Treating Community-acquired Bacterial Respiratory Tract Infections: Update on Etiology, Diagnosis, and Antimicrobial Therapy

Acute bacterial sinusitis (ABS), acute bacterial exacerbations of chronic bronchitis (ABECB), and community-acquired pneumonia (CAP) are 3 respiratory tract infections (RTIs) in adults that pose a treatment challenge for clinicians in the primary care setting. Each of these conditions requires prompt initiation of therapy to achieve optimal patient outcomes, but diagnosis and selection of treatment typically are made without the benefit of diagnostic tests. Due to increasingly high levels of antibiotic resistance,^1,2 the decision to treat and the selection of therapy are critically important.^3-5

This article briefly reviews the etiology of community-acquired bacterial RTIs, important diagnostic considerations, and current treatment options for patients who have these infections.

Community-acquired respiratory tract infections: Viral vs bacterial

The debate regarding whether to prescribe antibiotics for patients with community-acquired RTIs continues, since most of these infections are viral. Approximately 2% of patients with acute sinusitis have a bacterial infection.^4,6 The etiology of acute exacerbations of chronic bronchitis (AECB) is only about 50% bacterial; other causes for these exacerbations include viruses, allergens, and environmental pollutants.³ Among ambulatory patients with CAP, even when diagnostic testing is performed, the causative pathogen cannot be identified in 40% to 50% of patients.⁷ All of these findings support the view that many cases of acute sinusitis, AECB, or CAP are not caused by bacteria and patients with these types of infections will not benefit from antimicrobial therapy. A diagnostic challenge to primary care physicians is determining which patients have a bacterial infection.

Differential diagnosis of bacterial infection in patients with community-acquired respiratory tract infections

National and international guidelines have been developed to assist clinicians in the differential diagnosis of bacterial infections.^7-11

Acute sinusitis

Clinical diagnosis of acute sinusitis is based primarily on medical history, symptoms, and physical findings.¹⁴ A wide range of symptoms may occur in patients with acute sinusitis, as it does in patients with a common cold; TABLE 1shows the symptoms most likely to be associated with sinusitis.¹² No single clinical sign or symptom distinguishes between bacterial and viral causes of acute sinusitis; rather, it is the combination of these signs or symptoms that may lead to the diagnosis of bacterial sinusitis. A history of purulent secretions and symptoms that appear more severe than those typically associated with an upper RTI suggests ABS;¹³ however, purulent discharge alone is not always indicative of a bacterial infection. “Double-sickening,” in which the patient becomes ill and then gets worse, combined with elevation in Creactive protein may indicate a bacterial infection.¹⁴ Williams et al¹⁵ recommended that clinical diagnosis emphasize key features such as maxillary toothache, poor response to over-the counter decongestants or antihistamines, a history of colored nasal discharge, abnormal transillumination, and mucopurulent discharge on examination. A diagnosis of ABS may be made if symptoms persist for more than 10 days, worsen after 5 to 7 days, or are more severe than those normally associated with viral upper respiratory illness.^8,13

TABLE 1

Signs and symptoms associated with community-acquired respiratory tract infections^3,13,14,17

Acute exacerbations of chronic bronchitis

There is no definitive agreement regarding what constitutes an AECB. Symptoms originally described by Anthonisen et al¹⁶ are commonly used to define AECB: increased cough and sputum, increased sputum purulence, and increased dyspnea over baseline (TABLE 1).¹⁷ A thorough physical and detailed medical history usually are sufficient to diagnose AECB while ruling out conditions such as pneumonia, congestive heart failure, myocardial ischemia, upper RTI, pulmonary embolism, and recurrent aspiration. A chest x-ray or an electrocardiogram may help with differential diagnosis in some patients.^17,18 Nevertheless, determination of whether an acute exacerbation is bacterial or viral may be difficult because many patients with this disease have persistent airway colonization with the same bacteria thought to be responsible for AECB. To help physicians decide if antibiotics are necessary, practice guidelines have stratified patients by type of exacerbation (mild, moderate, or severe) and risk factors (TABLE 2).

TABLE 2

Treatment of acute exacerbations of chronic bronchitis⁸

Community-acquired pneumonia

Patients with CAP usually present with acute onset of lower respiratory symptoms (TABLE 1). Older and immunosuppressed patients may present with nonrespiratory symptoms, such as confusion, worsening of a chronic condition, or even falls. It is important to note that no combination of clinical signs and symptoms is a definitive diagnosis of CAP.¹⁹ All patients with suspected CAP should have a chest radiograph with posteroanterior and lateral views, as radiographs are essential for confirming a diagnosis.³ The Infectious Diseases Society of America (IDSA) and the American Thoracic Society support use of the Pneumonia PORT (Pneumonia Outcomes Research Team) Severity Index (PSI) as a means of risk stratification, combined with careful assessment of the patient and use of clinical judgment when determining whether a patient can be treated on an outpatient basis or should be hospitalized.¹⁰

Although it is important to attempt to identify the infecting organism, antimicrobial treatment for CAP is empiric because of the time it takes to get laboratory results and the potential for rapid deterioration of the patient’s condition. Further, patients with CAP may not produce sputum for Gram stain and culture; or, if they do, it may be mixed with upper respiratory tract secretions. Streptococcus pneumoniae may not grow from sputum culture; or, if found, it may be unclear whether the patient is colonized or infected.²⁰ Bacteria cultures may not be helpful either, as blood cultures usually are sterile in patients with CAP.²⁰

