Ambulatory Hypertension Subtypes and 24-Hour Systolic and Diastolic Blood Pressure as Distinct Outcome Predictors in 8341 Untreated People Recruited From 12 Populations

Yan Li; Fang-Fei Wei; Lutgarde Thijs; José Boggia; Kei Asayama; Tine W Hansen; Masahiro Kikuya; Kristina Björklund-Bodegård; Takayoshi Ohkubo; Jørgen Jeppesen; Yu-Mei Gu; Christian Torp-Pedersen; Eamon Dolan; Yan-Ping Liu; Tatiana Kuznetsova; Katarzyna Stolarz-Skrzypek; Valérie Tikhonoff; Sofia Malyutina; Edoardo Casiglia; Yuri Nikitin; Lars Lind; Edgardo Sandoya; Kalina Kawecka-Jaszcz; Luis Mena; Gladys E Maestre; Jan Filipovský; Yutaka Imai; Eoin O’Brien; Ji-Guang Wang; Jan A Staessen

doi:10.1161/CIRCULATIONAHA.113.004876

. Author manuscript; available in PMC: 2015 Apr 29.

Published in final edited form as: Circulation. 2014 Jun 6;130(6):466–474. doi: 10.1161/CIRCULATIONAHA.113.004876

Ambulatory Hypertension Subtypes and 24-Hour Systolic and Diastolic Blood Pressure as Distinct Outcome Predictors in 8341 Untreated People Recruited From 12 Populations

Yan Li

Yan Li, MD, PhD

¹Center for Epidemiological Studies and Clinical Trials and Center for Vascular Evaluations, Shanghai Institute of Hypertension, Shanghai Key Laboratory of Hypertension, Ruijin Hospital, Shanghai Jiaotong University School of Medicine, Shanghai, China (Y.L., F.-F.W., J.-G.W.); Studies Coordinating Centre, Research Unit Hypertension and Cardiovascular Epidemiology, KU Leuven Department of Cardiovascular Sciences, University of Leuven, Belgium (L.T., Y.-M.G., Y.-P.L., T.K., J.A.S.); Centro de Nefrología and Departamento de Fisiopatología, Hospital de Clínicas, Universidad de la República, Montevideo, Uruguay (J.B.); Tohoku University Graduate School of Pharmaceutical Sciences and Medicine, Sendai, Japan (K.A., M.K., T.O., Y.I.); Department of Hygiene and Public Health, Teikyo University School of Medicine, Tokyo, Japan (K.A., T.O.); Research Center for Prevention and Health and Steno Diabetes Center, Gentofte, Denmark (T.W.H.); Division of Cardiovascular Medicine, Department of Clinical Sciences, Danderyd Hospital, Karolinska Institutet, Stockholm, Sweden (K.B.-B.); Department of Medicine, Glostrup Hopsital, University of Copenhagen, Copenhagen, Denmark (J.J.); Copenhagen University Hospital, Copenhagen, Denmark (C.-T.P.); Cambridge University Hospitals, Addenbrook’s Hospital, Cambridge, United Kingdom (E.D.); First Department of Cardiology, Interventional Electrocardiology and Hypertension, Jagiellonian University Medical College, Kraków, Poland (K.S.-S., K.K.-J.); Department of Clinical and Experimental Medicine, University of Padova, Padova, Italy (V.T., E.C.); Institute of Internal Medicine, Novosibirsk, Russian Federation (S.M., Y.N.); Section of Geriatrics, Department of Public Health and Caring Sciences, Uppsala University, Uppsala, Sweden (L.L.); Asociación Española Primera de Socorros Mutuos, Montevideo, Uruguay (E.S.); Laboratorio de Neurociencias and Instituto Cardiovascular, Universidad del Zulia, Maracaibo, Venezuela (L.M., G.E.M.); Faculty of Medicine, Charles University, Pilsen, Czech Republic (J.F.); Conway Institute of Biomolecular and Biomedical Research, University College Dublin, Dublin, Ireland (E.O.); and the Department of Epidemiology, Maastricht University, Maastricht, The Netherlands (J.A.S.)

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¹, Fang-Fei Wei

Fang-Fei Wei, MD

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¹, Lutgarde Thijs

Lutgarde Thijs, MSc

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¹, José Boggia

José Boggia, MD, PhD

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¹, Kei Asayama

Kei Asayama, MD, PhD

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¹, Tine W Hansen

Tine W Hansen, MD, PhD

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¹, Masahiro Kikuya

Masahiro Kikuya, MD, PhD

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¹, Kristina Björklund-Bodegård

Kristina Björklund-Bodegård, MD, PhD

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¹, Takayoshi Ohkubo

Takayoshi Ohkubo, MD, PhD

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¹, Jørgen Jeppesen

Jørgen Jeppesen, MD

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¹, Yu-Mei Gu

Yu-Mei Gu, MD

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¹, Christian Torp-Pedersen

Christian Torp-Pedersen, MD, PhD

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¹, Eamon Dolan

Eamon Dolan, MD, PhD

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¹, Yan-Ping Liu

Yan-Ping Liu, MD

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¹, Tatiana Kuznetsova

Sofia Malyutina, MD, PhD

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¹, Edoardo Casiglia

Edoardo Casiglia, MD, PhD

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¹, Yuri Nikitin

Yuri Nikitin, MD, PhD

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¹, Lars Lind

Lars Lind, MD, PhD

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¹, Edgardo Sandoya

Edgardo Sandoya, MD, PhD

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¹, Kalina Kawecka-Jaszcz

Kalina Kawecka-Jaszcz, MD, PhD

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¹, Luis Mena

Luis Mena, MD

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¹, Gladys E Maestre

Gladys E Maestre, MD, PhD

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¹, Jan Filipovský

Jan Filipovský, MD, PhD

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¹, Yutaka Imai

Yutaka Imai, MD, PhD

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¹, Eoin O’Brien

Eoin O’Brien, MD, PhD

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¹, Ji-Guang Wang

Ji-Guang Wang, MD, PhD

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¹, Jan A Staessen

Jan A Staessen, MD, PhD

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¹, on behalf of the International Database on Ambulatory blood pressure in relation to Cardiovascular Outcomes (IDACO) Investigators

^✉

Correspondence to Jan A. Staessen, MD, PhD, Studies Coordinating Centre, Research Unit Hypertension and Cardiovascular Epidemiology, KU Leuven Department of Cardiovascular Sciences, University of Leuven, Campus Sint Rafaël, Kapucijnenvoer 35, Box 7001, BE-3000 Leuven, Belgium. jan.staessen@med.kuleuven.be or ja.staessen@maastrichtuniversity.nl

PMCID: PMC4414316 NIHMSID: NIHMS682765 PMID: 24906822

Abstract

Background

Data on risk associated with 24-hour ambulatory diastolic (DBP₂₄) versus systolic (SBP₂₄) blood pressure are scarce.

