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Sabtu, 20 Oktober 2012

JURNAL INTERNASIONAL KEPERAWATAN MATERNITAS


Early Menopause Predicts Future Coronary Heart Disease and Stroke: The Multi-ethnic Study of Atherosclerosis
Melissa Wellons, MD, NCMP, Pamela Ouyang, MBBS, Pamela J. Schreiner, PhD, David M. Herrington, MD, Dhananjay Vaidya, PhD Oct 19, 2012
Authors & Disclosures
Menopause. 2012;19(10):1081-1087. © 2012  The North American Menopause Society

Abstract and Introduction

Abstract

Objective: Cardiovascular disease is the number one killer of women. Identifying women at risk of cardiovascular disease has tremendous public health importance. Early menopause is associated with increased cardiovascular disease events in some predominantly white populations, but not consistently. Our objective was to determine if self-reported early menopause (menopause at an age <46 y) identifies women as at risk for future coronary heart disease or stroke.
Methods: The study population came from the Multi-Ethnic Study of Atherosclerosis, a longitudinal, ethnically diverse cohort study of US men and women aged 45 to 84 years enrolled in 2000-2002 and followed up until 2008. The association between a personal history of early menopause (either natural menopause or surgical removal of ovaries at an age <46 y) and future coronary heart disease and stroke was assessed in 2,509 women (ages 45-84 y; 987 white, 331 Chinese, 641 black, and 550 Hispanic) from the Multi-ethnic Study Atherosclerosis who were free of cardiovascular disease at baseline.
Results: Of 2,509 women, 693 (28%) reported either surgical or natural early menopause. In survival curves, women with early menopause had worse coronary heart disease and stroke-free survival (log rank P = 0.008 and P = 0.0158). In models adjusted for age, race/ethnicity, Multi-ethnic Study Atherosclerosis site, and traditional cardiovascular disease risk factors, this risk for coronary heart disease and stroke remained (hazard ratio, 2.08; 95% CI, 1.17-3.70; and hazard ratio, 2.19; 95% CI, 1.11-4.32, respectively).
Conclusions: Early menopause is positively associated with coronary heart disease and stroke in a multiethnic cohort, independent of traditional cardiovascular disease risk factors.

Introduction

Cardiovascular disease (CVD) is the leading cause of death in US women.[1] The early identification of women at high risk of CVD and implementation of appropriate lifestyle and medical therapy are of tremendous public health importance. Current strategies for identifying high-risk women involve counting major coronary heart disease (CHD) factors and estimating 10-year risk with algorithms.[2-4]The algorithm most commonly used to identify women at high risk of CHD, the Framingham risk score, relies heavily on age and biomarkers. Clinical history, including smoking history, is incorporated. However, reproductive health history is not, yet a number of cohort studies have identified an association between early menopause and cardiovascular risk.[5-12]
The Adult Treatment Panel II report included a history of premature menopause in global CVD risk assessment.[13] It considered premature menopause without estrogen therapy a risk factor for CHD. This, plus one other risk factor (family history of premature CHD, current cigarette smoking, hypertension, low high-density lipoprotein [HDL] cholesterol level, or diabetes), identified a woman as having high CHD risk. This was based on observational studies that indicated that increases in low-density lipoprotein with menopause were reversed by hormone therapy (HT).[14] The panel posited that the presence of estrogen may protect women from CHD. However, subsequent panels (Adult Treatment Panel III[3,15]) dropped early menopause as a risk factor. This may have been because HT was not shown to confer protection from CHD in randomized trials.[16,17]
Whether HT benefits vascular health is intensely debated. However, observational studies consistently show that early age at menopause is associated with CHD[7,10] and, possibly, stroke.[9] These studies have included mostly white or European populations and may not be generalizable to US women not of European origin. Therefore, we investigated whether early menopause (menopause before age 46 y) was associated with CHD and stroke in a multiethnic population of US women. We further investigated whether this relationship was independent of traditional CVD risk factors.

