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. 2001 Jun 16;322(7300):1447–1451. doi: 10.1136/bmj.322.7300.1447

Midlife vascular risk factors and Alzheimer's disease in later life: longitudinal, population based study

Miia Kivipelto a, Eeva-Liisa Helkala b, Mikko P Laakso c, Tuomo Hänninen d, Merja Hallikainen a, Kari Alhainen e, Hilkka Soininen d, Jaakko Tuomilehto f, Aulikki Nissinen b
PMCID: PMC32306  PMID: 11408299

Abstract

Objective

To examine the relation of midlife raised blood pressure and serum cholesterol concentrations to Alzheimer's disease in later life.

Design

Prospective, population based study.

Setting

Populations of Kuopio and Joensuu, eastern Finland.

Participants

Participants were derived from random, population based samples previously studied in a survey carried out in 1972, 1977, 1982, or 1987. After an average of 21 years' follow up, a total of 1449 (73%) participants aged 65-79 took part in the re-examination in 1998.

Main outcome measures

Midlife blood pressure and cholesterol concentrations and development of Alzheimer's disease in later life.

Results

People with raised systolic blood pressure (⩾160 mm Hg) or high serum cholesterol concentration (⩾6.5 mmol/l) in midlife had a significantly higher risk of Alzheimer's disease in later life, even after adjustment for age, body mass index, education, vascular events, smoking status, and alcohol consumption, than those with normal systolic blood pressure (odds ratio 2.3, 95% confidence interval 1.0 to 5.5) or serum cholesterol (odds ratio 2.1, 1.0 to 4.4). Participants with both of these risk factors in midlife had a significantly higher risk of developing Alzheimer's disease than those with either of the risk factors alone (odds ratio 3.5, 1.6 to 7.9). Diastolic blood pressure in midlife had no significant effect on the risk of Alzheimer's disease.

Conclusion

Raised systolic blood pressure and high serum cholesterol concentration, and in particular the combination of these risks, in midlife increase the risk of Alzheimer's disease in later life.

What is already known on this topic

Vascular risk factors may play an important part as risk factors for Alzheimer's disease

No population based studies have evaluated prospectively the impact of both midlife blood pressure and cholesterol concentration in both men and women on the subsequent development of Alzheimer's disease

What this study adds

Raised systolic blood pressure and high serum cholesterol concentration, and in particular the combination of these risks, in midlife increased the risk of Alzheimer's disease in later life

Raised systolic blood pressure and hypercholesterolaemia may have a role in the pathogenesis of Alzheimer's disease; more emphasis should be placed on identification and appropriate treatment of these conditions

Introduction

Risk factors for vascular disease may also be risk factors for Alzheimer's disease. Some cross sectional studies have investigated the relation of blood pressure and cholesterol concentration to cognitive function in late life, but with conflicting results. Furthermore, one limitation of cross sectional studies is that they cannot readily determine causality. This shortcoming can to some extent be overcome with longitudinal, population based studies. Two such studies have found that raised blood pressure precedes the development of Alzheimer's disease—one conducted in a Swedish population aged 70 years and followed for 9-15 years and the other in Japanese-American men with a mean age of 53 followed for 25 years.1,2 In addition, Finnish men aged 70-89 with Alzheimer's disease were found to have had raised serum cholesterol concentrations 15-25 years before the onset of the disease.3

It is important to identify early risk factors for Alzheimer's disease because the neurodegenerative processes of Alzheimer's disease may begin in midlife.4 Identification of these risk factors may shed some light on the pathophysiology of Alzheimer's disease and also provide new potential avenues for its prevention and treatment. The preliminary findings showing an association between vascular risk factors and Alzheimer's disease need to be replicated in independent populations, and no population based study has yet evaluated the association of both midlife blood pressure and cholesterol concentrations with Alzheimer's disease in later life in both sexes. We investigated the putative impact of raised blood pressure and cholesterol concentrations in midlife on the subsequent development of Alzheimer's disease in a population based sample.