Methods and Results

We recorded 24-hour blood pressure and health outcomes in 8341 untreated people (mean age, 50.8 years; 46.6% women) randomly recruited from 12 populations. We computed hazard ratios (HRs) using multivariable-adjusted Cox regression. Over 11.2 years (median), 927 (11.1%) participants died, 356 (4.3%) from cardiovascular causes, and 744 (8.9%) experienced a fatal or nonfatal cardiovascular event. Isolated diastolic hypertension (DBP₂₄≥80 mm Hg) did not increase the risk of total mortality, cardiovascular mortality, or stroke (HRs≤1.54; P≥0.18), but was associated with a higher risk of fatal combined with nonfatal cardiovascular, cardiac, or coronary events (HRs≥1.75; P≤0.0054). Isolated systolic hypertension (SBP₂₄≥130 mm Hg) and mixed diastolic plus systolic hypertension were associated with increased risks of all aforementioned end points (P≤0.0012). Below age 50, DBP₂₄ was the main driver of risk, reaching significance for total (HR for 1-SD increase, 2.05; P=0.0039) and cardiovascular mortality (HR, 4.07; P=0.0032) and for all cardiovascular end points combined (HR, 1.74; P=0.039) with a nonsignificant contribution of SBP₂₄ (HR≤0.92; P≥0.068); above age 50, SBP₂₄ predicted all end points (HR≥1.19; P≤0.0002) with a nonsignificant contribution of DBP₂₄ (0.96≤HR≤1.14; P≥0.10). The interactions of age with SBP₂₄ and DBP₂₄ were significant for all cardiovascular and coronary events (P≤0.043).

Conclusions

The risks conferred by DBP₂₄ and SBP₂₄ are age dependent. DBP₂₄ and isolated diastolic hypertension drive coronary complications below age 50, whereas above age 50 SBP₂₄ and isolated systolic and mixed hypertension are the predominant risk factors.

Keywords: ambulatory blood pressure monitoring, blood pressure component, cardiovascular diseases, population

Hypertension remains the predominant driver of cardiovascular disease. In 2001, hypertension caused 8 million deaths worldwide, representing 14% of global mortality.¹ In an individual-subject meta-analysis of close to 1 million people, the risk of coronary heart disease and stroke gradually increased with blood pressure from levels as low as 115 mm Hg systolic and 75 mm Hg diastolic.² The Framingham investigators^3,4 and other researchers⁵ showed in studies published as early as 1971 that diastolic pressure was the strongest predictor of coronary heart disease below age 50 with an increase in the importance of systolic blood pressure with advancing age.

Using blood pressure levels of 140 mm Hg systolic and 90 mm Hg diastolic, current guidelines subdivide hypertension on conventional sphygmomanometry into isolated diastolic, isolated systolic, and diastolic combined with systolic (mixed) hypertension.⁶ Several population studies have demonstrated that isolated diastolic hypertension confers a cardiovascular risk that was intermediate between normotension and isolated systolic or mixed hypertension.^7,8 Compared with conventional sphygmomanometry, ambulatory blood pressure monitoring substantially refines risk stratification.⁹ To our knowledge, no previous study has assessed the risks associated with isolated diastolic, isolated systolic, and mixed hypertension on 24-hour ambulatory monitoring or examined the age dependency of 24-hour diastolic and systolic ambulatory blood pressure as independent risk factors in the general population. We addressed these issues by analyzing the International Database on Ambulatory blood pressure in relation to Cardiovascular Outcomes (IDACO).¹⁰

Methods

Study Population

At the time of writing this report, the IDACO database¹⁰ included 12 randomly recruited population cohorts^11–20 and 12 711 participants with available data on the conventional and ambulatory blood pressure. All participants gave informed written consent. We excluded participants if they were younger than 18 years (n=303), if they were taking antihypertensive drugs at baseline (n=2144), or if they had <10 daytime or 5 nighttime blood pressure readings (n=1923). Thus, the number of subjects included in the present analysis totaled 8341. (for details, see the Expanded Methods and Table I in the online-only Data Supplement).

Blood Pressure Measurement

Methods used for conventional and ambulatory blood pressure measurement are described in detail in the Expanded Methods in the online-only Data Supplement. Conventional blood pressure was the average of 2 consecutive readings. Portable monitors were programmed to obtain ambulatory blood pressure readings at 30-minute intervals throughout the whole day,^12,19 or at intervals ranging from 15^11,17,18 to 30^12,19 minutes during daytime and from 30^{11,12,17–19} to 60¹⁴ minutes at night. To categorize levels of the ambulatory blood pressure, we followed the guidelines of the European Societies of Cardiology and Hypertension.⁶ Ambulatory hypertension was a 24-hour level of ≥130 mm Hg systolic or ≥80 mm Hg diastolic. Using these thresholds, we categorized participants as being normotensive, or as having isolated diastolic, isolated systolic, or mixed hypertension on 24-hour ambulatory monitoring.

Other Measurements

We used the questionnaires originally administered in each cohort to obtain information on each participant’s medical history and smoking and drinking habits. Body mass index was body weight in kilograms divided by height in meters squared. We measured serum cholesterol and blood glucose by automated enzymatic methods. Diabetes mellitus was the use of antidiabetic drugs, a fasting glucose of ≥7.0 mmol/L,²¹ a random glucose of ≥11.1 mmol/L,²¹ a self-reported diagnosis, or diabetes mellitus documented in practice or hospital records.

Ascertainment of Events

We ascertained vital status and the incidence of fatal and nonfatal diseases from the appropriate sources in each country, as described in previous publications.^10,22 In most cohorts,^11–18 information on vital status was obtained, even if participants dropped out from follow-up. Outcomes were coded according to the international classification of diseases, as described in the Expanded Methods in the online-only Data Supplement. Fatal and nonfatal stroke did not include transient ischemic attacks. Coronary events encompassed death from ischemic heart disease, sudden death, nonfatal myocardial infarction, and coronary revascularization. Cardiac events comprised coronary end points and fatal and nonfatal heart failure. Hospitalizations for unstable angina were coded as ischemic heart disease. In the Danish¹¹ and Swedish¹⁴ cohorts, the diagnosis of heart failure required admission to hospital. In the other cohorts,^{12,13,15–20} heart failure was either a clinical diagnosis or the diagnosis on the death certificate, but in all cases it was validated against hospital files or the records held by family doctors. The composite cardiovascular end point included all aforementioned end points plus cardiovascular mortality. In analyses of fatal combined with nonfatal outcomes, we only considered the first event within each disease cluster.

