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Article |

Illness Among Schoolchildren During Influenza Season:  Effect on School Absenteeism, Parental Absenteeism From Work, and Secondary Illness in Families FREE

Kathleen M. Neuzil, MD, MPH; Cynthia Hohlbein, RN; Yuwei Zhu, MD, MS
[+] Author Affiliations

From the Department of Medicine, University of Washington School of Medicine (Dr Neuzil) and the Veterans Affairs Puget Sound Health Care System (Dr Neuzil and Ms Hohlbein), Seattle; and the Department of Pediatrics, Vanderbilt University School of Medicine, Nashville, Tenn (Dr Zhu).


Arch Pediatr Adolesc Med. 2002;156(10):986-991. doi:10.1001/archpedi.156.10.986.
Text Size: A A A
Published online

Background  High attack rates of Influenzavirus among school-aged children tend to be expected to cause significant disruption of usual activities at school and at home.

Objective  To quantify the effect of influenza season on illness episodes, school absenteeism, medication use, parental absenteeism from work, and the occurrence of secondary illness in families among a cohort of children enrolled in an elementary school during the 2000-2001 influenza season.

Design  Prospective survey study.

Setting  Kindergarten through eighth grade elementary school in Seattle, Wash.

Patients or Other Participants  All children enrolled in the school were eligible for the study. Study participants were 313 children in 216 families.

Main Outcome Measures  The primary outcome measure was missed school days. Secondary outcomes measures included total illness episodes, febrile illness episodes, medication usage, physician visits, parental workdays missed, and secondary illnesses among family members of children in the study cohort. Differences between the rates of study events among participants when influenza was circulating and the event rates during the winter season when influenza was not circulating were used to calculate influenza-attributable excess events.

Results  Total illness episodes, febrile illness episodes, analgesic use, school absenteeism, parental industrial absenteeism, and secondary illness among family members were significantly higher during influenza season compared with the noninfluenza winter season. For every 100 children followed up for this influenza season, which included 37 school days, an excess 28 illness episodes and 63 missed school days occurred. Similarly, for every 100 children followed up, influenza accounted for an estimated 20 days of work missed by the parents and 22 secondary illness episodes among family members.

Conclusion  Influenza season has significant adverse effects on the quality of life of school-aged children and their families.

Figures in this Article

INFLUENZA CAUSES annual winter epidemics of respiratory disease that affect all age groups and all segments of the population. Serious complications and hospitalizations due to Influenzavirus occur preponderantly in persons younger than 2 years, persons 65 years and older, and persons with certain chronic medical conditions. Deaths occur preponderantly in persons older than 70 years.17 However, even among otherwise healthy individuals, the health and economic consequences of influenza are substantial. Annual influenza attack rates vary from 10% to 30% in adults and 20% to 50% in children during interpandemic years, and may approach 70% during pandemic years.3,4,810 Among adults, influenza infections lead to increased health care visits, medication usage, work loss, and restricted activity days.1114

While the epidemic nature of influenza and the high attack rates in children would be expected to cause significant disruption of usual activities at school and at home, data on the effects of influenza on school-aged children are limited. In a study of healthy children aged 5 through 14 years enrolled in Tennessee Medicaid, influenza was associated with a health care visit in approximately 8% of the children and with an antibiotic prescription in approximately 7%.5 This study likely underestimated the effect of influenza on this population, as it did not examine the effects of influenza on school-aged children who did not seek medical care. Additional adverse effects of influenza in this population include the discomfort of the illness, increased over-the-counter medication usage, and school absenteeism.3,15 Influenza in a child may also affect the family. Working parents may stay home to care for a sick child, leading to industrial absenteeism,16 or sick children may transmit Influenzavirus to other family members.1720

Considering the potential for influenza to substantially affect the quality of life of children and their families, targeting school-aged children for prevention or treatment of influenza may reduce the individual and societal burden of this disease. This prospective study was designed to quantify the effect of influenza season on school and industrial absenteeism, on health care and medication usage, and on secondary illnesses within families, among a cohort of schoolchildren and their families.

