Risk of cardiovascular events among women with high normal blood pressure or blood pressure progression: prospective cohort study

David Conen; Paul M Ridker; Julie E Buring; Robert J Glynn

doi:10.1136/bmj.39269.672188.AE

BMJ. 2007 Sep 1; 335(7617): 432.

Published online 2007 Aug 19. doi: 10.1136/bmj.39269.672188.AE

PMCID: PMC1962877

PMID: 17704543

Risk of cardiovascular events among women with high normal blood pressure or blood pressure progression: prospective cohort study

David Conen, research fellow,¹ Paul M Ridker, professor of medicine,² Julie E Buring, professor of medicine,¹ and Robert J Glynn, associate professor of medicine (biostatistics)¹

Author information Article notes Copyright and License information PMC Disclaimer

Abstract

Objective To compare cardiovascular risk among women with high normal blood pressure (130-9/85-9 mm Hg) against those with normal blood pressure (120-9/75-84 mm Hg) and those with baseline hypertension.

Design Prospective cohort study.

Setting Women's health study, United States.

Participants 39 322 initially healthy women classified into four categories according to self reported baseline blood pressure and followed for a median of 10.2 years.

Main outcome measures Time to cardiovascular death, myocardial infarction, or stroke (major cardiovascular event—primary end point); progression to hypertension.

Results 982 (2.5%) women developed a major cardiovascular event, and 8686 (30.1%) women without baseline hypertension progressed to hypertension. The age adjusted event rate for the primary end point was 1.6/1000 person years among women with normal blood pressure, 2.9/1000 person years among those with high normal blood pressure, and 4.3/1000 person years among those with baseline hypertension. Compared with women with high normal blood pressure (reference group), those with normal blood pressure had a lower risk of a major cardiovascular event (adjusted hazard ratio 0.61, 95% confidence interval 0.48 to 0.76) and of incident hypertension (0.42, 0.40 to 0.44). The hazard ratio for a major cardiovascular event in women with baseline hypertension was 1.30 (1.08 to 1.57). Women who progressed to hypertension (reference group) during the first 48 months of the study had a higher cardiovascular risk than those who remained normotensive (adjusted hazard ratio 0.64, 0.50 to 0.81). Women with high normal blood pressure at baseline who progressed to hypertension (reference group) had similar outcome rates to women with baseline hypertension (adjusted hazard ratio 1.17, 0.88 to 1.55).

Conclusion The cardiovascular risk of women with high normal blood pressure is higher than that of women with normal blood pressure. The cardiovascular risk of women who progress to hypertension is increased shortly after a diagnosis of hypertension has been made.

Trial registration Clinical trials NCT00000479.

Introduction

Hypertension is defined as a systolic blood pressure of at least 140 mm Hg or a diastolic blood pressure of at least 90 mm Hg. However, cardiovascular risk is directly associated with blood pressure across a much wider spectrum of blood pressure levels, and no evidence of a threshold exists down to at least 115/75 mm Hg.¹ ² Although this relation is firmly established, little evidence is available about the risk of cardiovascular events in people whose blood pressure levels progress and who newly develop hypertension.

This question is important because people with blood pressure levels in the normal and high normal range have a substantial risk of developing hypertension over a short term period of four years.³ The cumulative lifetime risk of developing hypertension approaches 90% in a Western population,⁴ and the high global prevalence of hypertension further underscores the importance of the problem.⁵

Strategies to prevent or postpone hypertension in people with normal blood pressure could thus have a substantial impact on public health. Unfortunately, published guidelines for the management of people with hypertension have adopted different classification schemes for patients with blood pressure levels considered to be normal.⁶ ⁷ The Joint National Committee 7 guidelines from the United States introduced a category designated “prehypertension” for people with blood pressure levels from 120 to 139 mm Hg for systolic pressure or 80 to 89 mm Hg for diastolic pressure.⁷ On the other hand, the European guidelines partition these people into two groups: those with systolic blood pressure between 120 and 129 mm Hg or diastolic blood pressure between 80 and 84 mm Hg are classified as normal, whereas those with systolic blood pressure between 130 and 139 mm Hg or diastolic blood pressure between 85 and 89 mm Hg are classified as high normal.⁶ Evidence for a different clinical course among people in these two groups would support the relevance of this distinction. We therefore determined the long term outcome with regard to cardiovascular disease and progression to hypertension in a large cohort of initially healthy women with a wide range of blood pressures. We then evaluated in greater detail the outcome of women who developed hypertension during the first 48 months of the study.