Statistical Analysis

For database management and statistical analysis, we used SAS software, version 9.3 (SAS Institute, Cary, NC). Missing data were imputed using cohort- and sex-specific regression equations with age as explanatory variable (for details, see the Expanded Methods and Table II in the online-only Data Supplement). We tabulated the incidence of end points by blood pressure status on ambulatory measurement. We computed 95% confidence intervals (CIs) of rates as R±1.96 × √(R/T), where R and T are the rate and the denominator used to calculate the rate. We compared means and rates using the large-sample z test and proportions by the χ² statistic, respectively. We plotted the incidence of end points across categories of the ambulatory blood pressure, using Cox models standardized to the sex distribution and mean age in the whole study population. We compared hazard ratios (HRs) between categories of the ambulatory blood pressure using the Wald χ² statistic.

In multivariable-adjusted Cox regression analyses, we accounted for cohort, sex, age, body mass index, smoking and drinking, serum cholesterol, history of cardiovascular disease, and diabetes mellitus. To adjust for cohort, we pooled participants recruited in the European Project on Genes in Hypertension (Kraków, Novosibirsk, Padova, and Pilsen).¹⁸ We ascertained that the proportional hazard assumption was fulfilled by testing the interaction between blood pressure and follow-up time. We compared hazard ratios between subgroups according to age, sex, or ethnicity, using the appropriate interaction terms. To assess the prognostic significance of diastolic blood pressure at different levels of systolic blood pressure, and vice versa, we modeled the 10-year absolute risk of a composite cardiovascular end point using Cox regression, while standardizing to the average of the distributions in the whole study population (mean or ratio) of cohort, sex, age, body mass index, smoking and drinking, serum cholesterol, history of cardiovascular disease, and diabetes mellitus. Statistical significance was a α-level <0.05 on 2-sided tests.

Results

Baseline Characteristics

The 8341 participants included 5489 Europeans (65.8%), 1280 Asians (15.3%), and 1572 South Americans (18.9%), and 3888 women (46.6%). Age ranged from 18 to 94 years and averaged (±SD) 50.8±15.8 years. At enrollment, 2474 participants (29.7%) were smokers and 4061 (48.7%) reported intake of alcohol. In the whole study population, conventional blood pressure averaged (±SD) 128.7±21.4 mm Hg systolic and 78.6±11.3 mm Hg diastolic, whereas the 24-hour ambulatory blood pressure was 122.1±13.5 mm Hg systolic and 73.1±8.2 mm Hg diastolic.

Table 1 shows the participants’ baseline characteristics by categories of the 24-hour ambulatory blood pressure. Normotensive participants and patients with isolated diastolic hypertension had similar characteristics except for the proportion of women (52.6 versus 36.5%) and drinkers (45.0 versus 54.4%), and body mass index (24.5 versus 25.9 kg/m²) and serum cholesterol (5.48 versus 5.67 mmol/L). Patients with mixed or isolated systolic hypertension were older, more obese, had higher serum cholesterol and blood glucose levels, and were more likely to be diabetic than those with isolated diastolic hypertension (Table 1). The proportions of isolated diastolic, isolated systolic, and mixed hypertension were 5.9%, 3.9%, and 6.1%, respectively, among younger participants (aged <50 years), whereas the corresponding frequencies were 4.1%, 16.3%, and 18.4% among older adults (aged ≥50 years).

Table 1.

Baseline Characteristics of Participants by Categories of 24-Hour Ambulatory Blood Pressure

Characteristic	Normotension	Isolated Diastolic Hypertension	Mixed Hypertension	Isolated Systolic Hypertension
Number of subjects	5969	408	1071	893
European, (%)	3908 (65.5)^‡	221 (54.2)	720 (67.2)^‡	640 (71.7)^‡
Asian, (%)	983 (16.5)	55 (13.5)	140 (13.1)	102 (11.4)
South American, (%)	1078 (18.1)^‡	132 (32.4)	211 (19.7)^‡	151 (16.9)^‡
Women, (%)	3141 (52.6)^‡	149 (36.5)	315 (29.4)^†	283 (31.7)
Smokers, (%)	1741 (29.2)	132 (32.4)	348 (32.5)	253 (28.3)
Drinking alcohol, (%)	2684 (45.0)^‡	222 (54.4)	652 (60.9)^†	503 (56.3)
Diabetes mellitus, (%)	266 (4.5)	23 (5.6)	89 (8.3)	92 (10.3)^†
Cardiovascular disorders, (%)	243 (4.1)	23 (5.6)	59 (5.5)	67 (7.5)
Mean characteristic (SD)
Age, y	47.9 (15.7)	48.7 (11.4)	58.0 (12.0)^‡	62.3 (13.8)^‡
Body mass index, kg/m²	24.5 (3.9)^‡	25.9 (4.2)	26.6 (4.2)^†	26.5 (4.4)^*
Conventional blood pressure
Systolic, mm Hg	121.7 (16.3)	131.5 (13.2)	151.3 (22.8)	146.8 (22.8)
Diastolic, mm Hg	75.1 (9.3)	86.6 (8.2)	92.0 (10.9)	82.0 (10.3)
24-hour blood pressure
Systolic, mm Hg	115.7 (7.9)	124.5 (4.0)	143.6 (11.4)	137.6 (7.8)
Diastolic, mm Hg	69.6 (5.3)	82.9 (2.7)	87.2 (6.0)	74.5 (4.1)
Blood glucose, mmol/L	5.03 (1.17)	5.11 (1.25)	5.44 (1.66)^†	5.45 (1.64)^†
Serum cholesterol, mmol/L	5.48 (1.13)^†	5.67 (1.13)	5.78 (1.14)	5.86 (1.14)^†

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Hypertension was a 24-hour ambulatory blood pressure ≥130 mm Hg or 80 mm Hg diastolic. Mixed hypertension refers to diastolic combined with systolic hypertension. Significance of the difference with isolated diastolic hypertension:

P≤0.05;

^†

P≤0.01; and

^‡

P≤0.001. Significance levels were not calculated for blood pressure values, used to categorize participants.

