A rapid method for assessing the resistance of polyurethanes to biodeterioration

A rapid soil burial method for assessing the susceptibility of polyurethanes to biodeterioration was developed. The time of the test was reduced by prestressing the polyurethanes. The degree of deterioration was measured by following changes in the appearance of the polyurethanes and in selected physical properties. It was found that pre-stressing produced significant reductions in the tensile strength of a known susceptible polyurethane after burial in soil for 2 weeks. The reduction was greater than that found with unstressed polyurethanes buried for 26 weeks in active soil. Changes in tensile strength were less after burial for 4 weeks in sterile soil than after burial in active soil for the same period. The results suggest that deterioration of polyurethane during soil burial is a result of both chemical and microbial action.     

Rapid destruction of PVC piping by boring bivalves

It is becoming common practise to select plastics such as unplasticised polyvinyl chloride (PVC) for construction of submarine pipes and intakes, especially for service in conditions where wood is susceptible to attack. Recent cases indicate, however, that these materials may not necessarily be immune. Failure of PVC piping on the north coast of Java from attack by boring pholads, Martesia striata, occurred in approximately one year. It appears to be the most rapid yet reported. Destruction by marine borers within one to three years at this and other polluted harbour locations around the world lead us to conclude that eutrophication of the environment from anthropogenic sources can accelerate attack and biodeterioration of marine materials.     

Assessing the effect of biodegradable and degradable plastics on the composting of green wastes and compost quality

An assessment of the effect of the composting potential of Mater-Bi biodegradable plastic with green wastes, noted by GBIO, and degradable plastic (PDQ-H additive) with green wastes, noted by GDEG, was carried out in a lagged two-compartment compost reactor. The composting time was determined until constant mass of the composting substrates was reached. The green wastes composting process was used as control (G). After one week of composting, the biodegradable plastics disappeared completely, while 2% of the original degradable plastic still remained after about 8 weeks of composting. A net reduction in volatile solids contents of 61.8%, 56.5% and 53.2% were obtained for G, GBIO and GDEG, respectively. Compost quality was assessed in terms of nitrogen, potassium and phosphorus contents, which were found to be highest for GBIO compost. From the phytotoxicity test, it has been observed that a diluted extract of GBIO compost has produced the longest length of radicle. From the respiration test, no significant difference in the amount of carbon dioxide released by the composting of GDEG and G was observed. This study showed that the quality of the compost is not affected by the presence of the biodegradable and degradable plastics in the raw materials.     

Biological degradation of plastics: a comprehensive review

Lack of degradability and the closing of landfill sites as well as growing water and land pollution problems have led to concern about plastics. With the excessive use of plastics and increasing pressure being placed on capacities available for plastic waste disposal, the need for biodegradable plastics and biodegradation of plastic wastes has assumed increasing importance in the last few years. Awareness of the waste problem and its impact on the environment has awakened new interest in the area of degradable polymers. The interest in environmental issues is growing and there are increasing demands to develop material which do not burden the environment significantly. Biodegradation is necessary for water-soluble or water-immiscible polymers because they eventually enter streams which can neither be recycled nor incinerated. It is important to consider the microbial degradation of natural and synthetic polymers in order to understand what is necessary for biodegradation and the mechanisms involved. This requires understanding of the interactions between materials and microorganisms and the biochemical changes involved. Widespread studies on the biodegradation of plastics have been carried out in order to overcome the environmental problems associated with synthetic plastic waste. This paper reviews the current research on the biodegradation of biodegradable and also the conventional synthetic plastics and also use of various techniques for the analysis of degradation in vitro.     

Screening of fungal strains employed in the testing of plastics materials

The problems of selecting tests method and suitable challenge organisms for plastics materials are discussed. Enzyme activities of fungal strains employed in the testing of plastics have been investigated and compared with isolates of these organisms held elsewhere. The ability of organisms to clear a polycaprolactone diol medium has been assessed semiquantitatively and the results discussed in relation to the selection of organisms.     

Life cycle inventory analysis of co<Subscript>2</Subscript> emissions manufacturing commodity plastics in japan

The goal of this study was to calculate the average CO₂ emissions for manufacturing three commodity plastics, polyethylene (PE), polypropylene (PP), and polyvinyl chloride (PVC) in Japan. The CO₂ emissions were calculated from cradle to gate, excluding the calcination processes after use. As the results, the followings were observed: 1) The gross CO₂ emissions for the manufacture of plastics in Japan were 1.3, 1.4, and 1.7 kg-CO₂/kg-PE, PP, and PVC, respectively. These mainly reflected the difference of CO₂ emissions for the in-house electricity generation. 2) The CO₂ emissions for the electricity used for manufacturing PVC were higher than that used for PE and PP, because additional electricity was required for the electrolysis to produce chlorine. The gross electricity consumption for manufacturing PVC was 1.3 kWh/kg-PVC, and the other plastics consumed 0.5 kWh/kg-Products. In addition, the effects of energy saving were studied using a projected gas-diffusion electrode for the electrolysis of salt on the reduction of CO₂ emissions. It was estimated that the reduction in CO₂ emissions was 7% compared with the present PVC manufacturing processes.     

