Utilization and management of organic wastes in Chinese agriculture: Past, present and perspectives

Recycling and composting of organic materials such as animal waste, crop residues and green manures has a long tradition in China. In the past, the application of organic manures guaranteed a high return of organic materials and plant mineral nutrients and thus maintained soil fertility and crop yield. As a result of rapid economic development coupled with the increasing urbanization and labour costs, the recycling rate of organic materials in Chinese agriculture has dramatically declined during the last two decades, in particular in the more developed eastern and southeastern provinces of China. Improper handling and storage of the organic wastes is causing severe air and water pollution. Because farmers are using increasing amounts of mineral fertilizer, only 47% of the cropland is still receiving organic manure, which accounted for 18% of N,28% of P and 75% of K in the total nutrient input in 2000. Nowadays, the average proportion of nutrients (N+P+K) supplemented by organic manure in Chinese cropland is only 35% of the total amount of nutrients from both inorganic and organic sources.In China, one of the major causes is the increasing de-coupling of animal and plant production.This is occurring at a time when "re-coupling" is partly being considered in Western countries as a means to improve soil fertility and reduce pollution from animal husbandry. Re-coupling of modern animal and plant production is urgently needed in China. A comprehensive plan to develop intensive animal husbandry while taking into account the environmental impact of liquid and gaseous emissions and the nutrient requirements of the crops as well as the organic carbon requirements of the soil are absolutely necessary. As a consequence of a stronger consideration of ecological aspects in agriculture, a range of environmental standards has been issued and various legal initiatives are being taken in China. Their enforcement should be strictly monitored.     

超高温堆肥促进氮素减损的微生物机制研究进展

堆肥中氮的循环在很大程度上依赖微生物驱动的氮素转化。传统高温堆肥最高堆温普遍在55-60℃,温度的提高有利于缩短堆肥周期和提高堆肥品质。超高温堆肥作为近年来快速发展的新兴技术,不但能突破传统堆肥工艺堆温低的局限,并且持续的超高温调控了堆肥微生物组、堆肥环境与氮素的互作,减少了氮素的损失。本文综述了堆体的氮循环过程及超高温堆肥技术在保氮方面的显著优势,以及超高温堆肥过程中具有氮代谢功能的优势微生物种群及其影响因素,重点介绍有关超高温堆肥控制氮素损失的作用机制研究进展,同时对超高温堆肥现有研究中存在的问题进行分析并探讨解决途径。     

一株分离自绿化废弃物堆肥枯草芽孢杆菌的常压室温等离子诱变及其发酵条件

【背景】为了提高堆肥降解有机废弃物的效率,高效堆肥菌剂成为了研究热点,其中以真菌应用的研究为多,但真菌也有对氧气和底物敏感等缺点,细菌对堆肥的作用开始被研究。本实验室以羧甲基纤维素钠(CMC-Na)为底物,从绿化废弃物堆肥中筛选得到枯草芽孢杆菌(Bacillussubtilis,B.subtilis) BL03,它具有较好的纤维素分解能力,能提高绿化废弃物堆肥中纤维素降解和腐殖质合成的速度。【目的】进一步提高B.subtilisBL03的纤维素酶生产能力。【方法】利用常压室温等离子(Atmospheric and room temperature plasma,ARTP)诱变BL03菌,通过CMC-刚果红固体培养基观察水解透明圈,以及液体发酵后检测酶活力的方法进行3轮筛选;通过连续多代培养观察突变株的遗传稳定性;通过梯度温度、p H培养研究突变株发酵的最适生长温度、培养基初始pH;利用正交设计方法研究适合突变株发酵培养的工业级原料配方。【结果】筛选到2株正突变株,酶活力分别提高了69%和72%;连续10代培养稳定,验证了突变株的遗传稳定性;其中酶活力最高的突变株BLA3890最适培养温度为37°C、培养基初始pH为5.0-6.5,研究得到较经济的发酵培养基配方。【结论】ARTP诱变B. subtilis BL03后得到的突变株BLA1973和BLA3890在绿化废弃物堆肥或其他纤维素降解行业具有进一步研究和应用的价值。     