Selection of antimicrobial therapy

Once a bacterial infection is suspected, antibiotic treatment should be initiated promptly. Antibiotic therapy for ABS, ABECB, and CAP is simplified somewhat because the distributions of bacterial pathogens associated with each infection overlap substantially. The pathogens encountered most often in patients with ABS are Spneumoniae, Haemophilusinfluenzae, and Moraxella catarrhalis. To a lesser extent, anaerobic bacteria, other streptococcal species (including S pyogenes, S intermedius, and ahemolytic streptococci), and Staphylococcus aureusalso have been shown to cause ABS.²¹

Bacteria are isolated from the sputum of 40% to 60% of patients with AECB, and the predominant species are consistent with those listed for ABS. Atypical respiratory pathogens, most notably Chlamydophila(previously Chlamydia) pneumoniae, account for about 5% to 10% of organisms isolated from patients with ABECB.¹⁷ Patients with CAP also tend to be infected with the above-listed typical pathogens as well as the atypical Mycoplasma pneumoniae, C pneumoniae, and Legionella pneumophila. TABLE 3 lists pathogens associated with community-acquired bacterial RTIs and the effectiveness of commonly used antibiotics and telithromycin, a recently approved antimicrobial agent.

TABLE 3

Pathogens associated with ABS, CAP, and ABECB and in vitro effectiveness of commonly used antibiotics and telithromycin⁴⁰

Resistance of bacterial pathogens

Although the common causative pathogens for community-acquired bacterial RTIs are few, selection of antibiotic therapy is becoming more complicated by the increasing rate of bacterial resistance to many of the antibiotics commonly used to treat these RTIs.

Resistance has been documented for all organisms associated with community-acquired RTIs. Current estimates indicate that 25% to more than 50% of Spneumoniaestrains are not completely susceptible to penicillin and that nearly one third of strains may be resistant to macrolides.²² Penicillin-resistant Spneumoniaealso may have reduced susceptibility to other antibiotics, including tetracycline, erythromycin, azithromycin, cephalosporins, clindamycin, trimethoprim/sulfamethoxazole (TMP/ SMX), and chloramphenicol.²³Streptococcuspneumoniae have developed resistance to fluoroquinolones as well. This is of particular concern to the Centers for Disease Control and Prevention (CDC), having influenced its recommendations regarding empiric treatment of pneumonia.¹⁰ Macrolides have been mainstays in empiric therapy of CAP because of their activity against both typical and atypical respiratory pathogens; however, their effectiveness has been compromised by a rapid rise in resistance by S pneumoniae. Recent evaluation of Spneumoniae isolates collected between 2000 and 2001 showed that resistance rates to erythromycin, clarithromycin, and azithromycin had increased to 31.0%, 30.7%, and 31.0%, respectively.²⁴ Further, results from 1 recent surveillance study that examined macrolide resistance among patients with community-acquired RTIs being treated by primary care physicians indicated that 23% to 33% of Spneumoniaeisolates were resistant to macrolides.^24,25 Resistance also is becoming prevalent among other pathogens associated with community-acquired RTIs, including H influenzaeand Mcatarrhalis.^25-27 This may complicate management of patients with community-acquired RTIs; infection with a treatment-resistant pathogen can increase risk for morbidity and mortality if treatment fails to eradicate the bacteria.^20,28 However, the clinical impact of resistance remains controversial. Resistance may be overcome with the use of an antibiotic with pharmacokinetic properties or a dosing regimen that achieves very high drug concentrations at sites of infection. Host defense mechanisms also may contribute to eradication of organisms with in vitro resistance to an antibiotic.^29,30 Further, since many infections are caused by viruses with high-resolution rates and since some bacterial infections resolve due to host response, the in vivo efficacy of an antibiotic may be much higher than its in vitro sensitivity.

Antibiotics currently prescribed for patients with community-acquired bacterialRTIs

Empiric antibiotic therapy for patients with community-acquired bacterial RTIs should provide coverage against clinically important pathogens likely to be associated with these infections, including resistant strains (TABLE 3). The antibiotic selected should specifically target respiratory pathogens. For example, broad-spectrum antibiotics are not the optimum choice, as they affect both respiratory and nonrespiratory pathogens (eg, gram-negative enterics; Escherichia coliand Klebsiella pneumoniae), which may result in resistance among these organisms.^1,31

Antibiotics suitable for treatment of patients with ABS are summarized inTABLE 4. These agents vary widely in their spectra of activity as well as their ability to overcome pathogen resistance (TABLE 3). Amoxicillin, a very narrow-spectrum -lactam, generally is considered to be first-line therapy for children and adults who have ABS³² but may have little activity against resistant strains of S pneumoniae, H influenzae, and M catarrhalis.²

