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Abstract

Objective:

To determine whether low vitamin D concentrations are associated with an increased risk of incident all-cause dementia and Alzheimer disease.

Methods:

One thousand six hundred fifty-eight elderly ambulatory adults free from dementia, cardiovascular disease, and stroke who participated in the US population–based Cardiovascular Health Study between 1992–1993 and 1999 were included. Serum 25-hydroxyvitamin D (25(OH)D) concentrations were determined by liquid chromatography-tandem mass spectrometry from blood samples collected in 1992–1993. Incident all-cause dementia and Alzheimer disease status were assessed during follow-up using National Institute of Neurological and Communicative Disorders and Stroke/Alzheimer's Disease and Related Disorders Association criteria.

Results:

During a mean follow-up of 5.6 years, 171 participants developed all-cause dementia, including 102 cases of Alzheimer disease. Using Cox proportional hazards models, the multivariate adjusted hazard ratios (95% confidence interval [CI]) for incident all-cause dementia in participants who were severely 25(OH)D deficient (<25 nmol/L) and deficient (≥25 to <50 nmol/L) were 2.25 (95% CI: 1.23–4.13) and 1.53 (95% CI: 1.06–2.21) compared to participants with sufficient concentrations (≥50 nmol/L). The multivariate adjusted hazard ratios for incident Alzheimer disease in participants who were severely 25(OH)D deficient and deficient compared to participants with sufficient concentrations were 2.22 (95% CI: 1.02–4.83) and 1.69 (95% CI: 1.06–2.69). In multivariate adjusted penalized smoothing spline plots, the risk of all-cause dementia and Alzheimer disease markedly increased below a threshold of 50 nmol/L.

Conclusion:

Our results confirm that vitamin D deficiency is associated with a substantially increased risk of all-cause dementia and Alzheimer disease. This adds to the ongoing debate about the role of vitamin D in nonskeletal conditions.
Recent meta-analyses confirm that low serum vitamin D concentrations are associated with prevalent Alzheimer disease (AD) dementia and cognitive impairment.13 This is cause for concern given the high rates of vitamin D deficiency in older adults4 and continued uncertainty about the causes of AD and other forms of dementia.5 Both the 1,25-dihydroxyvitamin D3 receptor and 1α-hydroxylase, the enzyme responsible for synthesizing the bioactive form of vitamin D, are found throughout the human brain.6 In vitro, vitamin D increases the phagocytic clearance of amyloid plaques by stimulating macrophages7,8 and reduces amyloid-induced cytotoxicity and apoptosis in primary cortical neurons.9 Vitamin D deficiency has also been linked to vascular dysfunction and ischemic stroke risk10 as well as brain atrophy.11 However, reverse causation is also possible, as the onset of dementia may lead to dietary changes and reduced outdoor activity, which in turn result in lower vitamin D concentrations.12
Previous prospective studies have established that low vitamin D concentrations in elderly adults are associated with an increased risk of cognitive decline.3,1315 Furthermore, it has been hypothesized that the risk of cognitive decline markedly increases below a threshold between 25 and 50 nmol/L.12 However, preliminary prospective studies of vitamin D and dementia risk have been discordant. In a small study of 40 high-functioning elderly women, severe vitamin D deficiency (<25 nmol/L) was associated with a higher risk of non-AD dementias but not AD over 7 years.16 In contrast, in 10,186 individuals, severe vitamin D deficiency was associated with medical records indicating AD but not vascular dementia over 30 years of follow-up.17 The discrepancy in these findings may be due to a lack of statistical power16 or use of unstandardized dementia diagnoses from medical records, which may result in considerable misclassification.17 We therefore conducted what is to our knowledge the first large, prospective, population-based study incorporating a comprehensive adjudicated assessment of dementia and AD to examine their relationship with vitamin D concentrations.

METHODS

Participants.

Participants were selected from the Cardiovascular Health Study (CHS), a large, prospective, population-based study in the United States designed to investigate the underlying causes of cardiovascular disease in older men and women.18 The CHS recruited participants from 4 communities: Forsyth county, NC (36.1° north, 80.3° west); Sacramento county, CA (38.5° north, 121.4° west); Washington county, MD (39.6° north, 77.8° west); and Pittsburgh, PA (40.4° north, 80.0° west). The cohort consisted of 5,201 adults recruited in 1989–1990 and an additional 687 African-American participants recruited in 1992–1993. Of these 5,888 participants, 4,692 ambulatory participants had complete exam data in 1992–1993 (the baseline assessment for the current study). Serum 25-hydroxyvitamin D (25(OH)D) concentrations were not measured in 1,424 participants who had prevalent cardiovascular disease or stroke (one or more of the following: coronary heart disease, congestive heart failure, claudication, atrial fibrillation, pacemaker, implantable cardioverter defibrillator, stroke, or TIA), determined by medical records, ECG findings, and self-report.19 Further exclusions were insufficient serum volumes for vitamin D assay to be performed (<500 µL; n = 945) and missing adjudicated dementia status (n = 596).20 Participants with prevalent dementia at the time of the vitamin D collection (n = 69) were excluded from the main analyses but included in secondary analyses of prevalent dementia. This resulted in a final sample of 1,658 participants for the main prospective analyses and 1,727 participants for the secondary baseline analyses. Those lost to follow-up (defined as participants with serum 25(OH)D measured but no diagnostic assessment of incident dementia) were older (mean [SD], 74.3 [5.4] years vs 73.8 [4.6] years, p = 0.03), were more likely to be nonwhite (20.0% vs 13.1%, p < 0.001), and had lower serum 25(OH)D concentrations (mean [SD], 61.2 [39.4] nmol/L vs 64.4 [26.5] nmol/L, p = 0.03), but they were no more likely to be female (71.4% vs 69.2%, p = 0.31) or less educated (27.4% vs 23.4% did not finish high school, 53% vs 54% finished high school/some college/vocational qualifications, and 19.6% vs 22.6% completed college or professional qualifications, p = 0.10).

Standard protocol approvals, registrations, and patient consents.

The institutional review boards at each participating institution approved the research protocols, and all participants provided written informed consent.

Serum 25(OH)D measurement.

Serum samples collected in 1992–1993 were stored at −70 °C at the Laboratory for Clinical Biochemistry Research at the University of Vermont, and measurements were performed by the University of Washington Clinical Nutrition Research Unit in 2008.21 Total 25(OH)D (the sum of 25(OH)D2 and 25(OH)D3) was measured using liquid chromatography-tandem mass spectrometry (LC-MS) on a Waters Quattro micro mass spectrometer (Waters, Milford, MA); the interassay coefficient of variation was <3.4%.19 Calibration of serum 25(OH)D concentrations was verified using SRM 972 from the National Institute of Standards and Technology.22

Diagnosis of all-cause dementia and AD.

Dementia and AD status was assessed in 1998–1999 by a committee of neurologists and psychiatrists on the basis of annual cognitive assessments, repeat MRI scans, medical records, questionnaires, and proxy interviews. Diagnosis of dementia was based on a progressive or static cognitive deficit with impairment in at least 2 cognitive domains and a history of normal cognitive function before the onset of abnormalities. Incident all-cause dementia and AD were diagnosed according to the National Institute of Neurological and Communicative Diseases and Stroke/Alzheimer's Disease and Related Disorders Association (NINCDS-ADRDA) criteria. Further details can be found elsewhere.23

Covariates.

We adjusted for covariates identified as potential confounders13,12: age in years, season of blood collection (December–February, March–May, June–August, September–November), education status (did not finish high school, finished high school/some college/vocational qualifications, completed college/professional qualifications), sex, body mass index (BMI in kg/m2), smoking (nonsmoker, current smoker), alcohol consumption (National Institute on Alcohol Abuse and Alcoholism definitions: nondrinkers, moderate drinkers [women ≤7 drinks/week; men ≤14 drinks/week], heavy drinkers [women >7 drinks/week; men >14 drinks/week]), and significant depressive symptoms (score ≥8 on the revised 10-item Center for Epidemiologic Studies Depression Scale24).

