Alcohol Consumption as a Risk Factor for Dementia and Cognitive Decline: Meta-Analysis of Prospective Studies

CRITICAL REVIEW ARTICLE

Alcohol Consumption as a Risk Factor for Dementia and Cognitive Decline: Meta-Analysis of Prospective Studies Kaarin J. Anstey, Ph.D., Holly A. Mack, Ph.D., Nicolas Cherbuin, Ph.D.

The relationships between alcohol consumption and dementia and cognitive decline were investigated in a systematic review including meta-analyses of 15 prospective studies. Follow-ups ranged from 2 to 8 years. Meta-analyses were conducted on samples including 14,646 participants evaluated for Alzheimer disease (AD), 10,225 participants evaluated for vascular dementia (VaD), and 11,875 followed for any type of dementia (Any dementia). The pooled relative risks (RRs) of AD, VaD, and Any dementia for light to moderate drinkers compared with nondrinkers were 0.72 (95% CI ⫽ 0.61– 0.86), 0.75 (95% CI ⫽ 0.57– 0.98), and 0.74 (95% CI ⫽ 0.61– 0.91), respectively. When the more generally classified “drinkers,” were compared with “nondrinkers,” they had a reduced risk of AD (RR ⫽ 0.66, 95% CI ⫽ 0.47– 0.94) and Any dementia (RR ⫽ 0.53, 95% CI ⫽ 0.53– 0.82) but not cognitive decline. There were not enough data to examine VaD risk among “drinkers.” Those classified as heavy drinkers did not have an increased risk of Any dementia compared with nondrinkers, but this may reflect sampling bias. Our results suggest that alcohol drinkers in late life have reduced risk of dementia. It is unclear whether this reflects selection effects in cohort studies commencing in late life, a protective effect of alcohol consumption throughout adulthood, or a specific benefit of alcohol in late life. (Am J Geriatr Psychiatry 2009; 17:542–555) Key Words: Alzheimer disease, vascular dementia, mild cognitive impairment, epidemiology, systematic review, alcohol drinking

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s alcohol drinking is a modifiable behavior, there is a public health imperative to ensure that the best information is available concerning its safe use. This is often made difficult by conflicting or complex messages about the protec-

tive or adverse effects of alcohol. Unlike smoking, which has no beneficial effects on health, low to moderate alcohol consumption seems to be beneficial for some health outcomes, resulting in “J”shaped or inverse U-shaped associations between

Received September 2, 2008; revised January 7, 2009; accepted January 30, 2009. From the Centre for Mental Health Research, Australian National University, Canberra (KJA, NC); and Prince of Wales Medical Research Institute, University of New South Wales, Randwick, NSW (HAM), Australia. Send correspondence to Professor Kaarin J. Anstey, Ageing Research Unit, Centre for Mental Health Research, Australian National University, Canberra ACT 0200, Australia. © 2009 American Association for Geriatric Psychiatry

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Anstey et al. alcohol and mortality,1 cognitive function and heart disease.2,3 There is also evidence of cognitive benefits of alcohol consumption from animal studies. For example, in a study where rats were fed a diet containing no, moderate, or high doses of alcohol, the animals on the moderate dose performed better on a visual memory task than the two other groups and showed no sign of impaired hippocampal neurogenesis or neurotoxicity found in the high alcohol group.4 Other animal studies have also shown memory facilitation effects of alcohol consumption.5–7 In addition, Wang et al.8 demonstrated in a mice model that low wine consumption attenuated A␤ neuropathology typically associated with Alzheimer disease (AD). On the other hand, excessive alcohol use has been associated with brain damage in animals and humans.9 There are now many studies published that report associations between alcohol consumption and dementia and cognitive decline, with findings mostly showing either that alcohol drinkers have reduced risk or no difference in risk of dementia compared with nondrinkers.10 –12 However, there is a need to synthesize the available information and consider study characteristics and publication bias to interpret the overall findings from available literature. The present study aimed to synthesize available highquality information from prospective cohort studies to evaluate whether light, moderate or hazardous levels of alcohol consumption may increase or reduce risk of AD, vascular dementia (VaD), Any dementia, or cognitive decline in late life. A systematic review methodology developed in previous reviews of risk factors for dementia and cognitive decline was used to obtain estimates of the effect of alcohol on risk of dementia and cognitive decline.13,14 Importantly, this review excluded studies that did not screen for dementia or cognitive impairment at baseline.

METHODS Literature Search A literature search was conducted using the relevant databases PubMed (1950 to June 2007), PsycINFO (1872 to June 2007), and the Cochrane Library

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(1800 to June 2007), with searches being limited to studies in English and focused on humans. The reference lists of the retrieved articles were also hand searched for other applicable publications. The following combination of selected alcohol and cognition terms were used for the search, where * indicates a word truncation and # means wild card. The alcohol terms included ethanol, alcohol, alcohol*, drink*, drunk, drunk* (drunkenness), blood alcohol concentration/content, blood alcohol level, substance use/misuse/abuse/addiction, substance dependence/dependent, substance user(s), substance disorder(s), substance-related disorder(s), substance usage, substance abuser(s), substance addict(s), intoxicated, intoxication, abstinence, abstinent, abstainer(s), sober, sobriety, liquor, spirits, beer, ale, wine, brandy, gin, rum, tequila, vodka, whiskey/whisky, and champagne. The dementia and cognition terms included cognit*, cognitive, cognition, intell*, IQ, memory, Mini-Mental State Examination, Mini Mental Status Examination, dement* (dementia(s), demented, nondemented), VaD, Alzheimer*, senil*, presenil*, presenil*, mild cognitive impairment, mild cognitive impairment (MCI), neurocognit*, neurocognition, neurocognitive, neuropsychological assessment(s)/test(s)/testing/evaluation(s)/ exam(s)/examination(s)/measure(s)/ measurement(s), general mental ability, attention, executive function*, executive process*, executive process, executive control, psychomotor, perceptual speed, perceptual motor, reaction time, processing speed, speed of processing, crystallized intelligence#, crystallized ability#, fluid intelligence, and fluid ability. Inclusion and Exclusion Criteria Studies were required to have a minimum follow-up period of 1 year, and outcome measures had to include either dementia or cognitive decline. Studies on dementia needed to have screened for dementia at baseline or adjusted for cognitive function in the analyses. Studies evaluating cognitive change were required to have measured cognition at both baseline and follow-up periods and either implemented a dementia assessment at baseline, which excluded those participants with cognitive impairment or dementia, or adjusted for incident dementia and/or baseline cognition performance in analyses. To be included, all studies were also required to

