Group B streptococci

Group B streptococci can cause infection in people of any age; however, these organisms are common pathogens in infants younger than 3 months. Early-onset illness is often associated with maternal fever at the time of delivery, prolonged rupture of membranes, amnionitis, prematurity, and low birth weight.

Infected neonates usually manifest clinical symptoms within the first 6 to 12 hours of life. Symptoms include fever, respiratory distress, apnea, tachypnea, and hypoxemia. By 12 to 24 hours of age, signs of cardiovascular collapse are often apparent. Frequently, the syndrome of pulmonary hypertension of the newborn is present, and pulmonary or intracranial hemorrhage may become the terminal event.

Isolation of the organism establishes the diagnosis. Cultures from blood and cerebrospinal fluids must be obtained in all instances of suspected group B streptococcal pneumonia. Rapid diagnostic techniques have been helpful in providing early diagnoses. The radiographic findings in neonates with group B streptococcal pneumonia can be either a lobar (40%) or a diffuse reticulonodular pattern with bronchograms similar to findings of respiratory distress syndrome.

Aggressive cardiovascular and ventilatory support is usually required, particularly in the early stages of the disease. Antibiotic therapy should include a combination of ampicillin or penicillin and an aminoglycoside agent.

Although in the past the mortality rate of patients with group B streptococcal pneumonia could be as high as 50% to 60%, recent studies suggest improvement with prompt initiation of therapy and even better outcomes with maternal prophylaxis. Some infants experience a second episode of infection 1 to 2 weeks after discontinuation of antibiotic therapy. Infants with group B streptococcal pneumonia and meningeal involvement (30%) may demonstrate significant neurologic deficits (20%–50%).

Streptococcus pneumoniae

S. pneumoniae is a gram-positive diplococcus with at least 84 sera types; however, 80% of the serious infections are caused by only 12 sera types. Streptococci are a major cause of pneumonia in the United States, usually affecting infants younger than 2 years, with a peak age between 3 and 5 months. Patients with asplenia, functional hyposplenia, or malignancy or those receiving immunosuppressive drugs are at special risk of the development of invasive disease.

The radiographic finding in infants is often a patchy bronchopneumonia. Lobar consolidation is not uncommon. Penicillin is the drug of choice in the treatment of persons with streptococcal pneumonia. However, organisms relatively resistant to penicillin occur in 3% to 40% of culture-positive patients recorded in studies from different parts of the United States. In such instances pneumonias have been effectively treated with vancomycin or high-dose β-lactam cephalosporin agents, such as cefuroxime, ceftriaxone, or cefotaxime. Disease resulting from penicillin-resistant pneumococci should be considered in patients who received therapy with β-lactam antibiotics.

The pneumococcal 13-valent conjugate vaccine is recommended for all children aged 5 years and younger. It is also recommended for certain children aged 60 to 71 months with chronic medical conditions, immunosuppressive conditions, functional or anatomic asplenia, cerebrospinal fluid leaks, or cochlear implants. The pneumococcal polysaccharide vaccine, a 23-valent formulation, is recommended in children 2 years and older with an increased risk of invasive pneumococcal disease.

Haemophilus influenzae

Haemophilus organisms are small, nonmotile, gram-negative rods that occur in both encapsulated and nonencapsulated forms. Approximately 90% to 95% of invasive disease is caused by the encapsulated sera type B. A pleural effusion or empyema is detected in nearly 40% of patients with H. influenzae pneumonia. There is an extremely high incidence of bacteremia in this disease. Serious complications—such as epiglottitis, meningitis, and pericarditis—can be diagnosed in 15% to 20% of patients. Cellulitis, anemia, and septic arthritis occur infrequently.

In a hospitalized patient, administration of β-lactam agents or a second- or third-generation cephalosporin is generally an effective therapy. ^, The mortality rate in appropriately treated patients is generally considered to be less than 5% and often is related to associated meningitis, epiglottitis, or pericarditis rather than the pneumonic process itself. Hib conjugate vaccine is an important measure in reducing the incidence of Haemophilus -related disease and should be administered to all children. ^{, ,}

Staphylococcal pneumonia

Primary S. aureus pneumonia has decreased in frequency in recent years but still accounts for approximately 25% of cases in young infants. The incidence of secondary or metastatic dissemination has increased since 1972. Patients with primary pneumonia present with fever and respiratory symptoms, whereas those with metastatic disease often present with fever, generalized toxicity, and musculoskeletal symptoms. In patients presenting with primary staphylococcal pneumonia, the disease is often preceded by an upper respiratory tract infection. Pleural effusion or empyema develops in nearly 80% of the patients with primary staphylococcal pneumonia and is extremely common in patients with metastatic disease. It is not unusual for patients with staphylococcal pneumonia to remain bacteremic long after the initiation of appropriate antibiotic therapy.

