Clinical efficacy of milbemycin oxime in the treatment of nasal mite infection in dogs.

A multicentric clinical trial was done to evaluate the clinical efficacy of milbemycin oxime in the treatment of nasal mite (Pneumonyssoides caninum) infection in dogs. Milbemycin oxime was given to 70 dogs of different breeds, genders, and ages, with clinical signs associated with nasal mite infection. Twenty-five dogs had a verified infection, and 45 dogs had signs suggestive of nasal mite infection. Milbemycin oxime was given at the dosage of 0.5 to 1.0 mg/kg body weight orally once a week for three consecutive weeks. One month after initiation of treatment, 68 of the dogs had no more clinical signs associated with nasal mite infection.

The induction of chromosomal aberrations and SCEs by visible light in combination with dyes. II. Cell cycle dependence, and the effect of hydroxyl radical scavengers during light exposure in cultures of Chinese hamster ovary cells sensitized with acridine orange.

Chinese hamster ovary (CHO) cells were synchronized by mitotic shake-off, treated with the fluorochrome acridine orange (AO; 0.5 micrograms/ml), washed free of excess dye and subsequently exposed to visible light (2 X 40 W/8 Wm-2). The light exposure was performed on cells in the G1, G1/S, S or G2 phase of the cell cycle. AO + light induced high frequencies of aberration in the S phase and even higher in the G1 phase. The aberrations observed were all of the chromatid type. The chromosome-type aberrations (dicentrics, rings) obtained when cells in the G1 phase were exposed to X-rays were not found after corresponding treatments with AO + light. With the exception of an increased frequency of gaps, no chromosomal aberrations were induced in G2-phase cells. Sister-chromatid exchanges were efficiently produced by the photodynamic system in the G1, G1/S and S phase of the cell cycle. In other experiments, AO-treated unsynchronized CHO cells were exposed to light in the presence of the hydroxyl radical scavengers mannitol (100 mM) and 5-dimethyl thiourea (100 mM). In parallel experiments these scavengers were found to reduce markedly the chromosome breaking effects by X-rays but had no influence on the photodynamic induction of chromosomal alterations. The results presented show that the visible light-induced chromosomal alterations in CHO cells sensitized with the fluorochrome AO are obtained by an S-dependent mechanism. Furthermore, the results indicate that the hydroxyl free radical does not play a major role in the production of chromosomal alterations by AO + light.

The induction and repair of DNA damage detected by the DNA precipitation assay in Chinese hamster ovary cells treated with acridine orange + visible light.

The photodynamic effect of the dye acridine orange (AO) in combination with visible light (400-700 nm) was studied in Chinese hamster ovary (CHO) cells, the endpoints investigated being induction, as well as repair, of DNA strand breaks. Cells were treated for 20 min with AO (0.1-3.0 micrograms/ml), washed free of excess dye and subsequently exposed to low doses of visible light (2 x 40 W/8 W/m2) for 5-15 min. AO proved to be an efficient sensitizer for light-induced DNA strand breaks, detected with the DNA precipitation assay, and expressed as percentage of DNA precipitated. The induction of breaks was linear up to 0.5 micrograms/ml AO + 10 min of light, which corresponds to 55% precipitated DNA, and was dependent on the concentration of AO as well as on the dose of light delivered. As a comparison, 18 Gy of X-rays was required to yield an equivalent amount of induced DNA strand breaks. The rejoining of the light-induced DNA strand breaks was studied by incubating the AO-sensitized cells for 30-120 min at 37 degrees C directly after light exposure. A fast recover of 67-91% of the damage (compared to initial damage, recovery time = 0, and dependent on the concentration of AO) was observed during the first 30 min of incubation. However, a significant amount of DNA damage remained after 2 h of recovery. These remaining, long-lived lesions might be involved in the photoinduced and acridine-sensitized chromosomal aberrations and sister-chromatid exchanges (SCE). The significance of these observations is discussed in relation to AO-sensitized and photoinduced DNA damage and chromosomal alterations.

The induction of chromosomal aberrations and SCE by visible light in combination with dyes. I. The effect of hypoxia during light exposure in unsynchronized Chinese hamster ovary cells, sensitized with acridines.

A comparison has been made between the ability of different acridine compounds to act as sensitizers for visible light (400-700 nm) induced chromosomal aberrations and sister-chromatid exchanges (SCE) in unsynchronized Chinese hamster ovary (CHO) cells. Cells were treated for 20 min with acridines (0.1-5.0 microgram/ml), washed free of excess dye and subsequently exposed to visible light (2 x 40 W/8 W m-2) either in air or in nitrogen for 5-15 min. The 4 acridines tested, proved to be effective sensitizers for the induction of both chromosomal aberrations and SCE by visible light. The most pronounced effect was observed when the light exposure of the fluorochrome-pretreated cells was performed in air. Hypoxic conditions during light exposure reduced the effect dramatically, especially in the case of induced chromosomal aberrations. The order of efficiency for the induction of both chromosomal aberrations and SCE was acridine orange greater than acridine yellow greater than proflavine greater than 3,6-diamino-10-methylacridine. The results are discussed in terms of S-independent versus S-dependent mechanisms for inducing chromosomal alterations and the potential involvement of oxygen-derived free radicals in this process.

Chromosomal aberrations and sister-chromatid exchanges in lymphocytes of men occupationally exposed to styrene in a plastic-boat factory.

Workers in a Swedish factory making boats from plastics reinforced with glass fibre are exposed to a variety of chemicals, including styrene which is mutagenic after metabolic activation. The concentration of styrene in the air was measured in the breathing zones of workers occupied with various processes in boat making. Samples of air were taken 6 times during the years 1973-1978. The total exposure to styrene for the workers during this period was calculated and expressed as the average concentration in mg per m3 air during an 8-h workshift multiplied by the number of years of employment. A low-dose group (mean = 137 mg x m-3) and a high-dose group)mean - 1204 mg x m-3) were identified. Blood samples were taken in 1978 from workers belonging to the exposed groups and from a matched control group of employees in the same factory not exposed to styrene. Lymphocytes were cultured and examined for chromosomal aberrations and sister-chromatid exchanges. Exposed workers had a significantly (p less than 0.001) higher number of chromosomal aberrations (36 persons, mean = 7.9 aberrations/100 cells) compared with employees in the control group (37 persons, mean = 3.2 aberrations/100 cells). There was no significant difference between the mean values of the number of chromosomal aberrations between the highly exposed and the less exposed groups. But in the less exposed group there was an increase in the frequency of chromosomal aberrations with increasing exposure to styrene (r = 0.576). In the highly exposed group this dose response was not observed (r = 0.231). For the frequency of sister-chromatid exchanges (SCE) a slight (p less than 0.05) increase was found in the styrene-exposed group (20 persons, mean = 8.4 SCE/cell). The control group (21 persons) had a mean value of 7.5 SCE/cell. Again there was no difference between the highly exposed and the less exposed groups. Other environmental factors that may have clastogenic effects were studied, but multiple regression analysis failed to show a candidate responsible for the increase in chromosomal abnormalities in the exposed group.