An epidemiologic study of disease in 32 registered Holstein dairy herds in British Columbia.

Data recorded in a herd health management system were obtained from 32 registered Holstein dairy herds from British Columbia. Frequencies of disease were described, and the effect of herd, age, year, season, and the interrelationships between diseases within a lactation on the occurrence of disease were evaluated. Lactational incidence rates were computed for diseases with a short period of risk (ie, udder edema, milk fever, retained placenta, metritis, displaced abomasum, and ketosis), whereas for diseases with a longer period of risk (ie, cystic ovaries, mastitis and stable footrot), incidence densities were calculated. Overall, the disease incidence was low and showed an increase in frequency by year, which we attributed to more observing and complete recording by the owner, rather than an actual increase in disease incidence. Most diseases occurred early in lactation and their frequency increased with lactation number; the exception was udder edema, which occurred mainly during the first 2 lactations. An informal path model of disease interrelationships was made conditional on herd. Based on the results we inferred 2 independent pathways: one started by udder edema, and the other by milk fever. Udder edema was directly associated with mastitis occurrence from 0 to 30 d in lactation, metritis, and cystic ovaries. Mastitis from 0-30 d in lactation increased the risk of both mastitis from 31-150 d in lactation and cystic ovaries. Both of these increased the risk of late lactation mastitis. Milk fever was directly related with displaced abomasum, which increased the risk of footrot. In general, diseases that occurred in early lactation tended to increase the risk of other diseases later in lactation.

Cell replication rates and processes concerning antibody production in vitro are not influenced by 2.45-GHz microwaves at physiologically normal temperatures.

Several contradictory papers concerning the effects of microwaves on living organisms and on in vitro cell suspensions have been published through the years. These papers are difficult to interpret, because temperature measurement data are often lacking. Reliable temperature measurements are important, because they enable one to determine whether the observed microwave effects are thermal or nonthermal. Therefore, a method was developed to investigate microwave effects on cellular processes, in which the temperature was precisely monitored during microwave treatment using a fiberoptic thermometer. This method involved the processes required for in vitro production of monoclonal antibodies. Monoclonal antibodies are vital ingredients in (microwave-stimulated) immunostaining techniques and ELISAs, which have become important techniques in neuroscience. The effects of 2.45-GHz microwaves on mouse myeloma and (neural) hybridoma cell replication rates and on antibody production were investigated. In addition, the effects on the cell fusion abilities of spleen lymphocytes and myeloma cells and on in vitro immunization were studied. The results of this study show no effects of microwaves on either of the processes mentioned using exposure times up to 5 h a day at a physiologically normal temperature of 37 degrees C. It was concluded that the effects of 2.45-GHz microwaves detected at higher temperatures are thermal effects and that no indications for nonthermal 2.45-GHz microwave effects exist under the exposure conditions used in the present study.

Combining microwave stabilization and microwave-stimulated fixation of brain tissue with microwave-stimulated staining.

Microwave stabilization of rat brain tissue using saline was compared with microwave-stimulated fixation using either formaldehyde or Kryofix. Sections were stained according to the microwave-adapted Nissl, Klüver-Barrera, and Bodian methods. Depending on the preparative choice the microwave staining method had to be adjusted. Optimal combinations of preparative techniques and staining methods are feasible. In most cases the microwave saline-stabilized and microwave Kryofix-treated sections were better suited for application in neurohistology than the microwave formaldehyde-treated sections for light microscopy.

A rapid ELISA for measurement of anti-glomerular basement membrane antibodies using microwaves.

The presence of anti-glomerular basement membrane antibodies is one of the features of Goodpasture's syndrome. Since the disease has a rapidly progressive course, an early diagnosis is essential. As was already demonstrated in other ELISA methods, 2.45-GHz microwave irradiation can accelerate all kinds of time consuming processes in several laboratory techniques. The application of microwaves in an ELISA for the measurement of anti-GBM antibodies in serum indicated that a considerable time reduction of 75% can be achieved, resulting in a rapid and reliable assay. In addition, microwaves can also have a positive effect on the resolution of that particular ELISA as shown in this study.

ELISA incubation times can be reduced by 2.45-GHz microwaves.

The ELISA (Enzyme Linked Immuno Sorbent Assay) technique is widely applied in the field of immunology. The use of this technique implies several incubation periods, often requiring more than one hour each. Microwave irradiation is known to be very useful in accelerating different kinds of processes. This knowledge has led to the present study in which it is proved that 2.45-GHz microwaves are able to reduce ELISA incubation times. This time reduction of 50% or more concerns each of the four incubation steps of the specific indirect ELISA which is used to determine the amount of antibodies in NF90-hybridoma cell culture supernatants. These incubation steps involve the coating of the microtiter plate, the incubation with BSA against non-specific binding, and the incubations with the first and second antibody. Combinations of more microwave-influenced steps in one ELISA save a considerable amount of time. When in addition air is blown through the incubation fluid during microwaving, the extinction values are almost the same as those of conventionally performed ELISAs. Thus, a good match of power setting and irradiation time results in a total incubation time reduction from 5.5 hours to 2 hours in this particular ELISA. Carefully monitoring the temperature of the incubation fluids during irradiation with the use of a fiberoptic thermometer appeared to be of crucial importance in the development of an optimal procedure.

No evidence for effects of mild microwave irradiation on electrophysiological and morphological properties of cultured embryonic rat dorsal root ganglion cells.

Effects of mild microwave treatment (1 hr, 37 degrees C) on the in vitro development of rat mechanically dissociated dorsal root ganglion (DRG) neurons were investigated to establish whether microwave irradiation effects exist on nervous tissue other than heat induced tissue fixation. Phase contrast microscopy and immunocytochemical neurofilament stainings did not reveal significant differences between irradiated (2 hr after isolation) and control cultures, maintained up till 21 days. The electrophysiological properties of microwave exposed and non-exposed DRG neurons were compared using the whole-cell patch-clamp technique. Control neurons, in culture for 0-12 days, were excitable. In cultured cells (1-12 days), microwaved 2 hr after isolation, the action potentials were similar to or slightly different from those of the control cells. No acute microwave effects were found on neurons irradiated after 1 day of culture. These results suggest that mild microwave irradiation has neither significant acute nor strong long-term effects on DRG culture development and DRG neuron membrane properties, consistent with the notion that microwave effects essentially are temperature effects.

Morphological and functional properties of rat dorsal root ganglion cells cultured in a chemically defined medium.

A culture procedure for dorsal root ganglion (DRG) cells is presented using a completely defined culture medium without antibiotics, in combination with mechanical dissociation procedures. This culture procedure allows all dorsal root ganglion cell types to be cocultured for periods of at least 106 days. Some of the dorsal root ganglion neurons, which could be identified by their neurofilaments and the presence of fluoride resistant acid phosphatase, regained their original T-cell appearance within two weeks. After one month in culture ganglion-like reaggregates appeared. Schwann cells, satellite cells and fibroblasts were identified using morphological criteria. All neurons tested maintained excitability during, at least, the first 35 days in culture, since in all cases action potentials could be evoked by current pulses. The method has proved to be useful in the study of morphological, cytochemical and electrophysiological aspects of dorsal root ganglion cell differentiation in vitro.