Methods

Participants

All the women studied were participants in the women's health study, a completed randomised trial that evaluated the risks and benefits of low dose aspirin and vitamin E in the primary prevention of cardiovascular disease and cancer. Details of the study design have been described previously.⁸ ⁹ ¹⁰

Briefly, beginning in 1993, 39 876 female health professionals in the United States who were 45 years or older and free of cardiovascular disease, cancer, or other major illnesses were randomised to receive 100 mg aspirin every other day, 600 IU vitamin E every other day, both agents, or placebo. The trial initially had a β carotene arm, which was terminated early.¹¹ Information on baseline variables was collected with mailed questionnaires. Follow-up questionnaires asking participants about study outcomes and other information were sent every six months during the first year and every 12 months thereafter.

We used follow-up information from randomisation to the end of the trial on 31 March 2004 for this analysis. As of this date, follow-up was 97.2% complete for morbidity and 99.4% complete for mortality. For this analysis, the study population consisted of all 39 322 women with complete information about blood pressure, personal history of hypertension, and antihypertensive treatment at randomisation. We analysed incident hypertension among 28 863 (73.4%) women without hypertension at baseline. The median follow-up in this study was 10.2 years. Written informed consent was obtained from all participants, and the trial was monitored by an external data and safety monitoring board.

Study variables

Blood pressure at randomisation was self reported by the female health professionals, a group in which self report of blood pressure has proved highly accurate.¹ ¹² Participating women categorised their blood pressure levels into nine different categories for systolic blood pressure and seven different categories for diastolic blood pressure. The Spearman correlation coefficient of categories of blood pressure at baseline and at 12 months was 0.75 for systolic blood pressure and 0.64 for diastolic blood pressure. These coefficients compare favourably with those found for measured blood pressure.¹³ ¹⁴ ¹⁵

For the purpose of this study, we classified women into four predefined blood pressure categories: below 120 mm Hg for systolic pressure and 75 mm Hg for diastolic pressure (subsequently called optimal blood pressure), 120-9 mm Hg for systolic pressure or 75-84 mm Hg for diastolic pressure (subsequently called normal blood pressure), 130-9 mm Hg for systolic pressure or 85-9 mm Hg for diastolic pressure (subsequently called high normal blood pressure), and established hypertension. We defined established hypertension as self reported history of hypertension, taking antihypertensive treatment, or blood pressure levels of at least 140 mm Hg for systolic pressure or 90 mm Hg for diastolic pressure. We classified women with discordant systolic and diastolic blood pressure categories into the higher category.

Covariates of interest were self reported at study entry and included age, smoking, history of hypercholesterolaemia (self reported cholesterol of at least 240 mg/dl (6.22 mmol/l)), diabetes, body mass index (weight in kilograms divided by the square of height in metres), exercise, alcohol consumption, and highest educational level achieved.

Ascertainment of cardiovascular outcome variables

We asked all women who reported a myocardial infarction, stroke, or coronary revascularisation (percutaneous coronary angioplasty or bypass surgery) for permission to review their medical records. We confirmed that death was from cardiovascular causes on the basis of autopsy records, death certificates, medical records, or information obtained from family members. An endpoint committee of physicians reviewed medical records for reported events according to predefined criteria. We included only confirmed events in this analysis.

Definition of incident hypertension

We defined incident cases of hypertension for women without hypertension at baseline as meeting at least one of the following criteria: self report of a new diagnosis by a physician of hypertension at years 1 and 3 and yearly thereafter; self report of taking antihypertensive treatment at years 1, 3, and 4 and at the end of the study; or self reported blood pressure of at least 140 mm Hg for systolic pressure or 90 mm Hg for diastolic pressure at years 1 and 4 and at the end of the study.

Women who reported a new diagnosis of hypertension by a physician also provided the month and year of diagnosis. For a diagnosis defined by another criterion or a missing date for a physician's diagnosis, we randomly assigned a date between the latest questionnaire and the previous one. Women who developed cardiovascular disease, for which the management may interfere with blood pressure levels, were censored at the date of diagnosis and not considered at risk for incident hypertension thereafter.

Statistical analysis

The primary cardiovascular outcome variable was a composite of myocardial infarction, stroke, and death from cardiovascular causes. We also analysed the individual components, coronary revascularisation, and death from any cause as secondary variables. If a woman had several events, we counted only the first event in each category.

