Overview
Elevated
blood pressure (BP), also termed hypertension, is a common, powerful, and
independent risk factor for cardiovascular diseases (CVD) and kidney disease.
Approximately 25 percent of the adult U.S. population, about 50 million persons,
has hypertension, defined as current use of anti-hypertensive medication, a
systolic BP >140 mmHg, and/or diastolic BP > 90 mmHg. In view of the
epidemic of high BP and its complications, prevention and control of high BP
continues to be a major national health priority. Governments, institutions,
health care providers, insurers, private industry, and non-profit organizations
have committed substantial resources to prevent and treat hypertension. Still,
hypertension control rates have been unsatisfactory. Measuring BP to diagnose
hypertension and to monitor therapy is problematic. Concomitantly, the enormous
scope of the BP problem, the high aggregate costs of hypertension care, and the
potential for medication side effects have spawned efforts to target therapy
more effectively. This entails identifying lower risk individuals who might be
candidates for less aggressive therapy and higher risk individuals who should
receive more aggressive therapy. Measurement of BP outside of the office or
clinic setting by ambulatory BP (ABP) monitoring and self-measured BP (SMBP)
monitoring might accomplish these
objectives.
Clinic Blood
Pressure Measurements
BP as recorded in
the office or clinic setting is the standard technique recommended for
measurement of BP in routine medical care. The standard technique includes use
of a mercury sphygmomanometer (or a calibrated aneroid device or validated
electronic device) and an appropriate-sized cuff. Prior to measurement, patients
should rest quietly in the seated position for several minutes. At each visit,
at least two readings should be obtained. Except for those individuals with
extremely high BP, the diagnosis of hypertension and adjustments in medication
should then be based on the average of readings across two or more visits.
Clinic BP measurements have several limitations, even if they are measured
according to established guidelines. First, clinic BP measurements exhibit
enormous variability, which hinders accurate classification and which frustrates
providers and patients. Another limitation is that BP measured in the clinic may
not be a representative estimate of usual BP outside the clinic setting.
Commonly, BP rises in the clinic setting, in response to the observer and/or
other aspects of the medical environment. The difference between measurements
obtained in and outside the clinic setting leads to confusion about the
diagnosis of hypertension and the need to start or modify therapy.
Unfortunately, there are additional limitations because clinic measurements
often do not conform to established guidelines. Specific limitations include
lack of observer training, inadequate rest period prior to initial measurement,
use of wrong-sized cuffs, rapid deflation of cuff, incorrect position of
patients, and awkward position of the observer and/or manometer. Over the past
several years, stationary automated devices and aneroid devices have
increasingly replaced
mercury.
Evidence
Report/Technology
Assessment
Utility of Blood
Pressure Monitoring Outside of the Clinic
Setting
Summary
Agency
for Healthcare Research and Quality sphygmomanometers in the clinic setting.
Aneroid devices are inexpensive but still require an individual, typically a
health care provider, to manually inflate a cuff and record the appearance and
disappearance of Korotkoff sounds. In contrast, fully automated devices require
minimal technical skills, that is, only placement of a cuff and initiation of a
reading. An additional reason leading to greater use of aneroid and automated
devices stems from concerns over mercury
toxicity.
Self-measured
Blood Pressure (SMBP)
SMBP devices
include mercury sphygmomanometers, aneroid manometers, semiautomatic devices,
and fully automatic electronic devices. Automatic devices measure BP using an
oscillometric technique in which systolic and diastolic BP are estimated from
the pattern of vibrations in the cuff as it is deflated. Fully automated devices
are popular because the patient does not have to inflate the cuff or listen for
the appearance and disappearance of Korotkoff sounds. Although numerous, perhaps
hundreds, of SMBP devices are on the market, very few have been independently
validated. SMBP devices provide an opportunity to record BP at home, outside of
the artificial setting of the medical office or clinic. Ideally, the patient is
trained to record BP using a standard technique. Occasionally, physicians may
observe the patient recording a BP measurement in the clinic and then perform a
cross check of readings. The presentation of SMBP data is extraordinarily
variable. Commonly, patients at their own initiative provide written lists of
readings to their physicians at office visits. However, recent innovations have
greatly enhanced the potential utility of SMBP devices to synthesize and present
data. Contemporary SMBP devices have the capacity to store and download readings
via phone or computer. Data can then be synthesized and reports can be generated
and sent to the patient and/or physician. SMBP has several potential uses.
