Cadmium in the shore crab Carcinus maenas: seasonal variation in cadmium content and uptake and elimination of cadmium after administration via food.

The uptake and assimilation efficiency of cadmium administered via the food in the shore crab Carcinus maenas were investigated together with elimination kinetics and seasonal variations in cadmium content. The majority of shore crabs assimilated between 41 and 86% of the cadmium administered in their food. More than 90% of the cadmium taken up from food was retained in midgut gland. Elimination of cadmium after uptake from one meal of radioactively labelled soft parts of blue mussels could be described by a three-compartment model (percent 109Cd-retained = 64 x e(-0.001107 x t) + 25 x e(-0.0385 x t)+11 x e(-0.888 x t)). The biological half-life for cadmium in the most slowly exchanging compartment (containing 64% of the body burden) was 626 days. Groups of male and female shore crabs were collected from an uncontaminated site in the period May till October and the concentrations of cadmium in midgut gland and gills were determined. Male crabs had higher cadmium concentrations in the midgut gland in June and August (mean 2.7 microg Cd g(-1) dry weight) than they had in May, September and October (mean 1.7 microg Cd g(-1) dry weight). Females generally had slightly lower cadmium concentrations in the midgut gland than the males, except for a relatively high concentration in May. The cadmium concentrations in gills generally ranged between 0.3 and 0.5 microg Cd g(-1) dry weight) except for male values in October (mean 1 microg Cd g(-1) dry weight). Some of the seasonal changes in cadmium content of the crabs might plausibly be explained by changes in cadmium uptake from water, i.e. changes during the moult cycle and changes in cadmium uptake rates from water brought about by changes in ambient factors such as salinity and temperature. However, uptake of cadmium from water and transfer to the midgut gland take place at a rate that is two orders of magnitude too low to account for the increase in the cadmium concentrations in midgut gland in male crabs between May and June. The distribution of cadmium among tissues in crabs collected at uncontaminated sites also corresponds better with results obtained after administration of cadmium via the food than via water, and the exposure of the crabs to cadmium via the food is large enough to explain the increase in concentration between May and June.

109Cd transport in rat brain.

The brain distribution of 109CdCl2 following administration into either the tail vein, the lateral ventricle or the olfactory bulb was studied to clarify permeability of the brain barrier system to cadmium (Cd) and Cd movement in the cerebrospinal fluid (CSF) and the brain extracellular fluid. One hour after intravenous (i.v.) injection, 109Cd was largely concentrated in the choroid plexus, and 109Cd concentration in the major part of the brain parenchyma, except for the circumventricular organs such as the pineal gland and the regions around them, was low. Six days after i.v. injection, 109Cd concentration in the choroid plexus was still high, and 109Cd was also detected highly in the pineal gland and small part around the median eminence. 109Cd concentration in the major part of the brain parenchyma was decreased in parallel with that in the blood. In the case of injection of 109CdCl2 into the lateral ventricle, a large portion of 109Cd was detected in the ventricular system 6 days after injection, and 109Cd concentration in the major part of the brain parenchyma was less than the detection limit. These results suggest that Cd cannot easily get into the brain and is blocked not only by the blood- brain and the blood-CSF barriers, but also by the ependymal and pial surfaces. In the case of injection of 109CdCl2 into the olfactory bulb, a large portion of 109Cd was detected in the injected area 24 h after injection, and, the next 24 h later, 109Cd distribution in the brain was not changed appreciably. These results suggest that Cd cannot easily move in the brain extracelular space, and is taken up into the brain parenchyma.

A turnover study in the male rat of plasma-bound 59Fe, 114Inm and 109Cd with particular reference to the gonad.

After intravenous doses of the plasma-bound radionuclides 59Fe, 114Inm and 109Cd, only a minute percentage localizes in the rat testis and remains largely unchanged with time. Intratesticular injection of appropriately reduced volumes led to much higher proportionate percentage retention of 14, 65 and 11 for 59Fe, 114Inm and 109Cd, respectively. By this route, significant feedback of the elements escaping initial binding was prevented. Distinct but different testicular turnovers were now discernible. As a receptor of fluid and spermatozoa from the testicular tubules, the epididymis provides an indication of entry into and interaction of the metals with spermatogenic cells. For 59Fe no measurable changes were detected, whereas a progressive increase in epididymal 114Inm occurred, which had not reached a plateau by 70 days. 109Cd, now demonstrated within the testicular tubules by autoradiography, remained at constant organ level for upwards of 16 days but had declined by 25% by 57 days. At this point, the epididymis showed a five-fold increase in the radionuclide, declining to one-half this value by 126 days. Since 109Cd is carrier free, the data reflect a body turnover of dietary cadmium. These results, overall, are compatible with the entry of a proportion of each radionuclide into the seminiferous tubules and reaction with spermatogenic cells. Possible interpretations of the observed differences are presented.

Cadmium-109 metabolism in mice. IV. Diet versus maternal stores as a source of cadmium transfer to mouse fetuses and pups during gestation and lactation.