Blood pressure category and cardiovascular events

We calculated age adjusted incidences per 1000 person years stratified by blood pressure category for the primary and all secondary outcome variables. Subsequently, we constructed Cox proportional hazards models to calculate hazard ratios and 95% confidence intervals for the comparison of event rates in the four blood pressure categories. We chose the high normal blood pressure category as the reference group, because it constituted the main focus of this study. In a first step, we adjusted the crude models for age. Thereafter, we fitted a multivariable model adjusting for age, smoking, history of diabetes, body mass index, history of hypercholesterolaemia, exercise, alcohol consumption, highest educational level, and randomised treatment assignments (aspirin, vitamin E, and β carotene).

Blood pressure category and progression to hypertension

We calculated age adjusted incidences per 1000 person years for the development of incident hypertension during follow-up among women without hypertension at baseline, again stratified by blood pressure category. To compare the event rates among the different blood pressure categories, we constructed Cox proportional hazards models to calculate the adjusted blood pressure category specific hazard ratios for incident hypertension. Again, women with high normal blood pressure constituted the reference group. We adjusted this model for the same variables described above.

Blood pressure progression and cardiovascular events

We then categorised women into the following pre-specified categories: women without baseline hypertension who did not develop hypertension during the first 48 months of follow-up, women with baseline hypertension, and women without baseline hypertension who developed hypertension during the first 48 months of follow-up. In a second step, we further subdivided the last group into one group with baseline blood pressure values below 130/85 mm Hg and another group with baseline blood pressure values between 130 and 139 mm Hg for systolic pressure or between 85 and 89 mm Hg for diastolic pressure.

We constructed Cox proportional hazards models to compare the hazard ratios for developing a primary cardiovascular outcome event between these newly created categories. Because we assessed time to a first cardiovascular event beginning at month 48, women who had a primary cardiovascular outcome event or died during the first 48 months of follow-up were excluded from these analyses. We adjusted this model for age, smoking, diabetes, body mass index, and alcohol consumption at 48 months and for baseline history of hypercholesterolaemia, exercise, highest educational level, and randomised treatment assignments.

We entered categorical variables in the Cox models by using binary indicator variables. We used integer scores across categories to test for trend. We examined the proportional hazards assumption for all models by including a blood pressure category by time interaction in the model.¹⁶ We used SAS version 9 for all analyses. A two tailed P value <0.05 indicated statistical significance.

Results

Table 11 shows baseline characteristics stratified by blood pressure category. At baseline, 10 459 (26.6%) of the study participants had hypertension, 4988 (12.7%) had high normal blood pressure, 11 326 (28.8%) had normal blood pressure, and 12 549 (31.9%) had optimal blood pressure. Increasing blood pressure was associated with increasing age and body mass index and a higher prevalence of diabetes and hypercholesterolaemia. Moderate alcohol consumption, exercise, higher educational level, and white race were more prevalent in women with lower blood pressure levels.

Table 1

Baseline characteristics according to blood pressure category. Values are numbers (percentages) unless stated otherwise

Characteristics	Baseline blood pressure, systolic/diastolic (mm Hg)
Characteristics	<120/75 (n=12 549)*	120-9/75-84 (n=11 326)*	130-9/85-9 (n=4988)*	Hypertension† (n=10 459)*
Mean (SD) age (years)	53 (6)	54 (7)	56 (7)	57 (8)
Mean (SD) body mass index (kg/m²)	24.0 (3.7)	25.6 (4.4)	27.3 (5.3)	28.4 (5.9)
History of diabetes:
Yes	82 (0.7)	153 (1.4)	143 (2.9)	639 (6.1)
No	12 463 (99.4)	11 164 (98.7)	4842 (97.1)	9812 (93.9)
History of hypercholesterolaemia:
Yes	2708 (21.6)	2893 (25.6)	1551 (31.1)	4486 (42.9)
No	9837 (78.4)	8430 (74.5)	3432 (68.9)	5969 (57.1)
Smoking:
Current	1726 (13.8)	1469 (13.0)	681 (13.7)	1277 (12.2)
Former	4517 (36.0)	4003 (35.4)	1786 (35.9)	3759 (36.0)
Never	6296 (50.2)	5849 (51.7)	2514 (50.5)	5411 (51.8)
Hormone replacement therapy:
Never	6466 (51.6)	5744 (50.8)	2505 (50.3)	4836 (46.3)
Former	895 (7.2)	925 (8.2)	501 (10.1)	1241 (11.9)
Current	5160 (41.2)	4641 (41.0)	1973 (39.6)	4359 (41.8)
Exercise (times/week):
Rarely/never	4102 (32.7)	4233 (37.4)	2053 (41.2)	4683 (44.8)
<1	2494 (19.9)	2317 (20.5)	1017 (20.4)	1986 (19.0)
1-3	4253 (33.9)	3615 (31.9)	1519 (30.5)	2861 (27.4)
>3	1692 (13.5)	1159 (10.2)	395 (7.9)	925 (8.9)
Alcohol consumption‡:
Rarely/never	5240 (41.8)	4893 (43.2)	2281 (45.7)	5339 (51.1)
1-3 drinks/month	1744 (13.9)	1470 (13.0)	634 (12.7)	1327 (12.7)
1-6 drinks/week	4327 (34.5)	3784 (33.4)	1527 (30.6)	2751 (26.3)
≥1 drink/day	1235 (9.8)	1175 (10.4)	545 (10.9)	1040 (10.0)
White race	11 912 (95.7)	10 729 (95.6)	4706 (95.2)	9612 (92.7)
Highest educational level:
Less than a bachelors degree	6583 (53.3)	6127 (55.0)	2962 (60.3)	6543 (63.7)
Bachelors degree	3132 (25.4)	2642 (23.7)	1075 (21.9)	2069 (20.2)
Masters degree or doctorate	2641 (21.4)	2372 (21.3)	872 (17.8)	1657 (16.1)