Methods

Design Overview, Setting, and Participants

The Multi-ethnic Study Atherosclerosis (MESA) is a multicenter, longitudinal cohort study of the prevalence and correlates of subclinical CVD and the factors that influence its progression.[18] Between July 2000 and August 2002, a total of 3,213 men and 3,601 women who identified themselves as white, black, Hispanic, or Chinese; who reported that they were free of CVD; and who were 45 to 84 years of age were recruited from six US communities: Baltimore City and Baltimore County, MD; Chicago, IL; Forsyth County, NC; Los Angeles County, CA; Northern Manhattan and the Bronx, NY; and St Paul, MN. Details on the sampling frames and the cohort examination procedures have been published previously.[18]Informed consent was obtained from each participant, and the study was approved by the institutional review boards of each institution.
At the baseline examination (July 2000-August 2002), medical history, anthropometric measurements, and laboratory data were obtained. Age, sex, ethnicity, and medical and medication histories were obtained by questionnaire. Family history of CVD was defined as having a self-reported history of a first-degree relative (parent, sibling, or child) with heart attack. Ever smoking was defined as having smoked 100 or more cigarettes in a lifetime. Diabetes mellitus was defined as a fasting glucose of 126 mg/dL or greater[19] or use of a hypoglycemic medication.
Blood pressure (BP), weight, and height were measured using standardized protocols.[18,20]Hypertension was defined as a systolic BP greater than 140 mm Hg, diastolic BP greater than 90 mm Hg (Joint National Committee VI[21]), or self-report of hypertension plus the use of an antihypertensive medication. Body mass index (BMI) was calculated as weight (kg) divided by height squared (m2). Plasma total and HDL cholesterol and glucose levels were measured after a 12-hour fast.
As part of the in-person MESA baseline assessment, questions relevant to menopause status were asked of women participants. Natural menopause was determined with the questions "Have you gone through menopause (change of life)?" or "Are you currently going through menopause?" Age at natural menopause was determined with the question "At what age did you go through menopause (year)?" Surgical menopause was determined with the question "Have you had surgery to remove your ovaries?" Age at surgical menopause was determined with the question "At what age?" All women were asked, "Have you ever taken HT?"
These questions were asked as part of an interviewer-administered form. For each question, possible responses are "yes," "no," "don’t know," and/or "not applicable" or "N/A" (not applicable). The interviewer was instructed to have the participant choose the appropriate responses for each question. The interviewers were instructed not to probe or to make interpretations about a participant’s specific symptoms. They were instructed to ask questions as written and record answers as given. Chart reviews were not performed to confirm menopause status or surgical history.
For our study, early menopause was defined as self-reported menopause at age younger than 46 years. The use of the age cutpoint of 46 years allowed for the categorization of any woman notreporting menopause at baseline as unexposed to early menopause. This was because all MESA women were at least age 45 years of age at enrollment.
Among all MESA women (n = 3,601), 1,261 (35%) reported hysterectomy. This prevalence of hysterectomy appears consistent with a previously published report from the National Women’s Health Information Center that one third of women aged 60 years in the United States have undergone hysterectomy.[22] In our study, participants with hysterectomy without oophorectomy, missing data, or inconsistent data regarding menopause status were excluded from our sample (Figure 1). In our sample, 27% of women reported early menopause (either natural or surgical). In comparison, in a cohort study of age at natural menopause and mortality by Snowdon et al,[12] age 46 years represented the 25th percentile for age at natural menopause.
Description: http://img.medscape.com/article/771/887/771887-Figure1.jpg
Figure 1.
Flow of Multi-ethnic Study of Atherosclerosis Sample Selection of Women With and Without Early Menopause