STUDY DESIGN

We conducted a 1-year prospective study of the effect of influenza season on a cohort of children enrolled in a large elementary school in Seattle, Wash. Baseline surveys obtained information on household size, prevalence of childhood asthma, and receipt of influenza vaccine. When a child was absent from school during the winter season, from December 4, 2000, through April 13, 2001, surveys were sent to the child's parent or guardian to determine the reason for the absence, to characterize the types and severity of illnesses that occurred during the winter season, and to determine the effect of the illness on medication usage, physician visits, parental industrial absenteeism, and secondary illnesses within the family.

This study was approved by the Human Subjects Division at the University of Washington. Baseline surveys and informed consent were sent to all parents at the school. Parents chose to enroll in the study by returning the baseline survey and the accompanying informed consent. After receiving the informed consent from the parents, two of us (K.M.N., C.H.) obtained assent from the children. These children and their families constituted the study population.

SOURCE POPULATION

The study school is a parochial elementary school (grades kindergarten-8) located in central Seattle and draws children from 24 ZIP codes within the city, and 14 ZIP codes from the surrounding suburbs. The school represents an ethnically and socioeconomically diverse population of children. Of a total enrollment of 611 children, 18% are nonwhite; almost 20% receive financial aid.

DATA COLLECTION
Baseline Data

Baseline data on household size, ages of all household members, and receipt of influenza vaccine by each member of the family was collected from all of the 216 families who chose to participate. To determine the prevalence of asthma among the schoolchildren, the survey also included a question asking whether a physician had ever diagnosed asthma for the child.

Illness Data

Coded, computerized absentee records were obtained by the study coordinator (C.H.) from the school office at the end of each week. Children who were participating in the study were identified. From December 4, 2000, through April 13, 2001 (the day before spring break), the parent or guardian of a child listed on the computerized absentee records was sent a survey inquiring about the child's reason for missing school. If the child missed school for an illness, then the parent completed the remainder of the form, which asked details about the symptoms of the illness, medication usage, health care use, parental industrial absenteeism, and illnesses among other household members. The following symptoms were included on the survey: fever, coryza, sore throat, cough, myalgia, earache, headache, nausea, vomiting, and diarrhea. Parents returned the surveys in stamped, self-addressed envelopes to the study nurse (C.H.). If the survey was not received by the study nurse within 2 weeks, a telephone call was placed, and the details of the absence were ascertained by telephone interview.

Influenza Season

Influenza season was defined by prospective viral surveillance at the University of Washington Clinical Virology Laboratory at Children's Hospital and Medical Center.21 Influenza season was defined as the first day of the first week in which there were at least 5 isolates of Influenzavirus, until the last day of the last week in which there were at least 5 isolates of Influenzavirus.

MAIN OUTCOME MEASURES

The primary outcome measure was the total number of school days missed during influenza season compared with the noninfluenza winter season. Secondary outcomes included the total illness episodes, febrile illness episodes, other symptoms associated with the illness episodes, number of days that parents miss work secondary to childhood illness, the number of family members who become ill within 3 days of the child's illness, and the number of health care visits and medications dispensed during influenza season.

DATA ANALYSIS

The expected number of study outcomes during influenza season was calculated based on the rate of study outcomes observed during the noninfluenza winter season. The observed number of study events during influenza season was then compared with the expected number, and a relative risk was calculated. Influenza-attributable excess events were calculated by subtracting the expected outcomes from the observed outcomes during influenza season. An excess event rate per 100 children was then generated by dividing by the total number of children in the cohort (313), then multiplying by 100. The 95% confidence intervals were generated using StatXact (Cytel Software, Cambridge, Mass). χ2 or Fisher exact test was used as appropriate for symptom comparison between the influenza and noninfluenza winter season. In an attempt to control for the confounding effect of respiratory syncytial virus (RSV) circulation, a nested analysis was performed that was restricted to January 8, 2001, through March 31, 2001, during which the mean number of RSV isolates per week was equivalent during the influenza and noninfluenza winter season. All calculations other than the 95% confidence interval were done using SAS version 8.0 (SAS Institute Inc, Cary, NC).

Of 428 families with 611 children enrolled at the school, 216 families with 313 children chose to participate in the study. Baseline characteristics of the study population are given in Table 1. Participation was equally distributed through all of the grades—with a low of 9% of the participants being second graders to a high of 14% of participants being eighth graders. The prevalence of asthma among this study population was 12%, and 9 (24%) of 37 children with asthma received influenza vaccine during the study year. Among all participants, 6% of the study children, 25% of the parents, 37% of the grandparents, and 5% of other household members reported receiving influenza vaccine.