Incidence of Events

In the whole study population, median follow-up was 11.2 years (5th to 95th percentile interval, 2.5 –18.2). Across cohorts, median follow-up ranged from 2.5 years (2.3–2.6) in Jingning to 17.2 years (5.3–20.4) in Noorderkempen. During 92 379 person-years of follow-up, 927 participants died (10.0 per 1000 person-years) and 744 experienced a fatal or nonfatal cardiovascular event (8.25 per 1000 person-years). Mortality included 356 cardiovascular and 548 non-cardiovascular deaths and 23 deaths from unknown cause. Considering cause-specific first cardiovascular events, the incidence of fatal and nonfatal stroke amounted to 78 and 203, respectively. Cardiac events consisted of 216 fatal and 425 nonfatal events, including 90 fatal and 141 nonfatal cases of acute myocardial infarction, 122 deaths from ischemic heart disease, 56 sudden deaths, 37 fatal and 140 nonfatal cases of heart failure, and 71 cases of surgical or percutaneous coronary revascularization.

Risk by Categories of Ambulatory Blood Pressure

Median years of follow-up (5th to 95th percentile interval) amounted to 11.4 (2.6–18.3), 9.7 (2.4–18.2), 11.0 (2.7–17.3), and 10.8 (2.5–17.8) in normotensive individuals and in patients with isolated diastolic, isolated systolic, and mixed hypertension, respectively. Table 2 shows that the incidence rates were similar (P≥0.13) in normotensive participants and in patients with isolated diastolic hypertension except for cardiac end points (3.1 versus 5.9 events per 1000 person-years; P=0.021) and coronary events (2.2 versus 4.6 events per 1000 person-years; P=0.024). Compared with isolated diastolic hypertension, event rates were higher (P<0.001) in patients with mixed or isolated systolic hypertension. After standardization to the sex distribution (46.6% women) and mean age (50.8 years) in the whole study population, the incidence of a composite cardiovascular end point gradually increased from normotension, over isolated diastolic hypertension onto isolated systolic and mixed hypertension (Figure 1). Detailed information on the number of participants at risk, those retained in the analysis, and those with a cardiovascular (Table III in the online-only Data Supplement) or cardiac (Table IV in the online-only Data Supplement) end point is available by 2-year intervals in the online Data Supplement.

Table 2.

Incidence of End Points by Categories of 24-Hour Ambulatory Blood Pressure

End Point	Normotension	Isolated Diastolic Hypertension	Mixed Hypertension	Isolated Systolic Hypertension
Number of participants	5969	408	1071	893
Total mortality
Number of deaths	493	25	204	205
Rate	7.3 (6.6–7.9)	6.0 (3.6–8.3)	18.3 (15.8–20.8)^‡	22.0 (19.0–25.0)^‡
Cardiovascular mortality
Number of deaths	151	11	101	93
Rate	2.2 (1.9–2.6)	2.6 (1.1–4.2)	9.1 (7.3–10.8)^‡	10.0 (7.9–12.0)^‡
Noncardiovascular mortality
Number of deaths	328	14	100	106
Rate	4.8 (4.3–5.4)	3.4 (1.6–5.1)	9.0 (7.2–10.7)^‡	11.4 (9.2–13.5)^‡
All cardiovascular events
Number of events	329	28	200	187
Rate	4.9 (4.4–5.5)	6.8 (4.3–9.4)	18.9 (16.3–21.5)^‡	21.1 (18.1–24.1)^‡
Cardiac events
Number of events	211	24	124	118
Rate	3.1 (2.7–3.6)^*	5.9 (3.5–8.2)	11.5 (9.5–13.5)^‡	13.1 (10.7–15.4)^‡
Coronary events
Number of events	151	19	91	87
Rate	2.2 (1.9–2.6)^*	4.6 (2.5–6.7)	8.3 (6.6–10.0)^‡	9.5 (7.5–11.5)^‡
Stroke
Number of events	106	5	76	69
Rate	1.6 (1.3–1.9)	1.2 (0.1–2.3)	7.0 (5.4–8.6)^‡	7.6 (5.8–9.3)^‡

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Hypertension was a 24-hour ambulatory blood pressure ≥130 mm Hg systolic or 80 mm Hg diastolic. Incidence rates reflect the number of events per 1000 person-years. Significance of the difference with isolated diastolic hypertension:

P≤0.05; and

^‡

P≤0.001.

Incidence of the composite cardiovascular (CV) end point (A) and fatal combined with nonfatal cardiac events (B) in 4 categories of the ambulatory blood pressure. Incidence was standardized to the sex distribution (46.6% women) and mean age (50.8 years) in the whole study population. For each blood pressure category, the number of subjects at risk is given at the beginning of each 4-year interval. The time axis was curtailed at 16 years when ≈10% of participants were still being followed up. Tables III and IV in the online-only Data Supplement provide more detailed information by 2-year intervals up to 22 years on the number of participants at risk, the number of events, and the number of participants no longer followed up. Vertical bars denote the standard error. P values are for the differences across the 4 blood pressure categories.

In further multivariable-adjusted analyses with normotension as reference (Table 3), isolated diastolic hypertension did not increase the risk of total and cardiovascular mortality or stroke (HRs ≤1.54; P≥0.18), but was associated with a higher risk of a composite cardiovascular end point and of fatal combined with nonfatal cardiac and coronary events (HRs ≥1.75; P≤0.0054). With normotension as reference, both mixed and isolated systolic hypertension were associated with an increased risk of all end points under study (P≤0.0012) with the exception of noncardiovascular mortality (P≥0.096). The HRs were significantly higher (P≤0.046) in patients with mixed hypertension than in those with isolated systolic hypertension, except for fatal combined with nonfatal cardiac (P=0.065) and coronary events (P=0.17).

Table 3.