Biodegradation of plastics

Widespread studies on the biodegradation of plastics have been carried out in order to overcome the environmental problems associated with synthetic plastic waste. Recent work has included studies of the distribution of synthetic polymer-degrading microorganisms in the environment, the isolation of new microorganisms for biodegradation, the discovery of new degradation enzymes, and the cloning of genes for synthetic polymer-degrading enzymes.     

Biodeterioration of cinematographic cellulose triacetate by Sphingomonas paucimobilis using indirect impedance and chemiluminescence techniques

The bacterium Sphingomonas paucimobilis, isolated from cinematographic films in an earlier project, was able to biodeteriorate the cellulose triacetate material (acetylation degree of 2.7). Film colonization was monitored by the indirect impedance technique and the production of carbon dioxide. The presence of ruggedness and irregularities on the surface of the film, produced when the plasticizer was extracted, accelerated the biodeterioration of the material. In contrast, cinematographic films with their layered structure made of photographic gelatine emulsion were protected and no colonization was observed. The cinematographic film without photographic emulsion reached a 5% level of biodeterioration after six weeks of incubation, confirming the possibility of biodeterioration of archival cinematographic materials if conservation conditions are not adequate. Through viscosity measurements, a decrease in relative viscosity was observed on the biodeteriorated sample, with respect to the original material, confirming a lower molecular weight as a result of enzymatic activity of S. paucimobilis. Also, using chemiluminescence, the film surface oxidation on the biodeteriorated sample was observed. This technique was very sensitive in detecting material oxidation by reactive oxygen species generated by bacteria, and could be useful to study microbiological biodeterioration in polymeric materials.     

Biodeterioration of mineral materials by microorganisms—biogenic sulfuric and nitric acid corrosion of concrete and natural stone

In general, microorganisms such as chemolithotrophic and chemo‐organotrophic bacteria, cyanohacteria, algae, fungi, and lichens living on and in stone material may be of importance in biodeterioration. These groups contribute substantially to the deterioration of mineral materials such as natural stone, concrete, ceramics, and glass. The attack on mineral materials may be either strongly or mildly aggressive or both. A strongly aggressive attack is caused by biogenic mineral or organic acids. A mildly aggressive attack results from hydrophilic slimes such as heteropolysaccharides and/or proteins (biofilm) and their ability to accumulate water and salts. Attack by exoenzymes seems to be unimportant.

In recent years it has become possible to test the resistance of mineral materials to microbial attack by means of a biotest. Three simulation apparatuses were constructed; each allowed the incubation of test materials under microbiologically optimized conditions. Biodeterioration involving biogenic sulfuric acid corrosion, which under natural conditions needs eight times as long, was detectable within a few months. The results differed from those of purely chemical and/or physical tests of materials. Physical/chemical test methods are not sufficient to determine the resistance of materials to biological attack, because they do not include the interactions between microorganisms and their substrate, the mineral material. In the case of biogenic sulfuric acid corrosion, simulation experiments demonstrated differences in resistance of various concrete types, which ranged from I to 20% weight loss of test blocks within I year. With chemical testing only negligible differences in weight loss were noted. This was also the case with biogenic nitric acid corrosion. Thus, biotests assist in the selection of appropriate materials from many different ones.     

Applications and societal benefits of plastics

This article explains the history, from 1600 BC to 2008, of materials that are today termed ‘plastics’. It includes production volumes and current consumption patterns of five main commodity plastics: polypropylene, polyethylene, polyvinyl chloride, polystyrene and polyethylene terephthalate. The use of additives to modify the properties of these plastics and any associated safety, in use, issues for the resulting polymeric materials are described. A comparison is made with the thermal and barrier properties of other materials to demonstrate the versatility of plastics. Societal benefits for health, safety, energy saving and material conservation are described, and the particular advantages of plastics in society are outlined. Concerns relating to littering and trends in recycling of plastics are also described. Finally, we give predictions for some of the potential applications of plastic over the next 20 years.     