Statistical analysis.

Cox proportional hazards models were used to assess the associations between baseline serum 25(OH)D and the risk of incident all-cause dementia and AD. Participants were considered at risk for dementia from baseline (1992–1993) and were censored at death or the end of follow-up in June 1999. All-cause dementia included AD cases, and analyses for AD were censored for non-AD dementia. The proportionality of hazards assumption was assessed using the Schoenfeld residuals technique.25 We analyzed serum 25(OH)D using clinically relevant cutpoints: <25 nmol/L (severely deficient), ≥25 nmol/L to <50 nmol/L (deficient), and ≥50 nmol/L (sufficient).26 Linear trends across categories were tested by entering 25(OH)D groups into models as a continuous rather than a categorical variable. In basic adjusted models, we controlled for age and season of blood collection. In fully adjusted models, we controlled for education, sex, BMI, smoking, alcohol consumption, and depressive symptoms. To investigate any threshold, we used multivariate adjusted penalized smoothing spline plots. Eight outlying participants with 25(OH)D concentrations between 170 and 283 nmol/L were excluded due to imprecision at the extreme end of the distribution (none developed dementia during follow-up).
In secondary analyses, serum 25(OH)D concentrations were analyzed as a continuous rather than a categorical variable. 25(OH)D concentrations were standardized to have a mean of 0 and an SD of 1 to aid interpretation. Because 25(OH)D concentrations were positively skewed, they were normalized using a log transformation. We repeated the main analyses to include adjustments for health conditions that have been identified as potential mediators for the association between serum 25(OH)D concentrations and dementia risk12,13: diabetes (American Diabetes Association guidelines: using oral hypoglycemic agents or insulin, or plasma fasting glucose ≥7.0 nmol/L) and/or hypertension (3 categories; no hypertension: systolic <140 mm Hg and diastolic <90 mm Hg; treated hypertension: hypertensive medication; untreated hypertension: systolic ≥140 mm Hg or diastolic ≥90 mm Hg with no hypertensive medication). We also adjusted for ethnicity (white/black) and examined potential interactions with ethnicity in separate models, although it is recognized that this may represent overadjustment.27 In a further analysis, we adjusted for socioeconomic status indicators: annual income (<$12,000, $12,000–24,999, $25,000–49,999, ≥$50,000, missing) and usual lifetime occupation (professional/technical/managerial/administrative, sales/clerical service, craftsman/machine operator/laborer/farming/forestry, housewife, other/missing). Multivariate adjusted logistic regression models were used to investigate the cross-sectional association between serum 25(OH)D and prevalent all-cause dementia (n = 69) and AD (n = 34).
In sensitivity analyses, we excluded participants who developed all-cause dementia (n = 12) and AD (n = 6) within 1 year of baseline to remove the possibility that any association observed was determined by these “early converters.” p Values were 2-sided throughout, and the type I error rate for statistical significance was set at 0.05. Analyses were performed using Stata SE version 12 (StataCorp, College Station, TX) with the exception of the spline plots, which were fitted in R version 2.15.1 (www.r-project.org).

RESULTS

Table 1 displays baseline characteristics for the study population included in the main prospective analyses. Participants were followed up for a mean of 5.6 years (SD 1.6, median 6.1, range 0.1–8.4). During 9,317.5 person-years of follow-up, 171 participants developed all-cause dementia and 102 developed AD. The risk of developing both all-cause dementia and AD was significantly higher in participants who were either 25(OH)D deficient or severely deficient (table 2). In minimally adjusted models, those who were deficient had about a 51% increased risk of all-cause dementia, whereas the increased risk for those who were severely deficient was about 122%. The strength of the association observed for incident AD was similar to that observed for all-cause dementia. Additional adjustment for potential confounders did not alter the pattern of results, and there was a linear trend across groups in all analyses, suggesting a monotonic association. Kaplan-Meier plots for unadjusted rates of incident all-cause dementia and AD show clear differences in risk by 25(OH)D concentrations after 2–3 years of follow-up (figure 1). Multivariate adjusted smoothing spline plots suggest that the risk of all-cause dementia and AD markedly increases at 25(OH)D concentrations below 50 nmol/L (figure 2).
Table 1 Baseline characteristics of 1,658 CHS participants by serum 25(OH)D concentration
Table 2 Cox proportional hazards regression models of incident all-cause dementia and Alzheimer disease by serum 25(OH)D concentration
Figure 1 Kaplan-Meier curves for unadjusted rates of all-cause dementia and Alzheimer disease by serum 25-hydroxyvitamin D (25(OH)D) concentrations.
Figure 2 Multivariate adjusted smoothing spline plots showing the hazard ratios for dementia and Alzheimer disease by serum 25(OH)D concentrations
Models adjusted for age, season of vitamin D collection, education, sex, body mass index, smoking, alcohol consumption, and depressive symptoms. Hazard ratios centered on median serum 25-hydroxyvitamin D (25(OH)D) concentrations.
Secondary analyses incorporating continuous 25(OH)D concentrations gave a similar pattern of results. The multivariate adjusted risks for incident all-cause dementia and incident AD reduced by 18% (hazard ratio [HR] = 0.82, 95% confidence interval [CI]: 0.70–0.97, p = 0.02) and 20% (HR = 0.80, 95% CI: 0.65–0.99, p = 0.04), respectively, for each 1 SD increase in log-transformed 25(OH)D. Additional adjustment for diabetes or hypertension did not change the pattern of results for either incident all-cause dementia or AD, suggesting that these conditions are unlikely to mediate the observed associations (table 3). Adjustment for ethnicity attenuated the main results slightly but did not change the overall pattern of results, and there were no significant interactions (table e-1 on the Neurology® Web site at Neurology.org). Additional adjustment for income and occupation did not change the associations either (table e-2). The odds of prevalent all-cause dementia and AD at baseline in participants who were severely 25(OH)D deficient were 3–6 times higher than those with sufficient 25(OH)D, with a linear trend across groups (table e-3). After excluding participants who developed all-cause dementia and AD within 1 year of baseline, the multivariate adjusted HRs in participants who were severely 25(OH)D deficient and deficient compared to participants with sufficient 25(OH)D concentrations were 2.42 (95% CI: 1.33–4.39) and 1.54 (95% CI: 1.06–2.28) for incident all-cause dementia (p for linear trend = 0.001) and 2.36 (95% CI: 1.08–5.16) and 1.69 (95% CI: 1.04–2.73) for AD (p for linear trend = 0.007). This suggests that the association is not driven by “early converters.”
Table 3 Cox proportional hazards regression models of incident all-cause dementia and Alzheimer disease by serum 25(OH)D concentration with additional adjustment for potential mediators