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Alcohol, Dementia, and Cognitive Decline measure exposure to alcohol at baseline or during a follow-up period that preceded the final follow-up examination.15 Experimental and clinical studies (alcoholics compared with controls) were excluded. The selection criteria guidelines were parallel with the Cochrane Collaboration recommended search strategy.16,17 Retrieved articles were examined by at least two of the authors and rated against the selection criteria. Multiple Publications From a Single Study There were 14 cohort studies meeting criteria for which multiple publications were identified. To select individual publications for inclusion, precedence was given to studies (e.g., Zutphen Elderly Study), where alcohol was an independent predictor18 and not adjusted for in the analyses.19,20 Studies with a longer follow-up such as the Personnes Agées Quid21,22 or the Kame Project22 were included over those with a shorter observation period.23–26 If the publications from the same study (e.g., Duke Established Populations for Epidemiologic Studies of the Elderly) did not differ on follow-up period, cohort size or measures, then the more recent article22,27 was chosen over the earlier article.26,28 For the Kungsholmen Project, the article with the more detailed categorical measure for alcohol29 was chosen over the same alcohol measure that was dichotomized into yes/no groupings for alcohol consumption.30 No relevant multiple publications from a single study were identified that examined different alcohol measures or outcomes for dementia or cognition, or analyzed these assessments in different forms (categorical versus continuous). There were 22 studies meeting inclusion criteria that did not provide unique data.19,20,23–26,28,30 – 44 Outcomes Outcomes from the studies reviewed included AD, VaD, Any dementia, cognitive performance, MCI, or cognitive impairment as described previously.14 Several studies reported results by dementia subtype in addition to a general dementia outcome. Nine studies reported effects of alcohol for Alzheimer-type dementia10,11,29,45–50 and five reported on incidence of VaD.10,11,46,47,49 Eighteen studies assessed cognitive performance change, cognitive decline, MCI, or cognitive impairment.15,18,22,28,43,50 – 62

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Data Extraction From each of the selected journal articles, the following information was initially collated: study design (sample source, number of participants, observation period), sample characteristics (percentage female, average age, years of education), measurement of alcohol (amount and type of alcohol consumed, history of past consumption, frequency of consumption), measurement of dementia or cognition, unadjusted and adjusted estimates of association (odds ratio [OR], hazard ratio [HR], relative risk [RR], beta, and p values) with 95% confidence intervals and covariates. Data extraction was double checked by a second reviewer who was blinded to the title, authors, publication date, and journal name of the article. Data Compilation for Analysis Authors were contacted via E-mail for missing information. The longest follow-up period was chosen if an article reported data on multiple observations. For all studies, the number of participants analyzed for the association between alcohol and outcome was used as the sample size for this review. Preference was given to results adjusted for the most covariates. Type of Comparisons Articles meeting inclusion criteria reported various alcohol consumption categories ranging from broad measures of never versus ever consuming alcohol to “yes” versus “no” for past and/or current alcohol consumption.45,49 Most articles compared nondrinkers with various groups currently consuming alcohol (very light, light, mild, moderate, normal limits, exceeds normal limits, heavy, and excessive drinkers) or zero drinks versus number of drinks per week or per day. Frequency of consumption was converted to drinks or units per week. The classifications of light and moderate consumption described by authors were used without alteration. When possible, studies with similar comparison drinking frequency categories (light and mild drinkers) were combined. If grams of ethanol per unit/drink were reported conversions were performed to verify the accuracy of combining comparison groups.

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Anstey et al. Meta-analysis was conducted where there was more than one study compatible in terms of alcohol and outcome measures with groups formed by type of comparison, and further divided by type of outcome. There were enough data to conduct comparisons of light to moderate drinkers compared with nondrinkers, and heavy drinkers compared with nondrinkers for AD, VaD, and Any dementia outcomes. Analyses were also performed for the broad comparison of drinkers versus nondrinkers for AD, Any dementia, and cognitive decline. There were no compatible data to allow meta-analyses of the outcomes of cognitive impairment or cognitive performance change.

FIGURE 1.

Flowchart Describing the Process of Study Selection

Statistical Analysis For the current analyses, studies reporting OR, RR, or HR for dichotomous outcomes were considered the same effect size measure under the assumption that dementia is a rare event after previous similar studies.63,64 Meta-analyses were performed in RevMan (version 4.2). The fixed effects model with the generic inverse variance data type selection (option for log scale of OR, HR, and RR) was used in the calculation of pooled estimates unless heterogeneity was determined by ␹2 tests with a p value ⬍0.10; then the random effects method was used with the generic inverse variance data type selection.65

RESULTS Of the 38,611 abstracts identified in the database search, data were available for 25 reports from prospective cohort studies. Of these 15 reports included data suitable for inclusion in meta-analyses.10,11,21,29,46 – 49,52,53,62,66 – 68 Figure 1 shows the stages in identifying studies for inclusion in our review. The characteristics of the 15 studies included in the meta-analyses are shown in Table 1. Of the 15 studies, 14 screened for dementia at baseline, and one included cognition in analyses.52 A further 10 studies met selection criteria, but their data were not compatible with other studies and so they could not be included in meta-analyses. For meta-analysis, a total of 14,646 participants were included in the six studies on alcohol consump-

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tion and AD. Length of follow-up ranged from 2 to 7 years. A total of 10,225 participants were included in the five studies on alcohol and VaD. Length of follow-up ranged from 2 to 7 years. A total of 11,875 participants were included in the five studies on alcohol consumption and Any dementia with followups ranging from 2 to 8 years. Light to Moderate Drinkers Versus Nondrinkers Of the 15 studies suitable for meta-analysis, eight studies reported data on light to moderate drinkers.

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EVA; Nantes, Western France

WHIMS, Postmenopausal women aged 50–79 years

MoVIES, Largely rural, blue-collar community in Southwestern PA

Kungsholmen Project, Stockholm, Sweden, Community-based cohort 75⫹ years old PAQUID; Southwestern departments of Gironde and Dordogne, France; community residents aged 65 or older (seven strata or parishes)

Dufouil et al.52 (N ⫽ 1,094)

Espeland et al.62 (N ⫽ 4,372)

Ganguli et al.53 (N ⫽ 1,098)

Huang et al.29 (N ⫽ 378)

Larrieu et al.21 (N ⫽ 2,865)

Chongqing city, China; elderly people in six communities 60⫹ years old

Deng et al. (N ⫽ 2,632)

10

Study Name and Source

Fixed: 8

Varied: 3.7 (2.2)

Varied: 7.3 (2.7), Range 1.7–11.8

Varied: 4.2 (1.2)

Varied: 4 (NA)

Fixed: 2

Observation Period, Years (SDa)

Wine consumption, grouped by nondrinkers, mild drinkers, moderate drinkers; 1 glass ⫽ 125 mL

No drinking; minimal drinking (once a month or less); moderate drinking (more than once a month, averaging between daily and weekly) Categories by ethanol units: nondrinker light to moderate drinker and excessive drinkerd

Nondrinker (⬍1 unit per week), light-to-moderate drinker (1–21 units per week for men, or 1–14 units per week for women), excessive drinker (⬎21 units per week for men, or 0.14 units per week for women) Daily alcohol consumption was categorized as never, ⬍2 drinks, 2–5 drinks, or 5⫹ drinks Alcohol intake over past 3 months; if no current intake, but consumed in past asked if stopped due to health reasons

Alcohol Measure(s)

Characteristics of Studies Included in the Meta-Analyses

Study (No. Subjects)

TABLE 1.