An analysis by the Agency for Healthcare Research and Quality concluded that amoxicillin or folate inhibitors (eg, TMP/SMX) are the most cost-effective choices for initial therapy in an otherwise healthy adult population with uncomplicated ABS.³³ For adults who fail to improve after 2 to 3 days, broad-spectrum and β-lactamase-resistant antibiotics for 7 to 14 days should be considered. A clinical practice guideline sponsored by the American Academy of Family Physicians, the American College of Physicians-Society of Internal Medicine, the CDC, and the IDSA recommends initiating treatment with narrow-spectrum agents, eg, amoxicillin, doxycycline, or TMP-SMX for patients with severe or persistent moderate symptoms of ABS.^34,35

High-dose amoxicillin/clavulanate 2000/125 mg, twice daily, was shown to be effective in treating patients with ABS, ABECB, and CAP caused by S pneumoniae, including penicillin-resistant S pneumoniae.²⁹

The macrolides erythromycin, clarithromycin, and azithromycin are effective against susceptible strains of all organisms commonly associated with ABS, but many strains of S pneumoniaealso are resistant to these drugs.^23,26 Respiratory fluoroquinolones are effective against all pathogens commonly associated with ABS, including resistant strains;²⁶ however, they also have significant activity against gram-negative enterobacteriaceae and thus may increase the potential for emergence of resistant strains of these organisms.³⁶ Ketolides are derived from the macrolide class and were designed to be effective against macrolide-resistant, gram-positive cocci.¹⁰ The first ketolide, telithromycin, is an alternative to macrolides for the treatment of patients with ABS, ABECB, and CAP. It is highly active against both common and atypical respiratory pathogens, including resistant strains, but has little activity against either enterobacteriaceae or anaerobes.³⁷

All of the same considerations mentioned for the treatment of ABS also apply to the selection of therapy for patients with ABECB or CAP (TABLE 4). Empiric antimicrobial therapy for these 2 conditions, particularly CAP, also must cover atypical respiratory pathogens.^17,38 For a number of years, monotherapy with a macrolide provided coverage against all of the pathogens likely to be associated with CAP and ABECB. In light of the emergence of resistance to these drugs by S pneumoniae, physicians should consider local and regional resistance rates before prescribing. In fact, File and colleagues³⁹ have suggested that current recommendations favoring the use of macrolides in patients with CAP may have to be reconsidered if clinical failure continues to be observed with these agents. Cunha³⁸ has taken an even stronger position, stating that macrolide monotherapy should be avoided in patients with CAP because of the high prevalence of S pneumoni-aeresistance to this class of antibiotics. These authors’ conclusions should be carefully weighed against the CDC’s and IDSA’s recommendations. The CDC previously recommended combination of macrolides and ceftriaxone for hospitalized patients to avoid emergence of fluoroquinolone resistance. The IDSA recommended empiric use of fluoroquinolones with conversion based on culture sensitivities when available.

TABLE 4

Antibiotics currently being used for the treatment of community-acquired bacterial respiratory tract infections^41-44

Conclusions

Appropriate prescribing of antibiotics can effectively slow the development of bacterial resistance. Before selecting an antibiotic for a patient with a community-acquired RTI, primary care clinicians should first evaluate whether such treatment is even necessary. Treatment of ABS, ABECB, or CAP is compromised by increasing pathogen resistance to the currently used antibiotics. Use of high-dose amoxicillin and the other “older” antibiotics may delay the emergence of resistance to “newer” drugs, making newer drugs useful for treatment of more difficult cases. New agents to the antibiotic armamentarium give primary care physicians additional therapeutic options for patients who present with bacterial RTIs.

Financial disclosure:

Stephen Brunton, MD, is a consultant for and a member of the speakers’ bureaus for Aventis Pharmaceuticals Inc and Ortho-McNeil Pharmaceutical Inc.

Acute bacterial sinusitis (ABS), acute bacterial exacerbations of chronic bronchitis (ABECB), and community-acquired pneumonia (CAP) are 3 respiratory tract infections (RTIs) in adults that pose a treatment challenge for clinicians in the primary care setting. Each of these conditions requires prompt initiation of therapy to achieve optimal patient outcomes, but diagnosis and selection of treatment typically are made without the benefit of diagnostic tests. Due to increasingly high levels of antibiotic resistance,^1,2 the decision to treat and the selection of therapy are critically important.^3-5

This article briefly reviews the etiology of community-acquired bacterial RTIs, important diagnostic considerations, and current treatment options for patients who have these infections.

Community-acquired respiratory tract infections: Viral vs bacterial

The debate regarding whether to prescribe antibiotics for patients with community-acquired RTIs continues, since most of these infections are viral. Approximately 2% of patients with acute sinusitis have a bacterial infection.^4,6 The etiology of acute exacerbations of chronic bronchitis (AECB) is only about 50% bacterial; other causes for these exacerbations include viruses, allergens, and environmental pollutants.³ Among ambulatory patients with CAP, even when diagnostic testing is performed, the causative pathogen cannot be identified in 40% to 50% of patients.⁷ All of these findings support the view that many cases of acute sinusitis, AECB, or CAP are not caused by bacteria and patients with these types of infections will not benefit from antimicrobial therapy. A diagnostic challenge to primary care physicians is determining which patients have a bacterial infection.