Table Graphic Jump LocationTable 1. Baseline Characteristics of 313 Children in 216 Families Participating in Illness Survey Study*
INFLUENZA SEASON

Influenza season occurred in the Seattle area from January 8, 2001, through March 2, 2001. Influenza A (H1N1) and influenza B viruses circulated during this period. Influenza season included 37 school days. The noninfluenza winter season occurred from December 4, 2000, through January 5, 2001, and March 5, 2001, through April 13, 2001, representing 44 school days. Respiratory syncytial virus circulated in the Seattle area during the entire study period, from December 4, 2000, through April 13, 2001 (Figure 1). The mean number of RSV isolates per week was higher in influenza season than in the noninfluenza winter season, at 37 and 23 per week, respectively. From January 8, 2001, through March 31, 2001, the mean number of RSV isolates per week was 37 during both influenza season and the noninfluenza winter season. Parainfluenza virus circulated at relatively constant levels throughout the study period (Figure 1).

Place holder to copy figure label and caption

The number of isolates of influenza (solid line), respiratory syncytial virus (large dashed line), and parainfluenza (small dashed line) per week at Children's Hospital and Regional Medical Center, Seattle, Wash, during the 2000-2001 school year. Adapted from the University of Washington Clinical Virology Laboratory Web site.21

Graphic Jump Location
OUTCOME RATES

Throughout the school year, weekly rates of absenteeism were monitored. The weekly percentage of children in the study who missed school was similar to the percentage of all students who missed school (data not shown). From December 4, 2000, through April 13, 2001, on notification by the school that a study participant missed school, 868 surveys were mailed to parents and 804 (93%) were returned. Of these 804 returned surveys, 360 surveys indicated that either the child did not miss school, or that the child did miss school but was not ill. On 444 surveys, the parents confirmed that the child missed school owing to an illness.

Of the 444 illness episodes, 194 (43.7%) occurred during the noninfluenza winter season, and 250 (56.3%) occurred during influenza season. Among the 313 children monitored throughout the 44 days of the noninfluenza season, 194 illnesses occurred during the 13 772 child-days of follow-up. Using this rate as the background rate, the expected number of illness episodes during influenza season was calculated and compared with the observed number. As given in Table 2, the 250 reported illnesses during influenza season exceeded the expected number by more than 50%. The 87 excess illness events occurring among 313 children followed up during winter represents an estimated influenza attack rate of 28%. In addition to total illness episodes, days of school missed per episode was higher during influenza season than during the noninfluenza winter season. Febrile illnesses increased during influenza season, with the difference in illness episodes entirely accounted for by illness episodes with fever. Analgesic use during influenza season, and parental work absenteeism, were likewise higher than expected during influenza season. The observed numbers of antibiotic prescriptions and health care visits were not statistically significantly greater than expected during influenza season (Table 2).

Table Graphic Jump LocationTable 2. Effect of Winter Illness on School and Family Among 313 Schoolchildren Monitored From December 1, 2000, Through April 13, 2001

To determine the excess event rate for outcomes during influenza season, the expected rate during influenza season was subtracted from the observed rate (Table 2). It is estimated that for every 100 children followed up for this influenza season, which included 37 school days, an additional 28 illness episodes and 63 missed school days would occur. Similarly, for every 100 children followed up, influenza accounted for an estimated 20 excess days of work missed by the parents. When the study was restricted to periods of peak RSV activity, from January 8, 2001, through March 31, 2001, estimates of influenza-attributable events were similar (data not shown).

During influenza season, parents were much more likely to report illness in other household members in the 3 days following the child's absence from school compared with the noninfluenza winter season. An estimated 22 excess secondary illness episodes occurred for every 100 children followed up during this influenza season (Table 2). Of the 126 household members who became ill during influenza season within 3 days of the child's illness, 46% were parents, 33% were siblings aged 5 to 17 years, 20% were siblings younger than 5 years, and fewer than 1% were grandparents.