Participants and methods

Participants were derived from four separate independent population based samples studied within the framework of the North Karelia project and the FINMONICA study in 1972, 1977, 1982, and 1987.5 Participants who were still alive, aged 65-79 by the end of 1997, and living in two geographically defined areas in or close to the towns of Kuopio and Joensuu were the target of this study. From these 2293 people, a random sample of 2000 participants were invited to the re-examination carried out during 1998. Altogether 1449 (72.5%) people participated (figure on website). The mean length of follow up was 21 (SD 4.9) years (range 11-26 years; 26 years for 34.9%, 21 years for 38.1%, 16 years for 15.6%, and 11 years for 11.4% of participants). The study was approved by the local ethics committee, and written informed consent was obtained from all participants.

Examination and re-examination

The protocol for the midlife examination is described in greater detail elsewhere.5 In brief, the survey included a self administered questionnaire on medical history, cerebrovascular and cardiovascular events, and vascular conditions diagnosed by a physician. Height and weight were measured. Blood pressure was measured in the right arm after participants had been seated for five minutes. Venous blood specimens were taken for determination of serum cholesterol concentrations.5

During the re-examination in 1998, the survey methods followed those of the previous surveys in all aspects. Dementia was diagnosed in a three phase study design: a screening phase (phase 1), a clinical phase (phase 2), and a differential diagnosis phase (phase 3) (figure on website). The diagnosis of dementia was based on the Diagnostic and Statistical Manual of Mental Disorders, fourth edition,6 and the diagnosis of Alzheimer's disease was made according to the criteria of the National Institute of Neurological and Communicative Disorders and Stroke and the Alzheimer Disease and Related Disorders Association.7

A total of 57 (4%) participants were diagnosed as having dementia, of whom 48 fulfilled the diagnostic criteria for probable or possible Alzheimer's disease. All patients with Alzheimer's disease showed generalised or medial temporal atrophy, and none showed appreciable vascular pathology on magnetic resonance scans. Isolated minor lacunae or periventricular white matter signal changes were not considered as exclusion criteria for Alzheimer's disease. All patients with Alzheimer's disease scored four or less on the Hachinski ischaemia scale.8

Four patients were diagnosed as having vascular dementia, two as having Parkinson's disease with dementia, two as having alcoholic dementia, and one as having frontotemporal dementia. Since the focus of this study was Alzheimer's disease and the number of participants with non-Alzheimer dementia was small, these nine cases were excluded from further analyses.

Statistical analyses

Differences between the study groups were analysed with Student's t test and the χ2 test as appropriate. Midlife blood pressure values were classified into normal (<140 mm Hg), borderline (140-159 mm Hg), and high (⩾160 mm Hg) for systolic pressure; and normal (<90 mm Hg), borderline (90-94 mm Hg), and high (⩾95 mm Hg) for diastolic pressure. Midlife serum cholesterol concentrations were classified into high (⩾6.5 mmol/l) and normal (<6.5 mmol/l). The association between midlife blood pressure and cholesterol concentration and subsequent Alzheimer's disease was investigated with multiple logistic regression analyses, using normal blood pressure and cholesterol as the reference category (model 1). As blood pressure and cholesterol concentration are influenced by age and body mass index, the analyses were replicated controlling for these factors (model 2). Further analyses were carried out controlling also for education, history of myocardial infarction and cerebrovascular symptoms (used as indicators of vascular events), and smoking status and alcohol consumption (model 3).

Results

Sociodemographic and clinical characteristics

Table 1 shows the sociodemographic and clinical characteristics of the study population. Mean age was 50.4 years (SD 6.0, range 40-64 years) in the original survey and 71.3 years (4.0, 65-80) at re-examination. Patients with Alzheimer's disease were significantly older, and they also had less formal education than participants without dementia. Patients with Alzheimer's disease had higher body mass index, systolic blood pressure, and serum total cholesterol in midlife than did participants without dementia, but at re-examination these values were similar in the two groups. Diastolic blood pressure was similar in patients with Alzheimer's disease and participants without dementia both in midlife and at re-examination.

Table 1.