Radiographic findings of S. aureus pneumonia differ according to the stage of the disease. They vary from minimal changes to consolidation (most common) and are associated with pleural effusion (50%–60%) or pneumothorax (21%). Pneumatoceles usually appear during the convalescent stage and may persist for prolonged periods in asymptomatic patients. Antibiotic therapy should be administered intravenously and include a drug that is resistant to inactivation. Strong consideration should be given to providing antibiotic coverage for methicillin-resistant S. aureus, which can account for 1% to 30% of isolates depending on the prevalence in the area. The duration of therapy is usually lengthier in patients with staphylococcal disease than for patients with other bacterial pneumonias and consists of 21 days or more of treatment. The mortality rate of staphylococcal pneumonia varies from 23% to 33%. Increased mortality is usually associated with younger age, inappropriate initial antimicrobial therapy, or failure to drain an empyema appropriately.

Mycoplasma pneumonia

Mycoplasma organisms are the smallest free-living microorganisms. They lack a cell wall and are pleomorphic. Mycoplasma is an uncommon cause of pneumonia in children younger than 5 years but is the leading cause of pneumonia in school-aged children and young adults. Illness can range from a mild upper respiratory tract infection to tracheobronchitis to pneumonia. Symptoms include malaise, low-grade fevers, and headache. In 10% of children a rash develops that usually is maculopapular. Cough, if it develops, usually occurs within a few days and may continue for 3 to 4 weeks. Initially the cough is nonproductive but then may become productive and is usually associated with widespread rales on physical examination. Radiographic abnormalities vary but are usually bilateral and diffuse.

Isolation of Mycoplasma by culture is complicated by the requirement for special enriched broth or agar media, which are not widely available. It is successful in only 40% to 90% of cases and requires 7 to 21 days. A fourfold increase in antibody titer between acute and convalescent sera is diagnostic, but the time involved is lengthy, providing only a retrospective diagnosis. Complement fixation and immunofluorescent and several enzyme immunoassay antibody tests have been developed but are of limited diagnostic value. Serum cold agglutinins with titers of 1 : 32 or greater are present in more than 50% of patients with pneumonia by the beginning of the second week of illness. The PCR test has become an important means of diagnosing M. pneumoniae infections in clinical practice, allowing for initiation of therapy directed at the causative pathogen. Treatment of upper respiratory tract infections or acute bronchitis is rarely indicated, but treatment with erythromycin or another macrolide, such as azithromycin, is indicated for persons with pneumonia or otitis media.

Gram-negative bacteria

Pneumonia caused by gram-negative enteric bacteria, especially Pseudomonas, is almost always found in patients with underlying pulmonary disease, compromised immune status, or those receiving prolonged respiratory therapy. ^, Gram-negative enteric bacteria are a frequent cause of nosocomial infection in critical care units. These organisms can produce a severe necrotizing pneumonia that is associated with an increase in morbidity.

Legionella pneumophila

Pneumonia caused by Legionella pneumophila has been reported infrequently in the pediatric age group. The onset of this disease is characterized by high, unremitting fever; chills; and a nonproductive cough. Extrapulmonary manifestations include gastrointestinal symptoms such as diarrhea, liver involvement, and confusion. Chest radiographs typically consist of peripheral nodular infiltrates and pleural effusions. Cavitation occurs only in immunosuppressed individuals. Death in the normal host is unusual if prompt therapy with azithromycin or erythromycin is initiated.

Anaerobic bacteria

Pneumonia resulting from anaerobic upper respiratory flora is uncommon in healthy children. When it does occur, it is frequently associated with risk factors such as underlying pulmonary disease, a central nervous system (CNS) disorder (including seizures), a postanesthetic state, and aspiration of a foreign body. Lung abscess and empyema are frequent complications in persons with anaerobic bacterial pneumonias.

