Four of five soils studied adsorbed the bacteriophage φX‐174 in accordance with the Freundlich isotherm. The soil not adsorbing viruses was the coarsest textured and had the highest pH. For purposes of comparing rates in kinetic studies, this soil was considered to have a zero adsorption rate. The amount of virus adsorbed was linearly related to the square root of time. When adsorption rates for the soils were plotted against cation exchange capacities, specific surface areas, and organic matter contents, fair correlation was found for four of the soils. The lack of correlation for the one soil may have been due to its high organic matter content blocking virus adsorption. The rates of adsorption determined from square root of time plots were significantly correlated with soil pH at the 1% level (r = −0.94), indicating the importance of the influence of pH on virus charge.
Composted sewage sludge may be used to improve soil quality, but there remains some doubt concerning the microbiological safety of the product. Sewage sludge composts from 30 municipalities were sampled, and four samples (12%) contained salmonellae (two contained fewer than 0.3/g, and the other two had 21/g and 1.7 x 104/g). All 30 composts were inoculated with salmonellae; the populations decreased at a specific death rate of about 0.15 h-' over 24 h at 36°C. In irradiation-sterilized composts inoculated with salmonellae, the salmonellae grew at a rate of 0.65 doublings per h for over 24 h. Growth and death rates were found to be moisture and flora associated. The growth or death rates for antibiotic-resistant salmonellae were not different from those of nonresistant strains. It was concluded that the active indigenous flora of compost establishes a homeostatic barrier to colonization by salmonellae, and in the absence of competing flora, reinoculated salmonellae may grow to potentially hazardous densities. The active microflora of moist composts eliminated contaminating salmonellae (105/g) after 6 weeks.
The role of compost microflora in the suppression of salmonella regrowth in composted sewage sludge was investigated. Microbial inhibition studies of salmonella growth were conducted on nutrient agar, in composts that had been subjected to different temperatures in compost piles, and in radiation sterilized composts inoculated with selected fractions of the compost microflora. Agar assays of inhibition indicated that bacteria and actinomycetes were not suppressive to salmonellae, but a few fungi were. However, compost inoculation assays showed consistently that fungi were not suppressive, but bacteria and actinomycetes were. In compost inoculation assays, microbial antagonists, when present, either killed salmonellae or reduced their growth rate. No suppression of salmonellae occurred in compost taken from 70°C compost-pile zones despite the presence and growth of many types of microbes. With greater numbers and kinds of microbes in 55°C compost, salmonella growth was suppressed 100-10,000-fold. Salmonellae died when inoculated into compost from unheated zones (25-40°C) of piles. Prior colonization of compost with only noncoliform gram-negative bacteria suppressed salmonellae growth 3,000-fold. Coliforms when inoculated prior to salmonellae accounted for 75% of salmonella die-off. Mesophilic curing to allow colonization of curing piles in their entirety by gram-negative bacteria, especially coliforms, should be an effective way to prevent repopulation by salmonellae.
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