The hazards of cadmium in man and animals

Application of covalent affinity chromatography with thiol-disulphide interchange for determination of environmental exposition to heavy metals based on the quantitative determination of Zn-thionein from physiological human fluids by indirect method based on analysis of metal contents

Intoxication with heavy metals results in numerous poisonings and diseases. They disturb metabolism of the system, are the source of cancer, degeneration changes and others. As a result of kidney damage the urine of people exposed to heavy metals contains different low molecular weight proteins, oligopeptides and amino acids, indicating pathological changes. One of the proteins is a very specific metallopolythiopolypeptide--metallothionein (MT). Based on earlier investigations, a very good correlations has been found between the contents of metallothionein in urine and plasma and the concentration of heavy metals in the blood, urine, kidneys, liver and brain and general in level of exposition to heavy metals. The aim of our investigations was to carry out quantitative isolation of Zn-thionein (Zn-Th), in order to determine the level of exposition to heavy metals. For Zn-Th protein isolation by covalent affinity chromatography with thiol-disulphide interchange (CAC-TDI) was applied, which is a modern technique of separation of a high affinity, good repeatability and reproducibility, allowing specific isolation of the thiol-proteins CAC-TDI gel was used as a solid-phase extraction (SPE) support for preconcentration of Zn-Th protein and Zn bonded with Zn-Th from water, rine, plasma and breast milk samples. The investigations showed unfavourable effect of the support on separation of thiol proteins and good correlation between the concentration of MTs protein added to water, plasma and urine and the concentration of protein indirectly determined via atomic absorption spectrometric (AAS) method, by preconcentration on SPE support metals formerly bound with MT protein and absorbed on CAC-TDI gel and calculated from metals concentration. The present paper is a continuation of earlier experiments on quantitation of Hg-thionein and Cd-thionein in physiological fluids and homogenates.

Application of covalent affinity chromatography with thiol-disulphide interchange for determination of environmental exposure to heavy metals based on the quantitative isolation of Cd-thionein from human breast milk

The aim of this study was to test a new chromatographic method for the quantitative determination of Cd-thionein (Cd-Th) in human breast milk, in order to determine the level of exposure to heavy metals. Cd-thionein was isolated by covalent affinity chromatography with thiol-disulphide interchange, which is a modern separation technique of high affinity, good repeatability and reproducibility, allowing specific isolation of the thiolproteins. The fundamentals of indirect determination of the contents of metallothionein protein from human milk were worked out through estimation of the quantities of cadmium bound with Cd-thionein and adsorbed on covalent affinity chromatography gel during a separation process.

Cadmium exposure attenuates the initiation of behavioral sensitization to cocaine

Employing a paired-watering procedure to control for differential fluid intake confounds, adult male rats were exposed in the home cage to water containing 100 ppm cadmium chloride, or a control solution containing no added cadmium chloride. On Day 61 of exposure to their respective watering regimens, half the animals from each condition received 12 repeated daily i.p. injections of 10 mg/kg cocaine-HCl, or saline. Locomotor activity (total distance traveled) was recorded in Digiscan Activity Monitors for a 20-min baseline period prior to each injection, and for a 40-min period post-injection. On Day 13 of testing, all animals received saline injections only in the test chambers, in an effort to evaluate the role of conditioned cues in the expression of cocaine sensitization. On Day 14-16 of testing, all animals received successive daily challenges of 10, 20, and 40 mg/kg cocaine in the test chamber. The results indicated that the initiation (development) of behavioral sensitization to 10 mg/kg cocaine was attenuated in cadmium-exposed rats. Moreover, the supersensitivity to higher doses of cocaine during dose-effect testing that was registered by control animals pretreated with cocaine, was not evident in cadmium-exposed pretreatment animals. These data suggests that environmental contaminants may alter drug responsiveness, and thereby may influence patterns of drug selection and use.

The effects of cadmium exposure on ethanol pharmacokinetics

Twenty-four adult male rats were exposed in the home cage to water containing 100 ppm added cadmium chloride. An additional 24 animals were pair-watered with water containing no added cadmium. Following 60 days of exposure to their respective watering regimens, one third of the animals in each exposure group (N = 8/condition) received IP injections of 1.0, 2.0, or 3.0 g/kg ethanol (20% v/v). Serum alcohol concentrations were measured at 15, 30, 60, 120, 180, 240, and 360 min postinjection. Although serum alcohol concentrations increased with dose for both cadmium-exposed and control animals, there was no indication at any dose of group differences. The lack of differences in ethanol pharmacokinetics reported here is instructive with respect to improving our understanding of the mechanisms underlying cadmium/ethanol interactions.