The Use of the Microcomposter to Study the Dynamics of a Mini-Ecosystem

In this activity, students learn about the important topic of invasive species, specifically Zebra Mussels. Students role-play different characters in a real-life situation: the trial of the Zebra Mussel for unlawful disruption of the Great Lakes ecosystem. Students will also learn about jurisprudential inquiry by examining the trial process. This activity will reinforce important knowledge and skills underscored in the Life Science and Science in Personal and Social Perspectives Standards in the National Science Education Standards (National Research Council 1996).     

Utilization of Bacillus sp. strain TAT105 as a biological additive to reduce ammonia emissions during composting of swine feces

Bacillus sp. strain TAT105 is a thermophilic, ammonium-tolerant bacterium that grows assimilating ammonium nitrogen and reduces ammonia emission during composting of swine feces. To develop a practical use of TAT105, a dried solid culture of TAT105 (5.3 × 10⁹ CFU/g of dry matter) was prepared as an additive. It could be stored for one year without significant reduction of TAT105. Laboratory-scale composting of swine feces was conducted by mixing the additive. When the additive, mixed with an equal weight of water one day before use, was added to obtain a TAT105 concentration of above 10⁷ CFU/g of dry matter in the initial material, the ammonia concentration emitted was lower and nitrogen loss was approximately 22% lower in the treatment with the additive than in the control treatment without the additive. The colony formation on an agar medium containing high ammonium could be used for enumeration of TAT105 in the composted materials.     

Decrease of enteric micro-organisms from rural sewage sludge during their composting in straw mixture

AIMS: To study the decrease of enteric micro-organisms including viable nematode eggs, enteroviruses, faecal indicators (Escherichia coli and enterococci) and pathogenic bacteria (Listeria monocytogenes, Salmonella sp. and Clostridium perfringens) of a rural sewage sludge when it is composted for 7 months in mixture with straw. METHODS AND RESULTS: Numbers of the test organisms and the physico-chemical parameters were measured on a monthly basis on the mixture, on the compost after being turned, and on the pile in three positions representing the part by which air is incoming, the bottom of the pile and the part through which air is outgoing. The lowest temperature in the pile was observed at the bottom, where it did not exceed 50 degrees C against 66 degrees C in the two other areas. There were no significant differences between the three areas in terms of micro-organism survival. Infectious enteroviruses were inactivated rapidly and were not found after the first turning whereas some genomes were detected until after the third turning. Escherichia coli and enterococci presented a similar survival rate and their number decreased by 4 log(10) whereas Salmonella decayed at a greater rate than L. monocytogenes. The numbers of C. perfringens decreased gradually to reach a final concentration in the mature compost of about 10(2) CFU g(-1) dry matter (d.m.), which was similar to that of the faecal indicators. CONCLUSIONS: The hygienic effect of sludge composting in mixture with straw results in a significant reduction of enteric micro-organisms, the concentration of the faecal indicators in the final product being < 64 most probable number g(-1) d.m. The concentrations of Salmonella, enteroviruses and viable nematode eggs in the final product were not detectable which is in accordance with the French legislation. SIGNIFICANCE AND IMPACT OF THE STUDY: The results which pointed out the different behaviour of the test micro-organisms reflect the difficulty to propose a relevant indicator of hygienization. Otherwise, they show that composting is an efficient means for hygienization of sludge of rural wastewater treatment, where the straw is available close to their place of production.     

