Ferritin is a component of the neuritic (senile) plaque in Alzheimer dementia

Grundke‐Iqbal, Inge; Fleming, James T.; Tung, Yunn Chyn; Lassmann, Hans; Iqbal, Khalid; Joshi, Jayant G.

doi:10.1007/bf00334497

Cited by 239 publications

(136 citation statements)

References 29 publications

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“…Similar patterns have been described in studies of AD transgenic mice and postmortem human AD cases, and were attributed to the presence of amyloid plaques using histological confirmation [11][12][13][14][15][16][17][18][19]. It has been proposed that the visualization on MRI of plaques in humans and mice is based on the fact that these deposits colocalize with iron, which gives rise to magnetic susceptibility effects on T2*-weighted images over volumes that are much larger than the actual size of amyloid plaques [17,[19][20][21][22][23][24]. An alternative method to measure these susceptibility changes in the brain is to measure the relative phase in regions of interest (ROIs), because it has been shown that this is a reliable indicator of the iron content in the brain [25][26][27][28].…”

Section: Introductionsupporting

confidence: 59%

Cortical phase changes in Alzheimer's disease at 7T MRI: A novel imaging marker

Rooden

Versluis

Liem

et al. 2013

Alzheimer's & Dementia

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Background: Postmortem studies have indicated the potential of high-field magnetic resonance imaging (MRI) to visualize amyloid depositions in the cerebral cortex. The aim of this study is to test this hypothesis in patients with Alzheimer's disease (AD). Methods: T2*-weighted MRI was performed in 16 AD patients and 15 control subjects. All magnetic resonance images were scored qualitatively by visual assessment, and quantitatively by measuring phase shifts in the cortical gray matter and hippocampus. Statistical analysis was performed to assess differences between groups.Results: Patients with AD demonstrated an increased phase shift in the cortex in the temporoparietal, frontal, and parietal regions (P , .005), and this was associated with individual Mini-Mental State Examination scores (r 5 20.54, P , .05). Conclusion: Increased cortical phase shift in AD patients demonstrated on 7-tesla T2*-weighted MRI is a potential new biomarker for AD, which may reflect amyloid pathology in the early stages.

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Section: Introductionsupporting

confidence: 59%

Cortical phase changes in Alzheimer's disease at 7T MRI: A novel imaging marker

Rooden

Versluis

Liem

et al. 2013

Alzheimer's & Dementia

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“…82 The presence of ferritin in the senile plaque, has also been proposed as evidence for a role for free radicals in amyloid formation. 83 There is less evidence for a relation between AD and chronic low level hyperexcitatory events. However a correlation of extended dietary ingestion of a glutaminergic agonist, 13-methylamino-L-alanine, with a delayed occurrence of a neurological complex (Amyotrophic Lateral Sclerosis-Parkinsonism-Dementia) has been claimed.…”

Section: Aging and Alzheimer's Diseasementioning

confidence: 99%

The relationship between excitotoxicity and oxidative stress in the central nervous system

Bondy

LeBel

1993

Free Radical Biology and Medicine

149

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Abstract-Excitotoxicity and oxidative stress are two phenomena that have been repeatedly described as being implicated in a wide range of disorders of the nervous system. Such disorders include several common idiopathic neurological diseases, traumatic brain injury, and the consequences of exposure to certain neurotoxic agents. While there is evidence that metabolic derangements can lead to these adverse processes, and that these processes may synergize in their damaging effects, the degree of interdependence, and the causal relation between them is not clear. The intent of this review is to delineate potential mechanisms which may unit hyperexcitation to the excessive generation of reactive oxygen species. The degree of linkage between these events appears rather strong. It is likely that excitoxicity frequently leads to a pro-oxidant condition but that high rates of generation of reactive oxygen species are not invariably accompanied by a hyperexcited neuronal state Both excitoxic and 'oxidotoxic' states result from the failure of normal compensatory antiexcitatory and antioxidant mechanisms to maintain cellular homeostasis.

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“…Thus, although the presence of increased aluminum in AD brain is generally confirmed, in one recent report its presence in AD (senile) plaques has been attributed to experimental artifact (50). Similarly, the presence of an increased concentration of ferritin in AD brain reported earlier (31,33) and its localization in neuritic plaques of AD patients (51) has been conVolume 102, Supplement 3, September 1994 211 firmed, but its association with Al was not seen in several AD brains (33). Most reports show that familial cases of AD once considered due to genetic mutations in the AD-gene in chromosome 21 may also arise from mutations in chromosomes 19 and 14 (52).…”

Section: Role Of Iron In Plaque Formationmentioning

confidence: 83%

Iron and Aluminum Homeostasis in Neural Disorders

Joshi¹,

Dhar²,

Clauberg³

et al. 1994

Environmental Health Perspectives

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The brain is the most compartmentalized organ. It is also highly aerobic. Because nerve cells grow but do not regenerate, the brain is the organ best suited for the accumulation of metabolic errors colocalized in specific areas of the brain over an extended period. Alzheimer's disease (AD) is primarily a neurological disorder of the elderly. It is suggested that this disorder results from the accumulation of such errors, and that AD onset aluminum and iron contribute to but do not necessarily initiate the onset of the disease. In vitro and in vivo evidence summarized here suggests that this is effected by interfering in the utilization of glucose and glucose-6-phosphate, and sequestration of iron by ferritin. 3,Bamyloid precursor proteins (3,-APPs) are normal components of the human brain and some other tissues. Proteolysis of these, presumably by serine proteases, generates a 39 to 42 amino acid long peptide, the a-amyloid (f,-AP). In AD brains, ,B-AP aggregates into plaque, the hallmark of AD brains. Some of the a-APPs also contain a 56 amino acid long segment which inhibits serine proteases. We show that in vitro, at pH 6.5, aluminum activates ,Bchymotrypsin 2-fold and makes it dramatically resistant to protease inhibitors such as bovine pancreatic trypsin inhibitor (bPTI) or its mimic present in the fVamyloid precursor proteins (,B-APPs). Iron and oxygen are reported to favor cross-linking of ,-AP in vitro. Because iron and ferritin are components of neurotic plaques, and acidic pH are reported in AD brains, we suggest that deregulation of iron and aluminum homeostasis permit their colocalization, and contribute to the accumulation of metabolic errors leading to neuronal disorders including the formation of AD (senile) plaques. -Environ Health Perspect 102(Suppl 3): 207-213 (1994)

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Ferritin is a component of the neuritic (senile) plaque in Alzheimer dementia

Cited by 239 publications

References 29 publications

Cortical phase changes in Alzheimer's disease at 7T MRI: A novel imaging marker

Cortical phase changes in Alzheimer's disease at 7T MRI: A novel imaging marker

The relationship between excitotoxicity and oxidative stress in the central nervous system

Iron and Aluminum Homeostasis in Neural Disorders

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