Pharmacokinetics of pulmonary manganese absorption: evidence for increased susceptibility to manganese loading in iron-deficient rats

Heilig, Elizabeth; Molina, Ramon M.; Donaghey, Thomas C.; Brain, Joseph D.; Wessling‐Resnick, Marianne

doi:10.1152/ajplung.00382.2004

Cited by 38 publications

(38 citation statements)

References 33 publications

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“…The HFE variant may reduce immediate absorption of toxic divalent metals in particulate matter, because subjects with this variant have higher iron stores and downregulated iron absorption. Recently, Heilig et al 35 demonstrated that iron-deficient rats will absorb increased levels of manganese instilled in the lungs. The present findings are consistent with those results and support the hypothesis that genes that regulate intestinal absorption of divalent metals also regulate pulmonary metal absorption.…”

Section: Discussionmentioning

confidence: 99%

HFE Genotype, Particulate Air Pollution, and Heart Rate Variability

et al. 2006

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Background-Particulate air pollution has been associated with cardiovascular mortality and morbidity. Transition metals such as iron bound to the particles may be responsible for those associations. The protein product of the hemochromatosis (HFE) gene modulates uptake of iron and divalent cations from pulmonary sources and reduces their toxicity. Two HFE polymorphisms (C282Y and H63D) associated with increased iron uptake may modify the effect of metal-rich particles on the cardiovascular system. Methods and Results-We investigated the association between particulate matter Յ2.5 m in aerodynamic diameter and heart rate variability in 518 older men from the Normative Aging Study who were examined between November 2000 and December 2004. Linear regression models were fit to evaluate interactions between HFE genotype and particulate matter Յ2.5 m in aerodynamic diameter in relation to heart rate variability, controlling for potential confounders. A 10-g/m 3 increase in particulate matter Յ2.5 m in aerodynamic diameter during the 48 hours before heart rate variability measurement was associated with a 31.7% (95% CI, 10.3% to 48.1%) decrease in the high-frequency component of heart rate variability in persons with the wild-type genotype, whereas no relationship in the high-frequency component was observed in persons with either HFE variant. The difference in effect of particulate matter Յ2.5 m in aerodynamic diameter on the high-frequency component between persons with and without HFE variants was significant (P for interactionϭ0.02). Conclusions-The effect of particles on cardiac autonomic function was shielded in subjects with at least 1 copy of an HFE variant compared with wild-type subjects. Transition metals, including iron, bound to ambient particles and the related oxidative stress may play an important role in cardiac toxicity of particles.

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Section: Discussionmentioning

confidence: 99%

HFE Genotype, Particulate Air Pollution, and Heart Rate Variability

et al. 2006

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“…Kidney studies remain to show the importance of DMT1 as well as different isoforms (Abouhamed et al, 2006;Canonne-Hergaux & Gros, 2002;Wareing et al, 2003;. Pharmacokinetic studies show that iron status can alter lung Mn transport to circulation Heilig et al, 2005;Thompson et al, 2006) DMT1 is not the transporter involved . Recently is has been verified that the b/b Belgrade rat lacks transport mechanisms for divalent metals in its small intestine (Knopfel et al, 2005).…”

Section: Divalent Metal Transporter (Dmt1) In Mn Transportmentioning

confidence: 99%

Manganese neurotoxicity: A focus on the neonate

Erikson

Thompson

Aschner

et al. 2007

Pharmacology & Therapeutics

221

141

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Manganese (Mn) is an essential trace metal found in all tissues, and it is required for normal amino acid, lipid, protein, and carbohydrate metabolism. While Mn deficiency is extremely rare in humans, toxicity due to overexposure of Mn is more prevalent. The brain appears to be especially vulnerable. Mn neurotoxicity is most commonly associated with occupational exposure to aerosols or dusts that contain extremely high levels (> 1-5 mg Mn/m 3 ) of Mn, consumption of contaminated well water, or parenteral nutrition therapy in patients with liver disease or immature hepatic functioning such as the neonate. This review will focus primarily on the neurotoxicity of Mn in the neonate. We will discuss putative transporters of the metal in the neonatal brain and then focus on the implications of high Mn exposure to the neonate focusing on typical exposure modes (e.g., dietary and parenteral). Although Mn exposure via parenteral nutrition is uncommon in adults, in premature infants, it is more prevalent, so this mode of exposure becomes salient in this population. We will briefly review some of the mechanisms of Mn neurotoxicity and conclude with a discussion of ripe areas for research in this underreported area of neurotoxicity.

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“…79 Surprisingly, 54 Mn also failed to associate with Tf present in BAL from control rats. 64 This combined evidence completely rules out a role for DMT1, suggesting the existence of additional transport pathways for manganese in the lungs. …”

Section: Pulmonary Manganese Uptake and Iron Deficiencymentioning

confidence: 84%

“…[61][62][63] These channels, and others, are thought to maintain fluid balance in lungs, but potential roles in the transport of manganese and other metals are possible as well. 64 …”

Section: Other Manganese Transporters: Non-selective Ion Channelsmentioning

confidence: 99%

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Manganese Transport Across the Pulmonary Epithelium

Thompson¹,

Kim²,

Wessling‐Resnick³

2014

Manganese in Health and Disease

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Our lungs represent a significant exposure site to airborne metals. Manganese and other metals enter the bloodstream from a variety of airborne sources across the pulmonary epithelium. Once absorbed, manganese can be taken up by other organ systems like the brain, where it is known to exert neurotoxic effects. Models of pulmonary manganese absorption have been developed based on known pathways of uptake across the intestinal epithelium, which are regulated by iron status. The sum of evidence suggests that additional and perhaps unique transport pathways are available to manganese in order to transit the pulmonary epithelium. Both in vitro and in vivo models have been established to characterize not only the transport but also toxicity of manganese on pulmonary epithelial cells. Handling of manganese by the lungs plays an important role in the inflammatory response, and has a strong influence on lung infection. These issues and emerging new questions are discussed in this chapter.

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Pharmacokinetics of pulmonary manganese absorption: evidence for increased susceptibility to manganese loading in iron-deficient rats

Cited by 38 publications

References 33 publications

HFE Genotype, Particulate Air Pollution, and Heart Rate Variability

HFE Genotype, Particulate Air Pollution, and Heart Rate Variability

Manganese neurotoxicity: A focus on the neonate

Manganese Transport Across the Pulmonary Epithelium

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