Varicella was the primary diagnosis code for data shown.
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Zhou F, Harpaz R, Jumaan AO, Winston CA, Shefer A. Impact of Varicella Vaccination on Health Care Utilization. JAMA. 2005;294(7):797–802. doi:10.1001/jama.294.7.797
Author Affiliations: National Immunization
Program, Centers for Disease Control and Prevention, Atlanta, Ga. Dr Jumaan
is now with the Agency for Toxic Substances and Disease Registry, Atlanta,
Context Since varicella vaccine was first recommended for routine immunization
in the United States in 1995, the incidence of disease has dropped substantially.
However, national surveillance data are incomplete, and comprehensive data
regarding outpatient as well as hospital utilization have not been reported.
Objective To examine the impact of the varicella vaccination program on medical
visits and associated expenditures.
Design, Setting, and Patients Retrospective population-based study examining the trends in varicella
health care utilization, based on data from the MarketScan databases, which
include enrollees (children and adults) of more than 100 health insurance
plans of approximately 40 large US employers, from 1994 to 2002.
Main Outcome Measures Trends in rates of varicella-related hospitalizations and ambulatory
visits and direct medical expenditures for hospitalizations and ambulatory
visits, analyzed using 1994 and 1995 as the prevaccination baseline.
Results From the prevaccination period to 2002, hospitalizations due to varicella
declined by 88% (from 2.3 to 0.3 per 100 000 population) and ambulatory
visits declined by 59% (from 215 to 89 per 100 000 population). Hospitalizations
and ambulatory visits declined in all age groups, with the greatest declines
among infants younger than 1 year. Total estimated direct medical expenditures
for varicella hospitalizations and ambulatory visits declined by 74%, from
an average of $84.9 million in 1994 and 1995 to $22.1 million in 2002.
Conclusion Since the introduction of the varicella vaccination program, varicella
hospitalizations, ambulatory visits, and their associated expenditures have
declined dramatically among all age groups in the United States.
Varicella vaccine is recommended for routine immunization of children
aged 12 to 18 months and for older susceptible children and adults in the
United States.1-4 Before
its licensure in 1995, almost everyone developed chickenpox; thus, incidence
approximated the birth cohort, with about 13 000 hospitalizations and
100 to 150 deaths annually.5-9
Varicella vaccine coverage has increased steadily, reaching 81% in 2002
among children aged 19 to 35 months nationally, while varicella disease incidence
has declined in all age groups.10-12 However,
the impact of vaccination on varicella-related health care utilization has
been documented in only 1 study. Davis et al,13 using
data from the Nationwide Inpatient Sample, reported significant declines in
varicella hospitalization rates and associated charges. For the current study,
we used MarketScan databases to describe not only patterns of varicella hospitalization
but also patterns of ambulatory visits and their associated medical expenditures
in the United States. In addition, we stratified the analyses by state-level
varicella vaccination coverage and by type of health insurance plan. We evaluated
these factors beginning in 1994 (before availability of varicella vaccine)
through 2002 (7 years after vaccine licensure).
Data were obtained from the MarketScan databases,14 which
include information from approximately 40 self-insured employers, including
state governments, with about 4 million covered lives per year, from 1994
to 2002. The databases include more than 500 million claim records representing
employees, retirees, and dependents from more than 100 health insurance plans
in all continental states and the District of Columbia. The databases contain
patient demographics, physician characteristics, dates of services, length
of stay (LOS) in hospital, payments, International Classification
of Diseases, Ninth Revision, Clinical Modification (ICD-9-CM) diagnostic codes, Current Procedural Terminology 1998 codes, and other variables. Total payments reported in MarketScan
databases represent actual amounts paid to providers (eg, physicians and hospitals).