Respiratory syncytial virus

RSV is the most common cause of bronchiolitis and pneumonia in the United States in children between the ages of 6 months and 3 years. The disease produced by RSV varies from upper respiratory tract infection to severe bronchiolitis and pneumonia with wheezing and respiratory failure. Higher mortality rates and greater severity with prolonged symptoms occur in infants and children younger than 6 weeks of age and in those who have a history of prematurity, chronic lung disease, cardiopulmonary disease, congenital heart disease, pulmonary hypertension, or neuromuscular impairment, as well as in those receiving chemotherapy or immunosuppressive therapy. ^, Signs of RSV pneumonia include wheezing, dyspnea, pulmonary infiltrates, and areas of atelectasis and hyperinflation on the chest radiograph. RSV infection may result in increased airway reactivity and airway resistance that persists for months. Significant respiratory tract shedding of virus continues for up to 21 days from the onset of illness. Nosocomial spread of RSV infection is common; early diagnosis and appropriate isolation techniques are critical in hospitalized patients.

Methods for diagnosis of RSV include viral isolation in cell culture, immunofluorescence of exfoliated nasopharyngeal epithelial cells for detection of RSV antigens, and enzyme immunoassay for detection of RSV antigens in nasal secretions. ^, PCR technology is also commonly used.

All hospitalized patients with bronchiolitis and RSV pneumonia should be monitored for hypoxia, hypercarbia, and the need for ventilatory assistance. Supportive care includes the use of humidified oxygen, secretion clearance, and hydration. ^, Mechanical ventilation for respiratory failure is usually well tolerated. Extracorporeal membrane oxygenation has been used successfully in infants who do not respond to conventional ventilation. ^, The routine administration of bronchodilators and corticosteroids is not warranted; use should be individualized on the basis of clinical response. ^, Passive immunoprophylaxis has proved useful in high-risk populations in preventing RSV infection, as has palivizumab, a humanized mouse monoclonal antibody. ^, The incidence of bacterial superinfection in persons with RSV disease is low; therefore, prophylactic antibiotics are not recommended for RSV disease. ^{, ,} It is not unusual for an infant with RSV to require hospitalization for 7 to 10 days following the onset of illness. Long-term complications of RSV infection may include persistent bronchial reactivity, with lower respiratory tract symptoms in more than 70% of infants in the year following hospitalization. Whether moderately severe RSV infection predisposes a person to asthma later in life remains controversial.

Parainfluenza virus

Parainfluenza virus (types 1 and 2) is more often associated with laryngotracheobronchitis and croup than with pneumonia (usually type 3). Parainfluenza is second only to RSV as an etiology of lower respiratory tract disease responsible for the hospitalization of children. The pneumonia associated with parainfluenza is typically mild; however, fatal cases with prolonged viral shedding have been reported in patients with severe combined immunodeficiency disease. Conferred immunity following infection is low; repeat infection occurs in nearly 50% of patients by age 30 months, although it results in progressively milder illness. Parainfluenza virus, like RSV, has demonstrated the ability to elicit an immunoglobulin E–specific antibody response. Rapid identification of parainfluenza virus by either fluorescent or enzyme-linked immunologic techniques is possible, but results are variable depending on the viral type and antisera used. A viral culture may take up to 1 week. PCR methods are available for detection and differentiation, with high sensitivity and specificity. Treatment is supportive.

Adenovirus

Adenoviruses are responsible for approximately 3% of the pneumonias occurring in children. Clinical features are similar to other viral pneumonias except that the onset of illness is often gradual, occurring over several days. Of the 51 serotypes, types 3, 4, and 7 are the most common causes of lower respiratory tract disease in children. Adenovirus type 7 is most commonly associated with severe pneumonitis in infants and children and has a significant incidence of mortality and morbidity. ^, In 2007, a new strain of adenovirus 14 was isolated in previously healthy infants and young adults in the United States in whom fatal pneumonia developed. A clinical presentation similar to that of bacterial pneumonia—with massive pleural effusion, rhabdomyolysis, and myoglobinuria—has been reported with adenovirus type 21. In many infants with documented adenovirus respiratory tract infection, chronic pulmonary disease develops, which manifests as persistent atelectasis, bronchiectasis, and recurrent pneumonitis with areas of hyperinflation and interstitial fibrosis. Bronchiectasis and restrictive lung disease have been documented in children following acute adenovirus infection. Adenovirus pneumonia is the most common cause of bronchiolitis obliterans in children, and unilateral hyperlucent lung syndrome has been reported. Disseminated adenovirus occurs and is usually associated with infection by serotype 3, 7, or 21. It occurs most frequently in infants younger than 18 months and usually involves the heart, pericardium, liver, pancreas, kidneys, CNS, and skin. Fatal cases of adenovirus and pneumonia can occur in previously healthy young individuals. Diagnosis is made by cell culture and antigen and DNA detection by PCR. Adenovirus typing is available from some reference and research laboratories. Treatment is mainly supportive in immunocompetent patients, but cidofovir and intravenous immunoglobulins (IVIGs) have been used in some immunocompromised patients.