Incident dementia

Incident dementia or AD (N ⫽ 85)

Cognitive decline

Probable dementia; mild cognitive impairment; cognitive decline

Cognitive decline

Incident dementia: All (N ⫽ 121); AD (N ⫽ 84); VaD (N ⫽ 17); other (N ⫽ 20)

Outcome

DSM-III-R, MMSE, subpopulation were those subjects with baseline MMSE score ⱖ24 (N ⫽ 293) DSM-III-R, NINCDSADRDA, Hachinski score

DSM-III-R, CDR, CERAD, MMSE,c Composite Cognitive Scores

3MSE, neurocognitive assessment, neuropsychiatric examination

MMSEb

MMSE DSM-III-R

Outcome Measure(s)

(Continued)

Range 65 to 85⫹, ⬃58%,e at least primary school level, validated by a diploma versus no diploma

84.2(5.3); Range 75–90⫹; 21.9% ⱖ90⫹, 81.8%, ⬇6.7 (3.1); 57% ⱕ8 years

70.9 (3.8), 100%, ⬍high school ⫽ 6.44%; high school/GED ⫽ 20.91%; ⬎high school ⬍4 year college ⫽ 39.26%; ⬎4 yearr college ⫽ 33.39% 74.6 (5.34); Range 66.8– 97.1, 63.3%, 61.8% HS graduate or higher education

65 (2.95) Range 59–71, 58.9%, 10.74 (3.46)

67.42 (7.42), 56.38%, 11.38 (0.09)

Demographics: Age (M, SD), Female, Education in Years (M, SD)

Alcohol, Dementia, and Cognitive Decline

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CHS: 4 US communities (Forsyth County, NC, Sacramento County, CA, Washington County, MD and Allegheny County, PA); 65⫹ residents from selected from medicare eligibility ISHA and Ibadan, Nigeria; Crosscultural Study: Indianapolis community-dwelling African Americans and Yoruba people, Ibadan, Nigeria

Mukamal et al.46 (cases, N ⫽ 151; controls, N ⫽ 123)

Ogunniyi et al.66 (ISHA: cases N ⫽ 89; controls ⫽ 381) (Yoruba: case N ⫽ 62; control ⫽ 461)

WHICAP; community dwelling 65⫹

CSHA, Canada; 65⫹ community residents

Luchsinger et al.11 (N ⫽ 970)

Lindsay et al. (N ⫽ 3,985)

45

Study Name and Source

Continued

Study (No. Subjects)

TABLE 1.

2 and 5-year follow-up 2

Varied: median 6.0 for controls, median 6.1 for cases

Varied: 4 .1 (1.5), recruited between 1991 and 1996 and followed annually

Varied: 5 (NA)

Observation Period, Years (SDa)

Regular alcohol consumption ⫽ ⬎10 drinks per week

Alcohol type categorized by nondrinkers (0 servings reported), light drinkers (1 serving a month to 6 servings a week), moderate drinkers (1–3 servings a day), and heavy drinkers (⬎3 servings a day) 1 unit ⫽ 12 g ethanol Weekly number of drinks; categories: none, ⬍1, 1–6, 7–13, 14⫹

Regular consumption of beer, wine, and spirits was defined as at least once a week

Alcohol Measure(s)

Incident dementia

Incident dementia

Incident dementia (N ⫽ 260), AD (N ⫽ 199), DAS (N ⫽61)

Incident dementia (N ⫽ 194 AD cases)

Outcome

CSI’D, DSM-III-R, NINCDS-ADRDA

Screening: 3MSE, IQCODE, clinical diagnoses: DSM-IV, NINCDS-ADRDA, NINDS-AIREN, SCADDTC, neurologic Examination, MMSE

DSM-IV, CDR

3MS, NINCDS-ADRDA

Outcome Measure(s)

ISHA Cases: 82.9 (7.1); Controls: 78.3 (7.0); Yoruba Cases: 82.2 (10.0); Controls: 77.3 (7.5); ISHA Cases: 69.7%; Controls: 68.8%; Yoruba Cases: 83.9%; Controls: 66.8%; ISHA Cases: 8.7 (3.3); Controls: 9.4 (3.2); Yoruba Cases: 0.1 (0.8); Controls: 0.6 (1.7) (Continued)

Case: 77.8 (5.5); control: 77.5 (5.2); Total sample: 77.65 (5.35), 58.45%, 14.6 (4.6)

73.3 ⫾ 6.0; AD ⫽ 81.0; No A/D ⫽ 72.9, 55.11%; AD ⫽ 67.5%; No AD ⫽ 57.5%, 11.0 ⫾ 3.7; AD ⫽ 9.9; No AD ⫽ 11.1 75.3 ⫾ 5.8, 67%, 9.1 (4.6)

Demographics: Age (M, SD), Female, Education in Years (M, SD)

Anstey et al.

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Dubbo Study, NSW Australia; 60⫹ community dwelling MRC-CFAS; populationbased Rural2 and urban3 sites in UK

Simons et al.67 (N ⫽ 2,805) Varied: 16 years, followed every 2 years 2 and 6-year follow-up, Using 6 year follow-up data only from wave 3 Fixed: 7

Varied: 2.4 (0.3)

Varied: 6 (NA)

Observation Period, Years (SDa)

Alcohol consumption (yes/no)

Alcohol intake: ever, never, unknown

Alcohol intake grouped by # drinks/week: None, ⬍1 drink/week, 1 drink/ week—1 drink/day, 1–4 drinks/day, 4⫹ drinks/ day. Also characterized by type of alcohol: beer, wine, liquor, or fortified wine Average weekly intake, estimate lifetime alcohol consumption measured in drinks. Also type of drinker: nondrinker, past heavy drinker, problem drinker Standard drinks per week: any vs. nil

Alcohol Measure(s)

Incident dementia (N ⫽ 103), VaD: N ⫽ 50; AD: N ⫽ 42; Mixed: N ⫽ 2; Other: N⫽9

Incident MCI and dementia (N ⫽ 285) Incident dementia: wave 2: N ⫽ 133; wave 3: N ⫽ 142

Incidence dementia (All N ⫽ 44; AD N ⫽ 33)

Incident dementia (N ⫽ 197) AD: 146/197; VaD: 29/ 197; other dementia: 22/197

Outcome

MMSE, HDS, HDS-R, DSM-III-R, NINCDSADRDA, NINDSAIREN

Geriatric Mental State (AGECAT), MMSE

SPMSQ, ICD-9-CM, ICD10-AM

MMSE, Korean Dementia Rating Scale, DSM-IV

MMSE, DSM-III-R, NINCDS-ADRDA, NINDS-AIREN, GMS organic level, CAMDEX

Outcome Measure(s)

73.6 (5.9); Men Range 65– 92; Women Range 65–98, 60%, 25.95% low educational level (completion of only 6 years of elementary school)

Range 65–90⫹, 63.12%, 8.58% ⬍9 years

69.2 (7.0), 56.04%, 10.1 (1.8)

71.7 (4.9), 56.1%, Median interquartile range 3 years (0–6)

67.38 (7.48), 59%, 35% (N ⫽ 1854) primary education only; dichotomised into primary education or less, and more than primary education.