DISCUSSION

We have conducted what is to our knowledge the first large, prospective, population-based study to examine vitamin D concentrations in relation to a comprehensive adjudicated assessment of dementia and AD. We observed a strong monotonic association between 25(OH)D concentrations and the risk of both incident all-cause dementia and AD. This association was robust to adjustment for a range of potential confounders and the exclusion of dementia cases that occurred within a year of baseline.
The 2 previous studies that have investigated vitamin D and incident dementia have produced conflicting results. The first found that severe vitamin D deficiency was associated with non-AD dementia but not AD risk.16 The second found that severe vitamin D deficiency was associated with AD but not vascular dementia risk.17 However, the first study incorporated a small sample of high-functioning women (n = 40), and the lack of association with AD may reflect limited statistical power. The second study relied on registry data for dementia diagnoses, which may have resulted in considerable misclassification. Our results establish that low 25(OH)D concentrations are linked to an increased risk of incident all-cause dementia and AD, and they are consistent with studies suggesting a link with cognitive impairment1,3,12,26,28 and cognitive decline.1315 Few studies have examined potential mediators of this association, although there was no evidence in the present study or the InCHIANTI13 study for mediation by diabetes or hypertension.
A threshold below which the risk of dementia increases markedly has previously been hypothesized to lie in the 25–50 nmol/L range.12 The optimal level of vitamin D for general health remains controversial, with the Institute of Medicine recommending 50 nmol/L and the Endocrine Society recommending 75 nmol/L.29,30 A post hoc analysis of the Women's Health Initiative randomized controlled trial discovered that a relatively low dose of vitamin D (400 IU) in combination with calcium (1,000 mg) did not protect against dementia over a mean follow-up period of 7.8 years in women who had relatively high serum vitamin D levels at baseline (mean of 49 nmol/L in a small subsample).31 Our results clarify that the threshold above which older adults are unlikely to benefit from supplementation with regard to dementia risk is likely to lie in the region of 50 nmol/L when 25(OH)D concentrations are measured using LC-MS. This therefore adds to the ongoing debate regarding optimal vitamin D levels for different health outcomes.
A number of potential mechanisms linking low vitamin D levels with the risk of dementia have been identified.32 Vitamin D receptors are expressed throughout the brain, including areas involved in memory such as the hippocampus and dentate gyrus.6 Similarly, the enzyme that synthesizes the active form of vitamin D, 1α-hydroxylase, is produced in several cerebral regions. The active form of vitamin D, 1,25dihydroxy-vitamin D3 (1,25-D3), regulates neurotrophin expression, such as nerve growth factor, neurotrophin 3, and glial-derived neurotrophic factor,11 and the survival, development, and function of neural cells.33 In vitro, vitamin D stimulates macrophages, which increases the clearance of amyloid plaques, a hallmark of AD.7,8 Vitamin D also reduces amyloid-induced cytotoxicity and apoptosis in primary cortical neurons.9 A recent study found that amyloid-β induction of induced nitric oxide synthase, part of the inflammatory process of AD, is dependent on the disruption of the vitamin D-vitamin D receptor pathway.34 Vitamin D supplementation ameliorates age-related decline in learning and memory in aged rats.35 In addition, vitamin D deficiency has been linked to cerebrovascular pathology. Meta-analyses establish that 25(OH)D deficiency is associated with an increased risk of incident stroke,36 particularly ischemic stroke.10 A cross-sectional study of 318 elderly adults found that 25(OH)D deficiency was associated with increased white matter hyperintensity volume and a greater number of large vessel infarcts.37 In summary, low vitamin D concentrations may increase the risk of dementia and AD through both neurodegenerative and vascular mechanisms.
Our study has a number of strengths. The study sample was relatively diverse as it was population-based and included white and African-American men and women. A recent systematic review raised the possibility that the consistent observational associations between vitamin D levels and a wide range of health conditions may simply reflect reverse causation.38 However, in this study reverse causation is made less likely by the fact that participants were ambulatory and relatively healthy at baseline (their outdoor activity was not likely to be limited by impaired function linked to the onset of dementia). The long follow-up and exclusion of prevalent dementia and incident dementia occurring within a year of baseline also make reverse causation less likely. All-cause dementia and AD in the CHS were diagnosed by a committee of neurologists and psychiatrists using a comprehensive range of data, including neuroimaging, according to international criteria (NINCDS-ADRDA).23 Our study also has several limitations. While the CHS is multiethnic, it did not incorporate people of Hispanic or other ethnicities. Due to the exclusion of participants with cardiovascular disease and stroke at baseline, there were few cases of incident vascular dementia (n = 15). It was therefore not possible to investigate the relationship between vitamin D concentrations and incident vascular dementia due to a lack of statistical power, and further research is necessary to investigate generalizability to older adults with vascular dysfunction. In a cohort with a greater burden of vascular and metabolic dysfunction it would also be interesting to investigate these factors as time-varying covariates. The representativeness of our final sample may have been reduced due to the inability to include participants with insufficient serum volume for 25(OH)D measurement (n = 945) as well as those lost to follow-up (n = 596). It is possible that the delay between obtaining the blood samples in 1992–1993 and measuring 25(OH)D concentrations in 2008 could have introduced measurement error; however, this is unlikely to have introduced systematic bias. Despite the wide range of information (including repeat neuroimaging) available to the committee diagnosing all-cause dementia and AD, a degree of misclassification is still likely. In particular, many cases of AD may actually reflect a mixture of pathologies, so caution should be exercised when considering potential mechanisms. As with all observational studies, unmeasured confounding is possible, and our findings do not in themselves demonstrate a causal relationship.
We found a strong association between baseline vitamin D concentrations and the risk of incident all-cause dementia and AD over a mean of 5.6 years of follow-up in ambulatory older adults free from vascular conditions at baseline. Further studies are necessary to replicate our findings and extend them to more diverse populations. It would be useful to conduct prospective studies to investigate the association between vitamin D concentrations and incident vascular dementia and neuroimaging abnormalities. Our findings support the hypothesis that vitamin D may be neuroprotective and that “sufficiency” in the context of dementia risk may be in the region of 50 nmol/L. This information is likely to prove useful in improving the design and reducing the cost of randomized controlled trials investigating whether vitamin D supplements can be used to delay or prevent the onset of dementia and AD in older adults.

GLOSSARY

25(OH)D
25-hydroxyvitamin D
AD
Alzheimer disease
BMI
body mass index
CHS
Cardiovascular Health Study
CI
confidence interval
HR
hazard ratio
LC-MS
liquid chromatography-tandem mass spectrometry
NINCDS-ADRDA
National Institute of Neurological and Communicative Diseases and Stroke/Alzheimer's Disease and Related Disorders Association

Data Supplement

Three tables; one Microsoft Word file.
Neurology® data supplements are not copyedited before publication. Published editorials and translations have been copyedited. © 2014 American Academy of Neurology. Files in this Data Supplement:
Tables e-1 to e-3 - Microsoft Word file

Supplementary Material

File (9.2.14_vitamin_d_and_the_risk_of_dementia.pdf)
File (tables_e-1-3.docx)

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Letters to the Editor
28 August 2014
Vitamin D deficiency and the risk of dementia
Robert H Howland, Associate Professor of Psychiatry

In their post-hoc analysis of data from a prospective cohort study originally designed to investigate causes of cardiovascular disease, Littlejohns et al. [1] found baseline vitamin D deficiency was associated with a subsequent increased incidence of all-cause dementia, consistent with other observational association studies. Holick [2] described vitamin D deficiency as pandemic, affecting an estimated one billion or more people worldwide. Results from seven population based studies suggest the prevalence and incidence of dementia might be decreasing, [3,4] including in England [4] where rates of rickets have steadily increased during the past two decades. [5] If there is a valid association between vitamin D deficiency and dementia, why are declining rates of dementia seen amidst a vitamin D deficiency pandemic? Although preclinical studies provide a plausible mechanism linking vitamin D deficiency to cognitive impairment, causality cannot be established from association studies. Statistically significant but weak associations in observational studies are likely to be false and attributable to various sources of bias. Large observational studies, or meta-analyses of observational studies, enable greater precision and statistical significance of a finding, but this does not eliminate bias or provide validation.

1. Littlejohns TJ, Henley WE, Lang IA, et al. Vitamin D and the risk of dementia and Alzheimer disease. Neurology Epub 2014 Aug 6.

2. Holick MF. The vitamin D deficiency pandemic: A forgotten hormone important for health. Public Health Rev 2010;32:267-283.

