J.K. Malik

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.

Perturbations in immune responses induced by concurrent subchronic exposure to arsenic and endosulfan

The metalloid arsenic and the chlorinated insecticide endosulfan are common environmental contaminants. Humans, animals, and birds are exposed to these chemicals through water and food. Although health effects due to either arsenic or endosulfan exposure are documented, the toxicological impact of co-exposure to these environmental pollutants is unpredictable and unknown. The present study was undertaken to assess whether concurrent exposure to arsenic and endosulfan induces significant alterations in immunological functions. Day-old chicks were exposed to 3.7 ppm of arsenic via drinking water and to 30 ppm of endosulfan-mixed feed either individually or concurrently for up to 60 days. All the chicks were vaccinated with Ranikhet disease virus (F-strain; RD-F) on days 1 and 30. During the course of study and at term, parameters of cellular and humoral immunity were determined. None of the treatments altered the absolute body weight or body weight gain, except arsenic significantly reduced weight gain on day 60. Absolute, but not the relative, weights of spleen, thymus and bursa of Fabricius were significantly reduced in all the treatment groups. The metalloid and insecticide combination significantly depressed the ability of peripheral blood and splenic lymphocytes to proliferate in response to antigen RD-F and mitogen Con A. The delayed type hypersensitivity response to 2,4-dinitro-1-chlorobenzene or to PHA-P was also significantly decreased. Nitric oxide production by RD-F or lipopolysaccharide-stimulated peripheral blood and splenic mononuclear cells was significantly suppressed following concurrent exposure to arsenic and endosulfan. Furthermore, the combined exposure also decreased the antibody response to RD-F. The suppression of cellular and humoral immune responses was also evident following administration of individual compounds, and it was not exacerbated following concurrent exposure. To our knowledge, this is the first report describing the suppression of immune responses following exposure to arsenic alone or in combination with endosulfan at environmentally realistic concentrations in avian species. Therefore, immunotoxicological effects induced by concurrent exposure to arsenic and chlorinated pesticides should be considered when assessing the risk to human and animal health.

Pro-healing potential of hemin: An inducer of heme oxygenase-1

Hemin induces heme oxygenase (HO), an enzyme which degrades heme in a rate-limiting manner and has an important role in cellular protection against oxidative stress and apoptosis. This HO inducer may be of potential therapeutic value in wound healing and inflammation. To identify the beneficial activity of HO vis a vis wound healing, hemin was used as inducer of HO in rats using a full-thickness cutaneous wound model. Hemin treatment increased cellular proliferation and collagen synthesis as evidenced by increase in wound contraction and hydroxyproline and glucosamine contents. mRNA expression of cytokines endorsed fast healing as was indicated by inhibition of pro-inflammatory cytokines such as ICAM-1 and TNF-alpha and up-regulation of anti-inflammatory cytokine IL-10.

Effects of simultaneous repeated exposure at high levels of arsenic and malathion on hepatic drug-biotransforming enzymes in broiler chickens.

Groundwater contamination with arsenic is a major global health concern. The organophosphorus insecticide malathion has gained significance as an environmental pollutant due to its widespread use in agriculture, grain storage, ectoparasite control and public health management. The deleterious effects produced by arsenic or malathion alone are documented, but very little is known about the consequences of their coexposure. The aim of the current study was to examine the effects of repeated simultaneous exposure to arsenic and malathion on drug-biotransforming enzymes in the liver of broiler chickens. One-month-old broiler chickens were exposed daily to arsenic (50 ppm)-supplemented drinking water, malathion (500 ppm)-mixed diet or in a similar fashion coexposed to these agents for 28 days. At the term, changes in body weight, organ weights, and levels of hepatic cytochrome P450 (CYP), cytochrome b(5), microsomal and cytosolic proteins; aminopyrine N-demethylase (ANDM), aniline P-hydroxylase (APH), glutathione S-transferase (GST) and uridine diphosphate glucuronosyltransferase (UGT) were assessed. Arsenic, malathion or their coexposure decreased the body weight gain and liver weight. Brain weight (relative) was increased with arsenic or malathion, but not with the coexposure. Treatment with arsenic decreased the CYP and cytochrome b(5) contents by 39 and 36%, than with malathion by 54 and 22% and the coexposure by 45 and 28%, respectively. The ANDM activity was decreased with arsenic (44%), malathion (23%) and the coexposure (32%). Arsenic (23%) and the coexposure (37%), but not malathion (14%), reduced the APH activity. The activities of hepatic microsomal and cytosolic GST were increased with all the three treatments [Arsenic (microsomal: 88% cytosolic: 113%), malathion (microsomal: 137%, cytosolic: 94%) and coexposure (microsomal: 140%, cytosolic: 148%)]. These treatments did not significantly affect the hepatic UGT activity, but reduced the hepatic microsomal (arsenic: 28%, malathion: 34% and coexposure: 43%) and cytosolic (17-19%) protein contents. The effects of coexposure on the activities of various phase I and phase II drug-biotransforming enzymes were almost similar to that of arsenic or malathion. This study provides evidence that repeated coexposure to arsenic and malathion may influence the extent of drug metabolism in chickens.