Demographics: Age (M, SD), Female, Education in Years (M, SD)

b

SD ⫽ Standard deviation. MMSE used as an outcome measure for analysis but was part of a larger neuropsychological assessment. c Composite Cognitive Scores created from: Trailmaking Tests A and B, Word List Learning and Delayed Recall, Story Immediate Retell and Delayed Recall, Initial Letter and Category Fluency, 15-item Consortium to Establish a Registry for Alzheimer’s Disease (CERAD) version of the Boston Naming Test, CERAD Constructional Praxis, Clock Drawing. d Categories by ethanol units: nondrinker (⬍1 unit per week); light to moderate drinker (1–21 units per week for men, or 1–14 units per week for women); excessive drinker (⬎21 units per week for men, or ⬎14 units per week for women). In the present study, 18 occasional drinkers (⬍1 unit per week) were included in the nondrinker category. e Values are for the cohort analyzed in a separate PAQUID study article by Helmer.24 f Reported N analyzed for Wave 3 data collection.

a

Yoshitaker et al.49 (N ⫽ 826)

Hisayama Study, Japan; Hisayama residents 65⫹ in 1985

10/66 Dementia in developing Countries Research Program, Republic of Korea; community residents

Shin et al.48 (N ⫽ 510)

Yip et al.68 (N ⫽ 1,489f)

Rotterdam Study, Netherlands; Population cohort based

Ruitenberg et al.47 (N⫽ 5,395)

Study Name and Source

Continued

Study (No. Subjects)

TABLE 1.

Alcohol, Dementia, and Cognitive Decline

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Anstey et al. Four of these had different criteria to classify men and women10,29,48,68 and four studies used the same criteria to classify men and women.11,21,46,47 Combining men and women, three studies defined light to moderate drinking as 1–21 units of alcohol per week,10,29,68 1–27 drinks per week,11 2–28 drinks per week,21 and 1–14 drinks per week.48 Two studies did not specify a range for light to moderate, and reported results for different drinking frequencies. In both instances, results from three categories were combined to create a pooled estimate of light to moderate drinking46,47 that was comparable with the other studies. In one case, this included those reporting 1–13 drinks per week46 and in the other case this yielded a group reporting 1–21 drinks per week.47 All studies adjusted for age and sex in their analyses. The pooled RR of AD, VaD, and Any Dementia, for light to moderate drinkers compared with nondrinkers are shown in Table 2. Light to moderate

TABLE 2.

drinkers had significantly reduced risks of AD (RR ⫽ 0.72, z ⫽ 3.69, p ⫽ 0.0002), VaD (RR ⫽ 0.75, z ⫽ 2.13, p ⫽ 0.03), and Any Dementia (RR ⫽ 0.74, z ⫽ 2.89, p ⫽ 0.004). The test for heterogeneity was significant for AD (␹2[5] ⫽ 11.43, p ⫽ 0.04). To evaluate sex differences, results from the three studies reporting results separately for men and women were pooled.10,46,47 Compared with male nondrinkers, male light to moderate drinkers had reduced risks of AD (RR ⫽ 0.58, CI ⫽ 0.45– 0.75, z ⫽ 4.25, p ⬍0.001), VaD (RR ⫽ 0.49, CI ⫽ 0.31– 0.79, z ⫽ 2.98, p ⫽ 0.003), and Any dementia (RR ⫽ 0.55, CI ⫽ 0.42– 0.74, z ⫽ 3.99, p ⬍0.001). Compared with female nondrinkers, female light to moderate drinkers had reduced risks of AD (RR ⫽ 0.83, CI ⫽ 0.81– 0.85, z ⫽ 15.30, p ⬍0.001), VaD (RR ⫽ 0.57, CI ⫽ 0.34 – 0.95, z ⫽ 2.16, p ⫽ 0.030), and Any dementia (RR ⫽ 0.73, CI ⫽ 0.61– 0.88, z ⫽ 3.30, p ⬍0.001).

Relative Risks of Dementia for Light to Moderate Drinkers Versus Nondrinkers

Outcome Alzheimer disease

Vascular dementia

Any dementia

Study 29a

Huang et al. Luchsinger et al.11b Mukamal et al.46c Ruitenberg et al.47d Larrieu et al.21e Deng et al.10f Pooled Luchsinger et al.11b Ruitenberg et al.47g Deng et al.10f Mukamal et al.46c Pooled Yip et al.68h Espeland et al.62i Huang et al.29a Deng et al.10f Mukamal et al.46j Ruitenberg et al.47d Larrieu et al.21e Pooled

Weight (%)

Relative Risk

95% Confidence Interval

6.68 14.40 15.81 17.78 18.39 26.94 100 18.62 18.97 29.15 33.26 100 6.91 9.05 10.51 11.00 18.09 21.72 22.72 100

0.70 0.97 0.54 0.85 0.79 0.63 0.72 0.93 0.46 0.84 0.79 0.75 1.60 1.14 0.60 0.52 0.59 0.72 0.80 0.74

0.39, 1.26 0.69, 1.36 0.40, 0.73 0.65, 1.12 0.61, 1.03 0.55, 0.72 0.61, 0.86 0.50, 1.72 0.25, 0.85 0.51, 1.38 0.50, 1.25 0.57, 0.98 0.81, 3.15 0.65, 2.00 0.36, 1.00 0.32, 0.85 0.44, 0.80 0.57, 0.91 0.65, 0.99 0.61, 0.91

a

Estimates were adjusted for age, sex, education, smoking status, institutionalization, and baseline MMSE score. Estimates were adjusted for age, sex, education, and apolipoprotein E (APOE) E4 allele presence. c Estimates were adjusted for age, sex, race, diabetes, APOE E4 allele, and history of stroke. d Estimates were adjusted for age, sex, education, body mass index (BMI), systolic blood pressure, diabetes, and smoking. e Estimates were adjusted for age, sex, and education. f Estimates were adjusted for age, sex, education, blood pressure, current smoking status, history of stroke and MMSE score. g Estimates were adjusted for age and sex. h Estimates were adjusted for age, sex, social class, and education. i Estimates were adjusted for age, number of years since menopause, education, ethnicity, family income, smoking status, BMI, hypertension status, prior CVD, diabetes, statin use, aspirin use, prior hormone therapy, and baseline 3MSE score. j Estimates were adjusted for age, sex, race, APOE E4 allele, educational attainment, income level, marital status, estrogen replacement therapy, current smoking, former smoking, diabetes, BMI, total cholesterol level, atrial fibrillation, history of congestive heart failure, history of stroke, history of transient ischemic attack, and Kcal expended in daily activities. b

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Alcohol, Dementia, and Cognitive Decline

TABLE 3.

