Effect of a Multidomain Lifestyle Intervention on Estimated Dementia Risk
Abstract
We investigated the effect of a multidomain lifestyle intervention on the risk of dementia estimated using the validated CAIDE risk score (post-hoc analysis). The Finnish Geriatric Intervention Study to Prevent Cognitive Impairment and Disability (FINGER) is a 2-year randomized controlled trial among 1,260 at-risk older adults (60–77 years). Difference in the estimated mean change in CAIDE score at 2 years in the intervention compared to the control group was –0.16 (95 %CI –0.31 to 0.00) (p = 0.013), corresponding to a relative dementia risk reduction between 6.04–6.50%. This could be interpreted as a reflection of the prevention potential of the intervention.
INTRODUCTION
Preventing dementia is a major public health priority [1]. Early identification of at-risk individuals is essential for effective preventive strategies. Several dementia risk algorithms have been developed based on various combinations of risk factors, often non-modifiable (e.g., age, sex, genetics) [2]. However, in addition to quantifying dementia risk, it is important to estimate prevention potential, i.e. the “room for risk reduction” with preventive interventions. Risk scores including modifiable factors (e.g., lifestyle, vascular, or metabolic) may be particularly useful for this purpose.
The Finnish Geriatric Intervention Study to Prevent Cognitive Impairment and Disability (FINGER) was the first large, longer-term randomized controlled trial to report significant benefits on cognition [3], health-related quality of life [4], disability [5], and multimorbidity [6] for a 2-year multidomain lifestyle intervention among 1,260 older individuals with elevated dementia risk. Here we report post-hoc analyses of intervention effects on change in the Cardiovascular Risk Factors, Aging and Dementia (CAIDE) Dementia Risk Score. The CAIDE score is a validated tool for estimating dementia risk based on age, sex, education, systolic blood pressure, body mass index, serum total cholesterol, and physical activity [7, 8], and it was used to select at-risk participants to the FINGER trial.
METHODS
The FINGER trial (ClinicalTrials.gov NCT01041989) protocol [9], recruitment [10], and primary results [3] have been previously reported. FINGER is a multicenter study conducted in 6 centers in Finland. It was approved by the Coordinating Ethics Committee of the Hospital District of Helsinki and Uusimaa. Participants gave written informed consent.
Participants were recruited from previous population-based observational studies [10]. Eligibility criteria were: age 60–77 years; CAIDE Dementia Risk Score≥6 points (for screening purpose calculated based on data from previous surveys, up to 40 years before the trial); and at least one cognitive test criterion: the Consortium to Establish a Registry for Alzheimer’s Disease (CERAD) [11, 12] Word List Memory task (10 words x3) ≤19 words, or CERAD Word List Recall≤75%, or Mini-Mental State Examination (MMSE) [13]≤26/30 points. Exclusion criteria were: dementia; MMSE < 20 points; conditions affecting safe participation or preventing co-operation; and coincident participation in another trial.
Between September 7, 2009 and November 24, 2011, 2,654 individuals were screened for eligibility, and 1,260 were randomized 1:1 into the intensive multidomain intervention or regular health advice (i.e., control) group. Computer-generated randomization was done in blocks of four individuals at each site. Outcome assessors were blinded to allocation and not involved in the intervention. The control group received regular health advice. The intervention group received nutritional advice (individual and group sessions led by study nutritionists), physical exercise program supervised by study physiotherapists at the gym, cognitive training (individual computer-based training, and group sessions led by study psychologists), and management of metabolic and vascular risk factors [9]. The intervention was completed in February 2014.
Risk factors included in the CAIDE score are based on data from population register (age, sex), self-reported questionnaires (education, physical activity), measurements by the study nurse (systolic blood pressure, body mass index), and laboratory analyses (serum total cholesterol).The scoring system has been reported and validated previously [7, 8]. CAIDE Dementia Risk Score was calculated using data from the FINGER baseline, 12- and 24-month visits. In addition, APOE ɛ genotype was assessed [14]. T-test or χ 2 test was used for baseline comparisons between intervention and control groups. Mixed effects regression models with maximum likelihood estimation were used to analyze change in CAIDE score as a function of randomization group, time, and group x time interaction. All participants with CAIDE score available from at least one time point were included in the main analysis (intention-to-treat) (n = 1,254, 99.5%). Sensitivity analyses were conducted including only participants with CAIDE score data at all time points (n = 1,030). Potential effect modification by other variables (baseline age, continuous; sex; or presence of at least one APOE ɛ4 allele) was investigated by adding the group x time x variable interaction to the model, together with the main variable effect and variable x time and variable x group interactions.