3. Larson EB, Yaffe K, Langa KM. New insights into the dementia epidemic. N Engl J Med 2013;369:2275-2277.

4. Matthews FE, Arthur A, Barnes LE, et al. A two-decade comparison of prevalence of dementia in individuals aged 65 years and older from three geographical areas of England: Results of the Cognitive Function and Ageing Study I and II. Lancet 2013;382:1405-1412.

5. Goldacre M, Hall N, Yeates DGR. Hospitalisation for children with rickets in England: A historical perspective. Lancet 2014;383:597-598.

For disclosures, contact [email protected].

14 August 2014
Disturbed sleep: the trigger for vitamin D deficiency?
Sergio Tufik, Full Professor
Lais F. Berro, Sao Paulo, Brazil; Sergio B. Tufik, Sao Paulo, Brazil; Monica L. Andersen, Sao Paulo, Brazil
Littlejohns et al. confirmed that vitamin D deficiency is associated with increased risk of dementia. [1] Several studies have been proposing the widely prevalent lack of vitamin D as a potential cause of epidemic ill-health conditions. However, the trigger for this deficiency is poorly understood.

In addition to an increasingly large number of humans spending most daytime hours indoors, sleep deprivation is common place in modern society. In this regard, studies demonstrated anatomic and epidemiological connections between sleep problems and vitamin D deficiency. [2] Of importance, low vitamin D levels seem to be significantly associated with longer time to fall asleep [3] and excessive daytime sleepiness, [4] underlying conditions in sleep restricted individuals.

Although the cause and consequence between sleep impairment and vitamin D deficiency is not yet fully elucidated, this suggests a bidirectional relationship. We propose chronically restricted sleep as a potential trigger for inadequate vitamin D in modern society. To date, no studies specifically addressed the effects of sleep deprivation on vitamin D levels. In light of the recent findings by Littlejohns and colleagues, [1] disturbed sleep, a long known condition linked to aging, [5] could indirectly contribute to the development of dementia and Alzheimer disease.

1. Littlejohns TJ, Henley WE, Lang IA, et al. Vitamin D and the risk of dementia and Alzheimer disease. Neurology Epub 2014 Aug 6.

2. McCarty DE, Chesson AL Jr, Jain SK, Marino AA. The link between vitamin D metabolism and sleep medicine. Sleep Med Rev 2014;18:311-319.

3.Shiue I. Low vitamin D levels in adults with longer time to fall asleep: US NHANES, 2005-2006. Int J Cardiol 2013;168:5074-5075.

4. McCarty DE, Reddy A, Keigley Q, et al. Vitamin D, race, and excessive daytime sleepiness. J Clin Sleep Med 2012;8:693-697.

5. Ancoli-Israel S. Sleep and its disorders in aging populations. Sleep Med 2009;10:S7-11.

For disclosures, contact the editorial office at [email protected].

Information & Authors

Information

Published In

Neurology®
Volume 83Number 10September 2, 2014
Pages: 920-928
PubMed: 25098535

Publication History

Received: February 3, 2014
Accepted: May 28, 2014
Published online: August 6, 2014
Published in print: September 2, 2014

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Disclosure

The authors report no disclosures relevant to the manuscript. Go to Neurology.org for full disclosures.

Study Funding

The CHS was supported by contracts HHSN268201200036C, HHSN268200800007C, N01 HC55222, N01HC85079, N01HC85080, N01HC85081, N01HC85082, N01HC85083, N01HC85086, and grant HL080295 from the National Heart, Lung, and Blood Institute, with additional contribution from the National Institute of Neurological Disorders and Stroke. Additional support was provided by AG023629, AG20098, AG15928, and HL084443 from the National Institute on Aging. A full list of principal CHS investigators and institutions can be found at www.chs-nhlbi.org. Additional support was also provided by NIRG-11-200737 from the Alzheimer's Association, the Mary Kinross Charitable Trust, the James Tudor Foundation, the Halpin Trust, the Age Related Diseases and Health Trust, and the Norman Family Charitable Trust (to D.J.L.). This report presents independent research supported by the UK National Institute for Health Research (NIHR) Collaboration for Leadership in Applied Health Research and Care (CLAHRC) for the South West Peninsula. None of the funding sources had any role in the design of the study; in the analysis and interpretation of the data; or in the preparation of the manuscript. The views expressed in this publication are those of the authors and not necessarily those of the NHS, the NIHR, or the Department of Health in England. The NIH was involved in the original design and conduct of the CHS and in the data collection methods.