Relative Risks of Dementia for Heavy/Excessive Drinkers Versus Nondrinkers

Outcome

Study

Alzheimer disease

Vascular dementia

Any dementia

10a

Deng et al. Ruitenberg et al.47b Shin et al.48c Mukamal et al.46d Pooled Ruitenberg et al.47e Mukamal et al.46d Deng et al.10a Pooled Deng et al.10a Ruitenberg et al.47b Mukamal et al.46f Shin et al.48c Pooled

Weight (%)

Relative Risk

95% Confidence Interval

11.11 15.10 35.23 38.56 100 18.63 34.32 47.05 100 11.05 18.22 32.27 38.46 100

1.35 1.17 0.71 0.95 0.92 1.53 0.93 1.72 1.36 1.45 1.00 1.22 0.84 1.04

0.35–5.21 0.37–3.73 0.33–1.53 0.46–1.96 0.59–1.45 0.31–7.56 0.29–3.02 0.63–4.70 0.68–2.71 0.43–4.89 0.39–2.58 0.60–2.49 0.44–1.61 0.69–1.56

a

Estimates were adjusted for age, sex, education, blood pressure, current smoking status, history of stroke and MMSE score. Estimates were adjusted for age, sex, body mass index (BMI), systolic blood pressure, diabetes, smoking, and education. c Estimates were adjusted for age, gender, education, and lifetime alcohol consumption. d Estimates were adjusted for age, sex, race, diabetes, APOE E4 allele, and history of stroke. e Estimates were adjusted for age and sex. f Estimates were adjusted for age, sex, race, APOE E4 allele, educational attainment, income level, marital status, estrogen replacement therapy, current smoking, former smoking, diabetes, BMI, total cholesterol level, atrial fibrillation, history of congestive heart failure, history of stroke, history of transient ischemic attack, and Kcal expended in daily activities. b

Heavy/Excessive Drinkers Versus Nondrinkers

Drinkers Versus Nondrinkers

The pooled RRs of AD, VaD, and Any dementia for heavy/excessive drinkers versus nondrinkers are shown in Table 3. No significant effects were found, and no test of heterogeneity was significant.

The pooled RRs of AD, Any Dementia, and cognitive decline for drinkers compared with nondrinkers are shown in Table 4. Drinkers had reduced risk of AD and Any dementia (RR ⫽ 0.66), but there was no

TABLE 4.

Relative Risks of Dementia and Cognitive Decline for Drinkers Versus Nondrinkers

Outcome Alzheimer disease

Any dementia

Cognitive decline

Study 49a

Yoshitake et al. Lindsay et al.45b Pooled Ogunniyi et al.66c,d Yip et al.68e Ogunniyi et al.66f,d Simons et al.67g Pooled Ganguli et al.53h Dufouil et al.52i Pooled

Weight (%)

Relative Risk

95% Confidence Interval

13.99 86.01 100 7.31 10.07 11.79 70.84 100 46.04 53.96 100

0.56 0.68 0.66 0.82 0.80 0.49 0.66 0.66 0.08 0.84 0.28

0.22–1.43 0.47–0.99 0.47–0.94 0.36–1.85 0.40–1.60 0.26–0.93 0.51–0.83 0.53–0.82 0.02–0.30 0.66–1.07 0.03–2.83

a

Estimates were adjusted for age. Estimates were adjusted for age, sex, and education. c Ogunniyi et al. (2006) Yoruba sample. d Unadjusted estimates. e Estimates were adjusted for age, sex, social class, and education. f Ogunniyi et al. (2006) Indianapolis Study of Health and Aging (ISHA) sample. g Estimates were adjusted for age, sex, marital status, education, prior history of stroke, and activities of daily living. h Estimates were adjusted for age, sex, educational level, smoking status, depressive symptoms, recruitment status, baseline cognitive scores, and incident dementia. i Estimates were adjusted for age, gender, education level, cognitive functions, hypertension, and depressive symptoms at study entry. b

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Anstey et al. significant result for cognitive decline. The test for heterogeneity was significant for cognitive decline (␹2[1] ⫽ 11.80, p ⫽ 0.00006) suggesting that the pooled results for only two studies may not be reliable. Results of Studies Meeting Criteria but Not Compatible for Meta-Analyses Of the 10 studies providing data that met search criteria, but were not compatible for meta-analysis, no effect of alcohol on cognitive outcomes was found in four studies.18,51,58,60 A protective effect of alcohol use on 1 of 10 cognitive measures was found in one study.50 In another study, drinkers showed less decline on one of three cognitive measures although this disappeared when ounces of alcohol were considered.54 One study found that male problem drinkers had an increased risk of memory problems over a 6-year follow-up period.56 A protective effect of light to moderate alcohol consumption against cognitive decline was reported in three studies.22,57,61 Adjustment for Covariates We also recorded whether adjustment for covariates increased or decrease the effect sizes reported. Unadjusted and adjusted results were available for eight studies.10,11,29,46,47,49,62,67 Of these, the effect sizes increased in the adjusted analyses in five studies10,11,46,49,62 and were unchanged in the remaining three studies. Comparison of Former Drinkers and Lifetime Abstainers Five articles recorded information on former drinkers compared with lifetime abstainers.46 – 48,53,62 Three studies found no differences between former drinkers and abstainers on either baseline cognitive scores,62 or overall results4748 involving cognitive outcomes. One study53 found that when former drinkers were excluded from the nondrinker group, the effect sizes of the study reduced. These authors concluded that much of the difference between nondrinkers and drinkers is explained by the group of former drinkers, many who may have stopped drinking due to health problems. Another study found that former drinkers had 20%– 60% higher odds of incident dementia than abstainers.46

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DISCUSSION The results from this meta-analysis indicated that light to moderate alcohol intake was associated with a 25%–28% reduction in risk of AD, VaD, and Any dementia compared with alcohol abstinence in older adults. Heavy drinking was not associated with increased risk of dementia in the present study. This may have been due to sampling effects such that very heavy drinkers may be less likely to participate in cohort studies, or to achieve follow-up. It may also reflect survival effects. Alcohol dependence is associated with higher rates of cancer, liver disease, neurological damage, and mental disorders9 all of which increase mortality risk. As the samples included in the study were relatively old, there may have been a low probability of individuals with alcohol dependence being selected into these samples. Heavy drinkers may have already developed cognitive impairment or dementia and hence been screened out of the analyses reported. Although the analyses comparing drinkers with nondrinkers were based on very broad categories, it showed again that alcohol consumption was associated with reduced risk of dementia. The strengths of this study are the strict selection criteria such as the exclusion of studies that did not screen for dementia at baseline, the inclusion of both dementia and cognitive decline as outcome variables, and the reduction of publication bias by including studies from article reference lists, as well as those studies that included alcohol as a covariate, not just the main predictor. The results were consistent across comparisons of light to moderate drinkers and the broad range analysis of alcohol consumption versus no alcohol consumption. The study of alcohol drinking as a risk factor for health outcomes is complicated by issues such as beverage type, standard measurements of quantity, and other individual characteristics or behaviors that may interact with alcohol consumption to affect cognitive performance.69 With the exception of one study, all publications included in this review adjusted for multiple confounders. Nearly all studies adjusted for smoking status, which has been shown to increase the risk of dementia14 and in people with alcohol use disorders to compound the effects of chronic alcohol consumption.70,71 Where studies re-