ILLNESS CHARACTERISTICS

Fever was reported as a component of 67% of illnesses during influenza season compared with 49% of illnesses during the noninfluenza winter season (P = .001). Similarly, febrile respiratory illness (defined as fever with at least one of the following symptoms: cough, runny nose, or sore throat) was significantly more common in influenza season compared with the noninfluenza winter season (57% vs 44%, P = .04). The systemic symptoms of myalgia and headache were significantly more frequent during influenza season compared with the noninfluenza winter season among children aged 11 to 14 years, but not among younger children. There were no differences in the prevalence of nausea, vomiting, diarrhea, or earache among illnesses in any age group occurring during the influenza and noninfluenza winter season.

This Seattle population–based study examined the effect of the influenza season on multiple and diverse outcomes among schoolchildren and their families during the 2000-2001 winter season. Illness during influenza season was common, with an estimated 87 excess illness events occurring among 313 children followed up during the winter, for an attack rate of 28%. This likely represents a minimum estimate, as it only included children who were sufficiently ill to miss a day of school, and did not include illnesses that occurred only on weekends or school holidays. This attack rate is consistent with other studies that report symptomatic attack rates of 23% to 48% among school-aged children during interpandemic years.2225 The total number of school days missed during influenza season was likewise higher than expected based on the noninfluenza winter season baseline. We estimated that for this influenza season, which encompassed 37 school days, 63 excess school days were missed for every 100 children followed up. Estimates of school days missed per 100 children due to influenza infection from a randomized, controlled trial of influenza vaccine among schoolchildren in Russia were slightly higher at 79 school days missed for every 100 unvaccinated children.26

The increase in absenteeism for illness in our cohort was paralleled by increases in febrile illnesses and analgesic use. That fever is a major component of influenza illness in children is well established.27,28 Health care visits and antibiotic use did not increase significantly during influenza season compared with the noninfluenza winter season. This is in contrast to other studies that demonstrate significant excess outpatient health care visits and antibiotic prescriptions among school-aged children during influenza season.5 The reasons for this discrepancy are unclear, but may relate to differences in parents' knowledge and attitudes about viral illness, the threshold for bringing children to a physician, or our relatively small sample size.

The effect of influenza season on this cohort extended beyond illness in the schoolchildren. In this study, significant excess industrial absenteeism occurred among the parents, who missed almost 1 day of work for every 3 days of school missed by a child attributable to influenza infection. National data report that 57% of mothers and 97% of fathers of school-aged children work full-time and, thus, may need to miss work or hire alternative care if their children miss school.16 Presumably, our study population included fewer households with 2 working parents, or parents with more flexibility in their schedules or alternative child care providers. Rates of parental absenteeism could be higher in other populations. Our estimates of parental industrial absenteeism were based solely on missing work to care for a sick child, and did not include work that may have been missed if the child transmitted influenza to the parent.

Children more frequently shed Influenzavirus compared with adults,29 and this may facilitate the transmission of Influenzavirus. In a large general practice population outside London, England, during the pandemic of 1957, attack rates in adults who resided with school-aged children were 2 to 3 times higher than attack rates in adults who did not reside with school-aged children.30 Family studies of influenza transmission in Seattle and Tecumseh, Mich, during the 1970s found children to be the main introducers of influenza infection into households during interpandemic periods.17,18,20 In this study, the number of household members who became ill within 3 days of a child's absence from school was 2.2 times higher than expected during influenza season. For every 10 children who miss school for an influenza-related illness, our data suggest that 8 household members will subsequently become ill. Increased use of influenza vaccine among children could reduce illness in household or community contacts. In a 1995 randomized controlled trial of influenza vaccine for preschool-aged children, influenza-unvaccinated household contacts of influenza-vaccinated children had 42% fewer febrile respiratory illnesses compared with unvaccinated household contacts of control children.13 Mass vaccination of schoolchildren has been correlated with reduced respiratory illness in Tecumseh31 and with reductions in all-cause mortality rates in Japan,32 suggesting that immunization on a larger scale can affect community epidemics.

This was a survey study, and we did not attempt to diagnose the reported illnesses by clinical or laboratory evaluation. We assumed that noninfluenza illnesses occurred equally during the influenza and noninfluenza winter season, so that any excess during influenza season was attributable to influenza infection. Using a similar method, our estimates of influenza-associated hospitalizations and outpatients visits in children correlated well with laboratory documented rates of influenza disease.5,8 That most of the excess illness in this study was febrile illness is consistent with the clinical picture of Influenzavirus in children.9,23,24,27,28 Likewise, our secondary analysis that was restricted to peak RSV season yielded results similar to our primary analysis, suggesting that RSV was not a significant confounder.