The study sample consisted of all inpatient admissions and ambulatory
visits between January 1994 and December 2002 with varicella diagnoses (ICD-9-CM codes 052.xx). We examined outcomes using only
the primary diagnosis code and using all diagnoses to provide conservative
and liberal estimates, respectively. We excluded events with coexistent herpes
zoster diagnoses (ICD-9-CM codes 53.xx) as well as
varicella in persons aged 50 years or older because these also are likely
to represent herpes zoster.7
The MarketScan enrollment databases contain complete individual-level
enrollment records on enrollees. However, not all enrollees are included in
the enrollment databases. We included all enrollees aged 0 to 49 years from
the MarketScan enrollment databases in our analysis of hospitalizations and
ambulatory visit rates per 100 000 person-years. In a secondary analysis,
we analyzed varicella hospitalizations among all enrollees (regardless of
whether they were in the enrollment databases) as a proportion of total hospitalizations
from all enrollees. Otherwise, enrollees who were not in the enrollment databases
were excluded from analysis.
Because this study constituted analysis of secondary data without identifiers,
it did not require institutional review board approval or informed consent.
Analyses were performed with SAS, version 8.0, statistical software
(SAS Institute Inc, Cary, NC). We used 1994 and 1995 combined data as the
prevaccination baseline. We conducted Poisson regression analysis to assess
changes in varicella rates over time. P≤.05 was
considered statistically significant.
We created 3 age categories corresponding to the prevaccination incidence
and severity of varicella and to expected vaccination uptake: children younger
than 10 years (high incidence and low severity in prevaccination period; high
coverage after vaccination); children and adolescents aged 10 to 19 years
(intermediate incidence and severity; some coverage); and adults aged 20 to
49 years (low incidence and high severity; low coverage). We also evaluated
infants (younger than 1 year), who are not eligible for vaccination.
We conducted stratified analyses of ambulatory visits for children younger
than 10 years by state-level vaccination coverage and by type of health insurance
plan. There were too few hospitalizations and too few ambulatory visits in
older age groups for such analyses.
We stratified varicella vaccination coverage by categorizing children
as belonging to high- or low-coverage groups based on state of residence,
as reported by the National Immunization Survey.15 We
defined high-coverage states as those that consistently had higher annual
coverage than the national average and low-coverage states as those that consistently
had lower annual coverage than the national average during 1997-2003.10,15-20 Enrollees
from states whose coverage status changed during 1997-2003 were excluded from
We compared varicella rates between capitated and noncapitated (ie,
fee-for-service) insurance plans. Seven types of insurance plans were categorized
as capitated (health maintenance organization, capitated or partially capitated
point of service) or noncapitated (basic/major medical, comprehensive, exclusive
provider organization, noncapitated point of service, and preferred provider
We examined rates of ambulatory visits by residence in metropolitan
statistical areas (MSAs) vs non–metropolitan statistical areas (non-MSAs),21 and also by season.
We used total payments to providers to estimate expenditures for hospitalizations
and ambulatory visits. Expenditures were standardized to 2002 US dollars using
the medical Consumer Price Index.22 We calculated
mean LOS and total payments per hospitalization and mean total payments and
out-of-pocket payments (co-payments plus deductible) for ambulatory visits,
comparing prevaccination (1994 and 1995) and postvaccination (2001 and 2002)
periods. We used 1994, 1995, and 2002 US Census data23,24 and
values from the MarketScan databases to estimate national medical expenditures
(for hospitalizations and ambulatory visits only) for varicella in the prevaccination
and postvaccination periods.
Eligible enrollees in the MarketScan databases increased from about
1.2 million in 1994 to 3.5 million in 2002 (representing 0.6% and 1.8% of
the US population aged 0-49 years, respectively) (Table 1). About 26% of enrollees met the inclusion criteria in 1994
compared with 70% in 2002. This change was due to increasing completeness
of the enrollment databases over time. Throughout the study period, there
were slightly more female than male enrollees, there were more enrollees in
MSAs, and age distributions varied slightly. The proportion of enrollees covered
by managed care plans increased gradually over time.
Hospitalization rates with varicella as the primary diagnostic code
declined from 2.3 per 100 000 population in the prevaccination period
to 0.3 in 2002 (88% decrease; P<.001). Declines
in hospitalizations with varicella as any diagnosis were similar, from 4.8
to 0.6 per 100 000 population (85% decrease). For our main analyses,
we therefore present only data on events with primary varicella diagnostic
codes because they are more specific. Figure 1 shows the significant decline per 100 000 population in varicella
hospitalizations in all age groups between 1994 and 2002, from an average
of 9.9 in the prevaccination period to 0.9 in 2002 (91%) for children younger
than 10 years; from 1.5 to 0.1 (92%) for children and adolescents aged 10
to 19 years; and from 0.8 to 0.2 (78%) for adults aged 20 to 49 years. The
greatest decrease per 100 000 population, from an average of 45.1 in
the prevaccination period to 0 in 2002 (100%), occurred among infants. There
was no significant difference between rates of hospitalizations among enrollees
insured by noncapitated plans and those insured by capitated plans.