Repeated measurements, if averaged, should provide a more precise estimate of
usual BP than occasional measurements obtained in the clinic. As a substitute
for clinic BP, SMBP monitoring could then be used to adjust anti-hypertensive
drug therapy and thereby reduce the need for frequent clinic visits and their
associated costs and inconvenience. The extent to which physicians, or patients,
use SMBP data to adjust medication is unclear. In addition, selfmeasurement of
BP has also been proposed as a means to improve adherence with treatment.
Self-measurement of BP theoretically provides a means to diagnose white coat
hypertension (WCH), also termed nonsustained or office hypertension. This
pattern refers to an elevation of clinic BP in the hypertensive range but normal
or low BP outside the clinic setting. Individuals with WCH may be at
comparatively low risk for BP-related complications in comparison to individuals
with sustained hypertension. An important issue is whether the risk of WCH
exceeds that of
nonhypertensives.
Ambulatory
Blood Pressure
(ABP)
Measurement
ABP
monitoring is a noninvasive, fully automated technique in which BP is recorded
over an extended period of time, typically 24 hours. The required equipment
includes a cuff, a small monitor (attached to a belt), and a tube connecting the
monitor to the cuff. Usually, a trained technician places the device on the
patient, provides instructions to the patient, and then downloads data from the
device when the patient returns. Most ABP devices use an oscillometric
technique. Compared to SMBP, relatively few ABP devices are on the market.
However, in contrast to SMBP devices, most currently available ABP devices have
undergone validation testing, as recommended by the American Association of
Medical Instrumentation (AAMI) or the British Hypertension Society (BHS). During
a typical ABP monitoring session, BP is measured every 15 to 30 minutes over a
24-hour period (including both awake and asleep hours). The total number of
readings usually varies between 50 and 100. BP data are stored in the monitor
and then downloaded into device-specific computer software. The raw data can
then be synthesized into a report that provides mean values by hour and period
(daytime [awake], nighttime [asleep], and 24-hour BP), both for systolic and
diastolic BP. The most common output used in decisionmaking are absolute levels
of BP, that is, mean daytime, nighttime, and 24-hour values. Because of the
expense of ABP equipment (up to $5,000 for a monitor, cuff set, and software),
the requirement for technicians, the inconvenience and logistics of placing and
removing ABP devices, and, until recently, the lack of reimbursement, it is
uncommon for ABP monitoring to be done frequently. However, use of ABP will
likely increase as a result of the decision by the Centers for Medicare and
Medicaid Services (CMS) to cover ABP in selected settings, namely, the
identification of WCH. In addition to mean absolute levels of ABP, certain ABP
patterns may predict BP-related complications. The patterns of greatest interest
are WCH and nondipping BP. Using both daytime and nocturnal ABP, one can
identify individuals, termed nondippers, who do not experience the decline in BP
that occurs during sleep hours. Usually, nighttime (asleep) BP drops by 10
percent or more from daytime (awake) BP. Research has suggested that individuals
with a nondipping pattern (less than 10-percent BP reduction from night to day)
may be at increased risk of BP-related complications compared to those with a
normal dipping pattern.
Although ABP
could be used to monitor therapy, the most common application is diagnostic,
that is, to ascertain an individualís usual level of BP outside the
clinic setting and thereby identify individuals with WCH. In addition to
detection of WCH, ABP devices may be used to identify individuals with a
nondipping BP pattern and to evaluate apparent drug resistance, hypotensive
symptoms to medications, episodic hypertension, and autonomic dysfunction. Use
of ABP monitoring has been controversial. First, few prospective studies have
determined whether this technology predicts cardiovascular disease outcomes and
whether this technology provides additional information beyond that of routine
clinic measurements. Second, insurers have been concerned that health care
providers might overutilize ABP. Third, it has been unclear whether SMBP
monitoring is a satisfactory and less expensive alternative to ABP monitoring.
Accordingly, health insurers have been reluctant to reimburse for ABP
monitoring.
Reporting the
Evidence
The utility of BP monitoring
outside of the clinic setting was a topic nominated to the Agency for Healthcare
Research and Quality (AHRQ) by a group of experts in BP measurement. In
September of 2000, the AHRQ awarded a contract to the Johns Hopkins
Evidence-based Practice Center (EPC) to prepare an evidence report on this
topic. The Johns Hopkins EPC established a team and work plan to develop a
report that would identify and synthesize the best available evidence on BP
monitoring. One of the first tasks was the identification of an appropriate
partner. In December 2000, the National High Blood Pressure Education Program
(NHBPEP) of the National Heart, Lung, and Blood Institute (NHLBI) of the
National Institutes of Health (NIH) hosted a working meeting. The NHBPEP
includes representatives from national professional and voluntary organizations
as well as from Federal agencies. Arising from that meeting was an agreement
from the NHBPEP Coordinating Committee to partner with the Johns Hopkins EPC on
this project. A core group of five clinically and/or methodologically oriented
technical experts advised the EPC team at key points in the project. This group
included experts in ABP monitoring, SMBP monitoring, clinic BP measurement,
clinical hypertension, and diagnostic test evaluation. These individuals
reviewed draft research questions. Also, this core group along with additional
experts in BP measurement and hypertension provided early input at an ad hoc
meeting convened by the NHBPEP. The target population consisted of nonpregnant
adults with BP in the nonhypertensive or hypertensive range. These individuals
are candidates for BP monitoring, and many are candidates for anti-hypertensive
drug therapy.