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*Number of women across categories may not sum to the given number because of missing data.

†Defined as previous diagnosis of hypertension, systolic blood pressure ≥140 mm Hg, diastolic blood pressure ≥90 mm Hg, or receiving blood pressure lowering treatment.

‡One drink corresponds to 13 g alcohol.

Blood pressure category and cardiovascular events

After 10.2 years of follow-up, 982 confirmed major cardiovascular events had occurred among 39 322 women. Table 22 shows age adjusted event rates stratified by blood pressure category. Women with hypertension at baseline had the highest event rate (4.32 major cardiovascular events per 1000 person years). We saw a strong and consistent decrease in event rates down to the optimal blood pressure category among all primary and secondary outcomes evaluated. Of particular interest, the rate of major cardiovascular events among women with high normal blood pressure at baseline was almost twice as high as that for those with normal baseline blood pressure.

Table 2

Age adjusted incidences (per 1000 person years) of events according to blood pressure category

Endpoint	Baseline blood pressure, systolic/diastolic (mm Hg)
Endpoint	<120/75	120-9/75-84	130-9/85-9	Hypertension*
Major cardiovascular event†
No of events/person years	134/125 503	176/112 972	159/49 214	513/102 040
Age adjusted incidence	1.28	1.64	2.92	4.32
Stroke
No of events/person years	79/125 659	85/113 247	63/49 531	251/102 857
Age adjusted incidence	0.74	0.79	1.15	2.09
Myocardial infarction
No of events/person years	42/125 790	70/113 286	77/49 464	200/102 976
Age adjusted incidence	0.41	0.65	1.42	1.73
Death from cardiovascular causes
No of events/person years	30/125 952	37/113 562	32/49 781	140/103 835
Age adjusted incidence	0.29	0.34	0.55	1.09
Coronary revascularisation
No of events/person years	93/125 648	123/113 080	140/49 204	392/102 167
Age adjusted incidence	0.91	1.12	2.61	3.49
Death from any cause
No of events/person years	224/125 952	243/113 562	153/49 781	457/103 835
Age adjusted incidence	2.11	2.27	2.80	3.65

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*Defined as previous diagnosis of hypertension, systolic blood pressure ≥140 mm Hg, diastolic blood pressure ≥90 mm Hg, or receiving blood pressure lowering treatment.

†Defined as myocardial infarction, stroke, or death from cardiovascular causes.

Multivariable Cox proportional hazards models only slightly attenuated the strong trend across blood pressure categories (table 33).). In the fully adjusted model, women with normal blood pressure at baseline had a 39% lower risk of having a major cardiovascular event compared with those with high normal blood pressure and those with optimal blood pressure at baseline had a 49% lower risk. The risk of women with established hypertension at baseline was 30% higher.