Multistep approach to control microbial fouling of historic building materials by aerial phototrophs

The scientific multistep approach described herein is a result of two years of research into a control method against microbial fouling and biodeterioration of historic building materials by phototrophs. A series of tests were conducted to select the best antifouling agent for eliminating ‘green’ coatings and protecting surfaces against biofouling. Of the seven active compounds, two with the best penetration abilities were subjected to a photosynthetic activity inhibition test using confocal microscopy. Of the two, a quaternary ammonium salt (QAC) – didecyldimethylammonium chloride (DDAC) – was found to be the most effective. Ten biocides containing QACs at different concentrations were then tested against ‘green’ coatings on wood, brick and plaster, with the best four being selected for further research in model conditions. As a result, biocides containing >14% (v v^–1) DDAC were found to be successful antifouling agents for protecting historical materials against biodeterioration by phototrophs.     

Good manufacturing practices — A means of controlling biodeterioration

Control of biodeterioration and all aspects of product or operational safety depend upon good manufacturing practices and one of the most effective methods which has been developed to ensure this is by hazard analysis of critical control points (HACCP). This is an all embracing philosophy which examines the risk of microbiological biodeterioration from both the survival of spoilage micro-organisms to processing conditions or contamination at all stages of manufacture, and builds in the relevant quality assurance standards and processing specifications to minimise the risk of biodeterioration of the product and does not rely solely upon the analysis of the finished product. For manufacturers this requires knowledge and control of the microbiological quality of the raw materials, packaging components and processing environment; a validation of the ability of any in-process stages to destroy both pathogenic or spoilage micro-organisms and the effectiveness of the preservative system throughout the shelf-life of the product.     

Poly(ether urethane) networks from renewable resources as candidate biomaterials: synthesis and characterization

A series of poly(ether urethane) networks were synthesized from epoxidized methyl-oleate-based polyether polyol and 1,3-propandiol using l-lysine diisocyanate as a nontoxic coupling agent. Polyurethanes with different hard segment contents were prepared to tune the final properties of the materials. The polyurethanes were fully chemically and physically characterized, including water uptake and in vitro hydrolytic degradation measurements. The weight loss of the polyurethanes was traced, and the changes in the surface morphology with the degradation time were examined by scanning electron microscopy. The experimental results revealed that the hard segment content is the main factor that controls the physical, mechanical, and degradation properties of these polymers. The observed diversity in material properties suggests that these polyurethanes may be useful for a wide range of biomedical polymer applications.     

Accelerated laboratory test to study fungal biodeterioration of cementitious matrix

The present study aimed to develop an accelerated laboratory test to study the biodeteriorative effect of different fungal strains to a cementitious matrix. The test developed in this study permits to obtain a rapid fungal development on cement specimens. Three months of experiments only are needed to obtain first results, which is rather shorter than other test developed to date to study fungal biodeterioration. Results are mainly related to aesthetical biodeterioration. Results show that in these experimental conditions, fungal growth occurs since the first week of incubation. Stereomicroscopy observations showed that microbial growth was noticed only on the surface of specimens, while PAS staining revealed the real extent of microbial growth on and within the matrix as later confirmed by SEM observations of cross section showing the penetration of hyphae inside the matrix. Test can be used with short time of incubation, to test and to compare bioreceptivity of cement-based materials; and several months of incubation should allow the study of mechanisms involved in biodeterioration.     

Biodegradation of polyurethane: a review

Lack of degradability and the closing of landfill sites as well as growing water and land pollution problems have led to concern about plastics. Increasingly, raw materials such as crude oil are in short supply for the synthesis of plastics, and the recycling of waste plastics is becoming more important. As the importance of recycling increases, so do studies on elucidation of the biodegradability of polyurethanes. Polyurethanes are an important and versatile class of man-made polymers used in a wide variety of products in the medical, automotive and industrial fields. Polyurethane is a general term used for a class of polymers derived from the condensation of polyisocyanates and polyalcohols. Despite its xenobiotic origins, polyurethane has been found to be susceptible to biodegradation by naturally occurring microorganisms. Microbial degradation of polyurethanes is dependent on the many properties of the polymer such as molecular orientation, crystallinity, cross-linking and chemical groups present in the molecular chains which determine the accessibility to degrading-enzyme systems. Esterase activity (both membrane-bound and extracellular) has been noted in microbes which allow them to utilize polyurethane. Microbial degradation of polyester polyurethane is hypothosized to be mainly due to the hydrolysis of ester bonds by these esterase enzymes.     

Calibration of replacement international standards of diphtheria and tetanus toxoids for use in flocculation test

The 1st International Reference Reagents (IRR) of Diphtheria and Tetanus Toxoids for Flocculation Test (DIFT and TEFT) were established by the WHO in 1988. These reagents are essential for the standardization of assays used to calculate Lf units of toxoids. Candidate replacement materials were provided by several European vaccine manufacturers and were formulated and freeze-dried at NIBSC. This paper provides a summary of the results of an international collaborative study including 18 laboratories from 16 countries, which examined the candidate replacement materials in a variety of methods. Materials 02/176 and 04/150 were proposed and adopted by the Expert Committee on Biological Standardization of WHO in October 2007 as 2nd WHO International Standards of Diphtheria and Tetanus Toxoid for use in Flocculation Test. The replacement standards were assigned the value of 1100 and 690Lf/ampoule, respectively, based on results of flocculation tests carried out using provided reagents. Material coded 02/176 fully complied with the WHO specifications for stability, residual moisture content, precision of fill and sterility. Stability of material coded 04/150 was slightly lower than expected but predictions were based only on 2-year data and were to be further monitored, post-adoption.     

