论生物实验室废物的危害与处理

介绍了生物实验废物来源、种类及其危害;提出了实验污染物分类处理的措施;对实验室建设、新型人才培养、保护环境具有现实意义。     

Simple emission-reducing measures in an open biological waste treatment plant

In the course of composting biological waste, concentrations of various thermophilic and thermotolerant microorganisms increase. Moving piles of compost results in increased emissions of Actinomycetes and fungi. The present investigation deals with the reduction of airborne microorganism emission and immission in large-scale composting plants with open piles. Simple measures were introduced in order to reduce the release of bioaerosols when turning piles and the release of dust and bioaerols at large. These measures included the sealing of turning machinery with rubber mats, the wetting of piles before and after turning and regular cleaning and wetting driveways during the dry season.Concentrations of airborne microorganisms during the summer season were determined on 5 days before and after the introduction of emission-reducing measures using the six-stage Andersen cascade sampler. The investigation showed that following the introduction of emission-reducing measures there was, at all locations, a highly significant reduction not only of all culturable indicator organisms (thermophilic actinomycetes and Aspergillus fumigatus) but also of total microorganism concentrations (p < 0,001). The introduction of the simple emission-reducing measures mentioned above, however, reduced the immission in the vicinity of the plant to such a degree that the natural background levels were reached at a distance of 150 m.     

Response of biological waste treatment systems to changes in salt concentrations

The effect of NaCl on the yield of biological solids and on the ability of continuously cultured heterogeneous microbial populations to remove substrate was assessed by changing the salt concentration in the inflowing synthetic waste. During the period of increasing the salt concentration to 30,000 mg/l the system could not maintain a high substrate removal efficiency. However, after an acclimation period the system regained its former efficiency. Upon diluting the salt out of the system, a significant rise in cell yield was noted as the salt level passed through the range 8,000–10,000 mg/l. It was found that steady operation at a salt level of 8,000 mg/l sustained the cell yield at a high level.     

Metabolic uncouplers for controlling biomass accumulation in biological waste treatment systems

A number of lipophilic weak acids are known to reduce biomass production in biological waste treatment systems. A definitive mechanism on how metabolic uncouplers reduce biomass accumulation is yet to be developed. In addition to the classic uncoupler mechanism of reduced ATP production efficiency, three other mechanisms are reviewed here. Firstly, uncouplers can increase maintenance energy requirements by diverting energy to non-growth processes. Secondly, uncouplers can undermine biofilm integrity through changes in EPS production, quorum signaling molecules, and potentially, cell hydrophobicity. Finally, uncoupler toxicity can challenge the microbial diversity, leading to death of some and proliferation of new species in the biofilm with reduced biomass yield. There are observations linking these mechanisms together but more work is required to clarify them. Given the challenges of acclimation, accumulation and environmental risks associated with uncouplers, understanding how these mechanisms operate is imperative in their successful and sound application.     

Biopolymer particulate turnover in biological waste treatment systems: a review

Microorganisms — the major component in most biological waste treatment processes and a number of industrial fermentations — are not able to directly assimilate biopolymeric particulate material. Such organic particulates must first be solubilized into soluble polymers or monomers before they can diffuse through the capsular slime layer surrounding most bacteria, then transported across the cell membrane, to be used as either a carbon, energy or other essential nutrient source. Throughout these events, new cells are synthesized, which are themselves biopolymer particulates.The turnover of biopolymer particulates in biological treatment systems has not been examined with respect to its impact on system performance and culture physiology. The aim of this paper is to review the observations of particulate turnover in various biological treatment systems and to identify those fundamental mechanisms which govern microbial conversion of biopolymer particulates.Current address: Department of Chemical Engineering, California, Institute of Technology, Pasadena, Ca 91125 USA     

Production of metabolic and waste products by intensively farmed rainbow trout, Salmo gaivdnevi Richardson

The pollution production rate as measured by the increase in the amounts of ammonia, phosphate, nitrate, urea, and faeces in an intensive fish farm is described and is related to the amount of food fed per day or the biomass weight. Pollution production varied with fish size. Main pollutants produced per kg food fed per day were ammonia 31–37 g; phosphate 5.2–5.9 g; nitrate 9–15 g and suspended solids 40–9O g. Expressed as g kg⁻¹ fish produced per day ammonia ranged from 0.3–0.8 g; phosphate 0.067–0.17 g; nitrate 0.13–0.21 g and suspended solids 0.80–0.94 g. These rates differ from those reported in previous studies and these differences may be attributed to the design of the Shearwater farming system which involves self cleaning, intensively stocked tanks, a system which ultimately gives a more accurate assessment of pollution rates.     