Table 3

Cox proportional hazards models to compare risk of first cardiovascular event according to baseline blood pressure category. Values are hazard ratios (95% confidence intervals)

Endpoint	Baseline blood pressure, systolic/diastolic (mm Hg)
Endpoint	<120/75	120-9/75-84	130-9/85-9*	Hypertension†
Major cardiovascular event‡
Crude	0.33 (0.26 to 0.42)	0.48 (0.39 to 0.60)	1.0	1.56 (1.30 to 1.86)
Age adjusted	0.44 (0.35 to 0.55)	0.56 (0.45 to 0.70)	1.0	1.41 (1.18 to 1.69)
Multivariable adjusted§	0.51 (0.40 to 0.64)	0.61 (0.48 to 0.76)	1.0	1.30 (1.08 to 1.57)
Stroke
Crude	0.49 (0.36 to 0.69)	0.59 (0.43 to 0.82)	1.0	1.92 (1.46 to 2.53)
Age adjusted	0.66 (0.47 to 0.92)	0.69 (0.50 to 0.96)	1.0	1.74 (1.32 to 2.29)
Multivariable adjusted§	0.72 (0.51 to 1.01)	0.74 (0.53 to 1.03)	1.0	1.61 (1.21 to 2.14)
Myocardial infarction
Crude	0.21 (0.15 to 0.31)	0.40 (0.29 to 0.55)	1.0	1.25 (0.96 to 1.62)
Age adjusted	0.27 (0.19 to 0.40)	0.45 (0.33 to 0.63)	1.0	1.15 (0.88 to 1.50)
Multivariable adjusted§	0.34 (0.23 to 0.50)	0.50 (0.36 to 0.71)	1.0	1.03 (0.78 to 1.35)
Death from cardiovascular causes
Crude	0.37 (0.23 to 0.61)	0.51 (0.32 to 0.81)	1.0	2.10 (1.43 to 3.08)
Age adjusted	0.55 (0.33 to 0.91)	0.63 (0.39 to 1.01)	1.0	1.83 (1.25 to 2.69)
Multivariable adjusted§	0.66 (0.39 to 1.10)	0.65 (0.39 to 1.06)	1.0	1.68 (1.13 to 2.50)
Coronary revascularisation
Crude	0.26 (0.20 to 0.34)	0.38 (0.30 to 0.49)	1.0	1.35 (1.12 to 1.64)
Age adjusted	0.31 (0.24 to 0.41)	0.42 (0.33 to 0.54)	1.0	1.26 (1.04 to 1.53)
Multivariable adjusted§	0.38 (0.29 to 0.50)	0.49 (0.38 to 0.64)	1.0	1.08 (0.88 to 1.32)
Death from any cause
Crude	0.58 (0.47 to 0.71)	0.70 (0.57 to 0.85)	1.0	1.43 (1.19 to 1.72)
Age adjusted	0.81 (0.66 to 1.00)	0.84 (0.69 to 1.03)	1.0	1.27 (1.06 to 1.53)
Multivariable adjusted§	0.91 (0.73 to 1.13)	0.89 (0.72 to 1.10)	1.0	1.26 (1.04 to 1.52)

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*Reference category.

†Defined as previous diagnosis of hypertension, systolic blood pressure ≥140 mm Hg, diastolic blood pressure ≥90 mm Hg, or receiving blood pressure lowering treatment.

‡Defined as myocardial infarction, stroke, or death from cardiovascular causes.

§Adjusted for age, smoking, diabetes, history of hypercholesterolaemia, body mass index, exercise, alcohol consumption, highest educational level, and randomised treatment assignments (aspirin, vitamin E, and β carotene); owing to missing covariates, the multivariable (crude) analysis was based on 930 (982) major cardiovascular events, 456 (478) strokes, 365 (389) myocardial infarctions, 226 (239) cardiovascular deaths, 706 (748) revascularisations, and 1025 (1077) all cause deaths among 37 787 (39 322) women.

Women with hypertension had a substantially higher risk of stroke than women with high normal blood pressure (hazard ratio 1.61, 95% confidence interval 1.21 to 2.14), but the risk of coronary events (myocardial infarction or coronary revascularisation) did not differ significantly between the two groups. The lower risk of cardiovascular events in women with normal blood pressure compared with those with high normal blood pressure was consistent among all individual end points considered, although some of the secondary end points did not reach statistical significance in the fully adjusted models.

Blood pressure category and progression to hypertension

In total, 8686 (30.1%) of the 28 863 women without a diagnosis of hypertension at baseline developed incident hypertension during follow-up. The incidence of hypertension strongly increased across the different blood pressure categories, ranging from 16.0 events per 1000 person years in women with optimal blood pressure to 114.7 per 1000 person years in women with high normal blood pressure at baseline (table 44).). Across the three baseline blood pressure categories, 8.2%, 22.7%, and 51.8% of women developed hypertension after five years of follow-up. The corresponding 10 year cumulative risks of incident hypertension were 14.8%, 34.0%, and 64.2%. Women with normal blood pressure thus had a substantially lower risk of developing hypertension than women with high normal blood pressure. This large difference persisted over the entire follow-up period and remained almost unchanged after multivariable adjustment (hazard ratio 0.42, 0.40 to 0.44) (table 44).). We found evidence of violation of the proportional hazards assumption, with a greater relative hazard during early follow-up and attenuation over time.