Multivariable-Adjusted Hazard Ratios Associated With Isolated Diastolic, Isolated Systolic, and Mixed Ambulatory Hypertension

End Point (Number of End Points)	Isolated Diastolic Hypertension	P	Mixed Hypertension	P	Isolated Systolic Hypertension	P
Mortality
Total (927)	1.14 (0.76–1.71)	0.54	1.63 (1.37–1.93)	<0.0001	1.33 (1.12–1.57)	0.0012
Cardiovascular (356)	1.54 (0.82–2.87)	0.18	2.49 (1.91–3.25)	<0.0001	1.86 (1.42–2.44)	<0.0001
Noncardiovascular (548)	1.00 (0.58–1.72)	0.99	1.22 (0.97–1.53)	0.096	1.05 (0.84–1.32)	0.66
Fatal and nonfatal events combined
All cardiovascular (744)	1.75 (1.18–2.59)	0.0054	2.44 (2.03–2.93)	<0.0001	1.81 (1.50–2.19)	<0.0001
Cardiac (477)	1.96 (1.28–3.01)	0.0022	2.16 (1.72–2.73)	<0.0001	1.70 (1.34–2.16)	<0.0001
Coronary (348)	2.00 (1.23–3.25)	0.0052	2.19 (1.67–2.87)	<0.0001	1.77 (1.34–2.35)	<0.0001
Stroke (256)	1.33 (0.53–3.33)	0.54	3.06 (2.25–4.16)	<0.0001	2.13 (1.55–2.92)	<0.0001

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Ambulatory normotension is the referent group. All models were adjusted for cohort, sex, age, body mass index, smoking and drinking, serum cholesterol, history of cardiovascular disease, and diabetes mellitus. The cause of death was unknown in 23 cases.

Risks Associated with Diastolic and Systolic Blood Pressures

In line with previous publications based on the conventionally measured blood pressure,^4–6 we stratified our multivariable-adjusted analyses by age group (<50 and ≥50 years, Table 4). Median years of follow-up (5th to 95th percentile interval) amounted to 12.1 (2.5–18.6) and 11.1 (2.6–17.6) in younger and older participants, respectively. In younger participants, in fully adjusted models, which included both diastolic and systolic blood pressure, diastolic blood pressure predicted total (HR for 1-SD increase, 2.05; P=0.0039) and cardiovascular mortality (HR, 4.07; P=0.0032) and the composite cardiovascular end point (HR, 1.74; P=0.039), whereas 24-hour systolic blood pressure was not significantly associated with these end points (HR, ≤0.92; P≥0.068; Table 4). In older participants, systolic pressure predicted total and cardiovascular mortality and all of the end points combining fatal with nonfatal events (HR, ≥1.19; P≤0.0002), whereas diastolic pressure did not significantly predict any outcome (0.96≤HR≤1.14; P≥0.10). Analyses based on daytime (Table V in the online-only Data Supplement) or nighttime (Table VI in the online-only Data Supplement) blood pressure, or restricted to the 7949 subjects free of cardiovascular disease at baseline (Table VII in the online-only Data Supplement), or excluding 1 cohort at a time (Table VIII in the online-only Data Supplement), confirmed the results given in Table 4. Compared with the conventional blood pressure, 24-hour diastolic and systolic pressure retained their predictive superiority in all participants (Table IX in the online-only Data Supplement) as well as in categories based on blood pressure status on conventional measurement (online-only Data Supplement, pages 5–6).

Table 4.

Multivariable-Adjusted Standardized Hazard Ratios for 24-Hour Systolic and Diastolic Blood Pressures by Age Group

End Point		<50 years (n=3761)			≥50 years (n=4580)
End Point		n	Diastolic Pressure	Systolic Pressure	n	Diastolic Pressure	Systolic Pressure
Mortality
Total	A	64	1.38 (1.08–1.77)^†	1.20 (0.86–1.66)	863	1.17 (1.10–1.25)^‡	1.21 (1.14–1.29)^‡
Total	FA		2.05 (1.26–3.33)^†	0.56 (0.30–1.05)		1.03 (0.94–1.13)	1.19 (1.08–1.30)^‡
Cardiovascular	A	16	2.34 (1.61–3.39)^‡	2.23 (1.32–3.78)^†	340	1.31 (1.18–1.44)^‡	1.47 (1.35–1.61)^‡
Cardiovascular	FA		4.07 (1.60–10.4)^†	0.44 (0.13–1.56)		0.96 (0.85–1.10)	1.51 (1.34–1.70)^‡
Noncardiovascular	A	46	1.13 (0.83–1.55)	0.93 (0.61–1.42)	502	1.06 (0.97–1.16)	1.03 (0.94–1.12)
Noncardiovascular	FA		1.73 (0.96–3.12)	0.53 (0.25–1.13)		1.09 (0.95–1.25)	0.96 (0.84–1.10)
Fatal plus nonfatal events
All cardiovascular	A	47	1.65 (1.27–2.14)^‡	1.68 (1.19–2.36)^†	697	1.36 (1.27–1.46)^‡	1.44 (1.35–1.53)^‡
All cardiovascular	FA		1.74 (1.03–2.93)^*	0.92 (0.47–1.81)		1.06 (0.97–1.17)	1.39 (1.27–1.51)^‡
Cardiac	A	37	1.53 (1.12–2.08)^†	1.52 (1.01–2.27)^*	440	1.26 (1.16–1.38)^‡	1.37 (1.26–1.48)^‡
Cardiac	FA		1.67 (0.92–3.03)	0.88 (0.40–1.90)		1.01 (0.90–1.14)	1.36 (1.22–1.52)^‡
Coronary	A	28	1.63 (1.16–2.30)^†	1.67 (1.07–2.62)^*	320	1.25 (1.13–1.38)^‡	1.35 (1.23–1.48)^‡
Coronary	FA		1.73 (0.87–3.45)	0.92 (0.37–2.24)		1.01 (0.88–1.15)	1.35 (1.18–1.53)^‡
Stroke	A	7	2.31 (1.25–4.27)^†	2.43 (1.12–5.26)^*	249	1.61 (1.43–1.81)^‡	1.65 (1.49–1.83)^‡
Stroke	FA		2.24 (0.62–8.20)	1.04 (0.21–5.26)		1.14 (0.97–1.34)	1.52 (1.32–1.76)^‡

Open in a new tab

n indicates the number of events. The cause of death was unknown in 23 cases. Hazard ratios, presented with 95% confidence interval, express the risk associated with a 1-SD increase in 24-hour systolic (13.5 mm Hg) or diastolic (8.2 mm Hg) blood pressures. All models were adjusted for cohort, sex, age, body mass index, smoking and drinking, serum cholesterol, history of cardiovascular disease, and diabetes mellitus. Adjusted models (A) include either systolic or diastolic blood pressure, whereas fully adjusted models (FA) include both systolic and diastolic blood pressures in addition to the aforementioned covariables. Significance of the hazard ratios:

P≤0.05;

^†

P≤0.01, and

^‡

P≤0.001. The interactions of diastolic and systolic pressure with age (continuous) in fully adjusted models were significant or borderline significant for cardiovascular mortality (0.036≤P≤0.058), all cardiovascular events (0.0037≤P≤0.0048), and coronary events (0.012≤P≤0.043).