Key
Questions
After an extensive
deliberative process and with input from the technical experts, the following
questions were developed:
•
Comparison of clinic, ambulatory, and SMBP
readings:
1a. What is the
distribution of the BP differences between clinic, ambulatory, and SMBP
readings? If there are differences, are these differences
reproducible?
1b. What is the
prevalence of WCH as defined by SMBP? Is this pattern
reproducible?
1c. What is the
prevalence of WCH as defined by ABP measurement? Is this pattern reproducible?
• SMBP levels and WCH based on SMBP as related to clinical
outcomes.
2a. Is SMBP more or less
strongly associated with BPrelated target organ damage than clinic BP
measurements?
2b. Does SMBP predict
subsequent clinical outcomes?
2c. What
is the incremental gain in prediction of clinical outcomes from use of
self-measurement devices beyond prediction from clinic BP
alone?
2d. What is the effect of
treatment guided by SMBP in comparison to treatment guided by clinic BP, in
terms of:
i. BP-related target organ
damage
ii.
symptoms
iii. use of anti-hypertensive drug
therapy
iv. BP
control
• ABP levels and WCH
based on ABP as related to clinical
outcomes:
3a. Is ambulatory blood
pressure more or less strongly associated with BP-related target organ damage
than clinic BP measurements?
3b. Does
ambulatory blood pressure predict subsequent clinical
outcomes?
3c. What is the incremental
gain in prediction of clinical outcomes from use of ambulatory devices beyond
prediction from clinic BP alone?
3d.
What is the effect of treatment guided by ABP in comparison to treatment guided
by clinic BP, in terms of:
i.
BP-related target organ damage
ii.
symptoms
iii. use of anti-hypertensive drug
therapy
iv. BP
control
• Does the evidence for
the above questions vary according to a patient’s age, gender, income
level, race/ethnicity, and clinical subgroups (e.g., hypertensive/normotensive,
diabetic, renal transplant
status)?
Methodology
Searching
the literature included identifying reference sources, formulating a search
strategy for each source, and executing and documenting each search. A
comprehensive search plan was developed that include electronic and hand
searching. Several electronic databases were searched and a separate strategy
was developed for each. First searched was
MEDLINE®,
which was accessed through
PubMed®.
Searches using PubMed®
were completed in January 2001 and March 2001.
The Cochrane CENTRAL Register of Controlled Trials was searched once (Issue 1,
2001). HealthSTAR was searched in February 2001. Hand searching for possibly
relevant citations took several forms. First, priority journals were identified
through an analysis of the frequency of citations per journal in the database of
search results as well as through discussions amongst the EPC team. Fifteen
specialty and general journals were identified. The January to May 2001 issues
of these journals were searched. For the second form of hand searching, a
database of reference material, identified through an electronic search for
relevant guidelines and reviews, through discussions with experts, and through
the article review process, was created in the reference management software,
ProCite. A listing of titles and abstracts from this database, the BP References
Database, was reviewed by the principal investigator to identify key articles.
The reference lists of these articles were then reviewed to identify possibly
relevant citations. Finally, proceedings from recent conferences were also
reviewed.
Abstract and
Article Review Process
Specific
inclusion and exclusion criteria were applied at each of three levels of review
(two levels of abstract review, then article review). Inclusion criteria became
more stringent at each level. The titles and abstracts were reviewed for each
article identified. During the abstract review process, emphasis was placed on
identifying all articles that may possibly have original data pertinent to the
questions. For the first-level abstract review, titles and abstracts for all
articles retrieved by the literature search were printed on an abstract form and
distributed to two reviewers. Because of the extensive volume of literature, a
second level abstract review, at which additional exclusion criteria were
applied, was necessary. Citations deemed eligible for full article review based
on the initial abstract review were printed onto the second level abstract form
and distributed to two reviewers. The purpose of the article review was to
confirm the relevance of each article to the research questions, to determine
methodological characteristics pertaining to study quality, and to collect
evidence that addressed the research questions. Because of the large number of
citations that remained eligible for full article review even after the second
level abstract review, additional exclusion criteria were applied at the article
review level. The final full list of exclusion criteria differed by question.