Influenza

Three antigenically distinct influenza viruses exist—types A, B, and C. All three have hemagglutinin surface antigen, but only types A and B have neuraminidase surface antigen. Antigenic drift for types A and B produces minor changes in the surface antigens, resulting in endemic illness. Antigenic shift occurs only with influenza type A, resulting in a major change or new surface antigen for which there may be low or no immunity in the population. Influenza type A is subtyped by its surface antigens; currently, three influenza strains are circulating worldwide, including influenza A/H1N1, H1N2, and H3N2. ^,

Clinical signs of uncomplicated influenza pneumonia include coryzal symptoms followed by dyspnea, fever, cyanosis, cough, and wheezing. Children with influenza typically have a more sudden onset of “toxic” signs than do those with other viral diseases. Infection is associated with myalgia, encephalopathy, and cardiac involvement. Pathologically, influenza virus infection is similar to RSV in that the virus destroys ciliated respiratory epithelial cells with subsequent edema and an acute inflammatory response. Influenza has been associated with Reye syndrome and significant bacterial suprainfections. In patients in whom bacterial infection develops, there often is a period of apparent improvement before a sudden worsening that is heralded by the production of purulent sputum, return of fever, and development of pulmonary consolidation. Fatal outcomes have been reported in previously healthy children as well as in high-risk groups.

Prevention of influenza disease is possible with either administration of multivalent influenza vaccine (influenza A/H1N1, A/H3N2, and B) or chemoprophylaxis with oseltamivir or inhaled zanamivir (influenza A, B, and A/H1N1). One study showed the efficacy of aerosolized ribavirin in the treatment of persons with influenza B. ^, Diagnosis of influenza pneumonia may be made by a culture of the virus from respiratory secretions or with serologic techniques. Rapid diagnosis by means of immunofluorescence of exfoliated nasopharyngeal cells may be helpful, as well as by PCR. Treatment includes supportive care, monitoring of respiratory status, and administration of antiviral medications.

Measles

Measles is a highly contagious disease that is preventable by vaccine; the incidence fell below the endemic threshold in the United States in 2000. Endemic outbreaks continue in developing countries and when international travelers import measles to nonimmunized persons in the United States. ^, Typical disease manifests as high fever, cough, runny nose, and generalized rash. Respiratory symptoms are nearly universal in this illness, making the prevalence of measles pneumonia difficult to determine. Moist crackles develop in most children, and approximately 20% have expiratory wheezes and hypoxia. In cases in which radiographs have been obtained, a fine reticular infiltrate was present, compared with the nodular infiltrates in children with atypical measles. Although the clinical syndrome usually resolves over 1 to 2 weeks, both radiographic and pulmonary function abnormalities may persist for months. Severe life-threatening tracheitis may occur during the course of measles or bacterial suprainfection. In fatal cases, severe respiratory and nervous system diseases are manifested, and lung tissue demonstrating interstitial pneumonitis with diffuse endothelial cells, pneumatocyte degeneration, and presence of multinucleated giant cells has been reported.

Diagnosis is made by isolation of the virus, standard serology, or identification of viral ribonucleic acid by reverse transcription PCR. All suspected cases should be reported to local and state health departments. No antiviral agent is available; treatment is supportive. Two doses of vitamin A (200,000 International Units on consecutive days) have been shown to reduce pulmonary-specific and overall mortality rates in patients up to 2 years of age. Administration of IVIG may be of benefit to high-risk or immunosuppressed patients when it is started within 6 days of exposure.

