Administration of vitamin K1, SC, to anticoagulant-poisonsed (diphenadione) dogs provided diagnostic information within 4 hours, when vitamin K1 and its epoxide were measured in canine sera. Twelve dogs (2 groups of 6) were given 2.5 mg of diphenadione/kg of body weight for 3 days. Dogs were treated with vitamin K1, 2.5 (n = 6) or 5 mg/kg/day (n = 6) SC for 21 days, and their responses were compared. Four nonexposed control dogs were given 5 mg of vitamin K1/kg/day. Serum concentration of vitamin K epoxide was significantly (P less than 0.02) higher in diphenadione-exposed dogs than in control dogs 1 to 4 hours after the initial vitamin K1 treatment on day 4. Vitamin K epoxide/vitamin K1 ratios were similarly higher and became more distinct. Cessation of vitamin K1 therapy on day 24 resulted in prolongation of one-stage prothrombin times in diphenadione-exposed dogs, becoming clearly evident on day 27. Serum vitamin K1 concentrations were not detectable on day 27 in diphenadione-exposed dogs, whereas serum vitamin K1 concentrations were readily detectable in control dogs. One stage prothrombin time changes, during days 24 to 32, indicated 5 mg of vitamin K1/kg provided better protection than did 2.5 mg of vitamin K1/kg. Coagulopathy in the dogs was resolved by day 32.

The effects of administration of a commercially available extract of Gingko biloba (EGB) on bromethalin-induced brain lipid peroxidation and cerebral edema in adult male Sprague-Dawley rats was determined. Gingko biloba extract was given (100 mg/kg) by gavage immediately after bromethalin (1.0 mg/kg) administration. Rats were euthanatized at 24 hours after dosing. Brain lipid peroxidation was determined by measurement of brain malonaldehyde-thiobarbituric acid chromophore (MDA-TBA) concentration, brain sodium concentration, and brain water content. Treatment of bromethalin-dosed rats (10/group) with EGB was associated with a statistically significant (P < 0.05) decrease in clinical sign severity, compared with bromethalin-dosed saline solution-treated rats. All rats given bromethalin and saline solution developed clinical signs of toxicosis including CNS depression, hind limb weakness, ataxia, paralysis, and coma. Some rats given bromethalin and EGB developed clinical signs, however, none developed hind limb paralysis. The brain MDA-TBA concentration (2.4 +/- 0.5 delta MDA-TBA concentration/mg of protein), percentage of water in brain tissue (80.3 +/- 0.30%), and brain sodium concentration (6.68 +/- 0.21 mg/g of dry weight) were significantly increased in rats given bromethalin and saline solution, compared with control rats given saline solution (1.0 +/- 0.1 delta MDA-TBA concentration/mg of protein; 78.1 +/- 0.33% water in brain tissue; 4.83 +/- 0.30 mg of brain Na+/g of dry weight) and rats given bromethalin and EGB (1.6 +/- 0.2 delta MDA-TBA concentration/mg of protein; 79.3 +/- 0.31% water in brain tissue; 5.37 +/- 0.34 mg of brain Na+/g of dry weight). The MDA-TBA concentration (1.2 +/- 0.2 delta MDA-TBA concentration/mg of protein), percentage of water in brain tissue (78.7 +/- 0.40%), and brain sodium concentration (4.93 +/- 0.26 mg/g of dry weight) increased slightly in control rats given EGB.

Anticoagulant rodenticides are biocides that interfere with normal blood clotting, inhibit the vitamin K cycle in the liver, and cause death by hemorrhages. Even though the main target of these compounds is rodents, they may affect non-target species such as nocturnal birds of prey that feed on those rodents. To study secondary exposure to ARs, select species that specialize in rodent prey, such as nocturnal birds of prey. Besides their specialized diet in rodents, nocturnal birds of prey are one of the most widely distributed birds in Europe and live in rural and non-rural habitats, making them excellent sentinel species for several studies’ ecotoxicology studies. There are numerous studies regarding secondary AR exposure in raptor species all around the world, but evidence for population-level effects is still absent. The objective of this review is to show how ARs have influenced wild nocturnal birds of prey in Europe in the last decades, most affected species, and in summary, explain how they act and the main clinical signals/ lesions that can be observed in poisoned birds. Overall, a total of 19 works were included in this review, between the years 1983 to 2021 that satisfied all literature criteria. These 19 papers corresponded to 44 observations of different species, regarding eight types of anticoagulant rodenticide. In the future, more caution is needed in the use of anticoagulants for rodent control where avian predators may be exposed to poisoned prey. Some combinations can be highly lethal to the predator, putting it at risk species that are already treated, therefore new eco-friendly alternatives should be found.