Differential diagnosis of bacterial infection in patients with community-acquired respiratory tract infections

National and international guidelines have been developed to assist clinicians in the differential diagnosis of bacterial infections.^7-11

Acute sinusitis

Clinical diagnosis of acute sinusitis is based primarily on medical history, symptoms, and physical findings.¹⁴ A wide range of symptoms may occur in patients with acute sinusitis, as it does in patients with a common cold; TABLE 1shows the symptoms most likely to be associated with sinusitis.¹² No single clinical sign or symptom distinguishes between bacterial and viral causes of acute sinusitis; rather, it is the combination of these signs or symptoms that may lead to the diagnosis of bacterial sinusitis. A history of purulent secretions and symptoms that appear more severe than those typically associated with an upper RTI suggests ABS;¹³ however, purulent discharge alone is not always indicative of a bacterial infection. “Double-sickening,” in which the patient becomes ill and then gets worse, combined with elevation in Creactive protein may indicate a bacterial infection.¹⁴ Williams et al¹⁵ recommended that clinical diagnosis emphasize key features such as maxillary toothache, poor response to over-the counter decongestants or antihistamines, a history of colored nasal discharge, abnormal transillumination, and mucopurulent discharge on examination. A diagnosis of ABS may be made if symptoms persist for more than 10 days, worsen after 5 to 7 days, or are more severe than those normally associated with viral upper respiratory illness.^8,13

TABLE 1

Signs and symptoms associated with community-acquired respiratory tract infections^3,13,14,17

Acute exacerbations of chronic bronchitis

There is no definitive agreement regarding what constitutes an AECB. Symptoms originally described by Anthonisen et al¹⁶ are commonly used to define AECB: increased cough and sputum, increased sputum purulence, and increased dyspnea over baseline (TABLE 1).¹⁷ A thorough physical and detailed medical history usually are sufficient to diagnose AECB while ruling out conditions such as pneumonia, congestive heart failure, myocardial ischemia, upper RTI, pulmonary embolism, and recurrent aspiration. A chest x-ray or an electrocardiogram may help with differential diagnosis in some patients.^17,18 Nevertheless, determination of whether an acute exacerbation is bacterial or viral may be difficult because many patients with this disease have persistent airway colonization with the same bacteria thought to be responsible for AECB. To help physicians decide if antibiotics are necessary, practice guidelines have stratified patients by type of exacerbation (mild, moderate, or severe) and risk factors (TABLE 2).

TABLE 2

Treatment of acute exacerbations of chronic bronchitis⁸

Community-acquired pneumonia

Patients with CAP usually present with acute onset of lower respiratory symptoms (TABLE 1). Older and immunosuppressed patients may present with nonrespiratory symptoms, such as confusion, worsening of a chronic condition, or even falls. It is important to note that no combination of clinical signs and symptoms is a definitive diagnosis of CAP.¹⁹ All patients with suspected CAP should have a chest radiograph with posteroanterior and lateral views, as radiographs are essential for confirming a diagnosis.³ The Infectious Diseases Society of America (IDSA) and the American Thoracic Society support use of the Pneumonia PORT (Pneumonia Outcomes Research Team) Severity Index (PSI) as a means of risk stratification, combined with careful assessment of the patient and use of clinical judgment when determining whether a patient can be treated on an outpatient basis or should be hospitalized.¹⁰

Although it is important to attempt to identify the infecting organism, antimicrobial treatment for CAP is empiric because of the time it takes to get laboratory results and the potential for rapid deterioration of the patient’s condition. Further, patients with CAP may not produce sputum for Gram stain and culture; or, if they do, it may be mixed with upper respiratory tract secretions. Streptococcus pneumoniae may not grow from sputum culture; or, if found, it may be unclear whether the patient is colonized or infected.²⁰ Bacteria cultures may not be helpful either, as blood cultures usually are sterile in patients with CAP.²⁰

Selection of antimicrobial therapy

Once a bacterial infection is suspected, antibiotic treatment should be initiated promptly. Antibiotic therapy for ABS, ABECB, and CAP is simplified somewhat because the distributions of bacterial pathogens associated with each infection overlap substantially. The pathogens encountered most often in patients with ABS are Spneumoniae, Haemophilusinfluenzae, and Moraxella catarrhalis. To a lesser extent, anaerobic bacteria, other streptococcal species (including S pyogenes, S intermedius, and ahemolytic streptococci), and Staphylococcus aureusalso have been shown to cause ABS.²¹

Bacteria are isolated from the sputum of 40% to 60% of patients with AECB, and the predominant species are consistent with those listed for ABS. Atypical respiratory pathogens, most notably Chlamydophila(previously Chlamydia) pneumoniae, account for about 5% to 10% of organisms isolated from patients with ABECB.¹⁷ Patients with CAP also tend to be infected with the above-listed typical pathogens as well as the atypical Mycoplasma pneumoniae, C pneumoniae, and Legionella pneumophila. TABLE 3 lists pathogens associated with community-acquired bacterial RTIs and the effectiveness of commonly used antibiotics and telithromycin, a recently approved antimicrobial agent.

TABLE 3

Pathogens associated with ABS, CAP, and ABECB and in vitro effectiveness of commonly used antibiotics and telithromycin⁴⁰

Resistance of bacterial pathogens

Although the common causative pathogens for community-acquired bacterial RTIs are few, selection of antibiotic therapy is becoming more complicated by the increasing rate of bacterial resistance to many of the antibiotics commonly used to treat these RTIs.

