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Investigation of the relationship between iron and high field MRI in healthy and Alzheimer's disease tissue
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Finnegan, Mary E. (2013) Investigation of the relationship between iron and high field MRI in healthy and Alzheimer's disease tissue. PhD thesis, University of Warwick.
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Official URL: http://webcat.warwick.ac.uk/record=b2721556~S1
Abstract
It has been proposed that increased tissue iron concentration, which has been observed in
certain regions of the brain in individuals with Alzheimer’s Disease (AD), could provide a
marker for diagnosis through detection with MRI. This is investigated in this thesis using high
field MRI to examine post mortem human brain tissue. It is shown here that by using data from
multiple brain regions discriminant analysis can successfully differentiate between AD and
control samples, even when no statistically significant differences are observed in individual
brain regions.
A unique set of complementary techniques was used to investigate iron content, R2 and R2* of
tissue samples from the caudate nucleus, putamen, globus pallidus substantia nigra, amygdala
and pons, from a set of three control and AD cases. The particulate iron content of the samples
was investigated by SQUID magnetometry and was followed by iron quantification. A trend of
increased particulate and total iron concentration was observed in the AD tissue compared to
control, however this did not reach statistical significance in any brain region. High resolution
MRI relaxometry at 9.4 T was carried out on tissue from the caudate nucleus, putamen, globus
pallidus and substantia nigra using a custom design Bruker micro-imaging MicWB40 probe. As
part of the work towards this PhD the probe was tested, and MRI relaxometry protocols
optimised for high resolution (86 x 86 μm in plane, 150 μm slice thickness) mapping of tissue
samples with high iron concentration. Again, no statistically significant differences were
observed between AD and control tissue.
However, discriminant analysis of these data (particulate or total iron or R2 or R2*) from
multiple brain regions achieved differentiation between control and AD cases with 100%
sensitivity and specificity for this small sample set. This demonstrates the potential clinical
usefulness of MRI of measurements of non-haem brain iron to aid in disease diagnosis.
Synchrotron X-ray fluorescence (SXRF) mapping of 30 μm thick sections, cut from the MRI
samples, showed the relative concentration distribution of iron, copper and zinc in one AD and
control sample from each brain region. Each metal was shown to have a distinct distribution.
In particular, the inhomogeneity of iron concentration within individual brain regions, such as
the putamen, was demonstrated. This may explain the wide variation in iron concentration
reported in the literature for the same brain regions, and highlights the importance of close
anatomical matching of samples when making comparisons. The ability of high resolution SXRF
mapping to investigate the metal content within individual cells was demonstrated and used to
show an increase in iron in individual AD neurons, in addition to the surrounding grey and
white matter tissue.
Spatially matched SXRF and MRI maps were used to demonstrate a strong, statistically
significant linear relationship between tissue iron concentration and R2, R2* and R2’ at 9.4 T.
The gradient of the linear relationship between iron and R2, agrees extremely well with the
predicted gradient at this field, where the prediction was made by Vymazal et al. (1996) using
MRI relaxometry at 0.05 to 1.5 T. To the best of my knowledge, this is the first time that this
relationship has been quantified at 9.4 T, or at any field above 7 T.
MRI at 14.1 T was carried out on low iron concentration regions (the pons and amygdala).
Matched SXRF and R2* maps did not show a strong linear relationship between iron and R2*.
The iron concentration in these regions is less than 50 μg/g and it was concluded that in tissue
with low iron content, other tissue properties - such as water content - are dominating the
value of R2*. This result was replicated with data measured at 9.4 T, when only tissue with an
iron concentration of less than 50 μg/g was considered.
Item Type: | Thesis (PhD) | ||||
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Subjects: | R Medicine > RC Internal medicine > RC0321 Neuroscience. Biological psychiatry. Neuropsychiatry | ||||
Library of Congress Subject Headings (LCSH): | Alzheimer's disease -- Research, Tissue culture -- Magnetic resonance imaging, Iron in the body | ||||
Official Date: | November 2013 | ||||
Dates: |
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Institution: | University of Warwick | ||||
Theses Department: | School of Engineering | ||||
Thesis Type: | PhD | ||||
Publication Status: | Unpublished | ||||
Supervisor(s)/Advisor: | Collingwood, Joanna; Chappell, Michael; Dobson, Jon | ||||
Sponsors: | Alzheimer's Society; Diamond Light Source (Firm); University of Warwick; Birmingham Science City; Advantage West Midlands (AWM); European Regional Development Fund (ERDF) | ||||
Extent: | 1 volume (various pagings) : illustrations. | ||||
Language: | eng |
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