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. 2020 Apr 28;94(17):e1803–e1810. doi: 10.1212/WNL.0000000000009316

White matter hyperintensities mediate the association of nocturnal blood pressure with cognition

Anthony G Chesebro 1, Jesus D Melgarejo 1, Reinier Leendertz 1, Kay C Igwe 1, Patrick J Lao 1, Krystal K Laing 1, Batool Rizvi 1, Mariana Budge 1, Irene B Meier 1, Gustavo Calmon 1, Joseph H Lee 1, Gladys E Maestre 1, Adam M Brickman 1,
PMCID: PMC7274843  PMID: 32295824

Abstract

Objective

To test the hypotheses that hypertension and nocturnal blood pressure are related to white matter hyperintensity (WMH) volume, an MRI marker of small vessel cerebrovascular disease, and that WMH burden statistically mediates the association of hypertension and dipping status with memory functioning, we examined the relationship of hypertension and dipping status on WMH volume and neuropsychological test scores in middle-aged and older adults.

Methods

Participants from the community-based Maracaibo Aging Study received ambulatory 24-hour blood pressure monitoring, structural MRI, and neuropsychological assessment. Four hundred thirty-five participants (mean ± SD age 59 ± 13 years, 71% women) with available ambulatory blood pressure, MRI, and neuropsychological data were included in the analyses. Ambulatory blood pressure was used to define hypertension and dipping status (i.e., dipper, nondipper, and reverse dipper based on night/day blood pressure ratio <0.9, 0.9–1, and >1, respectively). Outcome measures included regional WMH and memory functioning derived from a neuropsychological test battery.

Results

The majority of the participants (59%) were hypertensive. Ten percent were reverse dippers, and 40% were nondippers. Reverse dipping in the presence of hypertension was associated with particularly elevated periventricular WMH volume (F2,423 = 3.78, p = 0.024) and with lowered memory scores (F2,423 = 3.911, p = 0.021). Periventricular WMH volume mediated the effect of dipping status and hypertension on memory (β = −4.1, 95% confidence interval −8.7 to −0.2, p < 0.05).

Conclusion

Reverse dipping in the presence of hypertension is associated with small vessel cerebrovascular disease, which, in turn, mediates memory functioning. These results point toward reverse dipping as a marker of poor nocturnal blood pressure control, particularly among hypertensive individuals, with potentially pernicious effects on cerebrovascular health and associated cognitive function.

The assessment of 24-hour ambulatory blood pressure allows more reliable measurement of blood pressure than what is typically measured clinically and the examination of blood pressure fluctuation over time.17 One indicator of fluctuation, nocturnal blood pressure decline or dipping, is a physiologically relevant effect associated with healthy blood pressure regulation.4,8 Nondipping, or a lack of nocturnal decline in blood pressure levels, is a frequent comorbidity with hypertension, with >40% of hypertensive older adults experiencing nondipping.9,10 Nondipping is associated with an increased risk of type 2 diabetes mellitus, reduced renal function, and left ventricular hypertrophy, and with severe vascular events such as coronary heart disease, stroke, and mortality.7,1114

A lack of nocturnal blood pressure dipping is a potential risk factor for small vessel cerebrovascular disease, although this relationship remains unclear.2,4,1517 Small vessel cerebrovascular disease is associated with lower cognitive functioning and higher risk for stroke, dementia, altered motor function, and mortality among older adults.1826 White matter hyperintensities (WMH), which are regions of increased signal on T2-weighted brain MRI, are established markers of small vessel cerebrovascular disease.20,21,25,27 However, the factors by which peripheral vascular conditions can cause WMH accumulation remain unclear.18,28,29 Furthermore, there is some evidence that the causes of WMH might vary by their regional distribution, with periventricular WMH being particularly sensitive to hemodynamic changes, or aberrations of blood flow, while deep WMH are more sensitive to long-term ischemic changes.1,30,31

The purposes of this study were to examine the independent and interactive relationship of hypertension and dipping status on WMH volume and to determine whether WMH burden statistically mediates the effect of hypertension and dipping status on memory functioning in late middle-aged community-dwelling adults. We hypothesized that individuals with both hypertension and nondipping status would have the greatest WMH volume, which would, in turn, would account for poorer memory functioning.

Methods

Participants

Four hundred thirty-five participants from the Maracaibo Aging Study (MAS32) with available ambulatory blood pressure, MRI, and neuropsychological data were included in the study. The MAS began in 1998 in Maracaibo, Venezuela, as a prospective, longitudinal, community-based cohort study of cognitive aging and dementia.32 Initially, the MAS recruited participants who were living in the Santa Lucia community and were >55 years old (n = 2,349). The study was expanded in 2010 to include participants >40 years old and living in either Santa Lucia or the Santa Rosa de Agua community 6 miles away.33

Standard protocol approvals, registrations, and patient consents

The MAS was approved by Institutional Review boards of the University of Zulia and Columbia University. All participants in the MAS provided informed consent.