Sociodemographic and clinical characteristics of the study population. Values are means (standard deviations) unless otherwise stated

Characteristic Alzheimer's disease (n=48) No dementia (n=1352) P value Participants (n=1409) Non-participants (n=591) P value (t test)
Male/female (%) 40/60 38/62  0.73* 38/62 36/64  0.57*
Duration of follow up (years) 20.6 (4.5) 20.9 (4.9) 0.75 20.9 (4.9)
Age (years):
 Midlife 54.0 (4.7) 50.2 (6.0) <0.001 50.4 (6.0) 51.2 (5.9)  0.007
 Re-examination 74.7 (3.8) 71.1 (4.0) <0.001 71.3 (4.0)
Education (years)  6.7 (2.7)  8.5 (3.5) <0.001  8.4 (3.5)  7.4 (2.9) <0.001
Mini-mental state examination 20.4 (3.0) 26.1 (2.0) <0.001 25.9 (2.4)
Body mass index (kg/m2):
 Midlife 27.6 (4.0) 26.5 (3.7)  0.038 26.6 (3.7) 27.2 (4.5)  0.002
 Re-examination 27.8 (4.4) 27.8 (4.3)  0.994 27.8 (4.3)
Systolic blood pressure (mm Hg):
 Midlife 152.7 (18.2) 143.9 (19.8)  0.002 144.3 (19.9) 150.2 (21.7) <0.001
 Re-examination 150.4 (23.5) 151.5 (23.4)  0.747 151.4 (23.3)
Diastolic blood pressure (mm Hg):
 Midlife 91.2 (9.5)  89.1 (10.9)  0.182  89.2 (10.9)  91.7 (11.3) <0.001
 Re-examination  80.4 (11.5)  80.5 (11.2)  0.965  80.4 (11.2)
Cholesterol (mmol/l):
 Midlife  7.2 (1.0)  6.7 (1.2)  0.001  6.7 (1.2)  7.0 (1.3) <0.001
 Re-examination  6.0 (1.0)  5.8 (1.0)  0.234  5.8 (1.0)
*

χ2 test was used. 

Blood pressure, cholesterol, and risk of Alzheimer's disease

High systolic blood pressure in midlife was a significant risk for Alzheimer's disease in later life (table 2), and this remained true after all the adjustments (models 2 and 3). Borderline high systolic blood pressure in midlife also increased the risk (model 1), but after adjustments (models 2 and 3) this association was no longer significant. Midlife diastolic blood pressure had no significant effect on the risk of Alzheimer's disease in any of the models. High serum cholesterol concentration in midlife was a significant risk for Alzheimer's disease, even after all the adjustments (models 1-3).

Table 2.

Association of midlife blood pressure and cholesterol concentrations with Alzheimer's disease later in life. Values are numbers (percentages) unless otherwise stated

Characteristic Alzheimer's disease (n=48) No dementia (n=1352) Odds ratio (95% CI)
Model 1* Model 2* Model 3*
Systolic blood pressure (mm Hg):
 <140 (normal) 12 (25) 606 (44.8) 1.0 1.0 1.0
 140-159 (borderline) 20 (42) 484 (35.8) 2.1 (1.0 to 4.3) 1.8 (0.85 to 3.7) 2.1 (0.8 to 5.0)
 ⩾160 (high) 16 (33) 262 (19.4) 3.1 (1.4 to 6.6) 2.3 (1.0 to 5.0) 2.8 (1.1 to 7.2)
Diastolic blood pressure (mm Hg):
 <90 (normal) 21 (44) 704 (52.1) 1.0 1.0 1.0
 90-94 (borderline)  9 (19) 289 (21.4)  1.0 (0.47 to 2.3) 1.1 (0.48 to 2.4) 1.4 (0.6 to 3.5)
 ⩾95 (high) 18 (38) 359 (26.6)  1.7 (0.88 to 3.2) 1.6 (0.84 to 3.2) 1.7 (0.8 to 3.6)
Cholesterol concentration (mmol/l):
 <6.5 (normal) 11 (23) 630 (46.6) 1.0 1.0 1.0
 ⩾6.5 (high) 37 (77) 722 (53.4) 2.9 (1.5 to 5.8) 2.7 (1.4 to 5.4) 2.2 (1.0 to 4.7)
Risk groups I:
 Single risk factor 23 (48) 660 (48.8) 1.0 1.0 1.0
 Combined 15 (31) 162 (12.0) 2.7 (1.4 to 4.4) 2.2 (1.1 to 4.4) 3.5 (1.6 to 7.9)
Risk groups II:
 Single risk factor 13 (27) 614 (45.4) 1.0 1.0 1.0
 Combined 30 (63) 427 (31.6) 3.3 (1.7 to 6.4) 2.9 (1.5 to 5.7) 2.8 (1.3 to 5.9)
*