Next, based on the data given in Table 4, we tested the interactions of 24-hour systolic and diastolic blood pressures with age, ethnicity, and sex. Using age as a continuous variable, the interaction terms with diastolic and systolic pressure in fully adjusted models were significant or borderline significant for cardiovascular mortality (0.036≤P≤0.058), the composite cardiovascular end point (0.0037≤P≤0.0048), and coronary events (0.012≤P≤0.043). When excluding 1 cohort at a time (Table VIII in the online-only Data Supplement), the interactions with age consistently retained significance for the composite cardiovascular end point (0.0009≤P≤0.050). For cardiovascular mortality and coronary events the interactions of age with systolic and diastolic blood pressure remained formally or borderline significant (0.0079≤P≤0.093), but lost significance for cardiovascular mortality after excluding Ohasama, Jingning, or Noorderkempen (0.12≤P≤0.20) and for coronary events with Montevideo removed (0.10≤P≤0.15). The hazard ratios associated with systolic and diastolic blood pressure were similar in Asians and whites (Table X in the online-only Data Supplement). As reported previously,²² the hazard ratios associated with 24-hour systolic blood pressure were higher in women than men (Table XI in the online-only Data Supplement) for all cardiovascular end points (P≤0.019) with the exception of cardiovascular mortality (P=0.079) and stroke (P=0.64). For 24-hour diastolic blood pressure, the fully adjusted hazard ratios were similar in women and men (P≥0.45).

Finally, we used Cox regression to model the 10-year absolute risk of a composite cardiovascular end point in relation to 24-hour diastolic pressure at different levels of 24-hour systolic pressure and vice versa. Figure 2 shows that the 10-year risk of fatal combined with nonfatal cardiovascular events increased (P<0.001) with 24-hour diastolic pressure irrespective of the level of systolic pressure. Risk also increased with the 24-hour systolic pressure independent of the 24-hour diastolic pressure.

Ten-year absolute risk of a composite cardiovascular (CV) end point associated with 24-hour diastolic blood pressure (DBP, A) and 24-hour systolic blood pressure (SBP, B) in participants with normal (full line) or elevated (dashed line) systolic pressure (A) or normal or elevated diastolic pressure (B) on ambulatory measurement. The cut-off points for 24-hour hypertension were ≥130 mm Hg systolic and ≥80 mm Hg diastolic, respectively. For each risk function, the number (n) of subjects contributing to the risk function is given. In the Cox regression models, 10-year absolute risk was standardized to the average of the distributions in the whole study population (mean or ratio) of cohort, sex, age, body mass index, smoking and drinking, serum cholesterol, history of cardiovascular disease, and diabetes mellitus. Ne indicates the number of events in each group. P values denote the significance of the independent contribution of diastolic pressure (A) or systolic pressure (B).

Discussion

Our analysis included 8341 untreated people randomly recruited from 12 populations and covered on average >11 years of follow-up (median). The key finding was that the risks conferred by diastolic and systolic blood pressure as measured by noninvasive 24-hour ambulatory monitoring were age dependent. Diastolic pressure and isolated diastolic hypertension were the drivers of coronary complications, in particular below age 50 years, whereas above age 50 years systolic pressure and isolated systolic and mixed hypertension became the predominant determinants of risk.

Systolic pressure increases with age until the eighth decade of life.²³ By contrast, diastolic pressure rises only until 50 years of age, after which it becomes steady or even slightly decreases.²³ In the Framingham Heart Study,^3,4 increasing age entailed a shift from diastolic to systolic pressure as the main predictor of cardiovascular risk. Below age 50 years, diastolic pressure was the strongest predictor, whereas the opposite occurred above 50 years of age. Khattar and colleagues used intra-arterial ambulatory blood pressure monitoring in 688 untreated hypertensive patients and obtained similar findings.²⁴ Our current study, based on noninvasive 24-hour ambulatory blood pressure monitoring and the analysis of cause-specific outcomes in general populations, consolidated these findings.

Several studies based on conventional sphygmomanometry^25–27 or on the self-measured blood pressure at home²⁸ reported that isolated diastolic hypertension confers low cardiovascular risk, in particular at young age. The Honolulu Heart Program²⁵ reported on 8006 Japanese-American men followed for 20 years. Cutoff levels for diastolic and systolic hypertension were levels of 90 and 160 mm Hg, respectively. For men aged 45 to 54 years, the relative risks compared with normotension were 1.4 (95% CI, 1.0–2.1), 4.3 (2.9–6.3), and 4.8 (2.1–11.0) for isolated diastolic, mixed, and isolated systolic hypertension.²⁵ For men aged 55 to 68 years, the corresponding hazard ratios were 1.8 (1.3–2.5), 1.7 (1.2–2.4), and 1.2 (0.7–2.0), respectively.²⁵ Fang and colleagues²⁶ used the same blood pressure criteria as the Honolulu investigators to categorize systolic and diastolic hypertension in 1560 participants (<60 years) in a worksite hypertension control program. Over 4.5 years of follow-up, 24 participants got a myocardial infarction (3.9 events per 1000 person-years). The rate was higher in the patients with mixed hypertension than in those with isolated diastolic hypertension (5.2 versus 2.2 per 1000 patient-years).²⁶ No myocardial infarction occurred in participants with diastolic hypertension and a systolic blood pressure <140 mm Hg.²⁶ Strandberg and coworkers recruited 3267 initially healthy Finnish men, aged 30 to 45 years, and followed mortality for up to 32 years.²⁷ With normotension as reference (blood pressure <160 mm Hg systolic and <90 mm Hg diastolic), the hazard ratios for mortality were 2.71 (2.00–3.66) in patients with mixed hypertension, but only 1.39 (1.04–1.87) or 1.14 (0.77–1.69) in patients with isolated diastolic hypertension and systolic pressure between 140 and 160 mm Hg or <140 mm Hg, respectively.²⁷

The Ohasama investigators²⁸ followed 1913 participants aged 40 or older (average 61 years) for 8 years. The blood pressure thresholds based on home blood pressure were 137 mm Hg systolic and 84 mm Hg diastolic. The cardiovascular death rate was similar (0.33 versus 0.26 deaths per 100 person-years) in normotensive participants and in those with isolated diastolic hypertension. Patients with mixed or isolated systolic hypertension on self-measurement at home had significantly elevated death rates amounting to 1.11 and 2.04 per 100 person-years, respectively.