This study included only 1 influenza season, in which influenza type B and type A (H1N1) strains circulated. The effect of influenza varies from year to year, and may be influenced by circulating strains and the underlying immunity in the population. While in adults morbidity is generally believed to be greatest when H3N2 viruses are circulating,3335 the effect of different viral strains on morbidity in school-aged children is not well established, as all 3 strains may cause high attack rates or serious illness.25,26,28,36 Studies that include multiple influenza seasons are needed to adequately address this issue.

Among a cohort of children followed up during the winter season, total illness episodes, school days missed, workdays missed by parents, and subsequent illnesses among household members were significantly increased when Influenzavirus circulated in the community. These data should aid pediatric health care providers and parents when deciding whether to immunize a healthy school-aged child with influenza vaccine. When planning important school events during influenza season, school administrators should be cognizant of the potential for significant increases in school absenteeism. Finally, this study reinforces the recommendation to vaccinate children if they reside in households with persons who are at increased risk for complications of Influenzavirus, to reduce the potential for transmission.4

Accepted for publication May 10, 2002.

This study was funded through a research grant from GlaxoWellcome Worldwide Epidemiology. GlaxoWellcome Worldwide Epidemiology had no role in the design, conduct, collection, analysis, or interpretation of the data and did not review or approve the manuscript prior to submission.

We are indebted to the students, parents, and staff at St Joseph's School for their enthusiastic participation in this study, and to Anne Cent, Children's Hospital and Regional Medical Center, Seattle, for her dedication to organizing and maintaining the viral surveillance data.

What This Study Adds

Symptomatic influenza illness is frequent among school-aged children. However, studies evaluating the effect of influenza illness on quality of life in such children are unavailable. This prospective, population-based study quantifies a major effect of Influenzavirus on multiple and diverse outcomes in schoolchildren and their families, including significant increases in school absenteeism, analgesic use, parental industrial absenteeism, and secondary illness among family members. Such information is important for both individual and public policy decisions regarding the use of influenza vaccine in school-aged children.

Corresponding author and reprints: Kathleen M. Neuzil, MD, MPH, University of Washington School of Medicine, Veterans Affairs Puget Sound Health Care System, 1660 S Columbian Way, Seattle, WA 98108 (e-mail:kneuzil@u.washington.edu).