Temperature effect on Fusarium oxysporum f.sp. melonis survival during horticultural waste composting

AIMS: The aim of this work was to study the effect of high temperatures generated during composting process, on the phytopathogen fungus Fusarium oxysporum f.sp. melonis. This investigation was achieved by both in vivo (semipilot-scale composting of horticultural wastes) and in vitro (lab-scale thermal treatments) assays. METHODS AND RESULTS: Vegetable residues infected with F. oxysporum f.sp. melonis were included in compost piles. Studies were conducted in several compost windrows subjected to different treatments. Results showed an effective suppression of persistence and infective capacity, as this process caused complete fungal elimination after 2-3 days of composting. In order to confirm the effect of high temperature during this process, in vitro experiments were carried out. Temperature values of 45, 55 and 65 degrees C were tested. All three treatments caused the elimination of fungal persistence. Treatment at 65 degrees C was especially effective, whereas 45 degrees C eliminated fungal persistence only after 10 days. CONCLUSIONS: The composting process is an excellent alternative for the management of plant wastes after harvesting, as this procedure is able to suppress infective capacity of several harmful phytopathogens such as F. oxysporum f.sp. melonis. SIGNIFICANCE AND IMPACT OF THE STUDY: Fusarium oxysporum f.sp. melonis is a plant pathogen fungus specially important in the province of Almería (south-east Spain), where intensive greenhouse horticulture is very extended. High temperatures reached during composting of horticultural plant wastes ensure the elimination of phytopathogen microorganisms such as F. oxysporum f.sp. melonis from vegetable material, providing an adequate hygienic quality in composts obtained.     

Efforts to Explain and Control the Prolonged Thermophilic Period in Two-phase Olive Oil Mill Sludge Composting

The aim of this paper was to evaluate the use of different bulking agents in different ratios as a means to control, optimise and eventually reduce the duration of the thermophilic period in two-phase olive oil mill sludge (OOMS) composting. The bulking agents used were: (i) olive tree leaves (OTL), (ii) olive tree shredded branches (OTB) and (iii) woodchips (WDC). The selection of these materials was based on their abundance and availability on the island of Crete, the southernmost point of Greece. The ratios studied were: Pile 1, OOMS:OTL in 1:1 v/v; Pile 2, OOMS:WDC in 1:1.5 v/v; Pile 3, OOMS:OTL in 1:2 v/v; Pile 4, OOMS:OTL:OTB in 1:1:1 v/v; and Pile 5, OOMS:OTL:OTB in 1:1:2 v/v. The composting system used was that of windrows with the volume of each pile approximately 20–25 m³. The experiments took place over two consecutive years. A composting turner was used and turnings were performed at one and two week intervals. In each pile a variety of physiochemical parameters were monitored. Temperature remained high in all five trials. Piles 1, 2, 3, 4 and 5 temperatures recorded values of above 50 °C for 106, 158, 160, 175 and 183 days, respectively. Volumes were reduced by approximately 67%, 62%, 63%, 80% and 84%, respectively. Temperature remained high, mainly due to the presence in large amounts of oily substances which during their complete oxidation release important amounts of energy and aid the cometabolism of more stable molecules such as lignin. This process is better described as the slow “burning” of a “fuel” mixture in an “engine” than composting. This approach is based on the extensive similarities of this process to that of crude oil sludge or similar waste composting.     

Synergy of two thermophiles enables decomposition of poly-epsilon-caprolactone under composting conditions

The ultimate degradation (i.e. complete mineralization) of biodegradable polymers proceeds through hydrolysis to the production of degradation intermediates (primary degradation) that are then taken into the microbial cell and further degraded to CO2 and water. We first isolated thermophilic actinomycete (Streptomyces thermonitrificans PDS-1), which has the activity of ultimate degradability, from compost in which poly-epsilon-caprolactone (PCL) degraded vigorously. We next tried to investigate the detailed mechanisms of degradation of the PCL in compost by developing a new experimental method in which isolated microorganisms are used to inoculate sterilized compost raw materials containing PCL. It was confirmed that the ultimate degradation of PCL could not be achieved by the action of the strain PDS-1 alone, and that a supplementary microorganism (Bacillus licheniformis HA1) isolated from compost utilizes the degradation intermediates and also increases the activity of the other primary microorganism (PDS-1) by adjusting the pH. We could thus show experimental proof of synergy between two thermophiles in the ultimate degradation of a biodegradable polymer in compost.