Authors

Affiliations & Disclosures

Thomas J. Littlejohns, MSc
From the University of Exeter Medical School (T.J.L., W.E.H., I.A.L., K.K., M.S., D.J.L.), Exeter, UK; Department of Internal Medicine and Geriatrics (C.A., O.B.), Angers University Hospital, Angers, France; Herbert Wertheim College of Medicine (P.H.M.C.), Florida International University, Miami; Mailman School of Public Health (L.F.), Columbia University, New York; Kidney Research Institute, Division of Nephrology (B.R.K.), University of Washington, Seattle; Departments of Epidemiology (L.H.K.) and Neurology and Psychiatry (O.L.L.), University of Pittsburgh, PA; Division of General Medicine (K.M.L.), Veterans Affairs Ann Arbor Center for Clinical Management Research, Ann Arbor, MI; and the Institute for Social Research and the Institute for Healthcare Policy and Innovation (K.M.L.), University of Michigan, Ann Arbor.
Disclosure
Scientific Advisory Boards:
1.
NONE
Gifts:
1.
NONE
Funding for Travel or Speaker Honoraria:
1.
NONE
Editorial Boards:
1.
NONE
Patents:
1.
NONE
Publishing Royalties:
1.
NONE
Employment, Commercial Entity:
1.
NONE
Consultancies:
1.
NONE
Speakers' Bureaus:
1.
NONE
Other Activities:
1.
NONE
Clinical Procedures or Imaging Studies:
1.
NONE
Research Support, Commercial Entities:
1.
NONE
Research Support, Government Entities:
1.
NONE
Research Support, Academic Entities:
1.
NONE
Research Support, Foundations and Societies:
1.
NONE
Stock/stock Options/board of Directors Compensation:
1.
NONE
License Fee Payments, Technology or Inventions:
1.
NONE
Royalty Payments, Technology or Inventions:
1.
NONE
Stock/stock Options, Research Sponsor:
1.
NONE
Stock/stock Options, Medical Equipment & Materials:
1.
NONE
Legal Proceedings:
1.
NONE
William E. Henley, PhD
From the University of Exeter Medical School (T.J.L., W.E.H., I.A.L., K.K., M.S., D.J.L.), Exeter, UK; Department of Internal Medicine and Geriatrics (C.A., O.B.), Angers University Hospital, Angers, France; Herbert Wertheim College of Medicine (P.H.M.C.), Florida International University, Miami; Mailman School of Public Health (L.F.), Columbia University, New York; Kidney Research Institute, Division of Nephrology (B.R.K.), University of Washington, Seattle; Departments of Epidemiology (L.H.K.) and Neurology and Psychiatry (O.L.L.), University of Pittsburgh, PA; Division of General Medicine (K.M.L.), Veterans Affairs Ann Arbor Center for Clinical Management Research, Ann Arbor, MI; and the Institute for Social Research and the Institute for Healthcare Policy and Innovation (K.M.L.), University of Michigan, Ann Arbor.
Disclosure
Scientific Advisory Boards:
1.
NONE
Gifts:
1.
NONE
Funding for Travel or Speaker Honoraria:
1.
NONE
Editorial Boards:
1.
NONE
Patents:
1.
NONE
Publishing Royalties:
1.
NONE
Employment, Commercial Entity:
1.
NONE
Consultancies:
1.
NONE
Speakers' Bureaus:
1.
NONE
Other Activities:
1.
NONE
Clinical Procedures or Imaging Studies:
1.
NONE
Research Support, Commercial Entities:
1.
NONE
Research Support, Government Entities:
1.
(1) UK Medical Research Council, grant number G0902158, Principal Investigator, 2010-2014.
Research Support, Academic Entities:
1.
NONE
Research Support, Foundations and Societies:
1.
NONE
Stock/stock Options/board of Directors Compensation:
1.
NONE
License Fee Payments, Technology or Inventions:
1.
NONE
Royalty Payments, Technology or Inventions:
1.
NONE
Stock/stock Options, Research Sponsor:
1.
NONE
Stock/stock Options, Medical Equipment & Materials:
1.
NONE
Legal Proceedings:
1.
NONE
Iain A. Lang, PhD
From the University of Exeter Medical School (T.J.L., W.E.H., I.A.L., K.K., M.S., D.J.L.), Exeter, UK; Department of Internal Medicine and Geriatrics (C.A., O.B.), Angers University Hospital, Angers, France; Herbert Wertheim College of Medicine (P.H.M.C.), Florida International University, Miami; Mailman School of Public Health (L.F.), Columbia University, New York; Kidney Research Institute, Division of Nephrology (B.R.K.), University of Washington, Seattle; Departments of Epidemiology (L.H.K.) and Neurology and Psychiatry (O.L.L.), University of Pittsburgh, PA; Division of General Medicine (K.M.L.), Veterans Affairs Ann Arbor Center for Clinical Management Research, Ann Arbor, MI; and the Institute for Social Research and the Institute for Healthcare Policy and Innovation (K.M.L.), University of Michigan, Ann Arbor.
Disclosure
Scientific Advisory Boards:
1.
NONE
Gifts:
1.
NONE
Funding for Travel or Speaker Honoraria:
1.
NONE
Editorial Boards:
1.
NONE
Patents:
1.
NONE
Publishing Royalties:
1.
NONE
Employment, Commercial Entity:
1.
NONE
Consultancies:
1.
NONE
Speakers' Bureaus:
1.
NONE
Other Activities:
1.
NONE
Clinical Procedures or Imaging Studies:
1.
NONE
Research Support, Commercial Entities:
1.
NONE
Research Support, Government Entities:
1.
(1) UK National Institute for Health Research (NIHR) Collaboration for Leadership in Applied Health Research and Care South West Peninsula (PenCLAHRC), n/a, Senior Lecturer, 2009-2013 and 2014-2018 (2) UK National Institute for Health Research (NIHR) Knowledge Mobilisation Fellowship, n/a, Fellow, 2014-2017
Research Support, Academic Entities:
1.
NONE
Research Support, Foundations and Societies:
1.
NONE
Stock/stock Options/board of Directors Compensation:
1.
NONE
License Fee Payments, Technology or Inventions:
1.
NONE
Royalty Payments, Technology or Inventions:
1.
NONE
Stock/stock Options, Research Sponsor:
1.
NONE
Stock/stock Options, Medical Equipment & Materials:
1.
NONE
Legal Proceedings:
1.
NONE
Cedric Annweiler, MD, PhD
From the University of Exeter Medical School (T.J.L., W.E.H., I.A.L., K.K., M.S., D.J.L.), Exeter, UK; Department of Internal Medicine and Geriatrics (C.A., O.B.), Angers University Hospital, Angers, France; Herbert Wertheim College of Medicine (P.H.M.C.), Florida International University, Miami; Mailman School of Public Health (L.F.), Columbia University, New York; Kidney Research Institute, Division of Nephrology (B.R.K.), University of Washington, Seattle; Departments of Epidemiology (L.H.K.) and Neurology and Psychiatry (O.L.L.), University of Pittsburgh, PA; Division of General Medicine (K.M.L.), Veterans Affairs Ann Arbor Center for Clinical Management Research, Ann Arbor, MI; and the Institute for Social Research and the Institute for Healthcare Policy and Innovation (K.M.L.), University of Michigan, Ann Arbor.
Disclosure
Scientific Advisory Boards:
1.
NONE
Gifts:
1.
NONE
Funding for Travel or Speaker Honoraria:
1.
- Travel grant: “Alzheimer�s Association International Conference (AAIC) Fellowship Committee” grant (Vancouver, BC, Canada, July 2012).
Editorial Boards:
1.
- G�riatrie, Psychologie et Neuropsychiatrie du Vieillissement, Associate Editor, since 2012 - Journal of Alzheimer's Disease, Associate Editor, since 2012
Patents:
1.
NONE
Publishing Royalties:
1.
NONE
Employment, Commercial Entity:
1.
NONE
Consultancies:
1.
NONE
Speakers' Bureaus:
1.
NONE
Other Activities:
1.
NONE
Clinical Procedures or Imaging Studies:
1.
NONE
Research Support, Commercial Entities:
1.
NONE
Research Support, Government Entities:
1.
NONE
Research Support, Academic Entities:
1.
NONE
Research Support, Foundations and Societies:
1.
NONE
Stock/stock Options/board of Directors Compensation:
1.
NONE
License Fee Payments, Technology or Inventions:
1.
NONE
Royalty Payments, Technology or Inventions:
1.
NONE
Stock/stock Options, Research Sponsor:
1.
NONE
Stock/stock Options, Medical Equipment & Materials:
1.
NONE
Legal Proceedings:
1.
NONE
Olivier Beauchet, MD, PhD
From the University of Exeter Medical School (T.J.L., W.E.H., I.A.L., K.K., M.S., D.J.L.), Exeter, UK; Department of Internal Medicine and Geriatrics (C.A., O.B.), Angers University Hospital, Angers, France; Herbert Wertheim College of Medicine (P.H.M.C.), Florida International University, Miami; Mailman School of Public Health (L.F.), Columbia University, New York; Kidney Research Institute, Division of Nephrology (B.R.K.), University of Washington, Seattle; Departments of Epidemiology (L.H.K.) and Neurology and Psychiatry (O.L.L.), University of Pittsburgh, PA; Division of General Medicine (K.M.L.), Veterans Affairs Ann Arbor Center for Clinical Management Research, Ann Arbor, MI; and the Institute for Social Research and the Institute for Healthcare Policy and Innovation (K.M.L.), University of Michigan, Ann Arbor.
Disclosure
Scientific Advisory Boards:
1.
NONE
Gifts:
1.
NONE
Funding for Travel or Speaker Honoraria:
1.
NONE
Editorial Boards:
1.
editorial advisory board member of Geriatr Psychol Neuropsychiatr Vieil
Patents:
1.
NONE
Publishing Royalties:
1.
NONE
Employment, Commercial Entity:
1.
NONE
Consultancies:
1.
Consultancies for the Korian group,Ipsen Pharma, MSD and �rontolop�le autonomie long�vit� des Pays de la Loire
Speakers' Bureaus:
1.
NONE
Other Activities:
1.
NONE
Clinical Procedures or Imaging Studies:
1.
NONE
Research Support, Commercial Entities:
1.
NONE
Research Support, Government Entities:
1.
NONE
Research Support, Academic Entities:
1.
NONE
Research Support, Foundations and Societies:
1.
NONE
Stock/stock Options/board of Directors Compensation:
1.
NONE
License Fee Payments, Technology or Inventions:
1.
NONE
Royalty Payments, Technology or Inventions:
1.
NONE
Stock/stock Options, Research Sponsor:
1.
NONE
Stock/stock Options, Medical Equipment & Materials:
1.
NONE
Legal Proceedings:
1.
NONE
Paulo H.M. Chaves, MD, PhD
