The brain is a major target for circulating gonadal steroids and the change in hormone
levels after menopause is likely to have implications for cognitive functioning. A number
of clinical and preclinical studies have linked gonadal steroids and cognition (e.g.1,2)
and it has been hypothesized that menopause has detrimental effects on cognition that are
over and above the expected effects of normal aging. While menopause results in
reproductive senescence, most of the symptoms of menopause are neurological3. However,
evidence for changes in brain functioning after menopause is equivocal. Some studies
found that cognitive performance after menopause decreased in domains such as memory,
attention, problem solving, and motor skills from pre-menopausal levels (e.g.1,4,5). As
many as 60% of women reported undesirable memory changes at mid-life6. Other studies have
not found changes in cognition after menopause (e.g.7-9) and not all women experience
negative effects of menopause on cognition10. However, women have a higher risk of
dementia compared to men11 and many hypotheses identify the sex differences in gonadal
steroids and the hormone change at menopause as related to risk for Alzheimer's disease
(AD) and/or dementia. The challenge in understanding the role of estrogen loss on the
risk for AD is the long lag time between the hormonal changes at menopause and the
clinical manifestations of AD. Thus, identifying how the hormone changes after menopause
are related to AD risk will alter the risk calculus for postmenopausal women in the
future. In addition, the neurobiological processes underlying how the change in the
hormonal environment at menopause influences brain functioning, what factors are
responsible for individual differences in cognition after menopause, and what
menopause-related symptoms are associated with risk for dementia are not well understood.
One mechanism hypothesized to be responsible for cognitive changes post menopause is the
effect of decreased estradiol on the functioning of neurotransmitter systems that support
cognition. The importance of the estrogen-cholinergic system interaction for cognition
has been demonstrated across a number of model systems from rats12 to non-human
primates13 to humans14. The investigators have shown that estrogen's interaction with the
cholinergic system is important for cognitive functioning in postmenopausal women14-16.
What has not not yet shown is how change in cholinergic system functioning as a result of
menopause is related to menopausal signs/symptoms that influence cognition as well as AD
biomarkers like amyloid, tau, and neurodegeneration. These are important relationships to
understand and may lead to individual risk profiles that can be observed earlier in the
aging process while treatment and prevention strategies may be effective.
This project will investigate the role of cholinergic system in cognitive functioning in
women after menopause. We have been examining the interaction of the neurotransmitter
acetylcholine with hormones after menopause for a number of years14-16. In these studies
with intensive repeated measures designs where the sample sizes were relatively small,
findings generally showed no benefit of estrogen therapy alone for cognition in normal
women post menopause. However, if the investigators induced a temporary impairment in the
cholinergic system, the beneficial effect of estradiol became manifest15 and this was
more prominent in younger postmenopausal women aged 50-60 compared to older women aged
70-8014. Furthermore, these studies showed significant heterogeneity of individual
responses with roughly 50% of women showing either compensatory or impaired responses
suggesting individual differences in risk profile (see preliminary data). What has not
yet demonstrated is how the sensitivity of the cholinergic system to temporary blockade
is related to menopause symptoms and known AD biomarkers that are associated with
increased risk for AD development or frank dementia.
The investigators propose that cholinergic antagonist drugs can be used to expose the
effects of menopause on cognitive functioning. Decreased cognitive performance during a
temporary cholinergic blockade "lesion" may be an indicator of susceptibility to the
negative effects of hormone withdrawal on the brain and risk for age-related cognitive
impairment and/or dementia. The study proposed here will be the first to link cholinergic
sensitivity to biomarkers of neurodegeneration and AD pathology. Specifically, the study
will investigate working memory performance and brain activation during a cholinergic
antagonist challenge compared to placebo and examine how factors associated with
menopause like gonadal steroids, autonomic symptoms, mood, and sleep as well as known
biomarkers associated with Alzheimer's disease (e.g. age, subjective cognitive
complaints, hippocampal and basal forebrain volume, beta amyloid, and tau load) combine
to predict which women are likely to experience cognitive impairment during the
cholinergic challenge procedure.
The results from this study will further the understanding of the neurotransmitter-based
mechanisms responsible for cognitive changes after menopause and how these may predict
late life cognitive dysfunction. After an examination of the neurobiology underlying the
cognitive change at menopause, future studies can develop strategies to mitigate
pathological processes that are enhanced by the menopausal hormone change.