monensin has been researched along with Plant-Poisoning* in 2 studies
2 other study(ies) available for monensin and Plant-Poisoning
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Flatpea intoxication in sheep and indications of ruminal adaptation.
This paper describes the signs of toxicity when seed-bearing flatpea (Lathyrus sylvestris L) hay is fed to sheep. Signs of intoxication (including seizure, muscular trembling and spasmotic torticollis) are similar to those observed for ammonia toxicity in ruminants. Accumulation of ammonia may be a direct consequence of flatpea ingestion, given that 2,4-diaminobutyric acid (DABA, a toxic constituent of flatpea) is known to inhibit hepatic urea synthesis. However, other modes of toxicity for DABA as well as other flatpea toxins may also contribute to this process of intoxication. Our evidence suggests that ruminal microbes are responsible for flatpea detoxification and host animal protection. The adaptation of sheep to flatpea may be a consequence of enhanced ruminal detoxification activity. Ruminal protective functions can be disrupted, however, through abrupt monensin feeding or the replacement of nonadapted for adapted rumen contents. This disruption temporarily suppresses mechanisms of ruminal detoxification. As a consequence sheep can again be made vulnerable to flatpea intoxication. Topics: Adaptation, Biological; Animal Feed; Animals; Fabaceae; Monensin; Plant Poisoning; Plants, Medicinal; Rumen; Sheep; Sheep Diseases | 1993 |
Clinical, clinicopathologic, and pathologic alterations in acute monensin toxicosis in cattle.
Twenty beef calves weighing approximately 180 kg were allotted to 3 groups. In group A, 6 calves were given 25 mg of mycelial monensin/kg of body weight orally and were evaluated at 1, 2, and 4 days for clinical, ECG, clinicopathologic, and pathologic alterations. In group B, 7 calves were given a single dose of monensin (40 mg/kg) and 5 were given a 2nd 40 mg/kg dose on day 7; calves were evaluated at days 1, 2, 4, 7, 8, 9, and 11. In group C, 2 calves served as controls. Monensin-treated calves developed anorexia, diarrhea, and lethargy after day 1. One group B calf died on day 7 with lesions of congestive heart failure. Electrocardiographic abnormalities were not observed in group A calves; in group B, prolongation of Q-T and QRS intervals occurred from days 2 to 11 and first degree heart block was seen from days 7 to 11. Clinicopathologic alterations included: increased serum activities of aspartate aminotransferase and creatine kinase in group B calves after day 2; decreased serum K+, Na+, and Ca2+ concentrations in both groups, and postdosing occurrence of leukocytosis. Calves were euthanatized sequentially and the lesions of monensin toxicosis were present in the heart, skeletal muscles, and rumen in groups A and B. Disseminated pale yellowish-brown areas of necrosis were present in the ventricular myocardium of 6 of 12 group B calves. Gross lesions were not present in the skeletal muscles or rumen. Microscopically, the myocardial and skeletal muscular lesions were characterized by sarcoplasmic vacuolation from mitochondrial swelling and lipid accumulation in calves killed after day 1 in groups A and B, and by myocardial necrosis with contraction bands, but without calcification, in group B calves killed by day 4. Acute rumenitis was present in groups A and B calves. Myotoxic effects of monensin may be related to its action as an ionophore producing altered intracellular ion concentrations and initiating degeneration and necrosis in striated muscle fibers. Topics: Acute Disease; Animals; Cassia; Cattle; Cattle Diseases; Diagnosis, Differential; Female; Furans; Heart; Male; Monensin; Muscles; Myocardium; Necrosis; Plant Poisoning; Plants, Medicinal; Rumen; Selenium; Vitamin E Deficiency | 1983 |