While hospitalization rates declined among both adults and children,
the proportion of hospitalizations among adults increased relative to that
of children. In the prevaccination period, 11.7% of varicella-related hospitalizations
occurred among infants while 21.4% occurred among adults; in 2002, no hospitalizations
occurred among infants and adults accounted for 40% of hospitalizations.
To verify that reductions in varicella hospitalizations were not an
artifact of changes in the enrollment database population or otherwise affected
by changes in health care utilization during the study interval, we analyzed
varicella hospitalization rates from all enrollees (regardless of study database
inclusion) as a proportion of total hospitalizations from all enrollees. Varicella
hospitalizations constituted an average of 0.025% of all annual hospitalizations
from all enrollees in the database in 1994 and 1995 compared with 0.003% in
2002, a decline of 87%.
The rate of ambulatory visits with varicella as the primary diagnosis
code declined from an average of 215 per 100 000 population in the prevaccination
period to 89 in 2002 (59% decrease; P<.001). The
decline was significant for all age groups (Figure
2). Similar declines were noted for ambulatory visits with any varicella
code, from 238 to 89 per 100 000 population (62% decrease). Between 1994
and 2002, rates per 100 000 population for varicella as the primary diagnosis
code declined from an average of 956 in the prevaccination period to 353 in
2002 (63%) for children younger than 10 years; from 136 to 78 (42%) for children
aged 10 to 19 years; and from 65 to 26 (60%) for adults aged 20 to 49 years
(Figure 2). The greatest decrease per
100 000 population, from an average of 1681 in the prevaccination period
to 167 in 2002 (90% decline), occurred among infants.
We identified 11 states with consistently high varicella vaccination
coverage and 19 states with consistently low coverage. Enrollees in both groups
experienced significant declines in the rate of varicella ambulatory visits
for children younger than 10 years. However, the decline in the high-coverage
group was faster, indicated by significant interaction for coverage by year
in the Poisson model (P = .006). In 2002,
the rate of varicella ambulatory visits for children younger than 10 years
was 289 per 100 000 population for high-coverage states and 483 per 100 000
population for low-coverage states. The corresponding rates for the same groups
of states in the prevaccination period were 808 and 1035 per 100 000
population, representing reductions of 64% and 53%, respectively.
The rate of varicella ambulatory visits for children younger than 10
years was significantly higher among enrollees insured by noncapitated plans
than those in capitated plans between 1997 and 2002. Decreases in both groups
were significant but were more rapid in the noncapitated group (P = .009).
In the prevaccination period, the ratio of hospitalizations to ambulatory
visits was 0.010 among children younger than 10 years, 0.011 for children
and adolescents aged 10 to 19 years, and 0.012 for adults aged 20 to 49 years.
However, by 2001-2002, these ratios decreased, especially among persons younger
than 20 years, with corresponding ratios of 0.002, 0.003, and 0.008 for persons
younger than 10 years, 10 to 19 years, and 20 to 49 years, respectively.
As previously reported,5,11,25-28 most
varicella-related ambulatory visits occurred during winter and spring. In
1994, 65% of visits occurred in December through May. This seasonality declined
somewhat by 2002, when 58% of visits occurred during those months. In the
prevaccine period, ambulatory visits were more common among those residing
in MSAs than in non-MSAs (206 vs 170 per 100 000 population, respectively; P<.001); this difference was significant for all age
groups. The MSA difference was no longer significant in 2002.