Effects of subchronic malathion exposure on the pharmacokinetic disposition of pefloxacin.

Malathion is one of the most extensively used organophosphorus pesticides applied in agriculture, mosquito eradication and in the control of animal ectoparasites and human body lice. The widespread use of malathion has raised concern over its potential to cause untoward health effects in humans, animals and birds. Malathion inhibits cytochrome P450 monooxygenases and has the potential to alter pharmacokinetic profiles of therapeutic agents that are metabolized in the liver. The present study was undertaken to evaluate the impact of subchronic exposure of malathion on the pharmacokinetic disposition of pefloxacin. Chickens were given either normal diet or malathion through food at a concentration of 1000ppm for 28 days. Subsequently, pefloxacin was administered either intravenously or orally (control) to birds fed normal diet and orally to malathion-exposed chickens at a dosage of 10mgkg(-1) body weight. Blood samples were drawn from the brachial vein at predetermined time intervals after drug administration. Plasma was separated and analyzed for pefloxacin by reverse-phase high performance liquid chromatography. The plasma concentration-time data were analyzed by non-compartmental techniques. Following intravenous administration of pefloxacin, elimination half-life (t(1/2β)), area under the plasma concentration-time curve (AUC) and mean residence time (MRT) were 8.2±0.7h, 66±9μghml(-1) and 10.5±1.1h, respectively, and when the drug was administered orally, the respective values of pharmacokinetic parameters were 8.2±0.4h, 31±3.1μghml(-1) and 11.7±0.6h. Malathion exposure significantly increased maximum plasma drug concentration, t(1/2β), AUC and MRT of pefloxacin to 54, 22, 117 and 37% of control, respectively. These findings provide evidence that subchronic malathion exposure markedly influences the elimination kinetics of pefloxacin which may be due to malathion-mediated inhibition of metabolism of pefloxacin.

Effects of aflatoxin B1 on tissue residues of enrofloxacin and its metabolite ciprofloxacin in broiler chickens

The impact of subchronic exposure of aflatoxin B1 on the tissue residues of enrofloxacin and its metabolite ciprofloxacin was examined in broiler chickens. Broiler chickens given either normal or aflatoxin B1 (750 μg/kg diet) supplemented diets for 6 weeks received enrofloxacin (10 mg/kg/day, p.o.) for 4 days and thereafter, residue levels were determined. Aflatoxin B1 induced alterations in serum marker enzymes. As compared to unexposed broiler chickens, enrofloxacin concentrations in aflatoxin B1-exposed broiler chickens were significantly higher in all tissues (0.62-4.53 μg/g) analyzed except muscle 24h after termination of enrofloxacin administration. Ciprofloxacin was detectable in tissues of only mycotoxin-exposed broiler chickens. Enrofloxacin residues in liver, kidney and skin plus fat persisted for 10 days in mycotoxin-exposed broiler chickens whereas it was detectable only in liver of unexposed broiler chickens. Our results indicate that subchronic aflatoxin B1 exposure markedly influences the residue levels of enrofloxacin and ciprofloxacin in tissues of broiler chickens.

Protective effect of curcumin against arsenic-induced apoptosis in murine splenocytes in vitro

Arsenic is a potent environmental pollutant and immunotoxic agent. Curcumin is a natural anti-oxidant used to treat a broad variety of diseases. Here, the effects were investigated of curcumin on sodium arsenite-induced apoptosis in murine splenocytes in vitro. Cells were exposed to sodium arsenite (NaAsO2, 5 µM) with and without curcumin (5 and 10 µg/ml) and incubated at 37°C for 12 h. NaAsO2 caused a decrease in cell viability and induction of apoptosis. These outcomes were concurrent with increases in the numbers of cells with reactive oxygen species generation, loss of mitochondrial transmembrane potential, an increase in the frequency of cells with sub-G1 DNA content, and DNA fragmentation. Co-administration of curcumin with the NaAsO2 caused significant recoveries in cell viability values and mitigation of the induced apoptosis-related molecular changes. A significant protection against apoptosis parameters in murine splenocytes simultaneously treated with NaAsO2 and curcumin suggested a protective efficacy of curcumin. From the results it is concluded that the immuno-modulation exerted by curcumin might be attributed to its multifaceted effects including its anti-oxidative and anti-apoptotic properties. These findings have implications not only for the under-standing of the toxicity of arsenic to murine splenocytes in vitro but are also potentially important for developing preventive and/or corrective strategies against/during chronic arsenicosis.