For instance, for question 1a, a comparison of BP by the different techniques,
the criterion of more than 1 day of measurement for clinic BP was added because
an average clinic BP based on just 1 day of measurements (typically just one to
three readings) is extremely imprecise and could lead to a biased comparison
with ABP or SMBP. Article review forms were developed to collect data in a
standardized fashion. This process was complex and time consuming due to the
heterogeneity of the literature and the diverse questions being addressed. These
forms then guided article review. For each of the articles deemed potentially
eligible after second-level abstract review, two reviewers read the article,
confirmed eligibility status, abstracted key information, and assessed study
quality on several dimensions. Because of heterogeneity in study design, data
collection forms and elements differed by research
question.
Presentation of
Results
Evidence tables that summarize
aspects of study quality, characteristics of the study population, and features
of BP measurement were constructed. For most research questions, these summary
tables were similar. However, the evidence tables that display study results
differed substantially by research question. Qualitative summaries were prepared
which synthesized the evidence and included, to a limited extent, a quantitative
assessment (for example, the number/percent of studies with significant
associations, overall and occasionally by relevant study characteristics). A
draft version of the report was distributed to the partner, the technical
advisory group, and other peer reviewers. All substantive comments were
collated, the responses of the EPC team summarized, and edits were made to the
report as
appropriate.
Findings
Key
question 1. Comparison of clinic BP, SMBP, and ABP
readings.
• Question 1a.
Distribution of BP differences.
A total
of 18 studies addressed the distribution of BP differences. BP levels measured
outside the clinic setting differed from those obtained in the clinic. For both
systolic and diastolic BP, clinic measurements exceeded SMBP, daytime ABP,
nighttime ABP, and 24-hour ABP. In the few studies that compared SMBP and ABP,
daytime ABP and SMBP appeared similar, while nighttime ABP was consistently
lower than SMBP. The literature was insufficient to determine whether these BP
differences are reproducible.
•
Question 1b. Prevalence of WCH based on
SMBP.
A total of four studies addressed
this issue. Hence, the literature was insufficient to determine the prevalence
of WCH by SMBP.
• Question 1c.
Prevalence of WCH based on ABP.
A total
of 16 studies addressed this issue. Prevalence varied by WCH definition and
study population. Overall, the prevalence was approximately 20 percent among
patients with hypertension. Only two studies addressed the reproducibility of
WCH. Hence, the literature was insufficient to determine whether WCH based on
ABP is reproducible.
Key question 2.
The relationship of SMBP levels and WCH based on SMBP to clinical
outcomes.
• Question 2a.
Associations of SMBP with target organ
damage.
Only one study addressed this
issue. Hence, the literature was insufficient to determine the associations of
absolute SMBP levels or WCH as determined by SMBP with left ventricular mass or
proteinuria.
• Question 2b.
Associations of SMBP with clinical outcomes in prospective
studies.
Only one study addressed this
issue. Hence, the literature was insufficient to determine whether absolute SMBP
levels or WCH based on SMBP predicts subsequent
CVD.
• Question 2c. Comparison
of risk prediction from SMBP and clinic
BP.
Only one study addressed this
issue. The dearth of studies combined with the poor or uncertain quality of
clinic BP measurements precluded an answer to this
question.
• Question 2d.
Effect of treatment guided by
SMBP.
Twelve trials addressed this
issue, but the evidence was inconsistent. In half of these trials, interventions
that included SMBP led to reduced BP. Two trials used contemporary SMBP
technology which can store and synthesize SMBP measurements and which can
generate BP reports. In both of these trials, the SMBP intervention led to
reduced BP.
Key question 3. The
relationship of ABP levels and WCH based on ABP to clinical
outcomes.
• Question 3a.
Cross-sectional associations of ABP with target organ
damage.
A total of 25 studies addressed
these issues. Left ventricular mass and albuminuria were positively associated
with ABP.
• Question 3b.
Associations of ABP with clinical events in prospective
studies.
A total of 10 studies
addressed this issue. In each study, at least one dimension of ABP predicted
subsequent clinical events, primarily CVD. In two of these studies, WCH was
associated with a reduced risk of CVD relative to the risk associated with
sustained hypertension. No prospective study adequately compared the risk
associated with WCH relative to the risk associated with non-hypertension. In
four of five studies, a nondipping or inverse dipping pattern predicted an
increased risk of adverse
events.
