[HTML][HTML] Homeostatic and toxic mechanisms regulating manganese uptake, retention, and elimination

JA Roth - Biological research, 2006 - SciELO Chile
JA Roth
Biological research, 2006SciELO Chile
This review attempts to summarize and clarify our basic knowledge as to the various factors
that potentially influence the risks imposed from chronic exposure to high atmospheric levels
of manganese (Mn). The studies describe the interrelationship of the different systems in the
body that regulate Mn homeostasis by characterizing specific, biological components
involved in its systemic and cellular uptake and its elimination from the body. A syndrome
known as manganism occurs when individuals are exposed chronically to high levels of Mn …
Abstract
This review attempts to summarize and clarify our basic knowledge as to the various factors that potentially influence the risks imposed from chronic exposure to high atmospheric levels of manganese (Mn). The studies describe the interrelationship of the different systems in the body that regulate Mn homeostasis by characterizing specific, biological components involved in its systemic and cellular uptake and its elimination from the body. A syndrome known as manganism occurs when individuals are exposed chronically to high levels of Mn, consisting of reduced response speed, intellectual deficits, mood changes, and compulsive behaviors in the initial stages of the disorder to more prominent and irreversible extrapyramidal dysfunction resembling Parkinson's disease upon protracted exposure. Mn intoxication is most often associated with occupations in which abnormally high atmospheric concentrations prevail, such as in welding and mining. There are three potentially important routes by which Mn in inspired air can gain access the body to: 1) direct uptake into the CNS via uptake into the olfactory or trigeminal presynaptic nerve endings located in the nasal mucosa and the subsequent retrograde axonal transport directly into the CNS; 2) transport across the pulmonary epithelial lining and its subsequent deposition into lymph or blood; and/or 3) mucocilliary elevator clearance from the lung and the subsequent ingestion of the metal in the gastrointestinal tract. Each of these processes and their overall contribution to the uptake of Mn in the body is discussed in this review as well as a description of the various mechanisms that have been proposed for the transport of Mn across the blood-brain barrier which include both a transferrin-dependent and a transferrin-independent process that may involve store-operated Ca channels.
SciELO Chile