24-Hour blood pressure monitoring

The ambulatory blood pressure measurement devices (validated oscillometric 90207; SpaceLabs monitors, Redmond, WA) were programmed to obtain measurements every 15 minutes during the day (6 am–10:59 pm) and every 30 minutes at night (11 pm–5:59 am) over a 24-hour period. Ambulatory hypertension was defined as a 24-hour average of systolic blood pressure >130 mm Hg or diastolic blood pressure >80 mm Hg or the use of antihypertensive medication, following the guidelines of the European Society of Cardiology and European Society of Hypertension.34 All participants who did not meet these criteria were considered normotensive. As suggested in previous work,35 we used the ambulatory blood pressure measurements to calculate the night/day blood pressure ratio to identify the change in nocturnal blood pressure relative to daytime blood pressure. A participant's nocturnal dipping profile was defined as the ratio of systolic nighttime blood pressure to systolic daytime blood pressure. Dipping status was defined according to established criteria35 as follows: dipper, a normal decrease in nocturnal systolic blood pressure relative to diurnal blood pressure (i.e., night/day blood pressure <0.9); nondipper, a small or nonexistent decrease in nocturnal systolic blood pressure relative to diurnal blood pressure (i.e., night/day blood pressure between 0.9 and 1.0); and reverse dipper, an abnormal increase in nocturnal systolic blood pressure relative to diurnal blood pressure (i.e., night/day blood pressure >1.0).

MRI acquisition and processing

MRI scans were obtained on a 1.5T scanner (Optima MR360; GE Healthcare, Chicago, IL) and included T1-weighted (repetition time 7,904 milliseconds, echo time 2,460 milliseconds, field of view 256 × 256 mm with 1-mm contiguous slices) and T2-weighted fluid-attenuated inversion recovery (repetition time 8,000 milliseconds, echo time 123 milliseconds, inversion time 2,000 milliseconds, field of view 256 × 162 mm with 2-mm contiguous slices). Exclusion criteria for MRI scans were the presence of a pacemaker, aneurysm clip, neurostimulator, or cochlear implant or body weight >110 kg. In addition, potential participants were excluded if they had a history of major medical conditions or procedures thought to confound measurement of WMH such as multiple sclerosis, brain radiotherapy, brain surgery, implants for Parkinson disease, lupus, brain tumor (lymphoma), HIV, neurocysticercosis, neurosyphilis, brain tuberculosis, and brain trauma with loss of consciousness. All clinical and neuroimaging data were collected within a 3-week time interval.

Whole-brain and regional WMH volumes were quantified with previously described methods.36,37 Briefly, each participant's T2-weighted fluid-attenuated inversion recovery image was brain extracted, and a single gaussian curve was fit to voxel intensity values in the brain-extracted image. Intensity values >2.1 SD above the whole-brain mean intensity value were labeled as hyperintense voxels. The threshold was set by a trained operator who visually inspected the results. The resulting map was manually inspected and corrected for each participant, with any mislabeled WMH voxels removed. WMH volume, in cubic centimeters, was defined as the number of labeled voxels multiplied by voxel dimensions.

The WMH volumes were coregistered to the brain extracted T1-weighted volumes defined by FreeSurfer (version 6.0, surfer.nmr.mgh.harvard.edu), and the euclidean distance between each WMH-labeled voxel and the nearest ventricle was computed. Following previously defined criteria,30,31,38 these distances were used to define periventricular WMH volume, which comprised all WMH voxels lying 3 to 13 mm from the ventricular surface, and deep WMH volume, which comprised all WMH voxels lying >13 mm from the ventricular surface.

Neuropsychological evaluation

The neuropsychological evaluation consisted of a test battery,39 adapted to be applied in this community-dwelling sample, and the Cambridge Neuropsychological Test Automated Battery.40 We selected the total learning score from the Selective Reminding Test41 as the memory score for this study. As an exploratory analysis, we selected performance measures from Paired Associated Learning (PAL), Intra-Extra Dimensional Set Shift (IED), and Reaction Time (RTI) from the Cambridge Neuropsychological Test Automated Battery as secondary cognitive measures.