Resistance has been documented for all organisms associated with community-acquired RTIs. Current estimates indicate that 25% to more than 50% of Spneumoniaestrains are not completely susceptible to penicillin and that nearly one third of strains may be resistant to macrolides.²² Penicillin-resistant Spneumoniaealso may have reduced susceptibility to other antibiotics, including tetracycline, erythromycin, azithromycin, cephalosporins, clindamycin, trimethoprim/sulfamethoxazole (TMP/ SMX), and chloramphenicol.²³Streptococcuspneumoniae have developed resistance to fluoroquinolones as well. This is of particular concern to the Centers for Disease Control and Prevention (CDC), having influenced its recommendations regarding empiric treatment of pneumonia.¹⁰ Macrolides have been mainstays in empiric therapy of CAP because of their activity against both typical and atypical respiratory pathogens; however, their effectiveness has been compromised by a rapid rise in resistance by S pneumoniae. Recent evaluation of Spneumoniae isolates collected between 2000 and 2001 showed that resistance rates to erythromycin, clarithromycin, and azithromycin had increased to 31.0%, 30.7%, and 31.0%, respectively.²⁴ Further, results from 1 recent surveillance study that examined macrolide resistance among patients with community-acquired RTIs being treated by primary care physicians indicated that 23% to 33% of Spneumoniaeisolates were resistant to macrolides.^24,25 Resistance also is becoming prevalent among other pathogens associated with community-acquired RTIs, including H influenzaeand Mcatarrhalis.^25-27 This may complicate management of patients with community-acquired RTIs; infection with a treatment-resistant pathogen can increase risk for morbidity and mortality if treatment fails to eradicate the bacteria.^20,28 However, the clinical impact of resistance remains controversial. Resistance may be overcome with the use of an antibiotic with pharmacokinetic properties or a dosing regimen that achieves very high drug concentrations at sites of infection. Host defense mechanisms also may contribute to eradication of organisms with in vitro resistance to an antibiotic.^29,30 Further, since many infections are caused by viruses with high-resolution rates and since some bacterial infections resolve due to host response, the in vivo efficacy of an antibiotic may be much higher than its in vitro sensitivity.

Antibiotics currently prescribed for patients with community-acquired bacterialRTIs

Empiric antibiotic therapy for patients with community-acquired bacterial RTIs should provide coverage against clinically important pathogens likely to be associated with these infections, including resistant strains (TABLE 3). The antibiotic selected should specifically target respiratory pathogens. For example, broad-spectrum antibiotics are not the optimum choice, as they affect both respiratory and nonrespiratory pathogens (eg, gram-negative enterics; Escherichia coliand Klebsiella pneumoniae), which may result in resistance among these organisms.^1,31

Antibiotics suitable for treatment of patients with ABS are summarized inTABLE 4. These agents vary widely in their spectra of activity as well as their ability to overcome pathogen resistance (TABLE 3). Amoxicillin, a very narrow-spectrum -lactam, generally is considered to be first-line therapy for children and adults who have ABS³² but may have little activity against resistant strains of S pneumoniae, H influenzae, and M catarrhalis.²

An analysis by the Agency for Healthcare Research and Quality concluded that amoxicillin or folate inhibitors (eg, TMP/SMX) are the most cost-effective choices for initial therapy in an otherwise healthy adult population with uncomplicated ABS.³³ For adults who fail to improve after 2 to 3 days, broad-spectrum and β-lactamase-resistant antibiotics for 7 to 14 days should be considered. A clinical practice guideline sponsored by the American Academy of Family Physicians, the American College of Physicians-Society of Internal Medicine, the CDC, and the IDSA recommends initiating treatment with narrow-spectrum agents, eg, amoxicillin, doxycycline, or TMP-SMX for patients with severe or persistent moderate symptoms of ABS.^34,35

High-dose amoxicillin/clavulanate 2000/125 mg, twice daily, was shown to be effective in treating patients with ABS, ABECB, and CAP caused by S pneumoniae, including penicillin-resistant S pneumoniae.²⁹

The macrolides erythromycin, clarithromycin, and azithromycin are effective against susceptible strains of all organisms commonly associated with ABS, but many strains of S pneumoniaealso are resistant to these drugs.^23,26 Respiratory fluoroquinolones are effective against all pathogens commonly associated with ABS, including resistant strains;²⁶ however, they also have significant activity against gram-negative enterobacteriaceae and thus may increase the potential for emergence of resistant strains of these organisms.³⁶ Ketolides are derived from the macrolide class and were designed to be effective against macrolide-resistant, gram-positive cocci.¹⁰ The first ketolide, telithromycin, is an alternative to macrolides for the treatment of patients with ABS, ABECB, and CAP. It is highly active against both common and atypical respiratory pathogens, including resistant strains, but has little activity against either enterobacteriaceae or anaerobes.³⁷

