various lignocellulosic components influence the assay although lignin derived materials appeared to be the major inhibitors.     

顺磁物质对土壤低场核磁共振信号特征及含水量测定的影响

核磁共振(NMR)技术由于具有高效快速、不破坏土壤结构且对人体无害等优点,逐渐被应用到土壤学相关领域研究中。然而,土壤中顺磁物质的存在对核磁共振信号特征的影响仍不明确。本研究旨在揭示顺磁物质对不同类型土壤低场核磁共振(LF-NMR)信号特征和土壤含水量测定的影响。结果表明:土壤水的LF-NMR信号量最高可达150左右,土壤矿物、有机质和微生物等固相物质的LF-NMR信号量基本不超过0.3,相对可以忽略。质地和顺磁物质对土壤水的LF-NMR信号量测量有更大影响。LF-NMR仪器存在弛豫时间监测盲区,信号量损失主要是由于顺磁物质加速了水中氢质子的弛豫过程,导致小孔隙中水分反馈的极快的LF-NMR信号不能被监测设备捕获。对于顺磁物质含量较少的壤性潮土(1.2%)和黏壤性黑土(1.3%),LF-NMR信号量损失不大,其与土壤含水量呈线性关系;但对于黏粒含量(45.3%)和顺磁物质含量(4.0%)较高的黏性红壤,测定中会损失一部分LF-NMR信号量,监测到的LF-NMR信号量与土壤含水量不再呈线性关系。此外,外源添加顺磁物质(3.0 g·L^-1的MnCl₂溶液)也会降低黑土和红壤中可被监测的LF-NMR信号量,黑土和红壤的信号量最大损失率分别为41.0%和46.7%,极大地改变其与土壤含水量之间的定量关系。因此,在利用LF-NMR测量富含顺磁物质(>1.3%)或有外源顺磁物质进入的黏性土壤的含水量时,应先通过校正降低顺磁物质等对LF-NMR信号量的影响。研究结果对利用低场核磁共振技术准确分析土壤水分分布及土壤孔隙结构具有重要意义。