Model 1 gives univariate odds ratios for the risk of Alzheimer's disease; model 2 controls for age and body mass index; model 3 controls for age, body mass index, education, history of myocardial infarction and cerebrovascular symptoms, smoking status, and alcohol consumption. 

In risk groups I, single risk factor indicates either systolic blood pressure ⩾160 mm Hg or cholesterol ⩾6.5 mmol/l, and combined indicates both of these risk factors. Risk groups II were similar, but the cut-off point for systolic blood pressure was 140 mm Hg. 

Because high systolic blood pressure and cholesterol concentration were significant risk factors for Alzheimer's disease, we evaluated the added risk related to possessing both these risk factors. Participants with both risk factors in midlife had significantly higher risk for Alzheimer's disease than did those with either of these risk factors alone (table 2).

Analyses included control for age at the time when risk factor data were collected, because the effects of the midlife variables were the focus of this study. The length of follow up did not differ between participants who developed Alzheimer's disease and those who did not; thus controlling for age at re-examination did not change the results (data not shown).

Medical history and Alzheimer's disease

Table 3 shows the medical history of the participants. Patients with Alzheimer's disease were more likely to have been treated with antihypertensive drugs in midlife, but at re-examination later in life there was no difference between the groups. At re-examination, patients with Alzheimer's disease were significantly more likely to have a history of myocardial infarction and cerebrovascular symptoms (almost invariably expressed as transient ischaemic attack) and less likely to be alcohol users than participants without dementia.

Table 3.

Relation of medical history and vascular characteristics to Alzheimer's disease. Values are numbers (percentages) unless otherwise stated

Characteristic* Alzheimer's disease (n=48) No dementia (n=1352) P value
Myocardial infarction:
 Midlife 3 (6) 34 (2.5) 0.245
 Re-examination 18 (38) 189 (14.0) <0.001
Cerebrovascular symptoms:
 Midlife 0 (0) 19 (1.4) 1.00
 Re-examination  9 (19) 89 (6.6) 0.004
Diabetes mellitus:
 Midlife 0 (0) 16 (1.2) 0.929
 Re-examination  6 (13) 88 (6.5) 0.177
Antihypertensive drug treatment:
 Midlife 13 (27) 194 (14.3) 0.015
 Re-examination 19 (40) 488 (36.1) 0.621
Cholesterol lowering drug treatment:
 Re-examination 10 (21) 208 (15.4) 0.436
Smoking:
 Midlife 23 (48) 577 (42.7) 0.474
 Re-examination 19 (40) 498 (36.8) 0.929
Alcohol use:
 Midlife 29 (60) 956 (70.7) 0.633
 Re-examination 22 (46) 964 (71.3) 0.003
*

Information was obtained from detailed questionnaires about medical history and medical conditions and events diagnosed by a physician. Midlife and re-examination indicates the visit when the questionnaire was answered. 

χ2 test was used. 

Discussion

This study showed that raised systolic blood pressure and high serum cholesterol concentrations in midlife increased the risk of Alzheimer's disease in later life. The combination of these risk factors in midlife, even when participants with borderline high systolic blood pressure were included, increased the risk to a greater extent than either of the risk factors on its own. Diastolic blood pressure in midlife was not associated with Alzheimer's disease in later life.

