Distribution of phosphorus, copper and zinc in activated sludge treatment process of swine wastewater.

Changes in swine wastewater chemical features during an activated sludge treatment process were surveyed on 11 farms, and analyzed with non-biodegradable elements, i.e., phosphorus (P), copper (Cu), and zinc (Zn). In piggery wastewater, they were linearly correlated with suspended solid (SS) concentrations and the major portion was in solid fractions. After the pretreatment step, they were removed, with 80% for total P, 85% for total Cu, and 84% for total Zn. After the activated sludge process, total P, Cu, and Zn were then removed at 83%, 96%, and 95%, respectively. Removing SS thoroughly at each step was shown to be the most important factor in preventing outflow of these elements, since there are linear correlations or a positive relationship between the removal of SS concentrations and their removal in solid form. Most of the P, Cu, and Zn in activated sludge effluent was in soluble form, and the concentrations of Cu and Zn in the effluent were low enough, while further P removal might be required.

Rate determination and distribution of anammox activity in activated sludge treating swine wastewater.

This paper presents a quantitative investigation and analysis of anammox activity in sludge taken from biological swine wastewater treatment plants. An incubation experiment using a (15)N tracer technique showed anammox activity in sludge taken from 6 out of 13 plants with the rate ranging from 0.0036 micromol-N(2)/g-VSS/h to 3.1 micromol-N(2)/g-VSS/h, and in a biofilm with the highest activity at 25.8 micromol-N(2)/g-VSS/h. It is notable that 9 out of 11 sludges in which the pH was maintained between 6.6 and 8.1 retained anammox activity, while those with either a lower or higher pH did not. Moreover, anammox-positive sludge had a significantly higher concentration of NO(2)(-)-N plus NO(3)(-)-N than did anammox-negative sludge. A significant difference was not observed between anammox-positive and -negative sludge regarding BOD/NH(4)(+)-N in the influent, DO concentration in aeration tanks, and the concentrations of NH(4)(+)-N, free nitric acid, and free ammonia.

Cellular migration in the postnatal rat cerebellar cortex: confocal-infrared microscopy and the rapid Golgi method.

Confocal laser microscopy of DiI-labeled slices of postnatal rat cerebellum (postnatal Day 4-10; P4-10) was compared to infrared microscopy and the rapid Golgi method (P0-14) to investigate postnatal migration of granule neurons. Vertical migration of the granule neurons occurred already at birth (P0). Surprisingly, mossy fibers often reached the external granule cell layer and were in close contact with the external granule cells. These mossy fibers may play a role in initiating granule cell migration. At this age, cell bodies of the immature neurons were attached to the external basal lamina by a process and extended down toward the presumptive internal granule cell layer. At P14, some granule cells remained attached to the surface, although their cell bodies exhibited the typical morphology of mature granule neurons and were located deep in the internal granule cell layer. These cells extended their endfeet-like processes all the way to the surface of the brain. These results indicate that the vertical pathways of granule cell migration form early and persist throughout the period of granule cell migration. Confocal infrared microscopy of DiI-labeled sections and the rapid Golgi method also allowed demonstration of tangentially migrating neurons that made one or more turns on the way to the internal granule cell layer. The rapid Golgi method confirmed that many Bergmann glial processes end at the level of the tangentially migrating granule cells whereas others project to the surface. These observations show that migratory granule cells take several different routes to their final destination, which cannot be explained by so-called radial glial guidance. The only mode of migration in evidence is consistent with process elongation and translocation of the nucleus within the preformed processes.