Using a previously developed filter adsorption technique, the inactivation of a human rotavirus, a coxsackievirus B5, and a bovine parvovirus was monitored during sludge treatment processes. During conventional anaerobic mesophilic digestion at 35 to 36°C, only minor inactivation of all three viruses occurred. The k' values measured were 0.314 log10 unit/day for rotavirus, 0.475 lglo unit/day for coxsackievirus B5, and 0.944 log10 unit/day for parvovirus. However, anaerobic thermophilic digestion at 54 to 56°C led to rapid inactivation of rotavirus (k' > 8.5 log10 units/h) and of coxsackievirus B5 (k' > 0.93 loglo unit/min). Similarly, aerobic thermophilic fermentation at 60 to 61°C rapidly inactivated rotavirus (k' = 0.75 loglo unit/min) and coxsackievirus B5 (k' > 1.67 log1o units/min). Infectivity of parvovirus, however, was only reduced by 0.213 loglo unit/h during anaerobic thermophilic digestion and by 0.353 lglo unit/h during aerobic thermophilic fermentation. Furthermore, pasteurization at 70°C for 30 min inactivated the parvovirus by 0.72 log10 unit/30 min. In all experiments the contribution of temperature to the total inactivation was determined separately and was found to be predominant at process temperatures above 54°C. In conclusion, the most favorable treatment to render sludge hygienically safe from the virological point of view would be a thermal treatment (60°C) to inactivate thermolabile viruses, followed by an anaerobic mesophilic digestion to eliminate thermostable viruses that are more sensitive to chemical and microbial inactivations.
A simple and reliable method is described which allows determination of virus inactivation rates during sludge treatment processes in situ. Bacteriophage f2 was adsorbed onto an electropositive membrane filter which was then sandwiched between two polycarbonate membranes with pores smaller than the virus diameter. The resulting sandwich was fixed in an open filter holder, and several such devices were connected before being exposed in sludge-digesting tanks. The device described prevented uncontrolled virus escape, but allowed direct contact of the various inactivating or stabilizing substances present in the environment tested with the virus adsorbed to the carrier membrane. After exposure to an environment, the surviving fraction of virus was eluted from the inner filter and determined by plaque counting. By using polycarbonate membranes without pores for sandwiching, the influence of temperature alone on virus inactivation could be measured. Thermophilic fermentation at 60 degrees C and at 65 kPa pressure led to a bacteriophage f2 titer reduction of 3.5 log10 units per h, whereas during thermophilic digestion at 54.5 degrees C titers decreased 1.2 log10 units per h. During mesophilic digestion an inactivation rate of only 0.04 log10 units per h was observed. Under these latter conditions, temperature had only a minor effect (19%) on virus inactivation, whereas at 54.5 degrees C during thermophilic digestion heat accounted for 32% of the total inactivation, and during thermophilic fermentation at 60 degrees C temperature and pressure were 100% responsible for virus denaturation.
In addition to the typical whorls of branches, fruiting bodies of the genus Polysphondylium bear spores that are characterized by the presence of polar spore granules (PG). This spore character is highly correlated with less easily assessible features of the life cycle such as the nature of the chemotactic response towards cAMP, mode of center initiation, absence of preaggregative cell adhesiveness and overall morphogenetic pattern. Many new strains were isolated which possess the PG character and the cluster of associated features but produce sorocarps which are not regularly branched. This newly recognized group represents a clearly separate unit with common, defined properties. Its taxonomic position in relation to the presently accepted genera of the Dictyosteliaceae, namely Dictyostelium and Polysphondylium, is discussed.
A detailed analysis of occurrence and distribution of cellular slime molds in soils of different forest types of Switzerland is given. Specific prevalence patterns representative for each forest type were determined. The degree of complexity of these prevalence patterns parallels tree diversity of the respective forest communities. A comparison of the prevalence patterns shows that by proceeding from species‐rich to species‐poor sites the frequent and common species disappear, whereas the infrequent and rare species are conserved. Thus, these latter species, which probably represent specialists, appear to be of considerable ecological significance. Dictyostelium mucoroides is the overwhelming dominant in all forest types. Polysphondylium violaceum and D. minutum are abundant in the deciduous forests. These three species account for 87% of the clones isolated. Two species are characteristic of conifer forests, D. aureo‐stipes var. Helvetium and D. polycarpum. Other species encounterd and listed in decreasing order are D. fasciculatum. P. filamentosum, D. sphaerocephalum, D. giganteum, Acytostelium leptosomum, D. aureum var. luteolum and D. polycephalum. Diversity of species is greatest in the mesic beech forests of the Midland, Jura or Forealps regions but reduced populations containing unique cellular slime molds occur in the highest spruce, larch, and pine forests of the Alps.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.
customersupport@researchsolutions.com
10624 S. Eastern Ave., Ste. A-614
Henderson, NV 89052, USA
This site is protected by reCAPTCHA and the Google Privacy Policy and Terms of Service apply.
Copyright © 2024 scite LLC. All rights reserved.
Made with 💙 for researchers
Part of the Research Solutions Family.