From the University of Exeter Medical School (T.J.L., W.E.H., I.A.L., K.K., M.S., D.J.L.), Exeter, UK; Department of Internal Medicine and Geriatrics (C.A., O.B.), Angers University Hospital, Angers, France; Herbert Wertheim College of Medicine (P.H.M.C.), Florida International University, Miami; Mailman School of Public Health (L.F.), Columbia University, New York; Kidney Research Institute, Division of Nephrology (B.R.K.), University of Washington, Seattle; Departments of Epidemiology (L.H.K.) and Neurology and Psychiatry (O.L.L.), University of Pittsburgh, PA; Division of General Medicine (K.M.L.), Veterans Affairs Ann Arbor Center for Clinical Management Research, Ann Arbor, MI; and the Institute for Social Research and the Institute for Healthcare Policy and Innovation (K.M.L.), University of Michigan, Ann Arbor.
Disclosure
Scientific Advisory Boards:
1.
NONE
Gifts:
1.
NONE
Funding for Travel or Speaker Honoraria:
1.
NONE
Editorial Boards:
1.
American Journal of Epidemiology, Associate Editor, 2012-present; no compensation Journal of Epidemiology (Japan Epidemiological Association), Associate Editor, 2011-present - no compensation
Patents:
1.
NONE
Publishing Royalties:
1.
NONE
Employment, Commercial Entity:
1.
NONE
Consultancies:
1.
NONE
Speakers' Bureaus:
1.
NONE
Other Activities:
1.
NONE
Clinical Procedures or Imaging Studies:
1.
NONE
Research Support, Commercial Entities:
1.
NONE
Research Support, Government Entities:
1.
NONE
Research Support, Academic Entities:
1.
NONE
Research Support, Foundations and Societies:
1.
NONE
Stock/stock Options/board of Directors Compensation:
1.
NONE
License Fee Payments, Technology or Inventions:
1.
NONE
Royalty Payments, Technology or Inventions:
1.
NONE
Stock/stock Options, Research Sponsor:
1.
NONE
Stock/stock Options, Medical Equipment & Materials:
1.
NONE
Legal Proceedings:
1.
NONE
Linda Fried, MD, MPH
From the University of Exeter Medical School (T.J.L., W.E.H., I.A.L., K.K., M.S., D.J.L.), Exeter, UK; Department of Internal Medicine and Geriatrics (C.A., O.B.), Angers University Hospital, Angers, France; Herbert Wertheim College of Medicine (P.H.M.C.), Florida International University, Miami; Mailman School of Public Health (L.F.), Columbia University, New York; Kidney Research Institute, Division of Nephrology (B.R.K.), University of Washington, Seattle; Departments of Epidemiology (L.H.K.) and Neurology and Psychiatry (O.L.L.), University of Pittsburgh, PA; Division of General Medicine (K.M.L.), Veterans Affairs Ann Arbor Center for Clinical Management Research, Ann Arbor, MI; and the Institute for Social Research and the Institute for Healthcare Policy and Innovation (K.M.L.), University of Michigan, Ann Arbor.
Disclosure
Scientific Advisory Boards:
1.
NONE
Gifts:
1.
NONE
Funding for Travel or Speaker Honoraria:
1.
NONE
Editorial Boards:
1.
NONE
Patents:
1.
NONE
Publishing Royalties:
1.
NONE
Employment, Commercial Entity:
1.
Employed by nonprofit university: Columbia University, Dean and DeLamar Professor of Public Health
Consultancies:
1.
Sanofi-Aventis
Speakers' Bureaus:
1.
NONE
Other Activities:
1.
NONE
Clinical Procedures or Imaging Studies:
1.
NONE
Research Support, Commercial Entities:
1.
Sanofi-Aventis (consulting)
Research Support, Government Entities:
1.
(1) National Institute on Aging, 1U01AG032947-01, Subcontract PI (prime: Johns Hopkins, University), 9/30/08-8/31/2011 (2) National Institute on Aging, 5R37AG019905-10, PI, 9/1/10-8/31/12 (3) National Institute on Aging, 5P01AG027735-05, Subcontract PI (prime: Johns Hopkins University), 8/01/08-6/30/12
Research Support, Academic Entities:
1.
NONE
Research Support, Foundations and Societies:
1.
NONE
Stock/stock Options/board of Directors Compensation:
1.
NONE
License Fee Payments, Technology or Inventions:
1.
NONE
Royalty Payments, Technology or Inventions:
1.
NONE
Stock/stock Options, Research Sponsor:
1.
NONE
Stock/stock Options, Medical Equipment & Materials:
1.
NONE
Legal Proceedings:
1.
NONE
Bryan R. Kestenbaum, MD, MS
From the University of Exeter Medical School (T.J.L., W.E.H., I.A.L., K.K., M.S., D.J.L.), Exeter, UK; Department of Internal Medicine and Geriatrics (C.A., O.B.), Angers University Hospital, Angers, France; Herbert Wertheim College of Medicine (P.H.M.C.), Florida International University, Miami; Mailman School of Public Health (L.F.), Columbia University, New York; Kidney Research Institute, Division of Nephrology (B.R.K.), University of Washington, Seattle; Departments of Epidemiology (L.H.K.) and Neurology and Psychiatry (O.L.L.), University of Pittsburgh, PA; Division of General Medicine (K.M.L.), Veterans Affairs Ann Arbor Center for Clinical Management Research, Ann Arbor, MI; and the Institute for Social Research and the Institute for Healthcare Policy and Innovation (K.M.L.), University of Michigan, Ann Arbor.
Disclosure
Scientific Advisory Boards:
1.
NONE
Gifts:
1.
NONE
Funding for Travel or Speaker Honoraria:
1.
NONE
Editorial Boards:
1.
NONE
Patents:
1.
NONE
Publishing Royalties:
1.
Kestenbaum, B., et al. (2009). Epidemiology and biostatistics : an introduction to clinical research. Dordrecht ; New York, Springer.
Employment, Commercial Entity:
1.
NONE
Consultancies:
1.
NONE
Speakers' Bureaus:
1.
NONE
Other Activities:
1.
NONE
Clinical Procedures or Imaging Studies:
1.
NONE
Research Support, Commercial Entities:
1.
Daiichi Sankyo Pharmaceuticals Inc. A74915 (Giachelli, PI) 05/01/2012 � 04/30/2014 0.1 calendar �Candidate vascular calcification genes in human smooth muscle tissue� $227,273 Role: Co-investigator
Research Support, Government Entities:
1.
NIH funding: NIH/NIDDK 1 R01DK094891-01 (Kestenbaum, PI) 09/01/2012 � 08/31/2015 3.6 calendar �Mineral Metabolism disturbances and arteriovenous fistula maturation� $217,500 Role: Principal investigator This 3-year project will evaluate whether mineral metabolism plays a role in arteriovenous fistula maturation.NIH/NHLBI 1 R01 HL096875 (Kestenbaum, de Boer, Co- PIs) 04/01/2010 � 06/30/2014 2.4 calendar �Phosphorous, vitamin D, and cardiovascular outcomes� $416,729 Role: Co- Role: Principal Investigator This 4-year project evaluates a comprehensive panel of serum and urine markers of mineral metabolism in association with clinical and subclinical cardiovascular disease in the Multi-Ethnic Study of Atherosclerosis.NIH/NIDDK 1 R21-DK081315-01A2 (Kestenbaum, PI) 07/01/2011 � 08/31/2014 1.2 calendar �Serum calcification activity in patients with chronic kidney disease� $125,000 Role: Principal investigator This 2-year project will develop a novel serum calcification assay for patients with chronic kidney disease. NIH/NIDDK 1 R01DK087726 (de Boer, PI) 07/01/2010 � 07/31/2014 1.2 calendar�Insulin Resistance in chronic kidney disease� $294,202 Role: Key PersonnelThis 4-year project will comprehensively characterize insulin sensitivity, beta-cell function, and glucose tolerance using gold-standard methods among individuals who have moderate-severe chronic kidney disease.NIH/NHLBI R01 DK102134 (Young, PI) 09/01/2013 � 08/31/2016 0.6 calendar �CKD targeted analyses of the Jackson Heart Study� Role: Co-investigator This 3-year project will determine novel and traditional risk factors for kidney disease progression and cardiovascular complications of kidney disease among African Americans in the Jackson Heart Study. NIH/NIDDK 1 R01DK094434 (Rosenfeld, PI) 08/01/2012 � 06/30/2017 0.6 calendar RANK-RANKL and vascular complications in chronic kidney disease $205,285 Role: Co-investigator This 5-year project combines laboratory and translational methods to determine the role of receptor activator of NFkB ligand (RANKL) in accelerated atherosclerosis of moderate-severe chronic kidney disease.
Research Support, Academic Entities:
1.
NONE
Research Support, Foundations and Societies:
1.
NONE
Stock/stock Options/board of Directors Compensation:
1.
NONE
License Fee Payments, Technology or Inventions:
1.
NONE
Royalty Payments, Technology or Inventions:
1.
NONE
Stock/stock Options, Research Sponsor:
1.
NONE
Stock/stock Options, Medical Equipment & Materials:
1.
NONE
Legal Proceedings:
1.
NONE
Lewis H. Kuller, MD, DrPH
From the University of Exeter Medical School (T.J.L., W.E.H., I.A.L., K.K., M.S., D.J.L.), Exeter, UK; Department of Internal Medicine and Geriatrics (C.A., O.B.), Angers University Hospital, Angers, France; Herbert Wertheim College of Medicine (P.H.M.C.), Florida International University, Miami; Mailman School of Public Health (L.F.), Columbia University, New York; Kidney Research Institute, Division of Nephrology (B.R.K.), University of Washington, Seattle; Departments of Epidemiology (L.H.K.) and Neurology and Psychiatry (O.L.L.), University of Pittsburgh, PA; Division of General Medicine (K.M.L.), Veterans Affairs Ann Arbor Center for Clinical Management Research, Ann Arbor, MI; and the Institute for Social Research and the Institute for Healthcare Policy and Innovation (K.M.L.), University of Michigan, Ann Arbor.
Disclosure
Scientific Advisory Boards:
1.
NONE
Gifts:
1.
NONE
Funding for Travel or Speaker Honoraria:
1.
NONE
Editorial Boards:
1.
NONE
Patents:
1.
NONE
Publishing Royalties:
1.
NONE
Employment, Commercial Entity:
1.
NONE
Consultancies:
1.
NONE
Speakers' Bureaus:
1.
NONE
Other Activities:
1.
NONE
Clinical Procedures or Imaging Studies:
1.
NONE
Research Support, Commercial Entities:
1.
NONE
Research Support, Government Entities:
1.