CHD and Stroke Outcomes

The MESA cohort has been followed for incident cardiovascular events for a median of 57.3 months (range, 1.3-73.2 months). The primary means of identifying possible events in MESA is participant self-report via post-baseline contacts (follow-up calls) conducted by telephone. Field center staff may also learn of potential events in other ways: participants may notify the clinic when they experience an event; a MESA examination may identify a possible event; investigation of one event may identify another event; National Death Index search could identify a death; or field center staff may learn of a participant’s death through an obituary or other public notice.
At intervals of 9 to 12 months, a telephone interviewer contacted each participant regarding hospital admissions, cardiovascular outpatient diagnoses, and deaths. To verify self-reported diagnoses, copies of all death certificates and medical records for hospitalizations and outpatient cardiovascular diagnoses were requested. For out-of-hospital cardiovascular deaths, next-of-kin interviews were performed. Records on an estimated 98% of reported hospitalized cardiovascular events and some information on 95% of reported outpatient diagnostic encounters were obtained. Two physicians independently reviewed and classified CVD events and assigned incidence dates. If they disagreed, they adjudicated their differences via discussion.
Periodically, the Coordinating Center will search the National Death Index for participants with whom the study has lost touch. The Field Centers will then be notified of these deaths so that additional information can be obtained and so that the death can go to physician review. Criteria for events are available on the MESA Web site (http://www.mesa-nhlbi.org/Mesa-Internal/manuals.asp) and are described in published MESA manuscripts.[23]
Reviewers classified an MI as definite or probable if either abnormal cardiac biomarkers (two times upper limits of normal) regardless of pain or ECG findings; evolving Q waves regardless of pain or biomarker findings; or a combination of chest pain and ST-T evolution or new left bundle branch block and biomarker levels one to two times the upper limits of normal was present. Reviewers classified a resuscitated cardiac arrest as present when a subject had successfully recovered from a full cardiac arrest through cardiopulmonary resuscitation (including cardioversion). The reviewers classified CHD death as present or absent based on hospital records and interviews with families. Definite fatal CHD required an MI within 28 days of death, chest pain within 72 hours before death, or a history of CHD and the absence of a known nonatherosclerotic or noncardiac cause of death. Neurologists reviewed and classified stroke as present if there was a focal neurologic deficit lasting 24 hours or until death, with a clinically relevant lesion on brain imaging and no nonvascular cause.
For this report, we defined incident CHD as definite or probable MI, resuscitated cardiac arrest, or definite CHD death. Incident stroke included fatal and nonfatal stroke. Follow-up was from the baseline examination until the first CVD event, loss to follow-up, death, or October 14, 2008, whichever came first.

Statistical Analyses

The association between early menopause and incident CHD and stroke was examined in Kaplan-Meier survival analyses and Cox proportional hazard models. Proportional hazard models were first adjusted only for age. The models were then adjusted for demographics (race/ethnicity and MESA site) and traditional CVD risk factors (hypertension, ever smoking, diabetes mellitus, and total and HDL cholesterol). Additional models included BMI and family history of CHD. Secondary analyses included adjustment for HT use and type of menopause (natural vs surgical). Interactions between early menopause and (1) HT use, (2) type of menopause, and (3) ever smoking were performed after adjustment for age, race/ ethnicity, and MESA site. We also performed sensitivity analyses that included adjustment for education as a proxy for socioeconomic status.
To assess discrimination of a model including traditional CVD risk factors only (hypertension, ever smoking, diabetes mellitus, and total and HDL cholesterol) versus a model that also includes early menopause, we performed multiple statistical tests. Hazard ratios (HRs) were estimated for each regression model. The incremental statistical significance of early menopause when added to the traditional CVD risk factor model was evaluated with the Wald test of significance of the Β coefficient. Discrimination was assessed using the area under the receiver operator characteristic curve (C-statistic). The C-statistic for each model was compared with the C-statistic for the baseline model using a binomial test (Mann-Whitney U test). All statistical analyses were performed with Stata version 8.0 (StataCorp, Austin, TX; http:// www.stata.com) with significance set at P <0.05 (two tailed).

Results

Table 1. Characteristics of Women With and Without Early Menopause (n = 2,509) 
Characteristic
Early menopause (n = 693)
No early menopause (n= 1,816)
P
Age, y


0.001
45-54
162 (23)
368 (20)

55-64
189 (27)
573 (32)

65-74
206 (30)
615 (34)

75-84
136 (20)
260 (14)

Education


0.34
<High school
152 (22)
268 (20)

graduate



≥High school
537 (79)
1,443 (80)

graduate



Race/ethnicity



White
241 (35)
746 (41)
<0.001
Chinese
56 (8)
275 (15)

Black
213 (31)
428 (24)

Hispanic
183 (26)
367 (20)

Live births, median
3 (1-4)
3 (2-4)
0.31
(IQR)



Pregnancies,
3 (2-5)
3 (2-5)
0.40
median (IQR)



Type of menopause


<0.001
Natural
446 (64)
1,623 (89)

Surgical
247 (36)
193 (11)