Organophosphate and carbamate pesticides

Publisher Summary This chapter discusses organophosphate (OP) and carbamate (CM) pesticides. OP and CM are used worldwide as pesticides in agriculture and public health protection, and in veterinary and human medicine. There is mounting evidence suggesting that these pesticides produce reproductive and developmental toxicity. OPs and CMs are used for a variety of purposes, such as insecticides to protect crops, gardens, homes and offices, agents of warfare, threat and terror, and therapeutic agents in human and veterinary medicine. For both types of pesticides, the brain is the primary target organ, especially during prenatal and neonatal periods, Toxicokinetic studies revealed that it is rapidly absorbed, distributed and metabolized in both animals and humans. Inhibition of AChE by OPs and CMs leads to excessive ACh accumulation at the synapses and NMJs, which results in overstimulation of muscarinic and nicotinic ACh receptors. Many OPs and CMs are developmental neurotoxicants, and therefore it is of great interest to focus on the effects of anti-ChEs on the developing central nervous system (CNS). It has been reported that multiple neurotransmitter systems are modulated by these pesticides. Mechanisms in reproductive and developmental toxicity, including oxidative stress in developmental neurotoxicity and endocrine disruption, are described in this chapter. Reproductive toxicity is expressed as alterations in sexual behavior and performance, infertility and/or loss of the fetus during pregnancy. The effects of toxicity in males and females are described in this chapter. The risk assessment process involves four steps: hazard identification, dose–response assessment, exposure assessment, and risk characterization.

Immunoprotective effect of curcumin on cypermethrin-induced toxicity in rats

Immunotoxicological effects of cypermethrin and their reversal by curcumin following oral administration were evaluated in rats. Mature male Wistar rats were orally administered cypermethrin (25 mg kg−1 body wt), curcumin (100 mg kg−1 body wt) or both daily for 4 weeks. At the end of fourth week, hematological, serum biochemical, and immunological parameters were studied. Subchronic exposure to cypermethrin significantly reduced body weight, total leukocyte count, lymphocyte count, serum total protein, serum albumin, serum globulin, antibody titer against sheep red blood cells, and cell-mediated immunity. Concomitant curcumin administration restored the changes in the body weight, hematological parameters, and serum biochemical indices and significantly increased the antibody titer, and cell mediated immunity. These results suggest that concurrent curcumin treatment has a beneficial role in mitigating immunotoxicological and other adverse effects of cypermethrin.

Chlorinated Hydrocarbons and Pyrethrins/Pyrethroids

Publisher Summary This chapter discusses chlorinated hydrocarbons and pyrethrins/pyrethroids. Chlorinated hydrocarbon insecticides were heavily used after their introduction, but due to ecological considerations, have been banned in most countries for the past three decades. There is an increasing concern that chlorinated hydrocarbon and pyrethroid insecticides produced reproductive and developmental toxicity. There is evidence suggesting that effects of the pyrethroids on dopaminergic nerve pathways may be a contributory factor in the etiology of environmentally induced Parkinsons disease. Pyrethroids (synthetic pyrethrins) are one of the important groups of insecticides, with low mammalian toxicity and rapid rate of degradation, are used widely as insecticides both in the house and in agriculture, and in medicine for the topical treatment of external parasites. The characterization of toxicokinetic profiles of insecticides including absorption, distribution, metabolism and excretion is important in evaluating their dosimetry, biological response and risk assessment in human beings exposed to these compounds. Due to their high lipid solubility, chlorinated hydrocarbon insecticides can be absorbed orally and topically and may undergo chemical or biochemical transformations by various mechanisms. The acute toxic signs associated with DDT and chlorinated benzene types of insecticides include paresthesia of the tongue, lips and face, apprehension, tremors and convulsions. Stimulation of the central nervous system is the most prominent effect. This chapter explains the risk assessment of this exposure which includes four steps: hazard identification, dose–response, assessments, exposure estimates and risk characterization. It also throws some light on the treatment options on the exposure of chlorinated hydrocarbons and pyrethrins/pyrethroids