Patient health history

Physicians and nurses collected demographic and clinical information. Diabetes mellitus was defined by the criteria specified in the Seventh Report of the Joint National Committee42: a fasting glucose serum level >125 mg/dL or taking an antidiabetic drug. History of vascular disease encompassed stroke events, ischemic heart disease, and heart failure. History of smoking was defined as past and/or current smoking. Obesity was defined as a body mass index ≥30 kg.2,43 Diagnosis of dementia was assigned according to a Clinical Dementia Rating44 (CDR) score ≥1 and a consensus conference that included study physicians, experts in dementia diagnosis.

Statistical analysis

We used a general linear model to examine the association of hypertension and dipping status with WMH volume and cognition. We examined the main effects of hypertension and dipping status, as well as their interactions on WMH volume and cognition, adjusting for age and sex/gender. Analyses involving cognition additionally adjusted for number of years of education. We then examined the association between WMH volumes (periventricular and deep) and memory, adjusting for age, sex/gender, and years of education.

We used a moderated mediation model to test whether dipping status moderates the association of hypertension with WMH and with memory and whether WMH mediate the relationship of hypertension and dipping status with memory. This model allowed us to simultaneously test whether WMH volume mediates the relationship between dipping status and memory in both normotensive and hypertensive individuals, mirroring the interaction effects probed in our initial analyses. Moderated mediation analyses were conducted with PROCESS 3.1 (model 8) for SPSS.45 This approach to mediation modeling is based on bootstrapping, which resamples the sample population over many iterations (k = 5,000) to obtain a more robust estimate of the effect size (β) and confidence interval (CI) of each variable, without any assumption of how the variables are distributed.45,46

To confirm that our initial analyses were not due to quasi-arbitrary cut points to define categorical dipping classes, we used a linear regression model adjusted for age and sex/gender to test the association of continuously defined nocturnal dipping profile (i.e., ratio of systolic nighttime blood pressure to systolic daytime blood pressure) with WMH volume, both as a main effect and interacting with hypertension status. Another linear regression model, adjusted for age, sex/gender, and years of education, was used to test the association of nocturnal dipping profile with total learning score, both as a main effect and interacting with hypertension status. To ensure that our findings were not simply driven by constantly elevated blood pressure levels, we performed a linear regression to test the independent associations of 24-hour average systolic blood pressure and nocturnal dipping profile, adjusting for age and sex/gender, with periventricular WMH volume. Finally, because individuals with hypertension were reliably older than those without, we repeated the primary statistical analyses in an age-restricted subsample, selecting only individuals 50 to 70 years old to ensure that age did not confound our results.

Data availability

Requests for access to the data used in this study will be considered on a case-by-case basis.

Results

Participants

Descriptive statistics for demographic and blood pressure variables are presented in table 1. Hypertensive participants were older than normotensive participants and were more likely to be reverse dippers. Sex/gender distribution and the number of years of education did not differ between groups. The frequency of comorbid vascular conditions, including diabetes mellitus and history of cardiovascular disease, was higher in hypertensive participants than in normotensive participants. History of smoking and current obesity did not differ between groups. Diagnosis of dementia did not differ between groups, although a slightly higher proportion of individuals with hypertension had CDR scores of 0.5. Hypertensive participants were more likely to be taking hypertensive medication than normotensive participants.

Table 1.

Descriptive data across the hypertension status

graphic file with name NEUROLOGY2019028811TT1.jpg

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Effects of hypertension and dipping profile by dipper categories

Hypertensive individuals had higher periventricular WMH volumes than those without hypertension (main effect of hypertension: F1,423 = 12.12, p = 0.001). This main effect was modified by an interaction between hypertension and dipping status (F2,423 = 3.78, p = 0.024); reverse dippers with hypertension had particularly elevated WMH volume compared with all other groups (figure 1A). Reverse dippers had greater periventricular WMH volume compared with dippers (p < 0.001) and nondippers (p < 0.001), while dippers and nondippers did not differ from each other (p = 0.89; main effect of dipping status F2,423 = 2.58, p = 0.08). Hypertensive individuals did not differ in deep WMH volume compared with all other groups (main effect of hypertension F1,423 = 2.39, p = 0.12, figure 1B). Dipping status did not moderate the relationship between hypertension and deep WMH volume (main effect of dipping status: F2,423 = 0.15, p = 0.86; interaction effect of dipping status by hypertension F2,423 = 0.85, p = 0.43).

Figure 1. WMH volume as a function of hypertension and dipping status.

Figure 1

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In each graph, the central bar represents the median, box marks the first and third quartiles, and bars extend 1.5 times the width of the box. Remaining points represent values outside this range. The y-axes are logarithmically scaled. (A) Reverse dipping in the presence of hypertension is associated with higher accumulation of periventricular white matter hyperintensity (WMH) volume at almost twice the rate of any other group. (B) There is no observed association among dipping status, hypertension, and deep WMH volume.