Hormone therapy


0.006
Ever use
362 (53)
837 (47)

Never use
319 (47)
946 (53)

Data are presented as n (%), unless otherwise indicated.
IQR, interquartile range
Table 1 includes the baseline characteristics of participants with early menopause (n = 693) versus no early menopause (n = 1816). Compared with participants without early menopause, a greater percentage of women with early menopause were black or Hispanic, 75 to 84 years old at baseline, surgically menopausal, and had ever used HT.
Table 2. CVD Risk Factors of Women With and Without Early Menopause (n = 2,509) 

Early
No early

CVD risk factors
menopause
menopause

(baseline examination)
(n = 693)
(n= 1,816)
P
Smoking



Never
380 (55)
1110(61)
<0.001
Past
209 (30)
532 (29)

Current
104 (15)
174 (10)

Total cholesterol, mg/dL
203 ± 37
201 ± 36
0.36
HDL cholesterol, mg/dL
56 ± 15
57 ± 15
0.44
Diabetes, %a
97 (14)
195 (11)
0.021
Systolic blood pressure,
129 ± 25
128 ± 23
0.29
mm Hg



Diastolic blood pressure,
69 ± 11
69 ± 10
0.68
mm Hg



Hypertension, %b
337 (49)
863 (48)
0.25
Family history of CVD
323 (50)
811 (47)
0.23
BMI
28.9 ± 6.3
28.2 ± 6.0
0.023
Data are presented as mean ± SD or n (%).
CVD, cardiovascular disease; HDL, high-density lipoprotein; BMI, body mass index.
aAmerican Diabetes Association 2003 definition[19] or use of diabetes medication. 
b
Joint National Committee VI definition or use of antihypertensive medication.
Table 2 includes the baseline CVD risk characteristics of participants with or without early menopause. Women with early menopause were more often smokers, had diabetes, and had a higher average BMI.

CHD and Stroke Events

Fifty CHD events (23 with early menopause vs 27 without) and 37 stroke events (18 with early menopause vs 19 without) occurred during a median follow-up of 4.78 years (interquartile range, 4.59-4.97 y). Traditional CVD risk factors were associated with incident CHD and stroke events (see Table, Supplemental Digital Content,http://links.lww.com/MENO/A28). CHD-free and stroke-free survival was significantly lower for women with early menopause (Figure 2 and Figure 3).
Description: http://img.medscape.com/article/771/887/771887-Figure2.jpg
Figure 2.
Kaplan-Meier Survival Curves for Coronary Heart Disease in Women With and Without Early Menopause
Description: http://img.medscape.com/article/771/887/771887-Figure3.jpg
Figure 3.
Kaplan-Meier Survival Curves for Stroke in Women With and Without Early Menopause

Early Menopause as a Predictor of CHD and Stroke

Early menopause was an independent predictor of CHD and stroke after adjustment for age, race/ethnicity, and MESA site (HR, 2.11; 95% CI, 1.19-3.75; and HR, 2.10; 95% CI, 1.08-4.07). It remained an independent predictor of CHD and stroke after further adjustment for traditional CVD risk factors (HR, 2.08; 95% CI, 1.17-3.70; and HR, 2.19; 95% CI, 1.11-4.32). The HRs were attenuated after adjustment for family history of CVD (HR, 1.80; 95% CI, 0.99-3.29; and HR, 1.98; 95% CI, 0.98-4.00). Further adjustment for HT use did not alter the HRs appreciably (HR, 1.85; 95% CI, 1.01-3.37; and HR, 2.03; 95% CI, 1.00-4.10; Table 3 ). In sensitivity analyses that also adjusted for education, the HRs were not significantly different.

Discrimination for CHD

The C-statistic for the traditional CVD risk factors was 0.68 in our sample. When the predicted hazard due to both early menopause and traditional CVD risk factors was used, the C-statistic was 0.70 (P = 0.55 vs traditional CVD risk factors alone).

Secondary Analyses

Adjustment for type of menopause did not alter the results significantly. Analyses did not provide evidence for interactions between early menopause and the covariates (1) HT use, (2) type of menopause, and (3) ever smoking. However, power was limited for these analyses.

