Iron levels in the human brain: A post-mortem study of anatomical region differences and age-related changes

Ramos, Patrícia; Santos, Agostinho; Pinto, Nair Rosas; Mendes, Ricardo; Magalhães, Teresa; Almeida, Agostinho

doi:10.1016/j.jtemb.2013.08.001

Cited by 170 publications

(142 citation statements)

References 38 publications

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“…10 and Table 2), which are consistent with previous in vivo MRI Li et al, 2014;Poynton et al, 2015;Rodrigue et al, 2013;AcostaCabronero et al 2016) and post-mortem iron analyses (Hallgren and Sourander, 1958;Ramos et al, 2014). Furthermore, the findings presented here also agree with the aforementioned studies in that independent of age, the basal ganglia system, RN and cerebellar DN contain more iron than the thalamus, hippocampus, amygdala, isocortex and WM.…”

Section: Discussionsupporting

confidence: 92%

High-resolution characterisation of the aging brain using simultaneous quantitative susceptibility mapping (QSM) and R2* measurements at 7 T

et al. 2016

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Quantitative susceptibility mapping (QSM) has recently emerged as a novel magnetic resonance imaging (MRI) method to detect non-haem iron deposition, calcifications, demyelination and vascular lesions in the brain. It has been suggested that QSM is more sensitive than the more conventional quantifiable MRI measure, namely the transverse relaxation rate, R2*. Here, we conducted the first high-resolution, whole-brain, simultaneously acquired, comparative study of the two techniques using 7 Tesla MRI. We asked which of the two techniques would be more sensitive to explore global differences in tissue composition in elderly adults relative to young subjects. Both QSM and R2* revealed strong agerelated differences in subcortical regions, hippocampus and cortical grey matter, particularly in superior frontal regions, motor/premotor cortices, insula and cerebellar regions. Within the basal ganglia system-but also hippocampus and cerebellar dentate nucleus-, QSM was largely in agreement with R2* with the exception of the globus pallidus. QSM, however, provided superior anatomical contrast and revealed age-related differences in the thalamus and in white matter, which were otherwise largely undetected by R2* measurements. In contrast, in occipital cortex, age-related differences were much greater with R2* compared to QSM. The present study, therefore, demonstrated that in vivo QSM using ultra-high field MRI provides a novel means to characterize age-related differences in the human brain, but also combining QSM and R2* using multigradient recalled echo imaging can potentially provide a more complete picture of mineralization, demyelination and/or vascular alterations in aging and disease.

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Section: Discussionsupporting

confidence: 92%

High-resolution characterisation of the aging brain using simultaneous quantitative susceptibility mapping (QSM) and R2* measurements at 7 T

et al. 2016

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“…Non-heme iron can only be studied directly postmortem (Hallgren & Sourander, 1958; Morris, Candy, Oakley, Bloxham, & Edwardson, 1992; Ramos et al, 2014; Ward et al, 2014), while in-vivo magnetic resonance imaging (MRI) can estimate iron deposits based on the interplay between its paramagnetic properties and the proton relaxation resonance behavior of tissue water (Schenck, 2003). Most of the non-heme iron in the brain affecting the MRI signal is believed to be consisting of ferritin and hemosiderin (Schenck, 2003; Schenck & Zimmerman, 2004).…”

Section: Introductionmentioning

confidence: 99%

“…Pre-menstrual blood loss reduces peripheral iron levels in women and may contribute to sex differences in brain iron accumulation (Tischler et al, 2012; Whitfield et al, 2003). Women had lower levels of brain iron compared to men from midlife to old age according to a recent histologic report (Ramos et al, 2014). Sex steroids, whose levels change post menopause (Al-Azzawi & Palacios, 2009), may also influence sex related variations of brain iron levels (Gu, Xi, Liu, Keep, & Hua, 2010).…”

Section: Introductionmentioning

confidence: 99%

Age and sex related differences in subcortical brain iron concentrations among healthy adults

Persson

Zhang

et al. 2015

NeuroImage

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Age and sex can influence brain iron levels. We studied the influence of these variables on deep gray matter magnetic susceptibilities. In 183 healthy volunteers (44.7 ± 14.2 years, range 20-69, ♀ 49%), in vivo Quantitative Susceptibility Mapping (QSM) at 1.5T was performed to estimate brain iron accumulation in the following regions of interest (ROIs): caudate nucleus (Cd), putamen (Pt), globus pallidus (Gp), thalamus (Th), pulvinar (Pul), red nucleus (Rn), substantia nigra (Sn) and the cerebellar dentate nuclei (Dn). We gauged the influence of age and sex on magnetic susceptibility by specifying a series of Structural Equation Models. The distributions of susceptibility varied in degree across the structures, conforming to histologic findings (Hallgren & Sourander, 1958), with the highest degree of susceptibility in the Gp and the lowest in the Th. Iron increase correlated across several ROIs, which may reflect an underlying age-related process. Advanced age was associated with a particularly strong linear rise of susceptibility in the striatum. Nonlinear age trends were found in the Rn, where they were the most pronounced, followed by the Pul and Sn, while minimal nonlinear trends were observed for the Pt, Th, and Dn. Moreover, sex related variations were observed, so that women showed lower levels of susceptibility in the Sn after accounting for age. Regional susceptibility of the Pul increased linearly with age in men but exhibited a nonlinear association with age in women with a leveling off starting from midlife. Women expected to be post menopause (+51 years) showed lower total magnetic susceptibility in the subcortical gray matter. The current report is consistent with previous reports of age related variations of brain iron, but also adds to the current knowledge by reporting age-related changes in less studied, smaller subcortical nuclei. This is the first in-vivo report to show lower total subcortical brain iron levels selectively in women from midlife, compared to men and younger women. These results encourage further assessment of sex differences in brain iron. We anticipate that age and sex are important co-factors to take into account when establishing a baseline level for differentiating pathologic neurodegeneration from healthy aging. The variations in regional susceptibility reported herein should be evaluated further using a longitudinal study design to determine within-person age related changes.

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“…15,16 Increased iron deposition has been found, especially in the hippocampus, in some cases of AD. 17 Post-mortem studies have indicated that the brain stores more iron as it ages and imaging studies by Bartzokis and others have shown increased levels of iron in the hippocampus and basal ganglia of patients with AD, PD and Huntington's disease. 18 The very rapid cognitive decline in our case could be linked with iron deposition.…”

Section: Discussionmentioning

confidence: 99%

Haemochromatosis and dementia: cause or contributor?

Hanmanthraya¹,

Byrne²

2015

Prog. Neurol. Psychiatry

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Iron levels in the human brain: A post-mortem study of anatomical region differences and age-related changes

Cited by 170 publications

References 38 publications

High-resolution characterisation of the aging brain using simultaneous quantitative susceptibility mapping (QSM) and R2* measurements at 7 T

High-resolution characterisation of the aging brain using simultaneous quantitative susceptibility mapping (QSM) and R2* measurements at 7 T

Age and sex related differences in subcortical brain iron concentrations among healthy adults

Haemochromatosis and dementia: cause or contributor?

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