The role of blood pressure

Two previous longitudinal, population based studies have shown an association between raised blood pressure and subsequent Alzheimer's disease.1,2 These studies, however, suggested that the risk was related to raised diastolic blood pressure rather than raised systolic pressure. Differences in the study settings and populations could account for the discrepancy. For instance, treatment patterns may have contributed to our finding. Participants with Alzheimer' s disease were more likely to have received antihypertensive drug treatment in midlife but, despite the treatment, still had higher systolic blood pressure in midlife than their counterparts without dementia. This is in line with findings that a considerable proportion of treated hypertensive patients do not achieve the target blood pressure and the fact that diastolic blood pressure has traditionally been the main indication for antihypertensive treatment.2,9,10

Our study, including both treated and untreated participants, may underestimate the risk related to diastolic blood pressure. Notably, in Japanese-American men the raised diastolic blood pressure in midlife predicted Alzheimer's disease only in participants never treated with antihypertensive drugs.2 From this perspective, our data should not be interpreted as discounting the potential risk of Alzheimer's disease related to raised diastolic blood pressure but rather as emphasising the importance of raised systolic blood pressure, even in people with normal diastolic blood pressure. Our findings are partly corroborated by the only drug trial to date showing that blood pressure control may prevent dementia, which was carried out in patients with isolated systolic hypertension.11

High serum total cholesterol concentration in midlife also predicted Alzheimer's disease in later life. This finding is consistent with the findings in elderly Finnish men.3 Our study extends these findings to younger age groups and both sexes, making these data more representative.

The role of cholesterol

In this study, clinical indicators of atherosclerosis were more common in patients with Alzheimer's disease than in participants without dementia. A population based, cross sectional study has previously indicated an increased risk of Alzheimer's disease in patients with atherosclerosis.12 Hypertension and hypercholesterolaemia may increase the risk of dementia by inducing atherosclerosis and impairing blood flow, but they may also directly induce the neurodegeneration of Alzheimer's disease.13 Controlling for vascular events did not change the association between midlife high systolic blood pressure and cholesterol concentration and subsequent Alzheimer's disease, suggesting that hypertension and hypercholesterolaemia themselves pose a risk for Alzheimer's disease. Furthermore, the combination of hypertension and hypercholesterolaemia in midlife was a particularly strong predictor of Alzheimer's disease; these factors may accelerate the development of Alzheimer's disease partly through different pathophysiological mechanisms.

Apolipoprotein E genotype may influence the observed associations, but more than 85% of the variation in serum cholesterol concentrations is thought to be independent of the apolipoprotein E genotype.14 Accordingly, the findings in elderly Finnish men suggested that high serum cholesterol concentration was an independent risk factor for Alzheimer's disease regardless of the apolipoprotein E genotype.3 However, more research is needed to determine if apolipoprotein E genotype modulates the effects of risk factors for Alzheimer's disease.

Study methodology

The design of our study as a population based, longitudinal study with a large cohort of participants and substantial response rate increases the credibility of these findings. No autopsy data were available to confirm the clinical diagnosis, although the accuracy of the clinical diagnosis of Alzheimer's disease at Kuopio University Hospital, verified by neuropathology, has been reported to be 96%.15

We investigated the possibility of selection bias due to non-participation. The prevalences of both raised systolic blood pressure and hypercholesterolaemia in midlife were higher among non-participants. People with cognitive decline are less likely to participate in clinical studies.16 Hence, if non-participants were at an increased risk of cognitive impairment and dementia, our results would represent an underestimate of the true effect of the risk factors rather than the opposite. Only participants scoring ⩽24 in the mini-mental state examination in the screening phase underwent the exhaustive examinations needed for the diagnosis of dementia. Some dementia cases may have been lost because of this cut-off score, and this may also have resulted in underestimation of the prevalence of dementia.

Conclusion

As the proportion of elderly people in the population increases, Alzheimer's disease will become an enormous public health problem. Interventions that could delay the onset of the disease, even modestly, would therefore have a major impact on public health.17 The observed relation between midlife vascular risk factors and Alzheimer's disease later in life may have implications for the prevention of dementia as both hypertension and hypercholesterolaemia can be treated.

Supplementary Material

[extra: Figure]

Acknowledgments

We thank Veli Koistinen, Veikko Jokela, and Pirjo Halonen for statistical help and Liisi Saarela for technical assistance.

Footnotes

Funding: Academy of Finland grants 37573 and 63645 and EVO grant 477268.

Competing interests: None declared.

Figure showing the study design appears on the BMJ's website

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[extra: Figure]

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