For hospitalizations with varicella as the primary diagnosis, mean LOS
and total hospitalization payments during the prevaccination period were 3.83
days (95% confidence interval [CI], 3.33-4.32 days) and $7626 (95% CI, $5586-$9667),
respectively. The corresponding values for the postvaccination period were
4.63 days (95% CI, 3.34-5.92 days) and $7993 (95% CI, $5055-$10 930),
respectively. Length of stay and payments did not change significantly between
the 2 periods. Mean total payments and out-of-pocket payments for ambulatory
visits during the prevaccination period were $89.51 (95% CI, $86.10-$92.92)
and $28.50 (95% CI, $27.39-$29.61), respectively. The corresponding values
for the postvaccination period were $86.11 (95% CI, $82.59-$89.64) and $23.73
(95% CI, $22.74-$24.72), respectively. The decline in out-of-pocket payments
was significant (P<.001). Mean LOS and total hospitalization
payments were significantly higher among those in noncapitated vs capitated
Based on our data with varicella as the primary diagnosis code, estimated
annual national medical expenditures for hospitalizations and ambulatory visits
declined in the United States from an average of $84.9 million in 1994 and
1995 to $22.1 million in 2002 (74%) (Table 2).
For ambulatory visits and hospitalizations with any varicella diagnosis code,
annual medical expenditures for varicella in the United States declined from
an average of $116.9 million in 1994 and 1995 to $27.0 million in 2002 (77%).
This is the first study, to our knowledge, to include both hospitalizations
and ambulatory visits in the analysis of varicella health care utilization
over a period that spanned introduction and maturation of the varicella vaccination
program in the United States. We found that rates of hospitalization and ambulatory
visits for varicella decreased markedly over the study interval and that disease
severity (as indicated by the changing ratio of hospitalization to ambulatory
visits over time) declined as well. While it was beyond the scope of the study
to conduct longitudinal analysis of individuals following vaccination to directly
compare varicella outcomes by vaccination status, a causal role of the vaccination
program in this decline is further supported by the inverse relationship between
pediatric vaccine coverage in individual states and the rate of varicella.
State-level coverage is associated with day care and school entry requirements,29 suggesting that such laws have had the intended effect
of reducing the burden of disease.
Health care utilization for varicella decreased across all age groups.
Hospitalization rates declined by 88% between the prevaccination period and postvaccine year 2002, and rates for outpatient visits declined by 59%. These
data are consistent with other observations.13,30 The
results are particularly notable for infants; since varicella vaccine is not
indicated for infants, the declines reflect reduced force of varicella infection
in the population (ie, herd immunity), as do declining rates among adults.2,9 The declining rates of varicella hospitalization
among adolescents and adults provide reassurance that to date, there is no
evidence that the pediatric vaccination program is increasing disease rates
in older children and adults, who are at greater risk of severe disease.31
The estimated national medical expenditures for varicella hospitalizations
and ambulatory visits together declined by about $63 million (74%) between
prevaccination and postvaccination years. In the prevaccination period, about
half of direct varicella health care expenditures were for outpatient visits.
Since licensure, however, expenditures have shifted to the outpatient setting,
with the proportion of varicella events that occur as hospitalization declining
by more than 55%. This trend may be partially due to an increasing portion
of varicella among vaccinated persons, who typically experience mild disease
and who may be at lesser risk of complications such as invasive group A streptococcal
expected, mean LOS and unit hospitalization payments were higher for noncapitated
plans than for capitated plans. Changes in patterns of insurance coverage
may have contributed somewhat to reductions in varicella hospitalization expenditures
over the study interval as well. However, changes in the mean unit cost between
the prevaccination and postvaccination periods were not significant for either
varicella hospitalization or varicella ambulatory visits.
This study was not designed to be a formal economic analysis or to evaluate
other potential outcomes of the varicella vaccination program, such as adverse
reactions to vaccination or changes in the incidence of herpes zoster. However,
our data could be used as input for evaluating the cost-effectiveness of the
varicella vaccination program. Based on 2002 Biological Surveillance (unpublished
data, Centers for Disease Control and Prevention) and National Immunization
Survey data,10-12 the
total costs of varicella vaccines for 4 million children, which approximates
the annual birth cohort in the United States, were estimated to be about $144
The changes we found in hospitalization rates following vaccine licensure
were qualitatively similar to those reported by Davis et al,13 although
our study methods were different. Davis et al used a sample of all US hospitalizations,
whereas we ascertained rates and expenditures from the MarketScan population
(ie, only private payment). Furthermore, to minimize misclassification, we
excluded hospitalizations with secondary codes for varicella from our analysis.