Analyses were adjusted by study site. Level of significance was set to p = 0.05 in all analyses; we also report three-way interactions with p < 0.10. Stata software version 14 was used.
RESULTS
Intervention and control groups were not significantly different in sociodemographic characteristics, vascular and lifestyle factors, medical history, cognitive performance (as previously described [3]), or CAIDE score (Table 1) at baseline. 1,254 (99.5%) participants had CAIDE score data from at least one trial visit.
Table 1
Baseline characteristics
| Number of participants | Intervention group (N = 631) | Control group (N = 629) | p | |
| Age at baseline, y | 1260 | 69.5 (4.7) | 69.2 (4.7) | 0.26 |
| Women, N (%) | 1260 | 286 (45.3) | 302 (48.0) | 0.34 |
| Education, y | 1258 | 10.0 (3.5) | 10.0 (3.4) | 0.94 |
| Body mass index | 1251 | 28.3 (4.5) | 28.1 (4.9) | 0.44 |
| Systolic blood pressure, mmHg | 1251 | 140.2 (16.6) | 140.0 (15.7) | 0.77 |
| Physical inactivity, N (%) | 1247 | 189 (30.2) | 175 (28.1) | 0.41 |
| APOE4 carrier, N (%) | 1175 | 189 (32.0) | 200 (34.2) | 0.43 |
| Baseline CAIDE score | 1233 | 7.9 (1.8) | 7.8 (1.9) | 0.69 |
Values are mean (SD) or N (%). The CAIDE Dementia Risk Score was calculated based on a combination of age, sex, education, systolic blood pressure, body mass index, total cholesterol and physical activity, as previously described [7].
The estimated mean change in CAIDE score in the intervention and control group during the trial is shown in Fig. 1. Between-group difference was significant (p = 0.013 for the group×time interaction). Estimated mean change in CAIDE score at 2 years was –0.15 (95%CI –0.26 to –0.04) in the control and –0.31 (95%CI –0.42 to –0.20) in the intervention group, with between-group difference –0.16 (95%CI –0.31 to 0.00). The estimated between group difference in mean change in CAIDE score at year 1 was –0.22 (95%CI –0.37 to –0.07). Results remained unchanged in sensitivity analysis (participants with CAIDE score data at all 3 time points).
Fig. 1
Change in CAIDE Dementia Risk Score during the 2-year intervention. The figure shows estimated means of CAIDE score at baseline, 12 and 24 months (lower scores indicate lower risk for dementia). Error bars are CIs. Mixed-model repeated-measures analysis was used to assess between-group differences (randomization group×time interaction) in change from baseline to 24 months.
The intervention benefit on CAIDE score change tended to be more pronounced among women than men (p = 0.098 for the randomization group x time x sex interaction). The 2-year estimated between-group difference for men was –0.03 (95%CI –0.24 to 0.19) and for women –0.31 (95%CI –0.54 to –0.08). There were no differences in attrition between men and women.
No significant differences were found by age or APOE ɛ4 carrier status (p > 0.32).
To translate the intervention-related change in CAIDE score into estimates of dementia risk reduction, we used a previously reported formula for calculating 20-year dementia risk in middle-aged individuals [7]:
where SCOREcontrol was the baseline CAIDE score (mean 7.86 for all participants) minus 1 point for age to reflect a middle-aged population; and SCOREintervention was SCOREcontrol minus 0.16 (estimated 2-year intervention-related decrease in CAIDE score). With a control group 20-year risk of 2.07%, and an intervention group risk of 1.94%, their ratio was 0.94. This indicated a relative risk reduction of 6.09%. Without the age adjustment, the relative risk reduction was 6.04%. Similar calculations using the observed 2-year difference in CAIDE score change between intervention and control groups (–0.17) with and without age adjustment resulted in a relative risk reduction between 6.44%and 6.50%.
DISCUSSION
In the FINGER trial, there was a significant beneficial intervention effect on reducing estimated dementia risk measured by the CAIDE score. This effect tended to be more pronounced in women. As the intervention was more intensive during the first year, the reduction in CAIDE score was also more pronounced during the first year followed by maintenance of the risk score reduction during the second year.