Discussion

 Early menopause was a significant predictor of future CHD and stroke in our population-based sample of multiethnic US women, independent of traditional CVD risk factors. We found that women with early menopause have approximately a twofold increased risk of a future CHD or stroke event. Our findings align with other large-scale epidemiologic studies of early age at natural menopause and CHD. However, most of these studies assessed CHD mortality and were predominantly in European or white cohorts.[7,8,11,24] For example, studies of Norwegian, Netherlands, and Seventh Day Adventist cohorts have all shown a 1.5- to 2-fold increase in CHD mortality in women with menopause at early ages (various ages <45 y) versus those with menopause at more average ages (various ages >49 y).[7,8,11] In the Nurses’ Health Study, early natural menopause (age at menopause, 40-44 vs 50-54 y) and MI were significantly related (relative risk, 1.42; 95% CI, 1.08- 1.86) after adjustment for traditional risk factors.[10]
As compared with prior studies of early age at surgical menopause and CHD events, our findings are not as strong.[6,25] However, prior studies did not always adjust for other risk factors[5,25] and included women close to the time of their surgical menopause. For our study, we defined early menopause as self-reported menopause that occurred naturally or surgically before age 46 years. We lacked adequate power to test for interactions between type of menopause (natural vs surgical) and early menopause and our CVD outcomes. Longer follow-up of the MESA cohort may provide sufficient power. This could provide valuable information for women weighing the risks and benefits of hysterectomy and oophorectomy. Currently, the risks and benefits of early hysterectomy and oophorectomy are unclear. A recent study of the Women’s Health Initiative (WHI) observational cohort found that in women who underwent hysterectomy at age younger than 40 years, oophorectomy is associated with a slightly lower risk of ovarian and, possibly, breast cancer without an increased risk of CVD.[26]

Early Menopause and Stroke

Our study showed that early menopause was associated with an increased risk of stroke. Prior studies have found a relationship between early menopause and stroke, although not consistently. Studies of a Japanese cohort[27] and the Framingham cohort[9] have found a twofold increased risk of stroke in women with menopause ages younger than 42 years as compared with women without early menopause. In the Framingham cohort, this increased risk persisted even when the sample was restricted to women who never smoked.[9] However, in a Norwegian cohort[28] and the Nurses’ Health Study,[10] age at natural menopause and stroke appeared unrelated.

Factors Affecting Early Menopause

Smoking and age at menopause are closely linked,[29-31] and smokers reach menopause, on average, 2 years earlier than nonsmokers do.[32] Thus, studies of the relationship between early menopause and CVD that do not adjust for smoking are probably confounded. Even in studies that control for smoking, significant interactions between smoking and early menopause may remain. For example, in the Nurses’ Health Study cohort (35,000 women), the significant relationship between early natural menopause and MI disappeared among the nonsmokers but remained in the smokers when these two groups were stratified. We did not have adequate power to test for an interaction between smoking history and early menopause when assessing our CVD outcomes. Longer follow-up of the MESA cohort may provide us with this information in the future.
In our study, after adjustment for family history of CVD, early menopause was no longer a statistically significant predictor of CVD events. This may be because (1) of insufficient power, (2) family history of CVD is a better predictor of CVD than early menopause, or (3) the variables are highly related. The timing of menopause and CVD both appear highly heritable. Family history of premature CHD is included in CVD risk algorithms developed for postmenopausal women.[2] Family history of menopause age is highly associated with age at natural menopause.[33,34] Because of these observations, crosscohort analyses of genetic variation in CVD and reproductive aging are currently underway.[35,36] However, studies of both family history of menopause and family history of CVD are also needed. These studies could identify the optimal family and reproductive history variables for inclusion in CVD risk algorithms.