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Alcohol, Dementia, and Cognitive Decline ported results for adjusted and unadjusted analyses, the ORs increased after adjustment in most studies. Definitions of mild to moderate drinking varied across studies in terms of number of units or drinks, and the definition of a unit or drink. This reflects the problem of comparing alcohol consumption data generally. However, all studies excluded very heavy drinkers from these categories. The different criteria for moderate drinking means that there is a lack of specificity of the results in relation to the upper end of the moderate drinking category. If some studies did include harmful drinkers and heavy drinking is a risk factor for dementia, then this would weaken the observed effect. This would occur particularly with women, because the level of harmful alcohol consumption for women is lower than for men. A limitation of the review was the pooling of men and women in most analyses, which was required because most studies did not report results separately for men and women. However, all studies adjusted for gender and separate results for men and women were pooled from three studies. The fact that reduced risk of all dementia outcomes were found for both men and women light to moderate drinkers shows that the overall effects observed in analyses including both genders were not specific to men or women. It is notable that the reduced risks of dementia associated with light to moderate drinking in men were larger than those observed in women. This may have been due to the same number of drinks being used to classify men and women in two of the studies46,47 that were included in the subanalyses of men and women. A limitation of the review was that there were too few studies within consistent outcome criteria to enable analysis according to beverage type. Furthermore, there is a lack of published data on how ethnicity interacts with alcohol to effect brain development and dementia. Overall, our findings suggest that among older adults participating in cohort studies, light to moderate alcohol consumption is associated with reduced risk of dementia in older adults over 2– 8 years of follow-up. As no studies included follow-up of individuals from early or mid-adulthood, it is unknown how selection effects may have biased the results. For example, very heavy drinkers may have already had cognitive impairment or dementia and hence been screened out of these studies or analyses.

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Alternatively, participants with neurological conditions or dementia may have ceased drinking as a consequence of their disease. The low prevalence of heavy drinkers in population-based studies of older adults may have reduced the likelihood of this review identifying significant associations between harmful alcohol use and dementia or cognitive decline. Hence, the null result reported here must be taken as a preliminary finding, with further analyses on larger samples of hazardous drinkers required to fully assess this potential association. Research has shown that even young adult alcohol abstainers have lower cognitive test scores,72 so it is possible that the findings in late life reflect individual differences associated with drinking patterns across the entire lifespan. It is also possible that other health conditions, life style behaviors, and medications may explain the associations found between alcohol consumption and dementia and cognition because the studies reviewed did not adjust for the same covariates. Our results are for the most part consistent with another systematic review of the association between alcohol consumption and dementia.73 That review also found a protective effect of alcohol consumption for AD and dementia, but unlike our study, did not find a protective effect for VaD. The present review pooled data on the basis of level of alcohol consumption and conducted analyses separately for AD, VaD, Any dementia, and cognitive decline. The previous review pooled results on the basis of outcome but not the level of alcohol consumption. If the direction of effects of alcohol on dementia risk vary according to the level of consumption, then pooling across different levels of consumption may obfuscate findings. Compared with the previous review, our review included a wider list of search terms, and did not have a minimum date for inclusion of articles. Our review also excluded articles, where the sample had not been screened for dementia at baseline. This is particularly important because incipient dementia may affect alcohol drinking patterns and cognitive performance and is likely to be prevalent samples of older adults. The mechanisms underlying a putative protective effect of alcohol on cognition remain unclear. It is widely accepted that moderate alcohol consumption increases high-density cholesterol, which helps lower risk for cardiovascular events.74 –76 Alcohol in moderation also increases cerebral blood flow,77 de-

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Anstey et al. creases blood coagulation, increases antithrombotic activity (especially red wine), increases endothelial relaxation, and increases insulin sensitivity.75,78 Such effects are protective against atheroma, vascular occlusion, and cerebral hypoperfusion. The Northern Manhattan Study’s evaluation of inflammatory markers and Mini-Mental State Examination scores suggested that light to moderate alcohol consumption may modify inflammation as participants with a history of moderate alcohol consumption had lower IL-6 levels than abstainers nondrinkers or those who drank intermediate and heavy amounts.79 An antiinflammatory effect maybe one reason for the apparent protective effects moderate alcohol consumption has on cardiovascular disease, which may in turn reduce the risk of dementia.80,81 We conclude that light to moderate alcohol consumption in older adults is associated with reduced risk of dementia. Further research is required to clarify the mechanisms underlying the observed association between alcohol and brain function, to determine how this may be affected by cardiovascular disease. Importantly, further research is required to determine whether the results reported here will remain over longer follow-up intervals and how alcohol consumption (including binge drinking) in early

and midlife affects later dementia risk. Finally, the extent to which alcohol consumption interacts with other risk factors such as apolipoprotein E to moderate dementia risk needs to be evaluated before making recommendations on alcohol consumption to protect against dementia in the population. The clinical implications of this review are that low levels of alcohol may be beneficial for cognitive function in late life. However, these findings do not address broader potential adverse drinking outcomes associated with other clinical conditions or medication use. Hence, the overall safety of alcohol use in later life needs to be evaluated in relation to all of the available evidence regarding its associations with health and disease outcomes.

The authors thank Richard Burns, Haley Caldwell, and Jennifer Young. They also thank the authors who kindly provided data for the meta-analyses. This work was supported by Dementia Collaborative Research Centres, an Australian Government Initiative (to HAM), NHMRC Research Fellowship No. 366756 (to KJA), Alzheimer’s Australia Research and the Centre for Mental Health Research at the Australian National University (to NC).

References 1. Duffy JC: Alcohol consumption and all-cause mortality. Int J Epidemiol 1995; 24:100 –105 2. Svardsudd K. Moderate alcohol consumption and cardiovascular disease: is there evidence for a preventive effect? Alcohol Clin Exp Res 1998;22:307S–314S 3. Andreasson S. Alcohol and J-shaped curves. Alcohol Clin Exp Res 1998;22:359S–364S 4. Kalev-Zylinska ML, During MJ: Paradoxical facilitatory effect of low-dose alcohol consumption on memory mediated by NMDA receptors. J Neurosci 2007; 27:10456 –10467 5. Boulouard M, Lelong V, Daoust M, et al: Chronic ethanol consumption induces tolerance to the spatial memory impairing effects of acute ethanol administration in rats. Behav Brain Res 2002; 136:239 –246 6. Mikolajczak P, Okulicz-Kozaryn I, Nowaczyk M, et al: Ethanol facilitation of short-term memory in adult rats with a disturbed circadian cycle. Alcohol Alcohol 2001; 36:292–297 7. Rossetti ZL, Carboni S, Stancampiano R, et al: Bidirectional modulation of spatial working memory by ethanol. Alcohol Clin Exp Res 2002; 26:181–185 8. Wang J, Ho L, Zhao Z, et al: Moderate consumption of Cabernet Sauvignon attenuates A{beta} neuropathology in a mouse model of Alzheimer’s disease. FASEB J 2006; 20:2313–2320 9. Cargiulo T: Understanding the health impact of alcohol dependence. Am J Health Syst Pharm 2007; 64:S5–S11 10. Deng J, Zhou DH, Li J, et al: A 2-year follow-up study of alcohol

