[Emerging Infectious Diseases * Volume 3 * Number 2 * April-June 1997]

Dispatches

Invasive Haemophilus influenzae Type B Disease in Elderly Nursing Home
Residents: Two Related Cases

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      We investigated two fatal cases of invasive Haemophilus
      influenzae type b (Hib) infection in a community nursing home
      in western Sydney, Australia. Two elderly women had lived in
      the same room, and the onset of their illness was 5 days apart.
      Hib isolates from blood cultures showed identical profiles by
      pulsed field gel electrophoresis. These findings suggest that
      Hib infection was transmitted within this nursing home. Serious
      Hib disease may be underrecognized in this setting. Continued
      surveillance and serotyping of invasive H. influenzae disease
      is essential for identifying groups at increasing risk that may
      benefit from immunization against Hib.

After the introduction of routine childhood immunization against
Haemophilus influenzae type b (Hib), the incidence of invasive Hib disease
fell dramatically in several countries, including Australia (1-3). This
decline has been most evident among children aged less than 5 years.
Meanwhile, serious Hib infections, such as pneumonia and epiglottitis, have
been increasingly recognized among elderly, debilitated, and
immunosuppressed adults (4-6). However, clusters of Hib infection have
rarely been reported in adults. To examine their relatedness, we
investigated two fatal cases of Hib septicemia in a community nursing home.

Case Reports

Case 1
In June 1996, a 71-year-old female nursing home resident was hospitalized
after 3 days of unproductive cough, fevers, confusion, and increasing
dyspnea. She had a history of cerebrovascular disease, muscular dystrophy,
and congestive heart failure and was confined to a wheelchair. She had
clinical signs of left lower lobe pneumonia and was afebrile. A blood film
was normal, but a chest X-ray showed extensive bilateral pulmonary
infiltrates. Arterial blood gases showed severe hypoxia in room air (PO2 44
mm Hg, saturation 77%). Ceftriaxone 1 g and metronidazole 500 mg were given
intravenously for suspected aspiration pneumonia, but the patient became
severely hypotensive and died 8 hours after admission to the hospital. The
following day, betalactamase-negative Hib was isolated from blood cultures
collected before the patient died.

Case 2
Two days after the first patient was hospitalized, an 80-year-old female
resident of the same nursing home became ill with fever and sore throat.
She had a history of chronic airflow limitation, mild renal impairment, and
dementia. Her sore throat rapidly worsened, and the next day she was
hospitalized with severe dysphagia. On examination, she was febrile
(38.5°C) and hypotensive (90/60 mm Hg) and had pretracheal cellulitis. No
clinical evidence of pneumonia was observed, and a chest X-ray was normal.
She was intubated, and extensive epiglottitis, laryngitis, and tracheitis
were noted. Ceftriaxone 2 g, gentamicin 80 mg, flucloxacillin 1 g, and
metronidazole 500 mg were administered intravenously. Inotropes were given
for hypotension and acute renal failure, but the patient's condition
deteriorated rapidly, and she died 9 hours after admission to the hospital.
Beta-lactamase-negative Hib was subsequently isolated from blood cultures
collected before the patient died.

Investigation
For several months, these two women had occupied beds in the same six-bed
room (the largest room) in the 44-bed nursing home. The home employed 37
nursing and ancillary staff. During 3 weeks before the investigation, 20
residents and several staff had been unwell with bronchitis, for which many
had received oral antibiotics. No sputum samples had been collected for
culture from residents or staff. Two other elderly residents had died
during the preceding 10 days, but their case notes did not document any
fever or symptoms suggesting infection. On the first day of our
investigation, two elderly residents were febrile. One woman had bilateral
bronchopneumonia that was not responding to oral cefaclor and was
hospitalized; blood and sputum cultures yielded no pathogens, and urine
samples did not contain Hib capsular antigen. The other woman had been
febrile for 1 week, with a cellulitic leg ulcer and pleuritic chest pain of
uncertain etiology. Because of her other chronic illnesses she was treated
palliatively and died 1 week later. A swab of her leg ulcer yielded group G
streptococcus, blood cultures were negative, and sputum was not obtained.

Throat swabs were collected from all 81 residents and staff at the nursing
home and cultured for Hib on bacitracin chocolate blood agar. We
administered rifampicin chemoprophylaxis to all roommates of the index case
patients and 28 staff who had been in regular close contact with the two
case patients during the week before their illness. No new febrile
illnesses occurred during 3 weeks of follow-up, and Hib was not isolated
from any throat swab cultures. The Hib isolates from the first and second
patients were examined by pulsed field gel electrophoresis and had
identical profiles that were distinguishable from several epidemiologically
unrelated isolates (Figure).