Table 4

Risk of developing hypertension among 28 863 women without hypertension at baseline

	Baseline blood pressure level, systolic/diastolic (mm Hg)			P for trend
	<120/75	120-9/75-84	130-9/85-9	P for trend
Absolute risk of developing hypertension
No of events/person years	1796/115 700	3765/89 999	3125/26 764
Age adjusted incidence/1000 person years	16.0	41.8	114.7
Hazard ratio (95% confidence interval)
Crude	0.14 (0.13 to 0.15)	0.38 (0.36 to 0.40)	1.0*	<0.0001
Age adjusted	0.15 (0.14 to 0.16)	0.39 (0.37 to 0.41)	1.0*	<0.0001
Multivariable adjusted†	0.17 (0.16 to 0.18)	0.42 (0.40 to 0.44)	1.0*	<0.0001

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* Reference category.

†Adjusted for age, smoking, diabetes, history of hypercholesterolaemia, body mass index, exercise, alcohol consumption, highest educational level, and randomised treatment assignments (aspirin, vitamin E, and β carotene); owing to missing covariates, the multivariable (crude) analysis was based on 8346 (8686) events of incident hypertension among 27 790 (28 863) women.

Blood pressure progression and cardiovascular events

During the first 48 months of follow-up, 22 886 (59.0%) women remained free of hypertension, 5694 (14.7%) progressed to hypertension (3274 (57.5%) women with baseline blood pressure below 130/85 mm Hg and 2420 (42.5%) women with high normal blood pressure at baseline), and 10 207 (26.3%) already had hypertension at baseline. We excluded 535 (1.4%) women with a major cardiovascular event or death during the first 48 months from these analyses.

Women who progressed to hypertension had a higher event rate during follow-up than women who remained free of hypertension and a lower event rate than women with hypertension at baseline (table 55).). This difference between women with incident hypertension and baseline hypertension was substantially attenuated after multivariable adjustment, but having hypertension at baseline remained associated with a significant 39% increase in risk (table 55,, fig 11).). After multivariable adjustment, women without progression to hypertension during the first 48 months had a 36% lower risk than women who progressed to hypertension.

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Fig 1 Blood pressure progression and risk of major cardiovascular events. Hazard ratios (with 95% confidence intervals) for a first major cardiovascular event in women with incident hypertension during the first 48 months (reference group), compared with women with persistent normotension and women with hypertension at baseline. The different categories are defined in table 55.. *Adjusted for age, smoking, diabetes, body mass index, and alcohol consumption at 48 months and for baseline history of hypercholesterolaemia, exercise, highest educational level, and randomised treatment assignments

Table 5

Cox proportional hazards models to assess risk of first major cardiovascular event among women with incident diagnosis of hypertension during first 48 months of follow-up (n=38 787)

	Hazard ratio (95% confidence interval)				P trend
	*No progression (n=22 886)**	*Progression to hypertension (n=5694)**		*Baseline hypertension (n=10 207)**
First model
Events/person years	214/137 767	106/34 038		332/60 250
Crude	0.50 (0.40 to 0.63)	1.0†		1.77 (1.42 to 2.20)	<0.0001
Age adjusted‡	0.60 (0.48 to 0.76)	1.0†		1.51 (1.22 to 1.89)	<0.0001
Multivariable adjusted§	0.64 (0.50 to 0.81)	1.0†		1.39 (1.11 to 1.74)	<0.0001
Second model		(From below high normal)¶	(From high normal)¶
Events/person years	214/137 767	47/19 622	59/14 416	332/60 250
Crude	0.38 (0.29 to 0.51)	0.59 (0.40 to 0.86)	1.0†	1.35 (1.02 to 1.78)	<0.0001
Age adjusted‡	0.50 (0.37 to 0.66)	0.68 (0.46 to 1.00)	1.0†	1.25 (0.95 to 1.65)	<0.0001
Multivariable adjusted§	0.53 (0.40 to 0.72)	0.70 (0.47 to 1.03)	1.0†	1.17 (0.88 to 1.55)	<0.0001

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*No progression defined as a blood pressure <140/90 mm Hg at baseline and during at least 48 months of follow-up in absence of blood pressure lowering treatment; progression to hypertension defined as blood pressure <140/90 mm Hg without blood pressure lowering treatment at baseline and developing hypertension during first 48 months of follow-up; hypertension defined as previous diagnosis of hypertension, systolic blood pressure ≥140 mm Hg, diastolic blood pressure ≥90 mm Hg, or receiving blood pressure lowering treatment at baseline.