Several subject-level meta-analyses^2,7,8 addressed the role of systolic and diastolic blood pressure or various subtypes of hypertension as cardiovascular risk factors. All were based on conventional sphygmomanometry. Kelly and colleagues⁷ did a prospective cohort study (from 1991 until 2000) in a nationally representative sample of 169 577 Chinese women and men, aged 40 years or more. These investigators used blood pressure levels of 90 mm Hg diastolic and 140 mm Hg systolic to classify subjects. Compared with normotension, relative risks of cardiovascular disease incidence and mortality were 2.73 (2.60–2.86) and 2.53 (2.39–2.68) for combined systolic and diastolic hypertension, 1.78 (1.69–1.87) and 1.68 (1.58–1.78) for isolated systolic hypertension, and 1.59 (1.43–1.76) and 1.45 (1.27–1.65) for isolated diastolic hypertension.⁷ The Asia Pacific Cohort Studies Collaboration⁸ studied 346 570 participants from 36 cohort studies. Outcomes were fatal and nonfatal cardiovascular disease. In multivariable-adjusted Cox regression, with normal blood pressure (<80 mm Hg diastolic and 120 mm Hg systolic) as the reference, hazard ratios were 1.81 (1.61–2.04), 2.18 (2.00–2.37), and 3.42 (3.17–3.70) for isolated diastolic, isolated systolic, and mixed hypertension, respectively.⁸ The Prospective Studies Collaboration² demonstrated in 958 074 participants (61 cohort studies) that at ages 40 to 69 years, each 20-mm Hg increase in systolic blood pressure or 10-mm Hg increase in diastolic blood pressure was associated with more than a doubling in the death rates of stroke, ischemic heart disease, or other vascular death. These findings in subject-level meta-analyses with a large sample size are in keeping with our current study that made use of ambulatory blood pressure monitoring instead of conventional sphygmomanometry.

Our findings argue against the suggestion to abandon diastolic pressure measurement and to rely only on systolic blood pressure for the management of hypertension.²⁹ Moreover, reversibility of the risk by blood pressure lowering treatment in patients with isolated diastolic hypertension³⁰ confirms that certainly in younger individuals diastolic blood pressure is a risk factor that must be treated. The prevalence of isolated diastolic hypertension on 24-hour ambulatory blood pressure measurement was 4.9% in the whole untreated IDACO cohort and 17.2% among untreated patients with ambulatory hypertension. In the National Health Examination Survey (NHES) and National Health and Nutrition Examination Survey (NHANES) studies, 6% to 9% of subjects with elevated blood pressure readings had an isolated elevation of diastolic blood pressure with a normal systolic blood pressure.³¹

Our current study has some potential limitations. First, the number of end points in some subgroups was relatively small, in particular in the younger age group, in whom healthy elastic arteries might lead to a relatively less elevated systolic than diastolic blood pressure. Diastolic blood pressure is the driving force in the coronary circulation. This constellation might explain why diastolic hypertension is a risk factor for premature coronary heart disease and therefore for cardiac events below age 50. Second, patients with diastolic or mixed hypertension can progress to isolated systolic hypertension, so called burned-out hypertension, because with aging large arteries stiffen, so that systolic blood pressure rises and diastolic blood pressure falls. Our categorical analyses did not account for this phenomenon. Finally, we could not adjust for the serum lipid profile over and beyond total serum cholesterol, because too few participants had measurements of low-density or high-density cholesterol. We also did not account for measures of renal function, because they were only available in 4808 of our participants. However, we previously demonstrated that the incremental predictive value of renal function in an epidemiological setting is small compared with the 24-hour ambulatory blood pressure.³² Other factors we did not account for include family history of heart disease, and use of medications after enrolment.

In conclusion, we show that the risks conferred by diastolic and systolic blood pressure on 24-hour ambulatory measurement are age dependent. The 24-hour diastolic blood pressure and isolated diastolic hypertension drive coronary complications below age 50, whereas above age 50 the 24-hour systolic blood pressure is the predominant risk factor.

Supplementary Material

Supplemental Data

NIHMS682765-supplement-Supplemental_Data.pdf^{(379.5KB, pdf)}

CLINICAL PERSPECTIVE.

No previous study has assessed the risks associated with isolated diastolic, isolated systolic, and mixed hypertension on 24-hour ambulatory monitoring or examined the age dependency of 24-hour systolic and diastolic ambulatory blood pressures as independent risk factors in the general population. In 8341 untreated people (mean age, 50.8 years; 46.6% women) randomly recruited from 12 populations and followed up for a median of 11.2 years, the risks conferred by diastolic and systolic ambulatory blood pressure were age dependent. Ambulatory diastolic pressure and isolated diastolic hypertension drove coronary complications below age 50 years, whereas above 50 years of age 24-hour systolic pressure and isolated systolic and mixed hypertension were the predominant determinants of risk. Our findings argue against the suggestion to abandon diastolic pressure measurement and to rely only on systolic pressure for the management of hypertension. Moreover, in younger individuals elevated diastolic pressure as assessed by 24-hour ambulatory monitoring is a risk factor that must be treated.

Acknowledgments

We gratefully acknowledge the expert assistance of Sandra Covens and Annick De Soete (Studies Coordinating Center, Leuven, Belgium).

Sources of Funding

The European Union (grants IC15-CT98-0329-EPOGH, LSHM- CT-2006–037093 InGenious HyperCare, HEALTH-F4-2007–201550 HyperGenes, HEALTH-F7-2011- 278249 EU-MASCARA, HEALTH- F7-305507 HOMAGE, and the European Research Council Advanced Researcher Grant 294713 EPLORE) and the Fonds voor Wetenschappelijk Onderzoek Vlaanderen, Ministry of the Flemish Community, Brussels, Belgium (G.0734.09, G.0881.13 and G.088013) supported the Studies Coordinating Centre (Leuven, Belgium). The European Union (grants LSHM-CT-2006–037093 and HEALTH-F4-2007–201550) also supported the research groups in Shanghai, Kraków, Padova and Novosibirsk. The Danish Heart Foundation (grant 01-2-9-9A-22914), and the Lundbeck Fonden (grant R32-A2740) supported the studies in Copenhagen. The Ohasama study received support via the Grants for Scientific Research (23249036, 23390171, 24591060, 24390084, 24591060, 24790654, 25461205, 25461083 and 25860156) from the Ministry of Education, Culture, Sports, Science, and Technology, Japan; and a Health Labour Science Research Grant (H23-Junkankitou [Seishuu]-Ippan-005) from the Ministry of Health, Labour, and Welfare, Japan; the Japan Arteriosclerosis Prevention Fund; and the Grant from the Daiwa Securities Health Foundation. The National Natural Science Foundation of China (grants 30871360, 30871081, 81170245, and 81270373), Beijing, China, and the Shanghai Commissions of Science and Technology (grant 07JC14047 and the “Rising Star” program 06QA14043 and 11QH1402000) and Education (grant 07ZZ32 and the “Dawn” project 08SG20) supported the JingNing study in China. The Comisión Sectorial de Investigación Científica de la Universidad de la República (Grant I+D GEFA-HT-UY) and the Agencia Nacional de Innovación e Investigación supported research in Uruguay. The 1R01AG036469 from the National Institute on Aging and Fogarty International Center is supporting the Maracaibo Aging Study.

