Coenzyme Q10 Cardioprotective Effects Against Doxorubicin-Induced Cardiotoxicity in Wistar Rat.

In the present study, we investigated the cardioprotective effects of coenzyme Q10 (Q10) against doxorubicin (DOXO) induced cardiomyopathy. Twenty adult rats were distributed in four experimental groups: group 1 received NaCl 0.9% at 1 ml/day for 14 days; group 2 received Q10 at 1 mg/kg/day for 14 days; group 3 received initial 7 days of treatment with NaCl 0.9% followed by a single dose of doxorubicin (12.5 mg/kg IP) and another 7 days of NaCl; and group 4 received initial 7 days of Q10 1 mg/kg/day, followed by a single dose of doxorubicin (12.5 mg/kg IP) and another 7 days of Q10. At the end of 14 days, systolic, diastolic and mean blood pressure, electrocardiogram (ECG), complete blood count, and serum biochemical profile were evaluated. We also analyzed heart histological and ultrastructure analysis, and estimated heart's oxidative stress and lipid peroxidation. DOXO administration altered ECG, with increase heart rate, P-wave duration, PR interval duration, and T-wave amplitude. All the parameters were significantly reduced following Q10 treatment. DOXO also caused increase in CK, CK-MB, LDH, and urea levels, which were not mitigated by Q10 treatment. However, Q10 reduced oxidative stress by interfering with superoxide dismutase, significantly decreasing lipid peroxidation in heart tissue. DOXO administration also leads to several histological and ultrastructure alterations including cardiomyocyte degeneration and intense intracelullar autophagosomes, all minimized by Q10 treatment. Q10 treatment prevented the ECG changes, minimized oxidative stress, lipid peroxidation, and DOXO-induced heart tissue alterations. Our findings suggest that pre- and post-treatment with Q10 exerts potential cardioprotective effect against the DOX-induced cardiotoxicity.

Sequential administrations of trifluoroacetate induce tolerance to Palicourea maccgravii, a monofluoroacetate-containing plant, in calves.

Monofluoroacetate (MFA) is considered one of the most toxic substances known. It is found naturally in plants, and causes sudden death syndrome in ruminants. Due to hyperacute evolution of poisoning and the absence of effective treatment, induction of resistance in animals might be the best tool to control MFA poisoning in ruminants. The objective of this study was to promote resistance in cattle against the toxic effects of MFA through its degradation by the ruminal microbiota after the administration of sodium trifluoroacetate (TFA). Ten calves were distributed into two groups: control group (n = 3) and treated group (n = 7). The calves in the treated group received 0.1 mg/kg live weight of TFA, whereas, those in the control group received water; both for 28 consecutive days. The calves were subjected to daily clinical evaluation and weekly blood biochemical determination to identify any signs of poisoning. After 28 d of administration of TFA or water, 2.0 g/kg body weight of Palicourea marcgravii leaves (containing 0.15% MFA) were administered using a stomach tube to determine the occurrence of resistance. The administration of TFA did not induce any clinical or biochemical changes in blood. The administration of P. marcgravii induced clinical changes in the calves of control group, but there was no change in the calves of the treated group. In conclusion, the administration of TFA to cattle can induce effective resistance against MFA poisoning.

Short communication: Parapoxvirus and Orthopoxvirus coinfection in milk of naturally infected cows.

Several studies have shown the occurrence of poxvirus infections associated with exanthematic lesions in cattle from many Brazilian states. Coinfection between viruses belonging to 2 genera, Orthopoxvirus (OPXV) and Parapoxvirus (PPV), was already identified from the lesions of affected cows and humans. The DNA and infectious viral particles of Vaccinia virus, an OPXV, have been detected in milk of naturally and experimentally infected cows. However, to date no reports have described the detection of Pseudocowpox virus, a PPV, in milk. Thus, we investigated the presence of PPV and OPXV in milk samples obtained from dairy cows from a Brazilian region with exanthematic disease outbreaks. From 2011 to 2014, 6 dairy farms with exanthematic disease outbreaks involving dairy cows, calves, and humans were visited. Twelve crusts of cows' teat lesions and 60 milk samples were collected. The crusts and milk samples were analyzed by PCR to detect OPXV or PPV DNA. According to the analyzed crusts, we detected PPV infection in 4 of the 6 visited farms, from which we investigated the PPV contamination in milk. From the 40 milk samples tested, PPV DNA was detected in 12 samples. Of these milk samples, 8 were positive for both PPV and OPXV. This is the first report of PPV DNA detection in milk samples from affected cows, indicating that the virus may be present in milk and potentially contaminating dairy products associated or not with OPXV. In addition to the lesions caused by direct contact, the presence of 2 or more poxvirus species in milk showed that the effect of zoonotic exanthematic diseases on public health and animal husbandry is relevant and cannot be overlooked.