The transfer of 109Cd from dam to offspring during gestation and lactation was studied in uniparous mice. From 70 to 210 d of age and during the subsequent reproductive period, young adult female mice received drinking water containing tracer amounts of 109Cd (8 ppb total Cd) and nutrient-sufficient or -deficient solid diet containing stable Cd (5 ppm Cd). The nutrient quality of the deficient diet was patterned after that consumed by Japanese women who contracted itai-itai disease. To evaluate established maternal stores as a potential source of cadmium transfer to pups, some dams were switched to water with no 109Cd and diet with an environmental or control level of cadmium (0.25 ppm Cd) during the reproductive period. The resulting pups were analyzed for 109Cd at birth and at 7-d intervals throughout the lactation period. Pup 109Cd content at birth, representative of the amount transferred via the placenta during gestation, accounted for less than 1% of the total 109Cd transferred during the full reproductive period. During lactation, 109Cd levels in pups from dams with current 109Cd exposure approximately tripled with each 7-d interval; no significant differences occurred due to nutrient quality of the dams' diet. For 21-d-old pups, 98% of the 109Cd burden came from the diet of the dam, while only 2% came from her tissue stores, primarily the hepatic one. Such fractions represented a transfer per pup of about 0.01% of the oral 109Cd dose ingested by the dam during the reproductive period and about 0.05% of the 109Cd in her tissue stores. Overall, transfer per litter amounted to about 7% of the dietary 109Cd dose absorbed and retained by the dam during that interval and about 0.2% of the 109Cd from tissue stores. On lactation d 21, 90% of the total 109Cd in pups was sequestered in the gastrointestinal tract. Cadmium transfer was additionally examined in multiparous mice that began a repetitive breeding program at 70 d of age at the time of introduction to the same diet/water regimens already described. Overall, females consuming nutrient-sufficient diet experienced 5 consecutive 42-d rounds of gestation/lactation, while their deficient diet counterparts experienced 3 nonconsecutive rounds during an equivalent period. Transfer was examined during their last gestation/lactation experience. Throughout the lactation interval, 109Cd transfer to pups was about 30% increased for multiparous versus uniparous females; however, transfer again was not significantly affected by nutrient quality of the dams' diet.(ABSTRACT TRUNCATED AT 400 WORDS)

Cadmium-109 metabolism in mice. I. Organ retention in mice fed a nutritionally sufficient diet during successive rounds of gestation and lactation.

Organ retention of 109Cd was studied in multiparous and virgin female mice provided tracer amounts of 109Cd in drinking water and stable Cd appropriate for the itai-itai experience in an otherwise nutrient replete solid diet. Breeder females maximally experienced 6 consecutive, 42-d rounds of gestation/lactation. On a round-by-round basis, breeder organ 109Cd content and concentration values were compared with those from their time-matched virgin controls. By the end of round 5, the 109Cd contents of some organs appeared to have plateaued in consecutive breeders. Comparing breeder with control values at that point, the following increases were observed: whole body (minus gastrointestinal tract), 4.7-fold; mammary tissue, 14.1-fold; liver, 5.9-fold; and kidney, 3.8-fold. For 109Cd concentrations, analogous increases were mammary tissue, 15.3-fold; liver, 4.0-fold; and kidney, 2.4-fold. Through the six rounds, a temporal shift in fractional 109Cd distribution was noted for breeder tissues where transfer occurred from those of the mammaries, remaining carcass, and liver to the kidneys. In spite of this shift, at the end of round 6 109Cd content in hepatic tissue still exceeded that in renal tissue; however, 109Cd concentration was 3.3-fold greater in the kidneys. For virgin female mice over the same period, a relatively smaller shift was observed from remaining carcass to kidneys. Unlike breeders, 109Cd content was identical in hepatic and renal tissues, while 109Cd concentration was 4.6-fold greater in the kidneys. With respect to renal 109Cd increases, the larger portion of these shifts had occurred by the end of round 2 for virgin mice and by the end of round 6 for breeder mice. Comparison of content and concentration measures for a single, time-matched, virgin male group with those from a virgin female group at the end of round 6 revealed distinguishable differences only for the mammary tissues; by either measure these were about threefold higher in the female one.

Cadmium-109 metabolism in mice. II. Organ retention in mice fed a nutritionally deficient diet during successive rounds of gestation and lactation.

Organ retention of 109Cd was studied in multiparous and virgin female mice provided trace amounts of 109Cd in drinking water and stable Cd as well as certain nutrient minerals, vitamins, and fat all apportioned in solid diet in amounts appropriate for the itai-itai experience. Breeder females maximally experienced 4 nonconsecutive rounds of gestation/lactation in a total of 5 such 42-d periods. On a round-by-round basis, breeder organ 109Cd content and concentration values were compared with those from their time-matched virgin controls. By the end of round 5, most organ 109Cd content values in breeders were still increasing. Relative to control values at that point, the following increases were observed: whole body (minus gastrointestinal tract), 4.7-fold; mammary tissue, 12.5-fold; liver, 4.7-fold; and kidney, 4.8-fold. Analogous increases in 109Cd concentration values were mammary tissue, 9.8-fold; liver, 2.8-fold; and kidney, 2.9-fold. Through the five rounds, a temporal shift in fractional Cd distribution was noted for breeder tissues where transfer occurred from those of the mammaries and remaining carcass to kidneys. Although by the end of the period 109Cd content in the liver still exceeded that in the kidneys, 109Cd concentration was 4.7-fold greater in renal tissues--an increase not matched by other breeder females consuming nutrient-replete rather than nutrient-deficient (itai-itai) diet. For virgin female mice over the same period, a shift of similar magnitude was observed from remaining carcass to kidneys. Not unlike the breeders, hepatic 109Cd content again exceeded that in renal tissues, while 109Cd concentration was 4.5-fold greater in the kidneys. With respect to renal 109Cd increases, the greater portion of these shifts had occurred by the end of round 3 for both breeder and virgin mice. Comparison of both content and concentration measures for a single, time-matched, virgin male group with those from a virgin female one at the end of round 3 showed only those for mammary tissues to be distinguishable, and by either measure were about fourfold higher in the female group.