We also excluded persons aged 50 years or older, who are at very low risk
of varicella, from analysis since varicella codes in this population often
represent misclassification of herpes zoster.7,8
There are limitations to our analysis. MarketScan data are obtained
from employer-based insurance, particularly from larger employers. The study
population is therefore somewhat homogeneous and not fully representative.
Nonetheless, with an average of 2.2 million enrollees who met the inclusion
criteria during the 1994-2002 study interval, the population is large, draws
from numerous medical settings, and represents a wide variety of geographic,
social, and economic strata. Nationally, while most children and younger persons
at risk of varicella are privately insured, utilization and medical expenditures
per case for varicella may be greater for persons with Medicaid or without
insurance,13 making these estimates conservative.
However, the proportion of the US population with private insurance has not
changed during the study interval35; any bias
in our analysis has been consistent over time and our estimates should provide
a fairly accurate reflection of the degree of reduction in varicella utilization
One should be cautious in conducting surveillance using data that are
collected for different (ie, administrative) purposes. There is no mechanism
to validate MarketScan diagnostic codes through direct medical chart reviews.
We did, however, review line listings for several hundred hospitalization
and ambulatory records in the MarketScan databases with primary or secondary
varicella diagnostic codes. We found no reason to question the validity of
these codes, with the exception of codes listing secondary varicella diagnoses
for hospitalization events, which we excluded from analysis. The diagnostic
codes that populate the MarketScan databases derive from abstraction of discharge
diagnoses, similar to diagnostic information collected for any other administrative
purposes; thus, data should be no less accurate than other ICD-9-CM–based data. The validity of these data is supported
by comparable rates and age distributions for varicella hospitalizations published
Our study may have missed some varicella events because of incomplete
coding or multiple insurance plans for the same enrollee. In general, these
instances are rare. Another limitation is that trends for varicella events
could be affected by secular changes in the MarketScan source population,
its enrollment databases, or in insurance or associated utilization patterns.
We showed that varicella hospitalizations among all enrollees (whether in
the study database or not) declined by 88% as a proportion of total hospitalizations.
This analysis controls for both changes in the study databases and changes
in criteria for hospitalization that might have occurred over time. Finally,
declines in hospitalization occurred among both capitated and noncapitated
insurance plans, also suggesting that the declines were not a simple artifact
of secular changes in insurance coverage.
The data in our study demonstrate the substantial success that the varicella
vaccine program has shown since it was implemented 10 years ago. However,
nationally representative data are needed to more accurately monitor the impact
of the varicella vaccination program. The Council of State and Territorial
Epidemiologists has recommended that states now begin to conduct case-based
Corresponding Author: Fangjun Zhou, PhD,
MS, National Immunization Program, Centers for Disease Control and Prevention,
1600 Clifton Rd NE, Mail Stop E-52, Atlanta, GA 30333 (email@example.com).
Author Contributions: Dr Zhou had full access
to all of the data in the study and takes responsibility for the integrity
of the data and the accuracy of the data analysis.
Study concept and design: Zhou, Harpaz, Jumaan,
Acquisition of data: Zhou.
Analysis and interpretation of data: Zhou,
Harpaz, Jumaan, Winston.
Drafting of the manuscript: Zhou, Harpaz, Jumaan.
Critical revision of the manuscript for important
intellectual content: Zhou, Harpaz, Jumaan, Winston, Shefer.
Statistical analysis: Zhou, Winston.
Administrative, technical, or material support:
Harpaz, Jumaan, Shefer.
Study supervision: Jumaan.
Financial Disclosures: None reported.
Disclaimer: The findings and conclusions in
this report are those of the authors and do not necessarily represent the
views of the Centers for Disease Control and Prevention, US Department of
Health and Human Services.
Acknowledgment: We thank the following individuals
from the Centers for Disease Control and Prevention: Jane Seward, MBBS, MPH,
and Dalya Guris, MD, MPH, for their thoughtful reviews of an early version
of the manuscript; and Mary McCauley, MTSC, for her editorial assistance.
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