NONE
Research Support, Academic Entities:
1.
NONE
Research Support, Foundations and Societies:
1.
NONE
Stock/stock Options/board of Directors Compensation:
1.
NONE
License Fee Payments, Technology or Inventions:
1.
NONE
Royalty Payments, Technology or Inventions:
1.
NONE
Stock/stock Options, Research Sponsor:
1.
NONE
Stock/stock Options, Medical Equipment & Materials:
1.
NONE
Legal Proceedings:
1.
NONE
Kenneth M. Langa, MD, PhD
From the University of Exeter Medical School (T.J.L., W.E.H., I.A.L., K.K., M.S., D.J.L.), Exeter, UK; Department of Internal Medicine and Geriatrics (C.A., O.B.), Angers University Hospital, Angers, France; Herbert Wertheim College of Medicine (P.H.M.C.), Florida International University, Miami; Mailman School of Public Health (L.F.), Columbia University, New York; Kidney Research Institute, Division of Nephrology (B.R.K.), University of Washington, Seattle; Departments of Epidemiology (L.H.K.) and Neurology and Psychiatry (O.L.L.), University of Pittsburgh, PA; Division of General Medicine (K.M.L.), Veterans Affairs Ann Arbor Center for Clinical Management Research, Ann Arbor, MI; and the Institute for Social Research and the Institute for Healthcare Policy and Innovation (K.M.L.), University of Michigan, Ann Arbor.
Disclosure
Scientific Advisory Boards:
1.
NONE
Gifts:
1.
NONE
Funding for Travel or Speaker Honoraria:
1.
NONE
Editorial Boards:
1.
NONE
Patents:
1.
NONE
Publishing Royalties:
1.
NONE
Employment, Commercial Entity:
1.
NONE
Consultancies:
1.
NONE
Speakers' Bureaus:
1.
NONE
Other Activities:
1.
NONE
Clinical Procedures or Imaging Studies:
1.
NONE
Research Support, Commercial Entities:
1.
NONE
Research Support, Government Entities:
1.
NIH, AG009740, Co-Investigator
Research Support, Academic Entities:
1.
NONE
Research Support, Foundations and Societies:
1.
NONE
Stock/stock Options/board of Directors Compensation:
1.
NONE
License Fee Payments, Technology or Inventions:
1.
NONE
Royalty Payments, Technology or Inventions:
1.
NONE
Stock/stock Options, Research Sponsor:
1.
NONE
Stock/stock Options, Medical Equipment & Materials:
1.
NONE
Legal Proceedings:
1.
NONE
Oscar L. Lopez, MD
From the University of Exeter Medical School (T.J.L., W.E.H., I.A.L., K.K., M.S., D.J.L.), Exeter, UK; Department of Internal Medicine and Geriatrics (C.A., O.B.), Angers University Hospital, Angers, France; Herbert Wertheim College of Medicine (P.H.M.C.), Florida International University, Miami; Mailman School of Public Health (L.F.), Columbia University, New York; Kidney Research Institute, Division of Nephrology (B.R.K.), University of Washington, Seattle; Departments of Epidemiology (L.H.K.) and Neurology and Psychiatry (O.L.L.), University of Pittsburgh, PA; Division of General Medicine (K.M.L.), Veterans Affairs Ann Arbor Center for Clinical Management Research, Ann Arbor, MI; and the Institute for Social Research and the Institute for Healthcare Policy and Innovation (K.M.L.), University of Michigan, Ann Arbor.
Disclosure
Scientific Advisory Boards:
1.
NONE
Gifts:
1.
NONE
Funding for Travel or Speaker Honoraria:
1.
NONE
Editorial Boards:
1.
NONE
Patents:
1.
NONE
Publishing Royalties:
1.
NONE
Employment, Commercial Entity:
1.
NONE
Consultancies:
1.
Lundbeck,Lilly,Baxter, Grifols,Cognoptix
Speakers' Bureaus:
1.
NONE
Other Activities:
1.
NONE
Clinical Procedures or Imaging Studies:
1.
NONE
Research Support, Commercial Entities:
1.
NONE
Research Support, Government Entities:
1.
NIA: P50 AG05133-27
Research Support, Academic Entities:
1.
NONE
Research Support, Foundations and Societies:
1.
NONE
Stock/stock Options/board of Directors Compensation:
1.
NONE
License Fee Payments, Technology or Inventions:
1.
NONE
Royalty Payments, Technology or Inventions:
1.
NONE
Stock/stock Options, Research Sponsor:
1.
NONE
Stock/stock Options, Medical Equipment & Materials:
1.
NONE
Legal Proceedings:
1.
NONE
Katarina Kos, MD, PhD
From the University of Exeter Medical School (T.J.L., W.E.H., I.A.L., K.K., M.S., D.J.L.), Exeter, UK; Department of Internal Medicine and Geriatrics (C.A., O.B.), Angers University Hospital, Angers, France; Herbert Wertheim College of Medicine (P.H.M.C.), Florida International University, Miami; Mailman School of Public Health (L.F.), Columbia University, New York; Kidney Research Institute, Division of Nephrology (B.R.K.), University of Washington, Seattle; Departments of Epidemiology (L.H.K.) and Neurology and Psychiatry (O.L.L.), University of Pittsburgh, PA; Division of General Medicine (K.M.L.), Veterans Affairs Ann Arbor Center for Clinical Management Research, Ann Arbor, MI; and the Institute for Social Research and the Institute for Healthcare Policy and Innovation (K.M.L.), University of Michigan, Ann Arbor.
Disclosure
Scientific Advisory Boards:
1.
NONE
Gifts:
1.
NONE
Funding for Travel or Speaker Honoraria:
1.
NONE
Editorial Boards:
1.
NONE
Patents:
1.
NONE
Publishing Royalties:
1.
NONE
Employment, Commercial Entity:
1.
NONE
Consultancies:
1.
NONE
Speakers' Bureaus:
1.
NONE
Other Activities:
1.
NONE
Clinical Procedures or Imaging Studies:
1.
NONE
Research Support, Commercial Entities:
1.
NONE
Research Support, Government Entities:
1.
NONE
Research Support, Academic Entities:
1.
NONE
Research Support, Foundations and Societies:
1.
NONE
Stock/stock Options/board of Directors Compensation:
1.
NONE
License Fee Payments, Technology or Inventions:
1.
NONE
Royalty Payments, Technology or Inventions:
1.
NONE
Stock/stock Options, Research Sponsor:
1.
NONE
Stock/stock Options, Medical Equipment & Materials:
1.
NONE
Legal Proceedings:
1.
NONE
Maya Soni, PhD*
From the University of Exeter Medical School (T.J.L., W.E.H., I.A.L., K.K., M.S., D.J.L.), Exeter, UK; Department of Internal Medicine and Geriatrics (C.A., O.B.), Angers University Hospital, Angers, France; Herbert Wertheim College of Medicine (P.H.M.C.), Florida International University, Miami; Mailman School of Public Health (L.F.), Columbia University, New York; Kidney Research Institute, Division of Nephrology (B.R.K.), University of Washington, Seattle; Departments of Epidemiology (L.H.K.) and Neurology and Psychiatry (O.L.L.), University of Pittsburgh, PA; Division of General Medicine (K.M.L.), Veterans Affairs Ann Arbor Center for Clinical Management Research, Ann Arbor, MI; and the Institute for Social Research and the Institute for Healthcare Policy and Innovation (K.M.L.), University of Michigan, Ann Arbor.
Disclosure
Scientific Advisory Boards:
1.
NONE
Gifts:
1.
NONE
Funding for Travel or Speaker Honoraria:
1.
NONE
Editorial Boards:
1.
NONE
Patents:
1.
NONE
Publishing Royalties:
1.
NONE
Employment, Commercial Entity:
1.
NONE
Consultancies:
1.
NONE
Speakers' Bureaus:
1.
NONE
Other Activities:
1.
NONE
Clinical Procedures or Imaging Studies:
1.
NONE
Research Support, Commercial Entities:
1.
NONE
Research Support, Government Entities:
1.
NONE
Research Support, Academic Entities:
1.
NONE
Research Support, Foundations and Societies:
1.
NONE
Stock/stock Options/board of Directors Compensation:
1.
NONE
License Fee Payments, Technology or Inventions:
1.
NONE
Royalty Payments, Technology or Inventions:
1.
NONE
Stock/stock Options, Research Sponsor:
1.
NONE
Stock/stock Options, Medical Equipment & Materials:
1.
NONE
Legal Proceedings:
1.
NONE
David J. Llewellyn, PhD*
From the University of Exeter Medical School (T.J.L., W.E.H., I.A.L., K.K., M.S., D.J.L.), Exeter, UK; Department of Internal Medicine and Geriatrics (C.A., O.B.), Angers University Hospital, Angers, France; Herbert Wertheim College of Medicine (P.H.M.C.), Florida International University, Miami; Mailman School of Public Health (L.F.), Columbia University, New York; Kidney Research Institute, Division of Nephrology (B.R.K.), University of Washington, Seattle; Departments of Epidemiology (L.H.K.) and Neurology and Psychiatry (O.L.L.), University of Pittsburgh, PA; Division of General Medicine (K.M.L.), Veterans Affairs Ann Arbor Center for Clinical Management Research, Ann Arbor, MI; and the Institute for Social Research and the Institute for Healthcare Policy and Innovation (K.M.L.), University of Michigan, Ann Arbor.
Disclosure
Scientific Advisory Boards:
1.
NONE
Gifts:
1.
NONE
Funding for Travel or Speaker Honoraria:
1.
(1) Roche, conference travel, (2) DSM, workshop travel and speaker honorarium.
Editorial Boards:
1.
NONE
Patents:
1.
NONE
Publishing Royalties:
1.
NONE
Employment, Commercial Entity:
1.
NONE
Consultancies:
1.
NONE
Speakers' Bureaus:
1.
NONE
Other Activities:
1.
NONE
Clinical Procedures or Imaging Studies:
1.
NONE
Research Support, Commercial Entities:
1.
NONE
Research Support, Government Entities:
1.
NONE
Research Support, Academic Entities:
1.
NONE
Research Support, Foundations and Societies:
1.
(1) Alzheimer's Association (NIRG-11-200737), (2) Norman Family Charitable Trust, (3) Age Related Diseases and Health Trust, (4) Sir Halley Stewart Trust, Lord Clinton's Charitable Trust, (5) RD&E Foundation Trust, (6) UK National Institute for Health Research (NIHR) Collaboration for Leadership in Applied Health Research and Care for the South West Peninsula (PenCLAHRC)
Stock/stock Options/board of Directors Compensation:
1.
NONE
License Fee Payments, Technology or Inventions:
1.
NONE
Royalty Payments, Technology or Inventions:
1.
NONE
Stock/stock Options, Research Sponsor:
1.
NONE
Stock/stock Options, Medical Equipment & Materials:
1.
NONE
Legal Proceedings:
1.
NONE