All of the same considerations mentioned for the treatment of ABS also apply to the selection of therapy for patients with ABECB or CAP (TABLE 4). Empiric antimicrobial therapy for these 2 conditions, particularly CAP, also must cover atypical respiratory pathogens.^17,38 For a number of years, monotherapy with a macrolide provided coverage against all of the pathogens likely to be associated with CAP and ABECB. In light of the emergence of resistance to these drugs by S pneumoniae, physicians should consider local and regional resistance rates before prescribing. In fact, File and colleagues³⁹ have suggested that current recommendations favoring the use of macrolides in patients with CAP may have to be reconsidered if clinical failure continues to be observed with these agents. Cunha³⁸ has taken an even stronger position, stating that macrolide monotherapy should be avoided in patients with CAP because of the high prevalence of S pneumoni-aeresistance to this class of antibiotics. These authors’ conclusions should be carefully weighed against the CDC’s and IDSA’s recommendations. The CDC previously recommended combination of macrolides and ceftriaxone for hospitalized patients to avoid emergence of fluoroquinolone resistance. The IDSA recommended empiric use of fluoroquinolones with conversion based on culture sensitivities when available.

TABLE 4

Antibiotics currently being used for the treatment of community-acquired bacterial respiratory tract infections^41-44

Conclusions

Appropriate prescribing of antibiotics can effectively slow the development of bacterial resistance. Before selecting an antibiotic for a patient with a community-acquired RTI, primary care clinicians should first evaluate whether such treatment is even necessary. Treatment of ABS, ABECB, or CAP is compromised by increasing pathogen resistance to the currently used antibiotics. Use of high-dose amoxicillin and the other “older” antibiotics may delay the emergence of resistance to “newer” drugs, making newer drugs useful for treatment of more difficult cases. New agents to the antibiotic armamentarium give primary care physicians additional therapeutic options for patients who present with bacterial RTIs.

Financial disclosure:

Stephen Brunton, MD, is a consultant for and a member of the speakers’ bureaus for Aventis Pharmaceuticals Inc and Ortho-McNeil Pharmaceutical Inc.

Acute bacterial sinusitis (ABS), acute bacterial exacerbations of chronic bronchitis (ABECB), and community-acquired pneumonia (CAP) are 3 respiratory tract infections (RTIs) in adults that pose a treatment challenge for clinicians in the primary care setting. Each of these conditions requires prompt initiation of therapy to achieve optimal patient outcomes, but diagnosis and selection of treatment typically are made without the benefit of diagnostic tests. Due to increasingly high levels of antibiotic resistance,^1,2 the decision to treat and the selection of therapy are critically important.^3-5

This article briefly reviews the etiology of community-acquired bacterial RTIs, important diagnostic considerations, and current treatment options for patients who have these infections.

Community-acquired respiratory tract infections: Viral vs bacterial

The debate regarding whether to prescribe antibiotics for patients with community-acquired RTIs continues, since most of these infections are viral. Approximately 2% of patients with acute sinusitis have a bacterial infection.^4,6 The etiology of acute exacerbations of chronic bronchitis (AECB) is only about 50% bacterial; other causes for these exacerbations include viruses, allergens, and environmental pollutants.³ Among ambulatory patients with CAP, even when diagnostic testing is performed, the causative pathogen cannot be identified in 40% to 50% of patients.⁷ All of these findings support the view that many cases of acute sinusitis, AECB, or CAP are not caused by bacteria and patients with these types of infections will not benefit from antimicrobial therapy. A diagnostic challenge to primary care physicians is determining which patients have a bacterial infection.

Differential diagnosis of bacterial infection in patients with community-acquired respiratory tract infections

National and international guidelines have been developed to assist clinicians in the differential diagnosis of bacterial infections.^7-11

Acute sinusitis

Clinical diagnosis of acute sinusitis is based primarily on medical history, symptoms, and physical findings.¹⁴ A wide range of symptoms may occur in patients with acute sinusitis, as it does in patients with a common cold; TABLE 1shows the symptoms most likely to be associated with sinusitis.¹² No single clinical sign or symptom distinguishes between bacterial and viral causes of acute sinusitis; rather, it is the combination of these signs or symptoms that may lead to the diagnosis of bacterial sinusitis. A history of purulent secretions and symptoms that appear more severe than those typically associated with an upper RTI suggests ABS;¹³ however, purulent discharge alone is not always indicative of a bacterial infection. “Double-sickening,” in which the patient becomes ill and then gets worse, combined with elevation in Creactive protein may indicate a bacterial infection.¹⁴ Williams et al¹⁵ recommended that clinical diagnosis emphasize key features such as maxillary toothache, poor response to over-the counter decongestants or antihistamines, a history of colored nasal discharge, abnormal transillumination, and mucopurulent discharge on examination. A diagnosis of ABS may be made if symptoms persist for more than 10 days, worsen after 5 to 7 days, or are more severe than those normally associated with viral upper respiratory illness.^8,13

TABLE 1

Signs and symptoms associated with community-acquired respiratory tract infections^3,13,14,17

Acute exacerbations of chronic bronchitis

There is no definitive agreement regarding what constitutes an AECB. Symptoms originally described by Anthonisen et al¹⁶ are commonly used to define AECB: increased cough and sputum, increased sputum purulence, and increased dyspnea over baseline (TABLE 1).¹⁷ A thorough physical and detailed medical history usually are sufficient to diagnose AECB while ruling out conditions such as pneumonia, congestive heart failure, myocardial ischemia, upper RTI, pulmonary embolism, and recurrent aspiration. A chest x-ray or an electrocardiogram may help with differential diagnosis in some patients.^17,18 Nevertheless, determination of whether an acute exacerbation is bacterial or viral may be difficult because many patients with this disease have persistent airway colonization with the same bacteria thought to be responsible for AECB. To help physicians decide if antibiotics are necessary, practice guidelines have stratified patients by type of exacerbation (mild, moderate, or severe) and risk factors (TABLE 2).