†Reference category.

‡Age at 48 months of follow-up used for adjustment.

§Adjusted for age, smoking, diabetes, body mass index, and alcohol consumption at 48 months and for baseline history of hypercholesterolaemia, exercise, highest educational level, and randomised treatment assignments (aspirin, vitamin E, and β carotene); owing to missing covariates, the multivariable analysis was based on 625 (compared with 652 in the crude and age adjusted analyses) major cardiovascular events during follow-up among 37 653 women.

¶Group of women with progression to hypertension divided into 3274 women who had a baseline blood pressure <130/85 mm Hg (below high normal) and 2420 who had baseline blood pressure 130-9/85-9 mm Hg (high normal).

In the second model, we found that women who had high normal blood pressure at baseline and who progressed to hypertension during follow-up had a similar risk of a major cardiovascular event to women with hypertension at baseline (P=0.28). Women who had a lower blood pressure at baseline and who progressed to hypertension had a 30% lower risk of a cardiovascular event than women with high normal blood pressure at baseline, a difference that was of borderline statistical significance (P=0.07) (table 55,, fig 22).

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Fig 2 Blood pressure progression and risk of major cardiovascular events stratified by baseline blood pressure. Hazard ratios (with 95% confidence intervals) for a first major cardiovascular event in women with high normal blood pressure at baseline and incident hypertension in the first 48 months (reference group), compared with women with persistent normotension, women with below high normal baseline blood pressure and incident hypertension in the first 48 months, and women with hypertension at baseline. The different categories are defined in table 55.. *Adjusted for age, smoking, diabetes, body mass index, and alcohol consumption at 48 months and for baseline history of hypercholesterolaemia, exercise, highest educational level, and randomised treatment assignments

Discussion

This study provides evidence that women's risk of having a major cardiovascular event is lower at lower blood pressure, without evidence of a threshold level. Our findings are in line with previous reports from two different cohort studies and from a large meta-analysis.¹ ² ¹⁷ In contrast to the previous studies, we focused our attention on women with high normal blood pressure and found that their risk of having a major cardiovascular event was 64% higher compared with women with normal blood pressure and almost doubled compared with women with optimal blood pressure at baseline.

These differences are important for several reasons. By combining the two categories normal and high normal blood pressure, the Joint National Committee 7 guidelines created a new blood pressure category called “prehypertension.”⁷ However, because of the large differences in cardiovascular risk, separate consideration of these two groups may be reasonable. By maintaining two different blood pressure categories (normal and high normal blood pressure), the European guidelines for the management of hypertension may more accurately reflect the risk distribution among people with blood pressure levels below 140/90 mm Hg.⁶

Other findings further underscore substantial differences between these two groups. Among participants of the Framingham Study aged below 65, the risk of developing hypertension over a period of four years was 18% in those with normal blood pressure and 37% in those with high normal blood pressure.³ Our study confirms and expands these findings. Among women with high normal blood pressure at baseline, 64% progressed to hypertension over a 10 year period, whereas only 34% of women with initially normal blood pressure developed hypertension during follow-up. The differences in risk were maintained during the entire 10 year follow-up period.

Our study indicates that women who progress to hypertension need to be identified early, as their risk of an adverse outcome is increased shortly thereafter. Women who developed hypertension during the first 48 months of follow-up had a 56% increased risk of a major cardiovascular event in the last six years of follow-up compared with women who did not develop hypertension during at least four years. Women with high normal blood pressure at baseline and progression to hypertension had a similar cardiovascular risk to women with baseline hypertension.

Taken together, the results of this and other studies suggest that preventive and research efforts to reverse blood pressure progression and reduce cardiovascular events should be focused on people with high normal blood pressure. Several interventions have been shown to be beneficial in this population. Physical exercise effectively reduces blood pressure levels independent of baseline blood pressure.¹⁸ Dietary intervention was effective in reducing systolic blood pressure by 3.5 mm Hg and diastolic blood pressure by 2.1 mm Hg,¹⁹ and blood pressure levels were further lowered by restricting dietary sodium intake.²⁰ Sodium reduction has recently been shown to potentially reduce cardiovascular events in people with prehypertension.²¹ Consuming a Mediterranean-style diet rich in olive oil and nuts is more effective in reducing blood pressure than a standard low fat diet.²²

