Essentiality Toxicity Carcinogenicity Lead(Pb) Exposure Toxicokinetics Toxicity Neurologic, Neurobehavioral, and Developmental Effects in Children Mechanisms of Effects on the Developing Nervous System Peripheral Neuropathy Hematologic Effects Renal Toxicity Lead and Gout Effects on Cardiovascular System Immunotoxicity Bone Effects Reproductive Effects Birth Outcomes Carcinogenicity Other Effects Dose Response Treatment Organic Lead Compounds Mercury (Hg) Exposure Disposition and Toxicokinetics Metabolic Transformation Cellular Metabolism Toxicology Biological Indicators Treatment Nickel (Ni) Exposure Toxicokinetics Essentiality Toxicity Nickel Carbonyl Poisoning Dermatitis Indicators of Nickel Toxicity

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Toxic effects of metals

https://stacks.cdc.gov/view/cdc/37676/cdc_37676_DS1.pdf

Toxicological Profile for Lead

The chronic toxicity of aluminium, cadmium, mercury, and lead in birds: a review.

Cadmium, lead, mercury, and aluminum are toxic metals that may interact metabolically with nutritionally essential metals. Iron deficiency increases absorption of cadmium, lead, and aluminum. Lead interacts with calcium in the nervous system to impair cognitive development. Cadmium and aluminum interact with calcium in the skeletal system to produce osteodystrophies. Lead replaces zinc on heme enzymes and cadmium replaces zinc on metallothionein. Selenium protects from mercury and methylmercury toxicity. Aluminum interacts with calcium in bone and kidneys, resulting in aluminum osteodystrophy. Calcium deficiency along with low dietary magnesium may contribute to aluminum-induced degenerative nervous disease.

Toxic and essential metal interactions

Molecular and ionic mimicry and the transport of toxic metals.

Experimental enhancement of lead toxicity by low dietary calcium.

Biological parameters known to be affected in lead poisoning were measured in rats following ingestion of graded dosages of lead Intranuclear inclusion bodies are formed in renal tubular lining cells with smaller doses of lead than produce other changes Decreased body weight is the next most sensitive abnormality This is followed by increased delta-aminolevulinic acid (ALA) excretion, reticulocytosis, renal edema, and aminoaciduria Anemia only occurs at the highest lead dosage Over a wide range of lead ingestion, urinary lead excretion remains constant, although renal lead content increases Quantitative lead analyses of cell organelles show that lead is concentrated within the inclusion bodies Relatively small amounts of lead are present in the cytoplasm and mitochondria It is suggested that soft-tissue lead accumulates in the intranuclear inclusion body, thereby sparing toxic injury to cytoplasmic organelles

Lead dosage and the role of the intranuclear inclusion body. An experimental study.

Dose-response to lead ingestion in rats fed low dietary calcium.

The Reproductive Ability and Progeny of F1 Lead-Toxic Rats*

ATTEMPTS to explain the morphological changes of the kidney induced by lead poisoning have been concerned chiefly with nuclear and cytoplasmic inclusions1,2. Cytoplasmic inclusions have been shown to contain Fe (ref. 1), but the composition of nuclear inclusions remains a subject for debate. It is still not clear whether lead is deposited within the kidney and some authors deny a direct action of this element in favour of a mechanism of indirect action through vascular changes3. Fortunately, the problem of detection of metallic localizations within the kidney is amenable to direct observations with the electron probe microanalyser, an instrument ideally suited to the purpose, with a detection limit of about 10−15 g and a spatial resolution of about 1 µm (ref. 4).

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Robert A. Goyer

Papers

Experimental enhancement of lead toxicity by low dietary calcium.

Lead dosage and the role of the intranuclear inclusion body. An experimental study.

Dose-response to lead ingestion in rats fed low dietary calcium.

The Reproductive Ability and Progeny of F1 Lead-Toxic Rats*

Electron probe microanalyser localization of lead in kidney tissue of poisoned rats.