These post-hoc analyses could be interpreted as a reflection of the prevention potential of the intervention. The FINGER intervention was started early, in at-risk individuals without substantial cognitive impairment [3], and therefore incident dementia was not a feasible outcome after 2 years. For several reasons, the estimates presented here may not reflect the actual magnitude of dementia risk reduction: The CAIDE Dementia Risk Score is based on simple cut-offs for risk factors, restricting its sensitivity to change over time. While it also includes non-modifiable risk factors, the intervention effect is less likely to be overestimated since risk estimates are adjusted for such factors. Also, the CAIDE score was developed as the first midlife risk score for estimating dementia risk 20 years later and was used to select FINGER participants based on pre-trial midlife data. In addition, the FINGER control group received a program of regular general health advice as per national guidelines, leading to more conservative intervention effect estimates than a “do-nothing” control group. Although the CAIDE score was also reduced in the control group (a benefit that may at least partly be explained by “trial effect”, regression to the mean or other factors) [15, 16], the reduction was significantly greater in the intervention group.
The intervention effect on the CAIDE score tended to be more pronounced among women, although the test of interaction was not significant. Given the limited sample size it is not possible to provide reliable estimates separately for men and women. Hopefully larger trials and joint analyses across multidomain lifestyle trials will allow more detailed subgroup analyses in the future, including analyses of sex differences in intervention efficacy and adherence.
We based our estimates of change in dementia risk on data from the middle-aged observational cohort originally used to develop the CAIDE score [7]. This is because dementia risk estimates in observational studies of older populations may be influenced by reverse causation, i.e., vascular/metabolic factors may be affected by “silent” disease processes. However, because the CAIDE risk score was developed and validated in a midlife population, the estimated risk of dementia is most likely an underestimation in this population of older adults. Ongoing FINGER extended follow-up will provide data on observed dementia incidence, and more accurate risk reduction estimates and evaluation of the CAIDE score as a potential surrogate outcome in lifestyle-based dementia prevention trials [17].
As FINGER targeted at-risk participants from the general population, the importance of potential risk reduction should be interpreted in a public health context. There is currently no direct evidence of cost-efficacy of dementia prevention interventions, but previous modelling studies have suggested that relatively small risk reductions (0.6–3.2%) may already be cost-effective [18].
The FINGER participants were recruited from previous population-based studies and they are well-representative of at-risk older adults in Finland [10]. The CAIDE score has been validated in, e.g., diverse population in the US, and therefore also our results may be at least to some extent generalizable to other older at-risk populations. However, the relative importance of modifiable risk factors may differ across populations and over time. In an early prevention trial it is still difficult to estimate the potential clinical significance of the findings. CAIDE risk score can be used as a tool to communicate dementia risk, and to select persons that may benefit from lifestyle interventions. Based on the current results, it can perhaps also be used to track risk factor changes. Novel biomarker assays as well as additional lifestyle and clinical measures may contribute to further development of more sensitive risk scores.
In conclusion, an important area for future developments in dementia prevention would be multifactorial algorithms that estimate both dementia risk and prevention potential and are highly sensitive to capturing change in various risk factors over time. Establishing risk models as surrogate outcomes for dementia development would greatly facilitate assessing the long-term impact of dementia prevention trials.
ACKNOWLEDGMENTS
The authors wish to thank all participants and staff and members of FINGER study group.
AS received research funding from the European Research Council grant 804371, Academy of Finland (287490, 294061, 319318), Finnish Cultural Foundation, Yrjö Jahnsson Foundation (Finland), Alzheimerfonden and Region Stockholm ALF (Sweden). RA received State research funding (EVO/VTR grants) of Oulu University Hospital and Oulu City Hospital (Finland). HS received funding from EU 7th framework collaborative project grant (HATICE), EU Joint Programme - Neurodegenerative Disease Research (MIND-AD), UEF Strategic funding for UEFBRAIN (Finland), and State research Funding (EVO/VTR grants) from Kuopio University Hospital (Finland). MK received research support from the Academy of Finland (317465), Finnish Social Insurance Institution, Finnish Ministry of Education and Culture, Juho Vainio Foundation (Finland), EU Joint Programme - Neurodegenerative Disease Research (MIND-AD and EURO-FINGERS), Alzheimer’s Research and Prevention Foundation (US), Alzheimerfonden (Sweden), Swedish Research Council, Center for Innovative Medicine (CIMED) at Karolinska Institutet, Region Stockholm (ALF, NSV), Knut and Alice Wallenberg Foundation (Sweden), Stiftelsen Stockholms sjukhem (Sweden), Konung Gustaf V:s och Drottning Victorias Frimurarstiftelse (Sweden). TN received research funding from EU Joint Programme - Neurodegenerative Disease Research (EURO-FINGERS) and Finnish Cultural Foundation, Juho Vainio Foundation; and Jalmari and Rauha Ahokas Foundation, Finland.
Authors’ disclosures available online (https://www.j-alz.com/manuscript-disclosures/21-0331r1).
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