Cadmium intake and systemic exposure in postmenopausal women and age-matched men who smoke cigarettes.

Mean blood cadmium (B-Cd) concentrations are two- to threefold higher in smokers than in nonsmokers. The basis for this phenomenon is not well understood. We conducted a detailed, multifaceted study of cadmium exposure in smokers. Groups were older smokers (62±4 years, n = 25, 20% male) and nonsmokers (62±3 years, n = 16, 31% male). Each subject's cigarettes were machine smoked, generating individually paired measures of inhaled cadmium (I-Cd) versus B-Cd; I-Cd and B-Cd were each evaluated three times, at monthly intervals. Urine cadmium (U-Cd) was analyzed for comparison. In four smokers, a duplicate-diet study was conducted, along with a kinetic study of plasma cadmium versus B-Cd. Female smokers had a mean B-Cd of 1.21ng Cd/ml, with a nearly 10-fold range (0.29-2.74ng Cd/ml); nonsmokers had a lower mean B-Cd, 0.35ng Cd/ml (p < 0.05), and narrower range (0.20-0.61ng Cd/ml). Means and ranges for males were similar. Estimates of cadmium amounts inhaled daily for our subjects smoking ≥ 20 cigarettes/day were far less than the 15 µg Cd reported to be ingested daily via diet. This I-Cd amount was too low to alone explain the 3.5-fold elevation of B-Cd in our smokers, even assuming greater cadmium absorption via lungs than gastrointestinal tract; cadmium accumulated in smokers' lungs may provide the added cadmium. Finally, B-Cd appeared to be linearly related to I-Cd values in 75% of smokers, whereas 25% had far higher B-Cd, implying a possible heterogeneity among smokers regarding circulating cadmium concentrations and potentially cadmium toxicity.

Low-volume, high-sensitivity assay for cadmium in blood and urine using conventional atomic absorption spectrophotometry.

An assay for cadmium in whole blood and urine using deuterium background-correction electrothermal atomic absorption spectroscopy (D(2)-ETAAS) was developed. Cadmium (in a 1- to 2-ml sample) was bound to 15 mg anion-exchange resin, interfering ions were removed in a 2-ml Bio-Spin column, and cadmium was extracted into 100 microl 1M nitric acid for analysis. Cadmium in the sample extract was concentrated 7-fold for blood and 10-fold for urine over the starting material. These steps produced cadmium atomic absorption traces with high signal to background ratios and allowed analysis against aqueous standards. At approximately 0.1 ng Cd/ml, mean intra- and interassay coefficients of variation were 11-12%. Cadmium recovery for 0.1 to 0.6 ng added cadmium was 107+/-4% for blood and 94+/-4% for urine (mean+/-SE, n=3). The mean detection limit (mean + 3 x SD of blank) was 0.008 ng/ml for blood and 0.003 ng/ml for urine. Samples from "unexposed" animals including humans ranged from 0.051+/-0.000 to 0.229+/-0.035 ng/ml. Values were approximately 10-fold lower than those obtained by the method of Stoeppler and Brandt using Zeeman background-correction ETAAS. This new high-sensitivity, low-volume assay will be useful for epidemiological studies, even those involving children, and will provide a means to help determine the contribution of cadmium to disease incidence in the general population.

Cadmium pathways during gestation and lactation in control versus metallothoinein 1,2-knockout mice.

Effects of metallothionein (MT) on cadmium absorption and transfer pathways during gestation and lactation in mice were investigated. Female 129/SvJ metallothionein-knockout (MT1,2KO) and metallothionein-normal (MTN) mice received drinking water containing trace amounts of (109)CdCl(2) (0.15 ng Cd/ml; 0.074 micro Ci (109)Cd/ml). (109)Cd and MT in maternal, fetal, and pup tissues were measured on gestation days 7, 14, and 17 and lactation day 11. In dams, MT influenced both the amount of (109)Cd transferred from intestine into body (two- to three-fold higher in MT1,2KO than MTN dams) and tissue-specific (109)Cd distribution (higher liver/kidney ratio in MT1,2KO dams). Placental (109)Cd concentrations in MT1,2KO dams were three- and seven-fold higher on gestation days 14 and 17, respectively, than in MTN dams. Fetal (109)Cd levels were low in both mouse types, but at least 10-fold lower in MTN fetuses. MT had no effect on the amount of (109)Cd transferred to pups via milk; furthermore, 85-90% of total pup (109)Cd was recovered in gastrointestinal tracts of both types, despite high duodenal MT only in MTN pups. A relatively large percentage of milk-derived intestinal (109)Cd was transferred to other pup tissues in both MT1,2KO and MTN pups (14 and 10%, respectively). These results demonstrate that specific sequestration of cadmium by both maternal and neonatal intestinal tract does not require MT. Although MT decreased oral cadmium transfer from intestine to body tissues at low cadmium exposure levels, MT did not play a major role in restricting transfer of cadmium from dam to fetus via placenta and to neonate via milk.

Role of fos and src in cadmium-induced decreases in bone mineral content in mice.

Cadmium decreases bone mineral in mice and stimulates osteoclast formation and activity in cell culture. Bones from fos-deficient mice contain very few osteoclasts; src-/- bones contain osteoclasts that fail to activate. Fos-/- and src-/- mice develop osteopetrotic bones and their teeth do not erupt. These mice were used to determine if cadmium requires c-Fos or c-Src and secondarily functional osteoclasts to decrease bone mineral content. Mice heterozygous for fos deficiency were mated to produce fos-/- and fos+/o (wild-type) offspring. Pups were divided into four groups: fos+/o, Cd-; fos+/o, Cd+; fos-/-, Cd-; and fos-/-, Cd+. Cd+ pups received daily sc injections (50 microg Cd/kg) on days 17-20 and Cd in drinking water thereafter (10 ppm, days 21-27; 20 ppm, days 27-50). An analogous protocol was followed mating mice heterozygous for src deficiency. For acute exposures, 50-day-old mice were placed on a low-calcium diet and given two sequential 100 microg Cd doses by gavage, and feces were monitored for excretion of bone calcium. Continuous exposure results demonstrate that cadmium (1) significantly decreased bone calcium content (14-15%) and concentration (12-13%) in both fos+/o and fos-/- mice, (2) doubled multinucleated osteoclast-like cell number in fos-/- bones, and (3) stimulated tooth eruption in 40% of fos-/- mice. Cd gavage stimulated bone calcium excretion in both fos+/o and fos-/- mice. In contrast, cadmium had no effect on bones or teeth in src-/- mice. Results indicate that cadmium can decrease bone mineral via a c-Fos-independent pathway; however, c-Src is required for cadmium to stimulate bone remodeling and tooth eruption pathways.