Evaluation of in vivo anthelmintic efficacy of certain indigenous plants against experimentally- induced Ascaridia galli infection in local birds (Gallus domesticus).

The present study was an attempt to evaluate the anthelmintic efficacy of certain indigenous plants against experimentally induced Ascaridia galli infection in local birds (Gallus domesticus). Two indigenous plants viz., Nyctanthes arbor-tristis and Butea monosperma were used based on indigenous technical knowledge (ITK) and ethno-medical uses. Three types of extracts, viz. ethanolic, hydro-ethanolic and aqueous extracts of each of the two plants were prepared and three doses at the rate of 100, 500 and 1000 mg/kg were used for in vivo studies. Piperazine hydrate liquid was used as standard drug at 200 mg/kg body weight. All biochemical and haematological parameters showed a significant increase from 14th day post treatment in birds of all the groups treated with N. arbor-tristis extract at all the doses irrespective of the solvent used. However, the increase in biochemical and haematological parameters with B. monosperma was observed from 21st day of post treatment in all the groups at all the doses. Similarly, piperazine treated group also showed significant increase from 14th day of post treatment. There was significant reduction in egg output in the droppings of the birds treated with ethanolic, hydroethanolic and aqueous extracts of N. arbor-tristis and B. monosperma when compared with infected controls from 7th day onwards.

Influence of malathion pretreatment on the toxicity of anilofos in male rats: a biochemical interaction study.

Toxicity of organophosphates stems mainly from the accumulation of acetylcholine due to inhibition of acetylcholinesterase (AChE). The consequences of excess acetylcholine depend on the events initiated by the interaction of acetylcholine with cholinergic receptors. Lipid peroxidation (LPO) induced by organophosphates also seems to be mediated via cholinergic receptors. Anilofos is a widely used thionoorganophosphate herbicide, while malathion is a thionoorganophosphate insecticide. Thionoorganophosphates undergo mixed function oxidase (MFO)-catalyzed bioactivation to oxons and can induce cholinergic crisis in mammals. Thus, factors (e.g. exposure to certain xenobiotics) which alter the MFO activity, can be assumed to affect the toxicity of these organophosphates. It was investigated in rats if malathion as an inhibitor of MFO can alter the toxicity of anilofos, examining certain biochemical traits in blood, brain and liver. Malathion or anilofos and their combination did not produce any obvious signs of toxicity. Malathion did not alter the anticholinesterase action of anilofos in blood, brain and liver. LPO was increased in erythrocytes, brain and liver with anilofos or malathion and their combination. Production of lipid peroxide in brain of malathion-pretreated rats given anilofos was significantly greater than in rats given anilofos alone. Malathion decreased glutathione (GSH) contents of liver and blood. Glutathione-S-transferase (GST) activity was decreased in the liver with malathion and its combination with anilofos. Total adenosine triphosphatase (ATPase) activity was not affected. Activities of Mg(2+)-ATPase and Na(+)-K(+)-ATPase were increased in the liver and erythrocytes, respectively, with the pesticide combination. Protein level in plasma was decreased with malathion and its combination with anilofos, but only with the combination in the liver. Results of the study indicate that malathion pretreament may not essentially alter the anticholinesterase action of anilofos, but may enhance anilofos-mediated oxidative damage to rat brain.