Because women with high normal blood pressure also have an increased prevalence of diabetes and hypercholesterolaemia, a multidimensional intervention programme targeting all cardiovascular risk factors and including dietary modification and regular physical exercise should be the most efficient approach to reduce cardiovascular risk. Several studies have documented the feasibility and efficacy of a multidimensional approach in this group.²³ ²⁴ ²⁵ ²⁶ Interestingly, the PREMIER trial suggested that a minimal counselling programme leads to a substantial reduction in blood pressure (−7.4 mm Hg for systolic blood pressure and −5.2 mm Hg for diastolic pressure) that is sustained over at least 18 months of follow-up.²⁴

Whether drug treatment should be used in people with high normal blood pressure is highly controversial.²⁷ No trial to date has examined the potential benefit of drug treatment to improve cardiovascular outcome in this large group of people. Thus, without hard endpoint data, blood pressure lowering drugs cannot be recommended, and aggressive lifestyle modifications remain the cornerstone of risk reduction. All women with normal or high normal blood pressure need regular blood pressure assessments. Whether other blood pressure measurement techniques such as home or ambulatory blood pressure measurement could improve risk stratification and management in this particular group of people deserves further study.²⁸ ²⁹

Strengths and limitations

Strengths of this study are the large sample size, the prospective design, and the complete long term follow-up with a large number of events. The study included predominantly white women, and our findings may not be generalisable to other populations. Another possible limitation is the use of self reported blood pressure and hypertension status. However, the prognostic value of self reported blood pressure in cohort studies involving US health professionals is similar to that of directly measured blood pressure in participants of other cohort studies.¹ Furthermore, the validity of this approach has been examined in the comparable nurses' health study, in which 99% of the women who reported high blood pressure had their diagnosis confirmed by review of medical records.¹² Self reported blood pressure, total cholesterol, and body mass index have previously been shown in the women's health study to be strong predictors of cardiovascular risk, with relative risks consistent in magnitude with those seen in other major studies.³⁰ ³¹ ³² Systolic blood pressure is the strongest cardiovascular risk factor after age in the women's health study,³³ further underscoring its predictive validity. Finally, we found correlation coefficients for systolic and diastolic blood pressure categories that were at least as strong as those reported in the literature for office measured blood pressure, indicating consistent reporting of blood pressure over time.¹³ ¹⁴ ¹⁵

Conclusions

Women with high normal blood pressure have a substantially increased risk of developing hypertension or a major cardiovascular event during follow-up compared with women with normal blood pressure. These people need close follow-up and lifestyle modifications. Although the overall risk of an adverse outcome in women with “prehypertension” is increased, this group is a heterogeneous population. The increase in risk is substantially more pronounced in women with high normal blood pressure. Therefore, a classification using two different categories for people with “prehypertension” may be more accurate. This differentiation is important in order to optimise the implementation of preventive strategies in those women at high risk for adverse events. Once hypertension has developed, the cardiovascular event rate is increased shortly after the diagnosis of hypertension has been made, especially among women with high normal blood pressure at baseline.

What is already known on this topic

Observational studies have shown a direct association between cardiovascular risk and blood pressure across a broad spectrum of blood pressure levels
Guidelines use different classification schemes for blood pressure levels currently considered as normal (prehypertension versus normal and high normal blood pressure)
Cardiovascular outcomes among people who progress to hypertension are not well defined

What this study adds

Compared with women with normal blood pressure, those with high normal blood pressure have a substantially higher risk of cardiovascular events and incident hypertension
Maintaining two different blood pressure categories for people with prehypertension seems to be appropriate
Risk of cardiovascular events among women who progress to hypertension is increased shortly after a diagnosis of hypertension has been made

Notes

We thank the participants of the women's health study for their outstanding commitment and cooperation and the entire women's health study staff for their expert and unfailing assistance.

Contributors: DC and RJG were responsible for the study concept and design. All authors were involved in data acquisition. DC drafted the manuscript. All authors critically revised the manuscript for important intellectual content. DC and RJG did the statistical analysis. DC, PMR, and JEB obtained funding. RJG provided administrative, technical, and material support and supervised the study. DC is the guarantor.

Funding: DC is supported by grants from the Swiss National Science Foundation (PBBSB-113207) and the Janggen-Poehn Foundation, St Gallen, Switzerland. The women's health study was supported by grants HL-43851 and CA-47988 from the National Heart, Lung, and Blood Institute and the National Cancer Institute. The funding agencies had no role in the design, conduct, data management, analysis, or manuscript preparation.

Competing interests: None declared.

Ethical approval: Institutional review board of Brigham and Women's Hospital, Boston.

Provenance and peer review: Non-commissioned; externally peer reviewed.

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