• Question 3c.
Comparison of risk prediction from ABP and clinic
BP.
A total of nine prospective studies
addressed this issue, but only two studies assessed incremental gain, that is,
whether ABP provided additional information that was predictive of risk beyond
that of clinic BP. However, the poor or uncertain quality of clinic BP
measurements precluded a satisfactory comparison of risk prediction from ABP and
clinic BP.
• Question 3d.
Effect of treatment guided by ABP.
Only
two trials addressed this issue. Hence, the literature was insufficient to
determine the effects of treatment guided by
ABP.
Key question 4. Findings
according to subgroups.
• The
vast majority of studies included both men and women, but few studies reported
results separately by gender.
• Few
studies reported enrollment of African- Americans, and race-stratified data were
rarely presented.
• The only notable
subgroup finding was a higher prevalence of WCH in women than in
men.
In summary, ABP levels and ABP
patterns were associated with BP-related target organ damage in cross-sectional
studies. Likewise, in prospective studies, higher ABP, sustained hypertension,
and a nondipping ABP pattern were associated with an increased risk of
subsequent CVD events. Few studies examined corresponding relationships for
SMBP. An inadequate number of clinic BP measurements, as well as the poor or
uncertain quality of clinic BP measurements, precluded satisfactory comparisons
of risk prediction based on ABP or SMBP with risk prediction based on clinic BP.
In aggregate, these findings provide some support for use of ABP monitoring in
evaluating prognosis. However, evidence was insufficient to determine whether
the risks associated with WCH are sufficiently low to consider withholding drug
therapy in this large subgroup of hypertensive patients. For SMBP, available
evidence from several trials suggested that use of SMBP can improve BP control;
however, further trials that evaluate contemporary SMBP devices are
needed.
Future
Research
The optimal approach to
measure BP remains uncertain. In view of the high prevalence of uncontrolled
hypertension, the continuing epidemic of BP-related diseases, and the potential
for alternative measurement techniques to improve diagnosis and target therapy,
there is a need for comparative studies that assess the relative efficacy,
feasibility, and costs of ABP, contemporary SMBP technology, and clinic BP.
Specific types of research needs are as
follows:
• Prospective
observational studies that include SMBP, ABP, and clinic BP. Specific research
questions include:
• What is the
repeatability of WCH?
• What are the
risks associated with WCH? In particular, is the risk associated with WCH
sufficiently low to justify non-treatment? If yes, in which
patients?
• Does WCH as assessed by
SMBP carry the same risk as WCH as assessed by
ABP?
• What are the risks associated
with nondipping status?
• Is
nondipping status a surrogate for some other variable that might be measured
more easily, that is, without ABP?
•
What is the incremental gain from use of SMBP or ABP over clinic BP
alone?
• Clinical trials that test
whether contemporary SMBP technology, compared to conventional management by
clinic BP, can improve BP control and health outcomes. An additional comparison
group might include BP management by ABP. These trials should also compare the
aggregate costs of these
approaches.
• Decision analyses that
determine the costs and effects of strategies that integrate clinic BP, SMBP,
and ABP.
• Synthesis of evidence on
BP measurements in clinic setting, including issues related to the accuracy and
performance of different devices (mercury, aneroid, automated BP) and different
observers (physicians, nurses,
technicians).
In future research,
clinic BP should be measured appropriately by trained observers using validated
equipment; measurements should be obtained at several visits. Also, because of
the dearth of large-scale, high-quality studies, there is a clear need for
government sponsorship of key studies. To improve the quality of ABP and SMBP
publications, standardized methods should be disseminated to researchers and
authors. Also, journals should require standardized approaches for presenting
ABP data. For published articles, full copies of protocols should be made
available, perhaps on the Web. This is especially important because the intense
pressure from editors to shorten manuscripts typically leads to reductions in
the methods
section.
Availability of
the Full Report
The full evidence
report from which this summary was taken was prepared for the Agency for
Healthcare Research and Quality (AHRQ) by the Johns Hopkins Evidence-based
Practice Center (EPC), Baltimore, MD, under contract number 290-97-006. It is
expected to be available in fall 2002. At that time, printed copies may be
obtained free of charge from the AHRQ Publications Clearinghouse by calling 800-
358-9295. Requesters should ask for Evidence Report/Technology Assessment No.
63, Utility of Blood Pressure Monitoring Outside of the Clinic Setting.
In addition, Internet users will be able
to access the report and this summary
online
www.ahrq.gov
AHRQ
Pub. No. 03-E003
November
2002
ISSN 1530-4396