There was minimal effect of hypertension (F1,423 = 3.16, p = 0.08) and dipping status (F2,423 = 0.89, p = 0.41) on total learning score. However, dipping status moderated the effect of hypertension on total learning, with hypertensive reverse dippers having lower total learning scores than all other groups, paralleling the effects observed in periventricular WMH volumes (dipping status by hypertension interaction F2,423 = 3.91, p = 0.021; figure 2). Dipping status and hypertension were not associated with performance on other cognitive measures (PAL, IED, and RTI scores). There was a stronger relationship between periventricular WMH volume and total learning scores (β = −0.42, 95% CI −0.68 to −0.17, p = 0.001) than between deep WMH volume and total learning (β = −0.57, 95% CI −1.18 to 0.05, p = 0.073).

Figure 2. Total learning score as a function of hypertension and dipping status.

Figure 2

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Reverse dipping in the presence of hypertension is associated with markedly lower memory function compared with all other groups. The central bar represents the median; box marks the first and third quartiles; and bars extend 1.5 times the width of the box. Remaining points represent values outside this range.

Mediation model

Table 2 presents the results of the moderated mediation model used to test the relationship among dipping magnitude, hypertension, WMH volume, and total learning score. In hypertensive individuals, greater dipping magnitude (i.e., a higher night/day blood pressure ratio) was associated with an increase in WMH volume and a decrease in total learning, while no such effects were observed in normotensive individuals. In hypertensive individuals, the effect of dipping magnitude on total learning was mediated by periventricular WMH volume (index −4.86, 95% CI −10.22 to −0.14, p < 0.05). A similar indirect effect mediated by deep WMH volume was not observed (index −1.70, 95% CI −5.51 to 0.82, p > 0.1).

Table 2.

Direct and indirect effects of dipping status and WMH volume on total learning score in normotensive and hypertensive individuals

graphic file with name NEUROLOGY2019028811TT2.jpg

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Confirmatory analyses

Using dipping profile (i.e., the continuously defined night/day systolic blood pressure ratio) yielded results similar to those of the analyses that classified dipping status categorically. An increased dipping profile was associated with increased periventricular WMH volume (β = 7.98, 95% CI 3.47 to 12.5, p = 0.001) but not with deep WMH volume (β = 0.33, 95% CI −1.57 to 2.24, p = 0.73). The interaction of hypertension status with dipping profile was associated with increased periventricular WMH volume (β = 13.3, 95% CI 3.40 to 23.2, p = 0.009) but not with deep WMH volume (β = 3.43, 95% CI −0.79 to 7.65, p = 0.11). There was no observable relationship between dipping profile and total learning score (β = −7.45, 95% CI −19.8 to 4.87, p = 0.24). However, the interaction between hypertension status and dipping profile was strongly associated with a lower total learning score (β = −39.4, 95% CI −68.6 to −10.3, p = 0.008). Dipping profile and hypertension were not associated with other cognitive measures (PAL, IED, and RTI scores).

To ensure that the effects of dipping profile were not simply attributable to overall elevated blood pressure over a 24-hour period, we examined the simultaneous effects of average 24-hour systolic blood pressure and dipping profile on periventricular WMH volume and found that both 24-hour average blood pressure (β = 0.18, p < 0.001) and dipping profile (β = 0.10, p = 0.025) were independently associated with WMH volume. Although all primary analyses were adjusted for age, to ensure further that the relatively large age differences between hypertensive and normotensive individuals did not account for our primary findings, we conducted sensitivity analyses by restricting the sample to individuals ranging in age from 50 to 70 years (n = 216), which limited the age difference between groups to 2.4 years. In these supplementary analyses, the association between WMH volume and total learning score was slightly attenuated (within the CI of the association reported above), but our findings were otherwise the same.

Discussion

In this large community-based study with 24-hour ambulatory blood pressure monitoring, we examined the effects of 2 related vascular risk factors, hypertension and dipping status, on small vessel cerebrovascular disease and memory. Consistent with the results of previous studies,1,2,5,6,18,47 individuals with hypertension had elevated periventricular WMH volumes, but not deep WMH volumes, compared with individuals without hypertension. An increased nocturnal dipping profile was associated with an increase in WMH volume, particularly in hypertensive individuals. When defined categorically, dipping status did not show an independent relationship with WMH volume, as some previous studies reported.1,47 However, categorically defined dipping status did moderate the effect of hypertension: reverse dippers—those who experience a nocturnal increase in blood pressure—with hypertension as a group had a >2-fold increase in WMH volume compared with all other groups examined. The findings point to the relevance of nocturnal blood pressure status in cerebral vascular health.