The impact of culture medium on the development and physiology of biofilms of Pseudomonas fluorescens formed on polyurethane paint

Microbial biofilms cause the deterioration of polymeric coatings such as polyurethanes (PUs). In many cases, microbes have been shown to use the PU as a nutrient source. The interaction between biofilms and nutritive substrata is complex, since both the medium and the substratum can provide nutrients that affect biofilm formation and biodeterioration. Historically, studies of PU biodeterioration have monitored the planktonic cells in the medium surrounding the material, not the biofilm. This study monitored planktonic and biofilm cell counts, and biofilm morphology, in long-term growth experiments conducted with Pseudomonas fluorescens under different nutrient conditions. Nutrients affected planktonic and biofilm cell numbers differently, and neither was representative of the system as a whole. Microscopic examination of the biofilm revealed the presence of intracellular storage granules in biofilms grown in M9 but not yeast extract salts medium. These granules are indicative of nutrient limitation and/or entry into stationary phase, which may impact the biodegradative capability of the biofilm.     

A rapid evaluation plate-test for the biodegradability of plastics

Solid-media agar-plate tests were investigated for their potential to evaluate the biodegradation of polymeric particles by certain strains of microorganisms. A reliable test was developed. Stable suspensions of 1-m globules of two poly(3-hydroxyalkanoates) were prepared. These were mixed with liquified agar-agar to form turbid plates. Inoculation was carried out by plate puncturing. Seven strains isolated from sewage sludge formed clear zones. These zones were distinct, circular, and reproducible in outlook and growth. The maximal duration of single experiments was 192 h. A growth rate was defined. It allowed the classification of the polymers, and of the microorganisms used. Poly(3-hydroxybutyrate-co-valerate) was degraded faster by all the strains used than was the homopolyester poly(3-hydroxybutyrate). Strains achieving high zone growth rates generally did so on both of the polymers. This led to the assumption of similar enzymatic processes being active. Zone formation was concluded to be dependent on the amount of enzyme production plus the enzyme activity. The technique provides a means of either distinguishing the degradation abilities of a microorganisms, or the degradability of materials. Correspondence to: R.-J. Müller     

Establishing the Stages and Processes of Change for Weight Loss by Consensus of Experts

The present study aimed to establish, by a consensus of experts, the stages and processes of change for weight management in overweight and obese people. The first step involved developing two questionnaires aimed at assessing stages and processes of change for weight loss in overweight and obese people. The processes‐of‐change questionnaire consisted of 12 subscales, and contained 107 items. A three‐round Delphi study was carried out through a website, where participants were asked to give their opinion about the representativeness and clarity of the scale items. The stages‐of‐change questionnaire consisted of five items and was presented in the final round of the study. A team of 66 experts in the obesity field from 29 countries participated in the study. They were selected either because they belonged to the organizing committee of international associations related to obesity, or because of their research career. The required changes in the questionnaire were made according to the opinions of the participants. Some of these were the result of the group statistical response, whereas others were due to the suggestions made by the participants. A final version of the questionnaire consisting of 63 items was eventually obtained. The present study produced two questionnaires to assess stages and processes of change for weight management. The strength of the study lies in the consensus reached by the panel of experts in order to establish the required content of the questionnaires. The two measures provide useful tools for practitioners who wish to tailor weight‐management interventions according to transtheoretical model constructs.     

一株工业腐败物中魏氏柠檬酸杆菌的分离鉴定及产生物膜特性分析

【目的】分离和鉴定工业腐败物中高产细菌生物膜菌株,并明确该菌的部分产膜特性。【方法】通过微孔板结晶紫染色法对分离的菌株进行产膜能力评价,根据菌落形态、生理生化特性和16S rRNA序列的系统进化树分析进行菌株鉴定;同时利用扫描电子显微镜(SEM)和结晶紫染色法分别研究材料及温度对该菌产膜特性和能力的影响。【结果】筛选出一株高产细菌生物膜菌株,经鉴定该菌为魏氏柠檬酸杆菌;其在玻璃、不锈钢和聚氯乙烯(PVC)材料表面均能形成生物膜;温度条件显著影响产膜能力,在30°C时,菌株在PVC材料表面形成生物膜能力最强。【结论】工业腐败物中含有高产细菌生物膜菌株,并且产膜受附着物和温度影响。