Human immunodeficiency virus

Human immunodeficiency virus (HIV) infection in children most commonly presents with recurrent bacterial infections. The major causes of morbidity and mortality in pediatric AIDS patients are associated with lung disease, ranging from opportunistic infections such as Pneumocystis jiroveci pneumonia to entities such as chronic interstitial pneumonitis. ^, Treatment for specific pulmonary pathogens is discussed throughout this chapter, but specific guidelines for HIV/AIDS treatment are lengthy, rapidly changing, and beyond the scope of this chapter.

Vaccination

Passive immunization is also available for some viruses that can be associated with pneumonitis, but recommendations are ever-changing. Check the Centers for Disease Control and Prevention (CDC) recommendations and see Table 52.3 .

Chemoprophylaxis

Amantadine, rimantadine, oseltamivir, and zanamivir are approved for prophylaxis of viral respiratory tract infection caused by influenza. Amantadine and rimantadine have been shown to be effective prophylaxis for influenza type A. However, they are not active against influenza type A/H1N1 or influenza type B. Therefore, they are no longer recommended for prophylaxis. Oseltamivir and zanamivir have activity against influenza types A, B, and A/H1N1. Oseltamivir resistance has been reported among persons with influenza type A/H1N1 strains globally, but no significant resistance has been reported among persons with influenza type A/H1N1 strains circulating in the United States. Oseltamivir and zanamivir are recommended for persons at high risk for serious influenza infection who have not been vaccinated or who have received the vaccine within 2 weeks of the onset of an epidemic. They are also recommended for persons in whom appropriate immune response may not develop following vaccination and for persons who cannot receive the influenza vaccine because of allergic reactions. ^{, ,}

Therapy

Several antiviral agents inhibit the replication of respiratory viruses in vitro. Some of these drugs have been used clinically in both experimental and naturally occurring respiratory infections ( Table 52.6 ). Most influenza A and B virus strains are susceptible to oseltamivir and zanamivir. ^, These neuraminidase inhibitors have been shown to reduce the severity and duration of illness. Resistance to oseltamivir has been reported in persons with influenza type A/H1N1 strains but not A/H3N2 or B strains. Zanamivir is effective against influenza types A, B, and A/H1N1, but it has not been approved for therapeutic use in children younger than 7 years. Peramivir was approved to treat influenza infection in adults in December 2014. Peramivir is the first neuraminidase inhibitor approved in IV form. Peramivir is a neuraminidase inhibitor and should not be administered if the patient has a severe allergy to oseltamivir, zanamivir, or one of their metabolite components. Oral baloxavir is effective against influenza types A and B but has a different mechanism of action than neuraminidase inhibitors. Resistance patterns are perpetually changing; for the most up-to-date information regarding resistance patterns, see the CDC website at www.cdc.gov/flu/professionals/antivirals/ .

Ribavirin is a synthetic nucleoside analog licensed for use in aerosol form for the treatment of persons with severe RSV infection. This therapy may shorten the course of the illness and improve oxygenation in high-risk patients. A few children with severe combined immune deficiency have been treated with ribavirin with resulting clinical improvement and decrease in viral shedding. ^, Ribavirin aerosol may be effective in shortening the course of both influenza types A and B in infections in college students, and it is possible that parainfluenza and the measles virus can be treated with ribavirin. Various case reports of treatment in seriously ill adults with complicated viral infections suggest that ribavirin may be an effective treatment. Overall, the documented therapeutic benefit of antiviral agents has been inconclusive. Improvement is most apparent when the therapy was initiated early after the onset of infection. Future investigations are necessary to define the optimum dose/route of antiviral agents for each respiratory virus/pneumonia and to clarify the ability of antiviral therapy to modify serious lower respiratory tract infection in high-risk infants and children.

In persons with varicella or zoster, acyclovir reduces the period of viral shedding and the time needed to heal skin lesions. It can also prevent the dissemination of localized zoster in immunocompromised children. Thus, the use of acyclovir in immunosuppressed patients can be justified by the low toxicity of the drug and the potential severity of the illness. Ganciclovir is an antiviral drug with significant activity against cytomegalovirus. It has been used successfully in immunocompromised patients with disseminated cytomegalovirus and pneumonia. Symptomatic infection of the lower airway with herpes viruses is rare. When it occurs, it usually does so in an immunosuppressed child. Antiviral therapy for herpes viruses includes acyclovir, foscarnet, and adenine arabinoside. ^,