We observed a similar relationship of hypertension and dipping status on cognition: reverse dippers with hypertension demonstrated lower cognitive test scores than dippers and nondippers. Although nondipping has not been linked to small vessel cerebrovascular disease,1,2,47 a growing body of literature ties reverse dipping to other vascular morbidities,7,17,48,49 particularly in the presence of hypertension.48,49 The results presented here suggest that the co-occurrence of reverse dipping and hypertension may greatly increase the likelihood or severity of small vessel cerebrovascular disease, indicating that dipping status can moderate the effects of hypertension and that reverse dipping can amplify the effects of hypertension on cerebrovascular health. Our results also indicate that reverse dipping may be particularly pernicious with respect to small vessel cerebrovascular disease and memory function.

We observed an interaction between hypertension and dipping status on memory, which was present in the absence of main effects of either hypertension or dipping status. This observation suggests that the co-occurrence of these conditions, rather than the presence of either one individually, promotes the effects of small vessel cerebrovascular disease on memory, a finding not characterized previously. We did not observe an effect of dipping status and hypertension on other cognitive domains. While cognitive impairment associated with vascular disease has historically been conceptualized to affect primarily executive functioning, there is also a well-established link with vascular brain health and memory functioning.4,50 Given our previous work linking WMH to risk and progression of Alzheimer disease, a disease typically characterized clinically by an amnestic syndrome, memory function was our a priori hypothesis and primary interest in the current study.

When we examined hypertensive and dipping profiles continuously rather than characterizing participants categorically, we found that a higher nocturnal dipping profile, indicating the presence of a nondipping or reverse dipping, was associated with an increase in WMH volume and a decrease in memory in hypertensive individuals. We also demonstrated that periventricular WMH volume mediated the relationship between the vascular variables and memory, supporting the causal pathway in which hypertension and dipping status interact to increase WMH accumulation, which, in turn, promotes memory decline. Given the cross-sectional design of our study, we are unable to prove the causal pathway we proposed. However, the results are consistent with our hypothesized causal model of hypertension and dipping status interacting to promote small vessel cerebrovascular disease and associated memory dysfunction. Longitudinal studies will help clarify the time course and more definitely establish causality.

All participants were middle-aged to older adults, so the relationships established in this study can be generalized only to this age stratum. Furthermore, although age was related to all outcomes studied, we adjusted for age and conducted additional sensitivity analyses with restricted age. We did not observe any effects of sex/gender, and observed dipping effects were independent of 24-hour blood pressure. Together, these analyses suggest that our observations were not attributable to age differences between those with and those without hypertension and that dipping status is associated with markers of cerebrovascular disease above and beyond blood pressure alone.

Our study is unique in that it is a large, community-based cohort of participants selected only on the basis of age, with a special focus on late middle age, an advantage shared by few other studies.2 A number of the other studies examining similar variables included participants from various clinical settings,6,17,48 and most studies examining WMH volume or cognition with respect to diurnal blood pressure variation enrolled participants because they had hypertension.1,4,11,16,47,48 In the current study, we examined the effects of dipping status and hypertension on WMH volume and memory in a large community-based sample of Venezuelan adults. The consideration of other vascular comorbidities is important because reverse dipping frequently occurs concurrently with hypertension. While the exact causes of nondipping and reverse dipping remain unknown, the collection of ambulatory blood pressure measurements allows better clinical monitoring and is gradually being adopted as a more accurate alternative to standard clinical measures.4,6,49

In this community-based cohort study, we examined the effects of dipping status and hypertension on small vessel cerebrovascular disease and memory. We found that an increased dipping profile, particularly reverse dipping, was associated with an increase in cerebrovascular disease and a poorer memory functioning in hypertensive participants. Our results point toward the importance of reverse dipping as a potentially pathognomonic driver of small vessel cerebrovascular disease, particularly in the presence of hypertension, and add to the mounting evidence showing the importance of vascular contributions to memory decline.

Glossary

CDR

Clinical Dementia Rating

CI

confidence interval

IED

Intra-Extra Dimensional Set Shift

MAS

Maracaibo Aging Study

PAL

Paired Associated Learning

RTI

Reaction Time

WMH

white matter hyperintensities

Appendix. Authors

Appendix.

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Footnotes

Study funding

Supported by NIH (R01AG036469).

Disclosure

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

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Associated Data

This section collects any data citations, data availability statements, or supplementary materials included in this article.

Data Availability Statement

Requests for access to the data used in this study will be considered on a case-by-case basis.

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