Notes

Correspondence to Dr. Llewellyn: [email protected]
Go to Neurology.org for full disclosures. Funding information and disclosures deemed relevant by the authors, if any, are provided at the end of the article. The Article Processing Charge was paid by The National Institute for Health Research (NIHR) Collaboration for Leadership in Applied Health Research and Care (CLAHRC) South West Peninsula.
*
These authors contributed equally to the manuscript.

Author Contributions

Mr. Littlejohns: drafting and revising the manuscript for content, study concept and design, analysis and interpretation of data, and statistical analysis. Dr. Henley: revising the manuscript for content, study concept and design, analysis and interpretation of data, and statistical analysis. Dr. Lang: revising the manuscript for content, interpretation of data. Dr. Annweiler: revising the manuscript for content, interpretation of data. Dr. Beauchet: revising the manuscript for content, interpretation of data. Dr. Chaves: revising the manuscript for content, interpretation of data, obtaining funding. Dr. Fried: revising the manuscript for content, interpretation of data, acquisition of data. Dr. Kestenbaum: revising the manuscript for content, interpretation of data, acquisition of data, obtaining funding. Dr. Kuller: revising the manuscript for content, interpretation of data, acquisition of data. Dr. Langa: revising the manuscript for content, interpretation of data, acquisition of data, obtaining funding. Dr. Lopez: revising the manuscript for content, interpretation of data, acquisition of data. Dr. Kos: revising the manuscript for content, study concept and design, analysis and interpretation of data. Dr. Soni: revising the manuscript for content, study concept and design, analysis and interpretation of data, statistical analysis. Dr. Llewellyn: drafting and revising the manuscript for content, study concept and design, analysis and interpretation of data, acquisition of data, statistical analysis, study supervision and coordination, obtaining funding.

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