Am J Geriatr Psychiatry 17:7, July 2009

consumption and risk of dementia. Clin Neurol Neurosurg 2006; 108:378 –383 11. Luchsinger JA, Tang M-X, Siddiqui M, et al: Alcohol intake and risk of dementia. J Am Geriatr Soc 2004; 52:540 –546 12. Rozzini R, Sabatini T, Trabucchi M: Alcohol Consumption and the risk of dementia: biological and psychological mechanisms. J Am Geriatr Soc 2005; 53:175–176 13. Anstey KJ, Lipnicki DM, Low LF: Cholesterol as a risk factor for dementia and cognitive decline: a systematic review of prospective studies with meta-analysis. Am J Geriatr Psychiatry 2008; 16:343–354 14. Anstey KJ, von Sanden C, Salim A, et al: Smoking as a risk factor for dementia and cognitive decline: a meta-analysis of prospective studies. Am J Epidemiol 2007; 166:367–378 15. Xiong GL, Plassman BL, Helms MJ, et al: Vascular risk factors and cognitive decline among elderly male twins. Neurology 2006; 67:1586 –1591 16. Moher D, Tetzlaff J, Tricco AC, et al: Epidemiology and reporting characteristics of systematic reviews. PLoS Med 2007; 4:e78 17. Stroup DF, Berlin JA, Morton SC, et al: Meta-analysis of observational studies in epidemiology: a proposal for reporting. Metaanalysis Of Observational Studies in Epidemiology (MOOSE) group. JAMA 2000; 283:2008 –2012 18. Launer LJ, Feskens EJ, Kalmijn S, et al: Smoking, drinking, and thinking. The Zutphen Elderly Study. Am J Epidemiol 1996; 143: 219 –227

553

Alcohol, Dementia, and Cognitive Decline 19. Feskens EJ, Havekes LM, Kalmijn S, et al: Apolipoprotein e4 allele and cognitive decline in elderly men. BMJ 1994; 309:1202–1206 20. Schuit AJ, Feskens EJM, Launer LJ, et al: Physical activity and cognitive decline, the role of the apolipoprotein e4 allele. Med Sci Sports Exerc 2001; 33:772–777 21. Larrieu S, Letenneur L, Helmer C, et al: Nutritional factors and risk of incident dementia in the PAQUID longitudinal cohort. J Nutr Health Aging 2004; 8:150 –154 22. Bond GE, Burr RL, McCurry SM, et al: Alcohol and cognitive performance: a longitudinal study of older Japanese Americans. The Kame Project. Int Psychogeriatr 2005; 17:653– 668 23. Helmer C, Damon D, Letenneur L, et al: Marital status and risk of Alzheimer’s disease: a French population-based cohort study. Neurology 1999; 53:1953–1958 24. Helmer C, Letenneur L, Rouch I, et al: Occupation during life and risk of dementia in French elderly community residents. J Neurol Neurosurg Psychiatry 2001; 71:303–309 25. Lemeshow S, Letenneur L, Dartigues JF, et al: Illustration of analysis taking into account complex survey considerations: the association between wine consumption and dementia in the PAQUID study. Personnes Ages Quid. Am J Epidemiol 1998; 148:298 –306 26. Bond GE, Burr R, McCurry SM, et al: Alcohol, gender, and cognitive performance: a longitudinal study comparing older Japanese and non-Hispanic White Americans. J Aging Health 2004; 16:615– 640 27. Bassuk SS, Glass TA, Berkman LF: Social disengagement and incident cognitive decline in community-dwelling elderly persons. Ann Intern Med 1999; 131:165–173 28. Bassuk SS, Berkman LF, Wypij D: Depressive symptomatology and incident cognitive decline in an elderly community sample. Arch Gen Psychiatry 1998; 55:1073–1081 29. Huang W, Qiu C, Winblad B, et al: Alcohol consumption and incidence of dementia in a community sample aged 75 years and older. J Clin Epidemiol 2002; 55:959 –964 30. Backman L, Jones S, Small BJ, et al: Rate of cognitive decline in preclinical Alzheimer’s disease: the role of comorbidity. J Gerontol Ser B Psychol Sci Soc Sci 2003; 58B:P228 –P236 31. Engelhart MJ, Geerlings MI, Ruitenberg A, et al: Dietary intake of antioxidants and risk of Alzheimer disease. JAMA 2002; 287: 3223–3229 32. Fujishima M, Kiyohara Y: Incidence and risk factors of dementia in a defined elderly Japanese population: the Hisayama study. Ann N Y Acad Sci 2002; 977:1– 8 33. Fujishima M, Tsuchihashi T: Hypertension and dementia. Clin Exp Hypertens 1999; 21:927–935 34. He´bert R, Lindsay J, Verreault R, et al: Vascular dementia: incidence and risk factors in the Canadian study of health and aging. Stroke 2000; 31:1487–1493 35. Juan D, Zhou DHD, Li J, et al: A 2-year follow-up study of cigarette smoking and risk of dementia. Eur J Neurol 2004; 11:277–282 36. Kalmijn S, Feskens EJ, Launer LJ, et al: Polyunsaturated fatty acids, antioxidants, and cognitive function in very old men. Am J Epidemiol 1997; 145:33– 41 37. Laurin D, Verreault R, Lindsay J, et al: Omega-3 fatty acids and risk of cognitive impairment and dementia. J Alzheimer Dis 2003; 5:315–322 38. Morris MC, Evans DA, Bienias JL, et al: Vitamin E and cognitive decline in older persons. Arch Neurol 2002; 59:1125–1132 39. Ott A, Slooter AJ, Hofman A, et al: Smoking and risk of dementia and Alzheimer’s disease in a population-based cohort study: the Rotterdam Study. Lancet 1998; 351:1840 –1843 40. Paterniti S, Dufouil C, Alperovitch A: Long-term benzodiazepine use and cognitive decline in the elderly: the epidemiol-