Formation of ring-opened and rearranged products of guanine: mechanisms and biological significance

DNA damage by endogenous and exogenous agents is a serious concern, as the damaged products can affect genome integrity severely. Damage to DNA may arise from various factors such as DNA base modifications, strand break, inter- and intrastrand crosslinks, and DNA-protein crosslinks. Among these factors, DNA base modification is a common and important form of DNA damage that has been implicated in mutagenesis, carcinogenesis, and many other pathological conditions. Among the four DNA bases, guanine (G) has the smallest oxidation potential, because of which it is frequently modified by reactive species, giving rise to a plethora of lethal lesions. Similarly, 8-oxo-7,8-dihydroguanine (8-oxoG), an oxidatively damaged guanine lesion, also undergoes various degradation reactions giving rise to several mutagenic species. The various products formed from reactions of G or 8-oxoG with different reactive species are mainly 2,6-diamino-4-oxo-5-formamidopyrimidine, 2,5-diamino-4H-imidazolone, 2,2,4-triamino-5-(2H)-oxazolone, 5-guanidino-4-nitroimidazole, guanidinohydantoin, spiroiminodihydantoin, cyanuric acid, parabanic acid, oxaluric acid, and urea, among others. These products are formed from either ring opening or ring opening and subsequent rearrangement. The main aim of this review is to provide a comprehensive overview of various possible reactions and the mechanisms involved, after which these ring-opened and rearranged products of guanine would be formed in DNA. The biological significance of oxidatively damaged products of G is also discussed.     

生物垃圾处理过程中渗滤液混凝处理的实验研究

通过对混凝剂(PAS)用量、酸度、温度对垃圾处理过程中渗滤液混凝效果影响的研究,结果表明:用聚合硫酸铝进行混凝处理时,对渗滤液的氨氮处理效果不佳,对CODcr和浊度处理效果甚佳.根据三因素三水平的正交实验,得出处理过程中三个因素对CODcr去除率影响的主次关系为:pH＞聚合硫酸铝的用量＞温度.验证试验结果表明:混凝剂加入量15mL(10%)、pH为6.7、温度为50℃时为最优化工艺条件,CODcr去除率达到76.2%.     

Integration of biological waste conversion and wastewater treatment plants by microalgae cultivation

In this study, growth performance and lipid content of two microalgae species Neochloris oleoabundans and Chlorella vulgaris are monitored by using three different types of sludge waste feedstocks obtained from the water treatment plants located in Bedonia, Borgotaro and Fornovo (Montagna2000 Spa, Province of Parma, Italy). The sludge waste is optimized in order to achieve microalgal growth media and dispose of the sewage sludge produced at the wastewater treatment facilities. Both photoautotrophic and heterotrophic growth conditions are applied to the microalgal cultivations. The growth parameters of microalgae strains such as cell concentration, growth rate, optical density, cell biovolume, photosynthetic pigments and lipid contents are monitored. The amounts of total dried lipid biomass, obtained by the biological conversion of the wet sludge waste, are determined. Lipid production of microalgal cells grown in the medium optimized from sludge waste from the Fornovo site provides the highest amount of microalgal lipid content for N. oleoabundans and C. vulgaris photoautotrophic cultivations, while sludge waste from the Bedonia site provides for N. oleoabundans heterotrophic cultivation.     

Continuous biological waste gas treatment in stirred trickle-bed reactor with discontinuous removal of biomass

A new reactor for biological waste gas treatment was developed to eliminate continuous solvents from waste gases. A trickle-bed reactor was chosen with discontinuous movement of the packed bed and intermittent percolation. The reactor was operated with toluene as the solvent and an optimum average biomass concentration of between 5 and 30 kg dry cell weight per cubic meter packed bed (m3pb). This biomass concentration resulted in a high volumetric degradation rate. Reduction of surplus biomass by stirring and trickling caused a prolonged service life and prevented clogging of the trickle bed and a pressure drop increase. The pressure drop after biomass reduction was almost identical to the theoretical pressure drop as calculated for the irregular packed bed without biomass. The reduction in biomass and intermittent percolation of mineral medium resulted in high volumetric degradation rates of about 100 g of toluene m-3pb h-1 at a load of 150 g of toluene m-3pb h-1. Such a removal rate with a trickle-bed reactor was not reported before.     

活体生物药的应用及在遗传性代谢缺陷病治疗中的展望

活体生物药(live biotherapeutic products,LBPs)是指来自于人体肠道内或自然界中能够治疗人类疾病的活性菌。但天然筛选的活菌存在治疗效果不明显、差异性较大等缺点,难以满足个性化诊疗的需要。近年来,随着合成生物学的发展,研究者利用生命科学及工程科学手段,设计并构建了若干可响应外界复杂环境信号的工程菌株,加快了活体生物药的研发和应用过程。遗传性代谢缺陷病(inherited metabolic disease)是因体内某些酶的遗传缺陷致使体内相应的代谢物不能正常代谢而引发一系列临床症状的一类疾病,因此利用合成生物学技术,针对特定缺陷的酶设计重组活体生物药,未来有希望用于遗传性代谢缺陷病的治疗。本综述以活体生物药为切入点,并结合国内外文献综述,来探讨活体生物药在疾病治疗中的应用,以及对遗传性代谢缺陷病治疗的潜力。     

