Deferiprone Reduces Amyloid-β and Tau Phosphorylation Levels but not Reactive Oxygen Species Generation in Hippocampus of Rabbits Fed a Cholesterol-Enriched Diet

Prasanthi, Jaya R.P.; Schrag, Matthew; Dasari, Bhanu; Marwarha, Gurdeep; Dickson, April; Kirsch, Wolff M.; Ghribi, Othman

doi:10.3233/jad-2012-111346

Cited by 61 publications

(47 citation statements)

References 79 publications

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“…In animal models of Parkinson's disease, it has been shown to improve motor performance (Aguirre et al, ; Ayton, Lei, Duce, et al, ; Ayton, Lei, et al, ; Devos et al, ; Dexter et al, ; Workman et al, ). Deferiprone is neuroprotective in neuronal culture models of Aβ toxicity (Molina‐Holgado, Gaeta, Francis, Williams, & Hider, ; Part et al, ), and it has been shown to reduce Aβ burden and tau phosphorylation in a rabbit model of AD (Prasanthi et al, ). Deferiprone was shown to lower brain iron levels (as assessed by MRI and CSF ferritin) and improve motor performance in a Phase 2 study of Parkinson's disease (Devos et al, ), and there is now a Phase 2 study underway for AD (clinicaltrials.gov identifier: NCT03234686).…”

Section: Therapeutically Targeting Iron and Ferroptosis In Admentioning

confidence: 99%

“…In animal models of Parkinson's disease, it has been shown to improve motor performance (Aguirre et al, 2015;Ayton, Lei, Duce, et al, 2013;Ayton, Lei, et al, 2015;Devos et al, 2014;Dexter et al, 2011;Workman et al, 2015). Deferiprone is neuroprotective in neuronal culture models of Aβ toxicity (Molina-Holgado, Gaeta, Francis, Williams, & Hider, 2008;Part et al, 2015), and it has been shown to reduce Aβ burden and tau phosphorylation in a rabbit model of AD (Prasanthi et al, 2012).…”

Section: Ironmentioning

confidence: 99%

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Treating Alzheimer's disease by targeting iron

Nikseresht

Bush

Ayton

2019

British J Pharmacology

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No disease modifying drugs have been approved for Alzheimer's disease despite recent major investments by industry and governments throughout the world. The burden of Alzheimer's disease is becoming increasingly unsustainable, and given the last decade of clinical trial failures, a renewed understanding of the disease mechanism is called for, and trialling of new therapeutic approaches to slow disease progression is warranted. Here, we review the evidence and rational for targeting brain iron in Alzheimer's disease. Although iron elevation in Alzheimer's disease was reported in the 1950s, renewed interest has been stimulated by the advancement of fluid and imaging biomarkers of brain iron that predict disease progression, and the recent discovery of the iron‐dependent cell death pathway termed ferroptosis. We review these emerging clinical and biochemical findings and propose how this pathway may be targeted therapeutically to slow Alzheimer's disease progression. Linked Articles This article is part of a themed section on Therapeutics for Dementia and Alzheimer's Disease: New Directions for Precision Medicine. To view the other articles in this section visit http://onlinelibrary.wiley.com/doi/10.1111/bph.v176.18/issuetoc

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Section: Therapeutically Targeting Iron and Ferroptosis In Admentioning

confidence: 99%

Section: Ironmentioning

confidence: 99%

Treating Alzheimer's disease by targeting iron

Nikseresht

Bush

Ayton

2019

British J Pharmacology

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“…The scientists suggested that cholesterol-enriched diet may increase body iron deposition that may lead AD. Administering various metal chelators that will help prevent free radical reactions could be helpful in treating the disease [8,121,122]. Curcumin was found to have a high binding affinity for iron and copper, that may work as an iron chelator in AD [123,124].…”

Section: Turmeric and Saffronmentioning

confidence: 99%

“…Although the pathogenesis of the disease is still not fully understood there is a growing consensus that behind the complex molecular mechanism appears to be the accumulation and aggregation of protein fragments. Amyloid-Beta (Aβ), known as amyloid plaques on the blood vessels and the accumulation of intracellular neurofibrillary tangles (tau) that block neurotransmitters and alter metabolism of iron, cause the destruction of nerve cells that accompanies Alzheimer’s [5,6,7,8,9,10,11,12]. It is reported that increased Aβ levels in AD patients reduce plasmalogen levels [13], increase the formation of reactive oxidative species, and slowly obstruct cerebral function [14,15].…”

Section: Introductionmentioning

confidence: 99%

Vitamin E, Turmeric and Saffron in Treatment of Alzheimer’s Disease

Adalier

Parker

2016

Antioxidants

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Alzheimer’s disease (AD) is a growing epidemic and currently there is no cure for the disease. The disease has a detrimental effect on families and will strain the economy and health care systems of countries worldwide. The paper provides a literature review on a few ongoing possible antioxidant therapy treatments for the disease. The paper highlights use of vitamin E, turmeric and saffron for an alternative antioxidant therapy approach. Clinical studies report their therapeutic abilities as protective agents for nerve cells against free radical damage, moderating acetylcholinesterase (AChE) activity and reducing neurodegeneration, which are found as key factors in Alzheimer’s. The paper suggests that future research, with more clinical trials focused on more natural approaches and their benefits for AD treatment could be worthwhile.

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“…High cholesterol diet‐induced AD animal model can be applied to study the relationship between lipid metabolism disorders and AD pathological progress. However, the pathology of hyperphosphorylated Tau protein seldom occurred in the animal models fed with a high‐cholesterol high‐fat diet . The reason for the difference might be that the animals with inappropriate age have been employed in this model.…”

Section: Metabolic Damage Modelsmentioning

confidence: 99%

Advance of sporadic Alzheimer's disease animal models

Zhang

Chen

Mak

et al. 2019

Medicinal Research Reviews

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Alzheimer's disease (AD), the most common form of dementia, is a progressive neurodegenerative disease. In the past decades, numbers of promising drug candidates showed significant anti‐AD effects in preclinical studies but failed in clinical trials. One of the major reasons might be the limitation of appropriate animal models for evaluating anti‐AD drugs. More than 95% of AD cases are sporadic AD (sAD). However, the anti‐AD drug candidates were mainly tested in the familial AD (fAD) animal models. The diversity between the sAD and fAD might lead to a high failure rate during the development of anti‐AD drugs. Therefore, an ideal sAD animal model is urgently needed for the development of anti‐AD drugs. Here, we summarized the available sAD animal models, including their methodology, pathologic features, and potential underlying mechanisms. The limitations of these sAD animal models and future trends in the field were also discussed.

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Deferiprone Reduces Amyloid-β and Tau Phosphorylation Levels but not Reactive Oxygen Species Generation in Hippocampus of Rabbits Fed a Cholesterol-Enriched Diet

Cited by 61 publications

References 79 publications

Treating Alzheimer's disease by targeting iron

Treating Alzheimer's disease by targeting iron

Vitamin E, Turmeric and Saffron in Treatment of Alzheimer’s Disease

Advance of sporadic Alzheimer's disease animal models

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