Author | dc.contributor.author | Neumann, Karen F. | |
Author | dc.contributor.author | Rojo, Leonel | es_CL |
Author | dc.contributor.author | Navarrete, Leonardo P. | es_CL |
Author | dc.contributor.author | Farías, Gonzalo | es_CL |
Author | dc.contributor.author | Reyes, Paula | es_CL |
Author | dc.contributor.author | Maccioni Baraona, Ricardo | es_CL |
Admission date | dc.date.accessioned | 2011-04-06T10:48:45Z | |
Available date | dc.date.available | 2011-04-06T10:48:45Z | |
Publication date | dc.date.issued | 2008-10 | |
Cita de ítem | dc.identifier.citation | CURRENT ALZHEIMER RESEARCH, Volume: 5, Issue: 5, Pages: 438-447, 2008 | en_US |
Identifier | dc.identifier.issn | 1567-2050 | |
Identifier | dc.identifier.uri | https://repositorio.uchile.cl/handle/2250/119150 | |
Abstract | dc.description.abstract | Hyperinsulinemia as well as type II diabetes mellitus are among the risk factors for Alzheimer´s disease (AD).
However, the molecular and cellular basis that link insulin resistance disorders and diabetes with AD are far from clear.
Here, we discuss the potential molecular mechanisms that may explain the participation of these metabolic disorders in
the pathogenesis of AD. The human brain uses glucose as a primary fuel; insulin secreted by the pancreas cross the bloodbrain
barrier (BBB), reaching neurons and glial cells, and exerts a region-specific effect on glucose metabolism. Glucose
homeostasis is critical for energy generation, neuronal maintenance, neurogenesis, neurotransmitter regulation, cell survival
and synaptic plasticity. It also plays a key role in cognitive function. In an insulin resistance condition, there is a reduced
sensitivity to insulin resulting in hyperinsulinemia; this condition persists for several years before becoming fullblown
diabetes. Toxic levels of insulin negatively influence neuronal function and survival, and elevation of peripheral insulin
concentration acutely increases its cerebrospinal fluid (CSF) concentration. Peripheral hyperinsulinemia correlates
with an abnormal removal of the amyloid beta peptide (A) and an increase of tau hyperphosphorylation as a result of
augmented cdk5 and GSK3 activities. This leads to cellular cascades that trigger a neurodegenerative phenotype and decline
in cognitive function. Chronic peripheral hyperinsulinemia results in a reduction of insulin transport across the BBB
and a reduced insulin signaling in brain, altering all of insulin’s actions, including its anti-apoptotic effect. However, the
increase in brain insulin levels resulting from its peripheral administration at optimal doses has shown a cognitionenhancing
effect in patient with AD. Some drugs utilized in type II diabetes mellitus reduce cognitive impairment associated
with AD. The link between insulin resistance and neurodegeneration and AD, and the possible therapeutic targets in
preventing the insulin-resistance disorders are analyzed. | en_US |
Patrocinador | dc.description.sponsorship | Research has been supported by a grant from Fondecyt
1080254 and a grant from the Alzheimer´s Association,
U.S.A. Authors are grateful to Sarah Murray MD. for carefully
revising the text of this paper. | en_US |
Lenguage | dc.language.iso | en | en_US |
Publisher | dc.publisher | BENTHAM SCIENCE PUBL LTD | en_US |
Keywords | dc.subject | Insulin | en_US |
Título | dc.title | Insulin Resistance and Alzheimer's Disease: Molecular Links & Clinical Implications | en_US |
Document type | dc.type | Artículo de revista | |