Microbial recycling of mineral waste products

The applicability of biotechnological methods to metal recovery from non-sulfide industrial waste products (slag, galvanic sludge, filter-press residue, filter dust, and fly ash) was investigated. From some products, copper, chromium, zinc or vanadium were completely extracted by sulfuric acid produced by Thiobacillus thiooxidans. The efficiency of bacterial metal solubilization varied depending on the type of waste material and on the pulp density. Stepwise increase of pulp density promoted bacterial growth and activity, resulting in metal concentrations of 6.6 g Cu/l, 6.3 g V/l, 24.4 g Zn/l or 21 g Cr/l in the leaching medium. In some cases bacterial leaching was as effective as chemical leaching with sulfuric acid. The efficiency of both processes is considered. In principal, bacterial metal recovery from industrial waste products seems to be feasible and may contribute to an increase in future supplies of raw materials, as well as to detoxification of industrial waste products resulting in reduced environmental pollution problems.     

Chemical and spectroscopic analysis of olive mill waste water during a biological treatment

The treatment of olive mill waste water was studied on the laboratory scale. Physico-chemical analyses showed the final products had a mean pH of 5.4 without neutralisation and 5.7 when lime was added to the process. Raising the pH by adding lime had a positive outcome on the degradation of phenols, whose levels were reduced by over 76%. The lime also changed the structure of the organic matter, as seen in the infra-red spectra. Combining the FT-IR and 13C NMR data showed that with addition of lime, the density of aliphatic groups decreased to the benefit of aromatic groups, indicating that polymerisation of the organic matter occurred during the bioprocess. Under our experimental conditions, the biotransformation of olive mill waste water appears to favour the stabilisation of the organic matter through mechanisms analogous to those that lead to the formation of humus in the soil.     

Lipid peroxidation products in biological tissues

Over the past twenty-years of lipid peroxidation research in this laboratory, considerable effort has gone into development of new methods, with emphasis on measurement of lipid-soluble fluorophores and the volatile hydrocarbons ethane and pentane. Application of these and other methods has been made to biological materials and living animals. Although the various methodologies used in lipid peroxidation research do not necessarily measure the same class of products, and although agreement of results is not always 100%, there is substantial documentation of good correlations between measurements; for example, of trace volatile hydrocarbons with thiobarbituric acid-reacting substances, of pentane production with dietary and/or tissue vitamin E content, and of pentane production with lipid-soluble fluorophores accumulated in spleen as a function of oxidant stress. Individual methodologies do have their inherent limitations. However, measurements of multiple products and their correlations have added significantly to the base of information on biological damage and protection by dietary antioxidants against nutritional and toxicological insults to tissues, cells, and macromolecules as a result of peroxidative and oxidative reactions.     

Disposable products in the hospital waste stream.

Use of disposable products in hospitals continues to increase despite limited landfill space and dwindling natural resources. We analyzed the use and disposal patterns of disposable hospital products to identify means of reducing noninfectious, nonhazardous hospital waste. In a 385-bed private teaching hospital, the 20 disposable products of which the greatest amounts (by weight) were purchased, were identified, and total hospital waste was tabulated. Samples of trash from three areas were sorted and weighed, and potential waste reductions from recycling and substituting reusable items were calculated. Business paper, trash liners, diapers, custom surgical packs, paper gowns, plastic suction bottles, and egg-crate pads were among the 20 top items and were analyzed individually. Data from sorted trash documented potential waste reductions through recycling and substitution of 78, 41, and 18 tonnes per year (1 tonne = 1,000 kg = 1.1 tons) from administration, the operating room, and adult wards, respectively (total hospital waste was 939 tonnes per year). We offer specific measures to substantially reduce nonhazardous hospital waste through substitution, minimization, and recycling of select disposable products.     

Isolation of a microbial consortium from activated sludge for the biological treatment of food waste

The bacterial community in the activated sludge of a local wastewater treatment plant was studied in an effort to understand and exploit the metabolic versatility of microorganisms for the efficient biological treatment of food waste. Microorganisms capable of and efficient in degrading domestic food waste were screened based on their ability to produce areas of clearing on selective media containing protein, fat, cellulose and starch. Nine microbial species belonging to the genera Flavobacterium, Pseudomonas, Micrococcus, Aeromonas, Xanthomonas, Vibrio and Sphingomonas were found to degrade all components of food waste. These bacteria were added to domestic wastewater and shown to cause a 60% reduction in the biochemical oxygen demand (BOD) level of wastewater compared to a control in which no microorganisms were added. The ability of the microbial consortium to degrade domestic wastewater as evidenced by the decrease in BOD levels suggests its potential for use in the biological treatment of food waste.