Simonsen  LClarke  MJWilliamson  DGSroup  DFArden  NHSchonberger  LB The impact of influenza epidemics on mortality: introducing a severity index. Am J Public Health. 1997;871944- 1950
Glezen  WP Emerging infections: pandemic influenza. Epidemiol Rev. 1996;1864- 76
Glezen  WPCouch  RB Interpandemic influenza in the Houston area, 1974-76. N Engl J Med. 1978;298587- 592
Centers for Disease Control and Prevention, Advisory Committee on Immunization Practices (ACIP): prevention and control of influenza. MMWR Morb Mortal Wkly Rep. 2001;501- 46
Neuzil  KMMellen  BGWright  PF  et al.  The impact of influenza on hospitalizations, outpatient visits and antibiotic prescriptions in children. N Engl J Med. 2000;342225- 231
Izurieta  HSThompson  WWPiotr  K  et al.  Influenza and the rates of hospitalization for respiratory disease among infants and young children. N Engl J Med. 2000;342232- 239
Neuzil  KMWright  PFMitchel  EF  et al.  The burden of influenza illness in children with asthma and other chronic medical conditions. J Pediatr. 2000;137856- 864
Neuzil  KMZhu  YGriffin  MR  et al.  The burden of interpandemic influenza in children younger than 5 years: a 25-year prospective study. J Infect Dis. 2002;185147- 152
Glezen  WPKeitel  WATaber  LHPiedra  PAClover  RDCouch  RB Age distribution of patients with medically-attended illnesses caused by sequential variants of influenzaA/H1N1; comparison to age-specific infection rates, 1978-1979. Am J Epidemiol. 1991;133296- 304
Dunn  FLCarey  DECohen  AMartin  JD Epidemiologic studies of Asian influenza in a Louisiana parish. Am J Hyg. 1959;70351- 371
Sullivan  KMMonto  ASLongini Jr  IM Estimates of the US health impact of influenza. Am J Public Health. 1993;831712- 1716
Adams  PFHendershot  GEMarano  MA Current Estimates From the National Health Interview Survey.  Hyattsville, Md National Center for Health Statistics1996;Data from Vital Health Statistics, No. 199
Nichol  KLLind  AMargolis  KL  et al.  The effectiveness of vaccination against influenza in healthy, working adults. N Engl J Med. 1995;333889- 893
Keech  MScott  AJRyan  PJ The impact of influenza and influenza-like illness on productivity and healthcare resource utilization in a working population. Occup Med (Lond). 1998;4885- 90
Lenaway  DDAmbler  A Evaluation of a school-based influenza surveillance system. Public Health Rep. 1995;110333- 337
White  TLavoie  SNettleman  MD Potential cost savings attributable to influenza vaccination of school-aged children. Pediatrics. 1999;103e73
Foy  HMCooney  MKAllan  I Longitudinal studies of type A and B influenza among Seattle schoolchildren and families, 1968-1974. J Infect Dis. 1976;134362- 369
Fox  JPHall  CECooney  MKFoy  HM Influenza virus infections in Seattle families, 1975-1979: study design, methods, and the occurrence of infections by time and age. Am J Epidemiol. 1982;116212- 227
Hurwitz  ESHaber  MChang  A  et al.  Effectiveness of influenza vaccination of day care children in reducing influenza-related morbidity among household contacts. JAMA. 2000;2841677- 1682
Longini  IMKoopman  JSMonto  ASFox  JP Estimating household and community transmission parameters for influenza. Am J Epidemiol. 1982;115736- 751
Not Available, Respiratory virus surveillance, Seattle, Wash, September 2000 through June 2001. Available athttp://depts.washington.edu/rspvirus/Viral_Detections_2000.htmAccessed March 19, 2002
Clover  RDCrawford  SGlezen  WP  et al.  Comparison of heterotypic protection against influenza A/Taiwan/86 (H1N1) by attenuated and inactivated vaccines to A/Chile/83-like viruses. J Infect Dis. 1991;163300- 304
Gruber  WCTaber  LHGlezen  WP  et al.  Live attenuated and inactivated influenza vaccine in school-age children. AJDC. 1990;144595- 600
Piedro  PAGlezen  WP Influenza in children: epidemiology, immunity and vaccines. Semin Pediatr Infect Dis. 1991;2140- 146
Sugaya  NNerome  KIshida  M  et al.  Efficacy of inactivated vaccine in preventing antigenically drifted influenza type A and well-matched type B. JAMA. 1994;2721122- 1126
Khan  ASPolezhaev  FVailjeva  R  et al.  Comparison of US inactivated split-virus and Russian live attenuated, cold-adapted trivalent influenza vaccines in Russian schoolchildren. J Infect Dis. 1996;173453- 456
Wright  PFBryant  JDKarzon  DT Comparison of Influenza B/Hong Kong virus infections among infants, children and young adults. J Infect Dis. 1980;141430- 435
Wright  PFThompson  JKarzon  DT Differing virulence of H1N1 and H3N2 influenza strains. Am J Epidemiol. 1980;112814- 819
Long  CEHall  CBCunningham  CK  et al.  Influenza surveillance in community-dwelling elderly compared with children. Arch Fam Med. 1997;6459- 465
Woodall  JRowson  KEKMcDonald  JC Age and Asian influenza, 1957. BMJ. 1958;ii1316- 1318
Monto  ASDavenport  FM Modification of an outbreak of influenza in Tecumseh, Michigan by vaccination of school children. J Infect Dis. 1970;12216- 25
Reichert  TASugaya  NFedson  DSGlezen  WP  et al.  The Japanese experience with vaccinating schoolchildren against influenza. N Engl J Med. 2001;344889- 896
Neuzil  KMReed  GWMitchel Jr  EFGriffin  MR Influenza-associated morbidity and mortality in young and middle-aged women. JAMA. 1999;281901- 907
Housworth  JLangmuir  AD Excess mortality from epidemic influenza, 1957-1966. Am J Epidemiol. 1974;10040- 48
Simonsen  LFukuda  KSchonberger  LBCox  NJ Impact of influenza epidemics on hospitalizations. J Infect Dis. 2000;181831- 837
van den Dungen  FAvan Furth  AMFetter  WPZaaijer  HLvan Elburg  R Fatal case of influenza B virus pneumonia in a preterm neonate. Pediatr Infect Dis J. 2001;2082- 83