Appendix

List of IDACO Investigators

Copenhagen, Denmark

Tine W Hansen, MD, PhD; Hans Ibsen MD, DSci; Jørgen L Jeppesen, MD, DMSci; Susanne Rasmussen MD, PhD; Christian Torp-Pedersen, MD, DMSci

Ohasama, Japan

Kei Asayama, MD, PhD; Naomi Fukushima, MSc; Azusa Hara, PhD; Takuo Hirose, PhD; Miki Hosaka, MSc; Yutaka Imai, MD, PhD; Ryusuke Inoue, MD, PhD; Masahiro Kikuya, MD, PhD; Hirohito Metoki, MD, PhD; Kyoko Nomura, MD, PhD, MPH; Taku Obara, PhD; Takayoshi Ohkubo, MD, PhD; Michihiro Satoh, PhD; Megumi Tsubota-Utsugi, PhD, MPH

Noordenkempen, Belgium

Yu-Mei Gu, MD; Azusa Hara, PhD; Lotte Jacobs, PhD; Yu Jin, MD, PhD; Tatyana Kuznetsova, MD, PhD; Yan-Ping Liu, MD; Thibault Petit, MD; Jan A Staessen, MD, PhD; Lutgarde Thijs, MSc; Zhenyu Zhang, MD

Uppsala, Sweden

Kristina Björklund-Bodegård, MD, PhD; Lars Lind, MD, PhD

Montevideo, Uruguay

José Boggia, MD, PhD; Inés Lujambio, MD; Leonella Luzardo, MD MSc; Edgardo Sandoya, MD; Carlos Schettini, MD; Emma Schwedt, MD; Hugo Senra, MD; Mariana Sottolano, MD

JingNing, China

Qifang Huang, MD PhD; Lihua Li, MD PhD; Yan Li, MD, PhD; Changsheng Sheng, MD, PhD; Jiguang Wang, MD, PhD

Novosibirsk, Russian Federation

Sofia Malyutina, MD, PhD; Yuri Nikitin, MD, PhD

Dublin, Ireland

Eamon Dolan, MD, PhD; Eoin O’Brien, DSc, MD

Pilsen, Czech Republic

Jan Filipovský, MD, PhD; Jitka Seidlrova, MD, PhD

Padova, Italy

Edoardo Casiglia, MD; Valérie Tikhonoff, MD, PhD

Kraków, Poland

Marcin Cwynar, MD, PhD; Danuta Czarnecka, MD, PhD; Tomasz Grodzicki, MD, PhD; Kalina Kawecka-Jaszcz, MD, PhD; Agnieszka Olszanecka, MD, PhD; Katarzyna Stolarz-Skrzypek, MD, PhD; Wiktoria Wojciechowska, MD, PhD

Maracaibo, Venezuela

Gustavo E. Calmon, MD, MSc; Inara J. Chacon, MD, MSc; Carlos A. Chavez, MD; Vanessa G. Felix, PhD; Gladys E. Maestre, MD, PhD; Jesus D. Melgarejo BSc; Luis J. Mena, PhD; Egle R. Silva, MD

Footnotes

Disclosures

None.

References

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Associated Data

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

Supplementary Materials

Supplemental Data

NIHMS682765-supplement-Supplemental_Data.pdf^{(379.5KB, pdf)}

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PERMALINK

Ambulatory Hypertension Subtypes and 24-Hour Systolic and Diastolic Blood Pressure as Distinct Outcome Predictors in 8341 Untreated People Recruited From 12 Populations

Yan Li, MD, PhD

Fang-Fei Wei, MD

Lutgarde Thijs, MSc

José Boggia, MD, PhD

Kei Asayama, MD, PhD

Tine W Hansen, MD, PhD

Masahiro Kikuya, MD, PhD

Kristina Björklund-Bodegård, MD, PhD

Takayoshi Ohkubo, MD, PhD

Jørgen Jeppesen, MD

Yu-Mei Gu, MD

Christian Torp-Pedersen, MD, PhD

Eamon Dolan, MD, PhD

Yan-Ping Liu, MD

Tatiana Kuznetsova, MD, PhD

Katarzyna Stolarz-Skrzypek, MD, PhD

Valérie Tikhonoff, MD, PhD

Sofia Malyutina, MD, PhD

Edoardo Casiglia, MD, PhD

Yuri Nikitin, MD, PhD

Lars Lind, MD, PhD

Edgardo Sandoya, MD, PhD

Kalina Kawecka-Jaszcz, MD, PhD

Luis Mena, MD

Gladys E Maestre, MD, PhD

Jan Filipovský, MD, PhD

Yutaka Imai, MD, PhD

Eoin O’Brien, MD, PhD

Ji-Guang Wang, MD, PhD

Jan A Staessen, MD, PhD

Abstract

Background

Methods and Results

Conclusions

Methods

Study Population

Blood Pressure Measurement

Other Measurements

Ascertainment of Events

Statistical Analysis

Results

Baseline Characteristics

Table 1.

Incidence of Events

Risk by Categories of Ambulatory Blood Pressure

Table 2.

Figure 1.

Table 3.

Risks Associated with Diastolic and Systolic Blood Pressures

Table 4.

Figure 2.

Discussion

Supplementary Material

CLINICAL PERSPECTIVE.

Acknowledgments

Appendix

List of IDACO Investigators

Copenhagen, Denmark

Ohasama, Japan

Noordenkempen, Belgium

Uppsala, Sweden

Montevideo, Uruguay

JingNing, China

Novosibirsk, Russian Federation

Dublin, Ireland

Pilsen, Czech Republic

Padova, Italy

Kraków, Poland

Maracaibo, Venezuela

Footnotes

References

Associated Data

Supplementary Materials

ACTIONS

PERMALINK

RESOURCES

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