TABLE 2

Treatment of acute exacerbations of chronic bronchitis⁸

Community-acquired pneumonia

Patients with CAP usually present with acute onset of lower respiratory symptoms (TABLE 1). Older and immunosuppressed patients may present with nonrespiratory symptoms, such as confusion, worsening of a chronic condition, or even falls. It is important to note that no combination of clinical signs and symptoms is a definitive diagnosis of CAP.¹⁹ All patients with suspected CAP should have a chest radiograph with posteroanterior and lateral views, as radiographs are essential for confirming a diagnosis.³ The Infectious Diseases Society of America (IDSA) and the American Thoracic Society support use of the Pneumonia PORT (Pneumonia Outcomes Research Team) Severity Index (PSI) as a means of risk stratification, combined with careful assessment of the patient and use of clinical judgment when determining whether a patient can be treated on an outpatient basis or should be hospitalized.¹⁰

Although it is important to attempt to identify the infecting organism, antimicrobial treatment for CAP is empiric because of the time it takes to get laboratory results and the potential for rapid deterioration of the patient’s condition. Further, patients with CAP may not produce sputum for Gram stain and culture; or, if they do, it may be mixed with upper respiratory tract secretions. Streptococcus pneumoniae may not grow from sputum culture; or, if found, it may be unclear whether the patient is colonized or infected.²⁰ Bacteria cultures may not be helpful either, as blood cultures usually are sterile in patients with CAP.²⁰

Selection of antimicrobial therapy

Once a bacterial infection is suspected, antibiotic treatment should be initiated promptly. Antibiotic therapy for ABS, ABECB, and CAP is simplified somewhat because the distributions of bacterial pathogens associated with each infection overlap substantially. The pathogens encountered most often in patients with ABS are Spneumoniae, Haemophilusinfluenzae, and Moraxella catarrhalis. To a lesser extent, anaerobic bacteria, other streptococcal species (including S pyogenes, S intermedius, and ahemolytic streptococci), and Staphylococcus aureusalso have been shown to cause ABS.²¹

Bacteria are isolated from the sputum of 40% to 60% of patients with AECB, and the predominant species are consistent with those listed for ABS. Atypical respiratory pathogens, most notably Chlamydophila(previously Chlamydia) pneumoniae, account for about 5% to 10% of organisms isolated from patients with ABECB.¹⁷ Patients with CAP also tend to be infected with the above-listed typical pathogens as well as the atypical Mycoplasma pneumoniae, C pneumoniae, and Legionella pneumophila. TABLE 3 lists pathogens associated with community-acquired bacterial RTIs and the effectiveness of commonly used antibiotics and telithromycin, a recently approved antimicrobial agent.

TABLE 3

Pathogens associated with ABS, CAP, and ABECB and in vitro effectiveness of commonly used antibiotics and telithromycin⁴⁰

Resistance of bacterial pathogens

Although the common causative pathogens for community-acquired bacterial RTIs are few, selection of antibiotic therapy is becoming more complicated by the increasing rate of bacterial resistance to many of the antibiotics commonly used to treat these RTIs.

Resistance has been documented for all organisms associated with community-acquired RTIs. Current estimates indicate that 25% to more than 50% of Spneumoniaestrains are not completely susceptible to penicillin and that nearly one third of strains may be resistant to macrolides.²² Penicillin-resistant Spneumoniaealso may have reduced susceptibility to other antibiotics, including tetracycline, erythromycin, azithromycin, cephalosporins, clindamycin, trimethoprim/sulfamethoxazole (TMP/ SMX), and chloramphenicol.²³Streptococcuspneumoniae have developed resistance to fluoroquinolones as well. This is of particular concern to the Centers for Disease Control and Prevention (CDC), having influenced its recommendations regarding empiric treatment of pneumonia.¹⁰ Macrolides have been mainstays in empiric therapy of CAP because of their activity against both typical and atypical respiratory pathogens; however, their effectiveness has been compromised by a rapid rise in resistance by S pneumoniae. Recent evaluation of Spneumoniae isolates collected between 2000 and 2001 showed that resistance rates to erythromycin, clarithromycin, and azithromycin had increased to 31.0%, 30.7%, and 31.0%, respectively.²⁴ Further, results from 1 recent surveillance study that examined macrolide resistance among patients with community-acquired RTIs being treated by primary care physicians indicated that 23% to 33% of Spneumoniaeisolates were resistant to macrolides.^24,25 Resistance also is becoming prevalent among other pathogens associated with community-acquired RTIs, including H influenzaeand Mcatarrhalis.^25-27 This may complicate management of patients with community-acquired RTIs; infection with a treatment-resistant pathogen can increase risk for morbidity and mortality if treatment fails to eradicate the bacteria.^20,28 However, the clinical impact of resistance remains controversial. Resistance may be overcome with the use of an antibiotic with pharmacokinetic properties or a dosing regimen that achieves very high drug concentrations at sites of infection. Host defense mechanisms also may contribute to eradication of organisms with in vitro resistance to an antibiotic.^29,30 Further, since many infections are caused by viruses with high-resolution rates and since some bacterial infections resolve due to host response, the in vivo efficacy of an antibiotic may be much higher than its in vitro sensitivity.