         [Image] [Figures not available in ASCII version]
         Figure. Pulsed field gel electrophoresis of Haemophilus
         influenzae type b (Hib) isolates from blood culture of
         two elderly nursing home residents (lanes 1 and 2)
         compared with epidemiologically unrelated H. influenzae
         isolates sent to our laboratory for typing: lane 3,
         laboratory Hib strain; lane 4, non-H. influenzae; lane 5
         and 12, invasive nontypeable H. influenzae; lane 6-11,
         unrelated Hib isolates; lane 13, H. influenzae type a;
         lane 14, 1 kilobase molecular marker. The enzyme used
         for DNA digestion was Apal.

The relationship of these two fatal cases of Hib disease in time and place
and the clonality of the isolates provide good evidence that transmission
of Hib infection occurred in this nursing home. We were unable to
demonstrate that Hib caused any of the associated reports of bronchitis and
febrile illness among residents and staff, and our prevalence study did not
show any asymptomatic Hib carriage. However, the survey was performed 10
days after the onset of the second case of septicemia following widespread
use of antibiotics, and it may not have accurately reflected the prevalence
of Hib carriage at the time these cases occurred. It is also difficult to
evaluate whether chemoprophylaxis was a useful intervention in this
setting.

To our knowledge, this is the first reported cluster of invasive Hib
infection among adults in a community-based nursing home. Three other
clusters of Hib infection in adults have been described: one occurred in a
nursing home attached to a hospital, and two were nosocomial—including a
cluster of bronchitic illness (7-9). Our report provides further evidence
that Hib can cause clusters of serious disease among the elderly—at least
in institutions. Given that diagnostic procedures are performed
infrequently in many community nursing homes, Hib infection may be
underrecognized in this setting.

We were especially interested in these two cases in adults as they were the
only instances of invasive Hib disease reported to this Public Health Unit
from its population base of one million persons over 12 months—a rate of
0.3 per 100,000 population aged 15 years and older. This pattern of
notification differs markedly from that observed in western Sydney at the
time childhood Hib vaccination was first introduced in mid-1992. In 1992,
27 of 30 notifications of invasive Hib disease in this area were of
children aged less than 5 years, or 36.9 per 100,000 population (New South
Wales Health Department, unpub. data). Although invasive Hib infection
remains uncommon in adults in communities where childhood Hib vaccination
is routine, the relative frequency of invasive Hib infection is increasing
in older age groups.

Population-based studies of acute epiglottitis undertaken in northern
California and Rhode Island have also shown that the incidence of childhood
epiglottitis is falling rapidly since the introduction of Hib immunization,
while the incidence of epiglottitis in adults remains steady or is
increasing (10,11). Acute epiglottitis in children is usually caused by
Hib, and the falling incidence of epiglottitis in this age group is
explainable by immunization. In adults, most culture-positive cases of
acute epiglottitis are also caused by Hib (10,12). However, the incidence
of Hib-related epiglottitis in adults does not appear to be changing
appreciably—at least in Rhode Island—and Hib does not account for the
increasing incidence of epiglottitis observed in this age group (10).
Indeed, acute epiglottitis is frequently culture negative in adults, so
explaining its increasing incidence and ascertaining the etiologic agents
in older age groups require further study (10,12).

Invasive Hib disease should continue to be monitored in all age groups
after the introduction of childhood immunization against Hib. Evidence
suggests that Hib immunization reduces the acquisition of Hib carriage in
children, and reduced carriage among children may indirectly prevent Hib
disease in adults (13). However, surveillance data in western Sydney and
metropolitan Atlanta have not supported this hypothesis; rates of adult Hib
disease are remaining approximately unchanged, despite dramatic reductions
in childhood disease (5; New South Wales Health Department, unpub. data).
Only by serotyping isolates of H. influenzae that cause invasive disease
will it be possible to detect changing patterns of invasive Hib disease in
adults during this era of childhood immunization. Serotype-specific
surveillance of invasive H. influenzae disease is also needed to assess
progress towards the elimination of childhood Hib disease. In addition,
periodic cross-sectional serotyping studies of H. influenzae isolates
causing noninvasive disease would help measure the effects of Hib
immunization on the incidence of less serious forms of Hib infection. These
surveillance methods will identify groups at increasing or underrecognized
risk that may benefit from immunization.

Acknowledgments
The authors thank Graham O'Donnell (Department of Microbiology, Westmead
Hospital) and Marianne Kerr and Oanh Nguyen (Western Sector Public Health
Unit). The Master of Applied Epidemiology Program is funded by the
Commonwealth Department of Health and Family Services, Canberra.

Timothy C. Heath,*† Moira C. Hewitt,†‡ Bin Jalaludin,* Christine Roberts,†
Anthony G. Capon,* Peter Jelfs,§ and Gwendolyn L. Gilbert§
*Western Sector Public Health Unit, North Parramatta, New South Wales;
†Australian National University, Australian Capital Territory, Australia;
‡Department of Public Health and Community Medicine, Westmead, New South
Wales; and §Institute of Clinical Pathology and Medical Research, Westmead,
New South Wales

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Emerging Infectious Diseases
National Center for Infectious Diseases
Centers for Disease Control and Prevention
Atlanta, GA

URL: ftp://ftp.cdc.gov/pub/EID/vol3no2/ascii/heath.txt