Chronic cadmium exposure attenuates ethanol-induced hypoalgesia in the adult rat

Adult male rats were exposed to a diet containing either 100 ppm added cadmium (Cadmium-Diet), or a control diet containing no added chemicals (Control-Diet) for 67 days prior to pain reactivity testing using a tail-flick procedure. Rats were placed in restraining tubes for a 20-min acclimation period, then baseline tail-flick latencies in response to a radiant heat source were measured. Subsequently, half the animals from each group were serially injected intraperitoneally with either 0.5, 1.0, 1.5, or 2.0 g/kg body weight of a 20% v/v ethanol solution, and the other half of the animals were injected with an equivalent volume of saline. Tail-flick latencies were reassessed at 20-min intervals over the next 2 hr. Results indicated dose-dependent ethanol-induced hypoalgesia in the Control-Diet animals for the two highest doses, but ethanol-induced hypoalgesia was evident only at the highest dose for the Cadmium-Diet animals. Further, the magnitude of this hypoalgesic effect was significantly lower for the Cadmium-Diet animals than the Control-Diet animals at the 2.0 g/kg dose. Results are discussed in terms of an attenuation of the pharmacological properties of ethanol by cadmium.

The effects of naltrexone on cadmium-induced increases in oral ethanol self-administration

Adult male rats were exposed to a standard laboratory diet (N = 20), or an adulterated diet containing 100 ppm added cadmium (N = 20), for 60 days. On Day 61, half the animals from each dietary condition received subcutaneous implants of two 30 mg naltrexone pellets, and the remaining half the animals received identical implants of 30 mg placebo pellets. One week later, animals from groups created by this interaction (Groups Control-Placebo, Control-Naltrexone, Cadmium-Placebo, Cadmium-Naltrexone) were tested in an ethanol self-administration paradigm that presented a 10% ethanol solution (v/v) in both a choice and nonchoice format. The results indicated that cadmium exposure increased the oral self-administration of ethanol in the choice setting where water was offered as an alternative, and the opiate antagonist naltrexone failed to attenuate this effect.

Cadmium exposure results in decreased responsiveness to ethanol

Adult male Sprague-Dawley rats were maintained on an ad lib diet containing 100 ppm cadmium (Group Cadmium-Diet) or a control diet with no added cadmium. On Day 61, all animals (N = 10/group) were challenged with a single hypnotic dose of ethanol (3.5 g/kg IP), prepared from a 20% v/v solution of tap water and a stock solution of 95% ethanol. The latency from the time of the injection until the loss of the righting reflex was recorded, as well as the latency for recovery of the reflex. The results showed a nonsignificant trend for animals exposed to cadmium to lose the righting reflex less rapidly than controls, and Cadmium-Diet animals regained the righting reflex significantly more rapidly than controls. These findings suggest that the pharmacologic effectiveness of ethanol is altered by chronic exposure to dietary cadmium. The implications of these data for other studies of cadmium/ethanol interactions are discussed.

Ethanol self-administration in rats following exposure to dietary cadmium

Rats were maintained on an ad lib diet containing 100 ppm cadmium (Group Cadmium-Diet) or a control diet with no added cadmium (Group Control-Diet). After 55 days of exposure to their respective diets, animals were tested for fluid intake using a nonchoice procedure that presented a 15% ethanol solution in the home cage for 5 days. Subsequently, all animals were offered a 10% ethanol solution or tap water in a 3-bottle, 2-fluid choice test in the home cage. This fluid intake test was conducted for a 5 day baseline period, and then again concurrently with avoidance acquisition (14 days) and extinction (4 days) training on a free operant (Sidman) avoidance task that required animals to lever press to avoid electric footshock. After training was terminated the choice test was continued further in the home cage for a 15 day post-avoidance period. Ethanol intake was greater for animals exposed to cadmium on all tests of fluid consumption, and all animals consumed more ethanol during the periods following termination of the stressor (avoidance extinction, post-avoidance) than during the actual period of stress (avoidance acquisition). Interpretive comments focus on the effects of cadmium on stress reactivity, sensory processing, and metabolism.

Overview of analysis of carcinogenic and/or mutagenic metals in biological and environmental samples. I. Arsenic, beryllium, cadmium, chromium and selenium

One of the most dangerous and pernicious forms of pollution arises from the potential mobilization of a spectrum of toxic trace metals and metalloids in our environment. Among the most important elements in this regard are arsenic, beryllium, cadmium, chromium and selenium whose adverse toxic effects are now well recognized including their carcinogenicity and/or mutagenicity. These agents (and their derivatives) can be widely dispersed throughout the environment as a result of fossil fuel combustion, industrial and agricultural processes and natural processes. The trend for the immediate future appears to be of greater exposure to these metals not only as a result of generally increased usage patterns but also because of prospective enhanced use of fossil fuels for space heating and electricity generation. In order to more readily evaluate trends of human exposure as well as the toxicity, bioavailability, bioaccumulation and transport of these elements, sensitive analytical procedures are required for the determination of their various oxidation states (as well as their organic derivatives) in complex matrices such as those found in both environmental and biological samples. Hence, the principal objective of this overview is to highlight the more recent trends and state-of-the-art methodologies for the determination of arsenic, beryllium, cadmium, chromium and selenium (in their various forms) in environmental compartments such as air, water, soil and in human tissues (primarily blood, urine, and milk). Techniques to be discussed primarily include atomic absorption spectrometry, neutron activation analysis, gas chromatography, differential pulse polarography and electrochemical analysis. The importance of quality control and differentiation according to speciation will also be stressed.