Antibiotics currently prescribed for patients with community-acquired bacterialRTIs

Empiric antibiotic therapy for patients with community-acquired bacterial RTIs should provide coverage against clinically important pathogens likely to be associated with these infections, including resistant strains (TABLE 3). The antibiotic selected should specifically target respiratory pathogens. For example, broad-spectrum antibiotics are not the optimum choice, as they affect both respiratory and nonrespiratory pathogens (eg, gram-negative enterics; Escherichia coliand Klebsiella pneumoniae), which may result in resistance among these organisms.^1,31

Antibiotics suitable for treatment of patients with ABS are summarized inTABLE 4. These agents vary widely in their spectra of activity as well as their ability to overcome pathogen resistance (TABLE 3). Amoxicillin, a very narrow-spectrum -lactam, generally is considered to be first-line therapy for children and adults who have ABS³² but may have little activity against resistant strains of S pneumoniae, H influenzae, and M catarrhalis.²

An analysis by the Agency for Healthcare Research and Quality concluded that amoxicillin or folate inhibitors (eg, TMP/SMX) are the most cost-effective choices for initial therapy in an otherwise healthy adult population with uncomplicated ABS.³³ For adults who fail to improve after 2 to 3 days, broad-spectrum and β-lactamase-resistant antibiotics for 7 to 14 days should be considered. A clinical practice guideline sponsored by the American Academy of Family Physicians, the American College of Physicians-Society of Internal Medicine, the CDC, and the IDSA recommends initiating treatment with narrow-spectrum agents, eg, amoxicillin, doxycycline, or TMP-SMX for patients with severe or persistent moderate symptoms of ABS.^34,35

High-dose amoxicillin/clavulanate 2000/125 mg, twice daily, was shown to be effective in treating patients with ABS, ABECB, and CAP caused by S pneumoniae, including penicillin-resistant S pneumoniae.²⁹

The macrolides erythromycin, clarithromycin, and azithromycin are effective against susceptible strains of all organisms commonly associated with ABS, but many strains of S pneumoniaealso are resistant to these drugs.^23,26 Respiratory fluoroquinolones are effective against all pathogens commonly associated with ABS, including resistant strains;²⁶ however, they also have significant activity against gram-negative enterobacteriaceae and thus may increase the potential for emergence of resistant strains of these organisms.³⁶ Ketolides are derived from the macrolide class and were designed to be effective against macrolide-resistant, gram-positive cocci.¹⁰ The first ketolide, telithromycin, is an alternative to macrolides for the treatment of patients with ABS, ABECB, and CAP. It is highly active against both common and atypical respiratory pathogens, including resistant strains, but has little activity against either enterobacteriaceae or anaerobes.³⁷

All of the same considerations mentioned for the treatment of ABS also apply to the selection of therapy for patients with ABECB or CAP (TABLE 4). Empiric antimicrobial therapy for these 2 conditions, particularly CAP, also must cover atypical respiratory pathogens.^17,38 For a number of years, monotherapy with a macrolide provided coverage against all of the pathogens likely to be associated with CAP and ABECB. In light of the emergence of resistance to these drugs by S pneumoniae, physicians should consider local and regional resistance rates before prescribing. In fact, File and colleagues³⁹ have suggested that current recommendations favoring the use of macrolides in patients with CAP may have to be reconsidered if clinical failure continues to be observed with these agents. Cunha³⁸ has taken an even stronger position, stating that macrolide monotherapy should be avoided in patients with CAP because of the high prevalence of S pneumoni-aeresistance to this class of antibiotics. These authors’ conclusions should be carefully weighed against the CDC’s and IDSA’s recommendations. The CDC previously recommended combination of macrolides and ceftriaxone for hospitalized patients to avoid emergence of fluoroquinolone resistance. The IDSA recommended empiric use of fluoroquinolones with conversion based on culture sensitivities when available.

TABLE 4

Antibiotics currently being used for the treatment of community-acquired bacterial respiratory tract infections^41-44

Conclusions

Appropriate prescribing of antibiotics can effectively slow the development of bacterial resistance. Before selecting an antibiotic for a patient with a community-acquired RTI, primary care clinicians should first evaluate whether such treatment is even necessary. Treatment of ABS, ABECB, or CAP is compromised by increasing pathogen resistance to the currently used antibiotics. Use of high-dose amoxicillin and the other “older” antibiotics may delay the emergence of resistance to “newer” drugs, making newer drugs useful for treatment of more difficult cases. New agents to the antibiotic armamentarium give primary care physicians additional therapeutic options for patients who present with bacterial RTIs.

Financial disclosure:

Stephen Brunton, MD, is a consultant for and a member of the speakers’ bureaus for Aventis Pharmaceuticals Inc and Ortho-McNeil Pharmaceutical Inc.