Figures

Place holder to copy figure label and caption

The number of isolates of influenza (solid line), respiratory syncytial virus (large dashed line), and parainfluenza (small dashed line) per week at Children's Hospital and Regional Medical Center, Seattle, Wash, during the 2000-2001 school year. Adapted from the University of Washington Clinical Virology Laboratory Web site.21

Graphic Jump Location

Tables

Table Graphic Jump LocationTable 1. Baseline Characteristics of 313 Children in 216 Families Participating in Illness Survey Study*
Table Graphic Jump LocationTable 2. Effect of Winter Illness on School and Family Among 313 Schoolchildren Monitored From December 1, 2000, Through April 13, 2001

References

Simonsen  LClarke  MJWilliamson  DGSroup  DFArden  NHSchonberger  LB The impact of influenza epidemics on mortality: introducing a severity index. Am J Public Health. 1997;871944- 1950
Glezen  WP Emerging infections: pandemic influenza. Epidemiol Rev. 1996;1864- 76
Glezen  WPCouch  RB Interpandemic influenza in the Houston area, 1974-76. N Engl J Med. 1978;298587- 592
Centers for Disease Control and Prevention, Advisory Committee on Immunization Practices (ACIP): prevention and control of influenza. MMWR Morb Mortal Wkly Rep. 2001;501- 46
Neuzil  KMMellen  BGWright  PF  et al.  The impact of influenza on hospitalizations, outpatient visits and antibiotic prescriptions in children. N Engl J Med. 2000;342225- 231
Izurieta  HSThompson  WWPiotr  K  et al.  Influenza and the rates of hospitalization for respiratory disease among infants and young children. N Engl J Med. 2000;342232- 239
Neuzil  KMWright  PFMitchel  EF  et al.  The burden of influenza illness in children with asthma and other chronic medical conditions. J Pediatr. 2000;137856- 864
Neuzil  KMZhu  YGriffin  MR  et al.  The burden of interpandemic influenza in children younger than 5 years: a 25-year prospective study. J Infect Dis. 2002;185147- 152
Glezen  WPKeitel  WATaber  LHPiedra  PAClover  RDCouch  RB Age distribution of patients with medically-attended illnesses caused by sequential variants of influenzaA/H1N1; comparison to age-specific infection rates, 1978-1979. Am J Epidemiol. 1991;133296- 304
Dunn  FLCarey  DECohen  AMartin  JD Epidemiologic studies of Asian influenza in a Louisiana parish. Am J Hyg. 1959;70351- 371
Sullivan  KMMonto  ASLongini Jr  IM Estimates of the US health impact of influenza. Am J Public Health. 1993;831712- 1716
Adams  PFHendershot  GEMarano  MA Current Estimates From the National Health Interview Survey.  Hyattsville, Md National Center for Health Statistics1996;Data from Vital Health Statistics, No. 199
Nichol  KLLind  AMargolis  KL  et al.  The effectiveness of vaccination against influenza in healthy, working adults. N Engl J Med. 1995;333889- 893
Keech  MScott  AJRyan  PJ The impact of influenza and influenza-like illness on productivity and healthcare resource utilization in a working population. Occup Med (Lond). 1998;4885- 90
Lenaway  DDAmbler  A Evaluation of a school-based influenza surveillance system. Public Health Rep. 1995;110333- 337
White  TLavoie  SNettleman  MD Potential cost savings attributable to influenza vaccination of school-aged children. Pediatrics. 1999;103e73
Foy  HMCooney  MKAllan  I Longitudinal studies of type A and B influenza among Seattle schoolchildren and families, 1968-1974. J Infect Dis. 1976;134362- 369
Fox  JPHall  CECooney  MKFoy  HM Influenza virus infections in Seattle families, 1975-1979: study design, methods, and the occurrence of infections by time and age. Am J Epidemiol. 1982;116212- 227
Hurwitz  ESHaber  MChang  A  et al.  Effectiveness of influenza vaccination of day care children in reducing influenza-related morbidity among household contacts. JAMA. 2000;2841677- 1682
Longini  IMKoopman  JSMonto  ASFox  JP Estimating household and community transmission parameters for influenza. Am J Epidemiol. 1982;115736- 751
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