The impact of iron status and smoking on blood divalent metal concentrations in Norwegian women in the HUNT2 Study

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• 作者：H.M. Meltzer^a ; ^{helle.margrete.meltzer@fhi.no" class="auth_mail" title="E-mail the corresponding author} ; J. Alexander^a ; A.L. Brantsæ ; ter^a ; B. Borch-Iohnsen^b ; D.G. Ellingsen^c ; Y. Thomassen^c ; J. Holmen^d ; T.A. Ydersbond^e
• 关键词：DMT ; divalent metal transporter ; HUNT ; The North Trø ; ndelag Health Study
• 刊名：Journal of Trace Elements in Medicine and Biology
• 出版年：2016
• 出版时间：December 2016
• 年：2016
• 卷：38
• 期：Complete
• 页码：165-173
• 全文大小：1325 K

文摘

Low iron (Fe) stores may result in increased absorption of divalent metals, in particular cadmium (Cd). We have previously shown that in non-smoking women participating in the Norwegian HUNT2 cohort study this also included other divalent metals, e.g. manganese (Mn) and cobalt (Co). The diet is the main source of metals in non-smoking individuals, whereas in smoking individuals tobacco smoke contributes significant amounts of Cd and lead (Pb). The aim of the present study was to investigate the impact of smoking on the relationship between low iron status and divalent metals.

Blood concentrations of the divalent metals Cd, Mn, Co, Pb, copper (Cu) and zinc (Zn), determined using an Element 2 sector field mass spectrometer (ICP-MS), were investigated in smoking women of fertile age (range 21–55 years) (n = 267) from the HUNT2 cohort. Among these, 82 were iron-deplete (serum ferritin < 12 μg/L) and 28 had iron deficiency anaemia (serum ferritin < 12 μg/L & Hb < 120 g/L). 150 (56%) women smoked 10 or more cigarettes daily, 101 (38%) had smoked for more than 20 years, and 107 (40%) had smoked for 11–20 years. Results from the smoking population were compared with results from our previous study in non-smoking women (n = 448) of which 132 were previous smokers, all from the same cohort.

Increasing concentrations of Cd in blood were observed for previous smokers, low-to-moderate smokers and high intensity smokers in all subgroups compared to never smokers, and according to age groups, education level, BMI and serum ferritin. Smokers had higher Pb concentrations than non-smokers in all subgroups, but less pronounced than for Cd. Smoking was not associated with Mn and Co concentrations in blood.

In multiple regression models, low ferritin was associated with increased blood concentrations of Cd, Pb, Mn and Co. Ferritin was strongly associated with Cd at low smoking intensity, but was not a significant factor in heavy smokers, where intensity and duration of smoking emerged as main determinants. Ferritin associations with Co and Pb varied with tertiles of blood Cd. Ferritin emerged as the main determinant of blood Co and Mn, while for blood Pb, age and smoking intensity had higher impact. Cu and Zn remained within reference values and no significant associations with ferritin were found. Strong positive associations between blood concentrations of Pb, Mn, Cd and Co were observed, also when controlled for their common association with ferritin. Apart from these associations, the models showed no significant interactions between the divalent metals studied. Mild anaemia (110 < Hb < 120 g/L) did not seem to have any effect independent of low ferritin.

The results indicate that low serum ferritin facilitates absorption of certain divalent metal ions in female smokers as well as the previously shown effect in non-smokers. Even if smoking provides Pb and Cd, the mutual associations between Cd and other divalent metals in blood persisted in medium and heavy smokers. This indicates that the interrelationship between Cd and divalent metals not only reflect effects on the absorption, but possibly also on kinetic processes such as transportation in blood and other compartments, including excretion.