554

ogy of vascular aging study. J Clin Psychopharmacol 2002; 22:285–293 41. Rondeau V, Commenges D, Jacqmin-Gadda H, et al: Relation between aluminum concentrations in drinking water and Alzheimer’s disease: an 8-year follow-up study. Am J Epidemiol 2000; 152:59 – 66 42. Schofield PW, Tang M, Marder K, et al: Consistency of clinical diagnosis in a community-based longitudinal study of dementia and Alzheimer’s disease. Neurology 1995; 45:2159 –2164 43. Yaffe K, Blackwell T, Gore R, et al: Depressive symptoms and cognitive decline in nondemented elderly women: a prospective study. Arch Gen Psychiatry 1999; 56:425– 430 44. Richards M, Kuh D, Hardy R, et al: Lifetime cognitive function and timing of the natural menopause. Neurology 1999; 53:308 – 314 45. Lindsay J, Laurin D, Verreault R, et al: Risk factors for Alzheimer’s disease: a prospective analysis from the Canadian Study of Health and Aging. Am J Epidemiol 2002; 156:445– 453 46. Mukamal KJ, Kuller LH, Fitzpatrick A, et al: Prospective study of alcohol consumption and risk of dementia in older adults. JAMA 2003; 289:1405–1413 47. Ruitenberg A, van Swieten JC, Witteman JCM, et al: Alcohol consumption and risk of dementia: the Rotterdam Study. Lancet 2002; 359:281–286 48. Shin IIS, Stewart R, Kim J-M, et al: Mitochondrial aldehyde dehydrogenase polymorphism is not associated with incidence of Alzheimer’s disease. Int J Geriatr Psychiatry 2005; 20:1075–1080 49. Yoshitake T, Kiyohara Y, Kato I, et al: Incidence and risk factors of vascular dementia and Alzheimer’s disease in a defined elderly Japanese population: the Hisayama Study. Neurology 1995; 45: 1161–1168 50. Broe GA, Creasey H, Jorm AF, et al: Health habits and risk of cognitive impairment and dementia in old age: a prospective study on the effects of exercise, smoking and alcohol consumption. Aust N Z J Public Health 1998; 22:621– 623 51. Cervilla JA, Prince M, Mann A: Smoking, drinking and incident cognitive impairment: a cohort community based study included in the Gospel Oak project. J Neurol Neurosurg Psychiatry 2000; 68:622– 626 52. Dufouil C, Tzourio C, Brayne C, et al: Influence of apolipoprotein E genotype on the risk of cognitive deterioration in moderate drinkers and smokers. Epidemiology 2000; 11:280 –284 53. Ganguli M, Vander Bilt J, Saxton JA, et al: Alcohol consumption and cognitive function in late life: a longitudinal community study. Neurology 2005; 65:1210 –1217 54. Hebert LE, Scherr PA, Beckett LA, et al: Relation of smoking and low-to-moderate alcohol consumption to change in cognitive function: a longitudinal study in a defined community of older persons. Am J Epidemiol 1993; 137:881– 891 55. Morris MC, Evans DA, Tangney CC, et al: Fish consumption and cognitive decline with age in a large community Study. Arch Neurol 2005; 62:1849 –1853 56. Perreira KM, Sloan FA: Excess alcohol consumption and health outcomes: a 6-year follow-up of men over age 50 from the health and retirement study. Addiction 2002; 97:301–310 57. Richards M, Hardy R, Wadsworth MEJ: Alcohol consumption and midlife cognitive change in the British 1946 birth cohort study. Alcohol Alcohol 2005; 40:112–117 58. Verhaeghen P, Borchelt M, Smith J: Relation between cardiovascular and metabolic disease and cognition in very old age: crosssectional and longitudinal findings from the Berlin aging study. Health Psychol 2003; 22:559 –569 59. Waldstein SR, Giggey pp, Thayer JF, et al: Nonlinear relations of

Am J Geriatr Psychiatry 17:7, July 2009

Anstey et al. blood pressure to cognitive function: the Baltimore Longitudinal Study of Aging. Hypertension 2005; 45:374 –379 60. Solfrizzi V, D’Introno A, Colacicco AM, et al: Alcohol consumption, mild cognitive impairment, and progression to dementia. Neurology 2007; 68:1790 –1799 61. Barnes DE, Cauley JA, Lui LY, et al: Women who maintain optimal cognitive function into old age. J Am Geriatr Soc 2007; 55:259 – 264 62. Espeland MA, Gu L, Masaki KH, et al: Association between reported alcohol intake and cognition: results from the Women’s Health Initiative Memory Study. Am J Epidemiol 2005; 161:228 – 238 63. de Craen AJ, Gussekloo J, Vrijsen B, et al: Meta-analysis of nonsteroidal antiinflammatory drug use and risk of dementia. Am J Epidemiol 2005; 161:114 –120 64. Greenland S, Longnecker MP: Methods for trend estimation from summarized dose-response data, with applications to meta-analysis. Am J Epidemiol 1992; 135:1301–1309 65. Sutton AJ, Abrams KR, Jones DR, et al: Methods for Meta-Analysis in Medical Research. Chichester, UK, Wiley, 2000 66. Ogunniyi A, Hall KS, Gureje O, et al: Risk factors for incident Alzheimer’s disease in African Americans and Yoruba. Metab Brain Dis 2006; 21:235–240 67. Simons LA, Simons J, McCallum J, et al: Lifestyle factors and risk of dementia: Dubbo Study of the elderly. Med J Aust 2006; 184:68 –70 68. Yip AG, Brayne C, Matthews FE: Risk factors for incident dementia in England and Wales: the Medical Research Council Cognitive Function and Ageing Study. A population-based nested case-control study. Age Ageing 2006; 35:154 –160 69. Malarcher AM, Giles WH, Croft JB, et al: Alcohol intake, type of beverage, and the risk of cerebral infarction in young women. Stroke 2001; 32:77– 83 70. Durazzo TC, Meyerhoff DJ: Neurobiological and neurocognitive

Am J Geriatr Psychiatry 17:7, July 2009

effects of chronic cigarette smoking and alcoholism. Front Biosci 2007; 12:4079 – 4100 71. Durazzo TC, Rothlind JC, Gazdzinski S, et al: A comparison of neurocognitive function in nonsmoking and chronically smoking short-term abstinent alcoholics. Alcohol 2006; 39:1–11 72. Anstey KJ, Windsor TD, Rodgers B, et al: Lower cognitive test scores observed in alcohol abstainers are associated with demographic, personality, and biological factors: the PATH through life project. Addiction 2005; 100:1291–1301 73. Peters R, Peters J, Warner J, et al: Alcohol, dementia and cognitive decline in the elderly: a systematic review. Age Ageing 2008; 37:493– 494 74. Kondo K: Beer and health: preventive effects of beer components on lifestyle-related diseases. Biofactors 2004; 22:303–310 75. de Gaetano G, Di Castelnuovo A, Donati MB, et al: The mediterranean lecture: wine and thrombosis—from epidemiology to physiology and back. Pathophysiol Haemost Thromb 2003; 33: 466 – 471 76. Ecker RR, Klatsky AL: Doctor, should I have a drink? An algorithm for health professionals. Ann N Y Acad Sci 2002; 957:317–320 77. Volkow ND, Wang GJ, Franceschi D, et al: Low doses of alcohol substantially decrease glucose metabolism in the human brain. Neuroimage 2006; 29:295–301 78. Klatsky AL: Alcohol, cardiovascular diseases and diabetes mellitus. Pharmacol Res 2007; 55:237–247 79. Wright CB, Sacco RL, Rundek TR, et al: Interleukin-6 is associated with cognitive function: the Northern Manhattan Study. J Stroke Cerebrovasc Dis 2006; 15:34 –38 80. Romeo J, Warnberg J, Nova E, et al: Moderate alcohol consumption and the immune system: a review. Br J Nutr 2007; 98:S111– S115 81. Diaz LE, Montero A, Gonzalez-Gross M, et al. Influence of alcohol consumption on immunological status: a review. Eur J Clin Nutr 2002;56(suppl 3):S50 –S53

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