Limitations

Validity and Accuracy of Self-report of Age at Menopause. Our study has several limitations, including the accuracy and precision of self-reported menopause. Given a recent National Institutes of Health consensus definition of natural menopause as "12 months of amenorrhea following the final menstrual period (FMP),"[37] menstrual calendars obtained at the time of waning ovarian function are a reasonable gold standard for determining menopause. However, this requires following women beginning early in life. One menstrual calendar study that began during college life found that at ~7 years after menopause, 76% of women accurately report menopause within 1 year of their final menstrual period. On average, this recalled age is slightly higher than the menstrual calendar age at menopause.
Studies of precision of natural menopause recall from the Nurses’ Health Study[38] and National Health and Nutrition Examination Survey[39] have found worsening precision over time. Depending on the follow-up interval, 82% to 44% of women recall an age at menopause within 1 year of their initial report. Precision appears to decrease as time since menopause increases, but this decrease is not related to current age or education.[39] It may have a regression toward the mean pattern, with women initially reporting early menopause subsequently reporting an older age at menopause.[40] These previous studies of menopausal recall suggest that our findings may be biased toward the null.
Women's accuracy of reporting ovarian removal at hysterectomy appears low with a bias toward underreporting when checked against medical records (sensitivity and positive predictive value, 64% and 100%).[41] Women's precision in recalling age at surgical menopause appears superior to recalling age at natural menopause, with less variance over time.[38,39,42] Given these data, some participants excluded for reporting simple hysterectomies were probably surgically menopausal; however, it is improbable that surgically menopausal participants were misclassified. In general, accuracy and precision issues surrounding self-reported surgical menopause should not bias our findings significantly.
Exclusion of Simple Hysterectomy. Bias may be introduced by the exclusion or inclusion of women with simple hysterectomy in studies of the timing of menopause and clinical outcomes.[43,44] Loss of menstrual bleeding due to a waning of ovarian function cannot be observed in hysterectomized women. Age at menopause is thus unknown in this group. Studies including women with simple hysterectomy use varying definitions for age at menopause in women with simple hysterectomy (based on symptoms, surgery, or arbitrary age cutpoints). These varying definitions have been shown by some[43] but not other[44] researchers to alter conclusions significantly. We excluded women with simple hysterectomy from our analyses, and our findings are not applicable to this group.
Survival Bias. MESA participants were CVD-free at baseline at ages 45 to 84 years. Women in MESA may represent survivors of early menopause who did not develop CHD or die before enrollment. The true point estimate for the relationship between early menopause and CVD may be larger than we observed because of survival bias.
Strengths and Implications. We found that early menopause is a moderate predictor of CHD and stroke, even after adjusting for traditional CVD risk factors in a diverse population of US women. This may suggest that early menopause, if possible, should be avoided and that women with early menopause may be a group to target for aggressive CVD prevention strategies. Before the WHI trial findings were released, physicians recommended oral HT, anticipating that this therapy would negate any detrimental cardiovascular effects associated with menopause. Given the lack of cardioprotective benefit and potential harms of menopausal HT,[16,17] long-term therapy with HT is no longer recommended for postmenopausal women.[45] However, the use of HT in women with early menopause until the time of an average age of menopause (~50 y) remains in the guidelines,[46,47]although a paucity of data exists regarding the risks and benefits of this approach.
Given the current lack of evidence that perimenopausal or menopausal HT is cardioprotective, reducing the incidence of early surgical menopause by reducing elective oophorectomy may be an important step to reduce CVD risk. Since the release of the WHI results, the rate of elective oophorectomy has decreased.[48] In 2008, the American College of Obstetrics and Gynecology suggested that elective oophorectomy should be avoided in premenopausal women.[49] However, although women from the WHI observational cohort with hysterectomy have worse CVD risk as compared with women without hysterectomy,[50] recent data from the WHI suggest that simple hysterectomy and hysterectomy with oophorectomy carry equivalent CVD risks.[26] This suggests that CVD risk factors may contribute to problems underlying the decision to undergo hysterectomy as well as the development of CVD.
It is possible that CVD risk early in life contributes to both early menopause and CVD through similar mechanisms. Trajectories of risk factors for CVD (eg, cholesterol, weight, and BP) measured during the premenopause have been associated with the timing of subsequent natural menopause in one study.[51] Smoking has been associated with early natural menopause in numerous studies,[29-31]although there is no available evidence that smoking cessation extends menopause age. Reducing early menopause by eliminating smoking exposure could provide an additional benefit from smoking cessation.

Conclusions

In summary, our findings demonstrate a moderate association between early menopause and future CHD and stroke. This adds to the body of evidence that early menopause may identify the at-risk woman who may benefit from aggressive CVD primary prevention. Strategies to prevent early menopause, such as avoidance of smoking and oophorectomy, may have significant public health relevance for the prevention of CVD in women.

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