key: cord-0999381-ijxb6l7f
authors: File, Thomas M
title: Community-acquired pneumonia
date: 2003-12-13
journal: Lancet
DOI: 10.1016/s0140-6736(03)15021-0
sha: ce7967841d0be3469689d24ffe370fbb2a3c6966
doc_id: 999381
cord_uid: ijxb6l7f

This seminar reviews important features and management issues of community-acquired pneumonia (CAP) that are especially relevant to immunocompetent adults in light of new information about cause, clinical course, diagnostic testing, treatment, and prevention. Streptococcus pneumoniae remains the most important pathogen; however, emerging resistance of this organism to antimicrobial agents has affected empirical treatment of CAP. Atypical pathogens have been quite commonly identified in several prospective studies. The clinical significance of these pathogens (with the exception of Legionella spp) is not clear, partly because of the lack of rapid, standardised tests. Diagnostic evaluation of CAP is important for appropriate assessment of severity of illness and for establishment of the causative agent in the disease. Until better rapid diagnostic methods are developed, most patients will be treated empirically. Antimicrobials continue to be the mainstay of treatment, and decisions about specific agents are guided by several considerations that include spectrum of activity, and pharmacokinetic and pharmacodynamic principles. Several factors have been shown to be associated with a beneficial clinical outcome in patients with CAP. These factors include administration of antimicrobials in a timely manner, choice of antibiotic therapy, and the use of a critical pneumonia pathway. The appropriate use of vaccines against pneumococcal disease and influenza should be encouraged. Several guidelines for management of CAP have recently been published, the recommendations of which are reviewed.

bacilli (Enterobacteriaceae and pseudomonadas) are the cause of CAP in some patients (those who have had previous antimicrobial treatment or who have pulmonary comorbidities). 23 The frequency of other causes, such as Mycobacterium tuberculosis, C psittaci (psittacosis), C burnetii (Q fever), Francisella tularensis (tularaemia), and endemic fungi (histoplasmosis, coccidioidomycosis, blastomycosis) vary between epidemiological settings. Table 1 18,24-30 shows the causes of CAP in adults in hospital as reported by workers from several prospective studies in several worldwide locations who used comprehensive diagnostic approaches. The incidence of specific pathogens varied in accordance with the completeness of testing and specificity of diagnostic criteria (ie, definite vs presumptive diagnosis [table 1]). Collectively, S pneumoniae was the most frequently isolated organism, with the highest incidence of this pathogen reported in studies that included detection by a urinary antigen test. 28, 29 Relative to other pathogens, M pneumoniae, C pneumoniae, and L pneumophila were also common. These organisms (along with other Chlamydia spp and C burnetii) are often referred to as "atypicals", a label of contended scientific merit. Nevertheless, the term remains popular with clinicians and is in widespread use in recent scientific reports. 31 These atypical pathogens are not often identified in clinical practice, however, because (with the exception of L pneumophila) there is not a specific, rapid, or standardised test for their detection; as such, the frequency of these pathogens is probably underreported. 31 Community-acquired pneumonia Thomas 

This seminar relies on articles retrieved from a search of MEDLINE to identify pertinent articles about CAP published since 1997, and consensus statements of guidelines for the management of CAP in adults. [2] [3] [4] [5] [6] [7] [8] [9] [10] [11] [12] [13] [14] [15] A preference was given to published articles that were evidenced-based, extensively reviewed with a grading of studies in the literature, and supported by expert opinion.

This seminar reviews important features and management issues of community-acquired pneumonia (CAP) that are especially relevant to immunocompetent adults in light of new information about cause, clinical course, diagnostic testing, treatment, and prevention. Streptococcus pneumoniae remains the most important pathogen; however, emerging resistance of this organism to antimicrobial agents has affected empirical treatment of CAP. Atypical pathogens have been quite commonly identified in several prospective studies. The clinical significance of these pathogens (with the exception of Legionella spp) is not clear, partly because of the lack of rapid, standardised tests. Diagnostic evaluation of CAP is important for appropriate assessment of severity of illness and for establishment of the causative agent in the disease. Until better rapid diagnostic methods are developed, most patients will be treated empirically. Antimicrobials continue to be the mainstay of treatment, and decisions about specific agents are guided by several considerations that include spectrum of activity, and pharmacokinetic and pharmacodynamic principles. Several factors have been shown to be associated with a beneficial clinical outcome in patients with CAP. These factors include administration of antimicrobials in a timely manner, choice of antibiotic therapy, and the use of a critical pneumonia pathway. The appropriate use of vaccines against pneumococcal disease and influenza should be encouraged. Several guidelines for management of CAP have recently been published, the recommendations of which are reviewed.

The proportion of cases in recent studies with a defined cause ranged from 52 to 83%. By contrast, in an observational study that assessed the 'real-world' practice from several centres in the USA, only 6% of outpatients and a quarter of inpatients with CAP had the cause of their disease defined. 32 In a study of consecutive patients with CAP, Ruiz-Gonzales and colleagues 26 used microbiological analysis and PCR to test for respiratory pathogens in lung aspirate specimens obtained by transthoracic needle aspiration. Their results showed that use of these tests increased the proportion of cases of CAP for which a cause could be established to 83%, from 50% reported when conventional tests-ie, sputum and blood cultures and serological tests-were used. Their results also changed the ranking of pathogens established by conventional testing from M pneumoniae (35%), C pneumoniae (17%), S pneumoniae (17%) to S pneumoniae (30%), M pneumoniae (22%), C pneumoniae (13%). 26 Importantly, S pneumoniae represented one third of all causes not documented by conventional testing.

Legionella spp are still a common cause of severe CAP. A review of nine studies of CAP that resulted in admission to an intensive care unit (seven from Europe and one each from USA and South Africa) noted that Legionella spp were the second most commonly identified pathogens, with S pneumoniae being most often detected. 33 Aerobic gramnegative bacilli, H influenzae, and S aureus were also identified, although few of these cases could be judged as definite (ie, confirmed bacteraemia or isolation from pleural fluid or lung tissue). In an international collaborative survey of 508 patients with culture-positive legionellosis, 92% of the isolates with serogroup 1 were L pneumophila, accounting for 84% of the total. L pneumophila serogroup 1 accounted for 88% of isolates in America and Europe but for only 46% in Australia and New Zealand where L longbeachae accounted for 30% of cases. 34 The most common pathogens identified from recent studies of mild (ie, in ambulatory patients) CAP were S pneumoniae, M pneumoniae, Chlamydia spp, and viruses (mostly influenza virus). 35, 36 Mycoplasma spp were most common in patients younger than 50 years and without important comorbid conditions or abnormality of vital signs, whereas S pneumoniae was the most common pathogen for older patients or those with significant underlying disease. 36 An awareness of the likely cause of CAP in different settings is important to allow the start of appropriate antimicrobial treatment. Table 2 shows the most common pathogens associated with CAP as derived from collective results of various studies. 18,19,24-30, 33, 35, 36 Severity of illness is judged by site of care (outpatient vs inpatient).

Although objective confirmation is often difficult, multiple organisms that infect a patient concurrently or sequentially can cause CAP. 37, 38 For example, influenza A or C pneumoniae infection might be followed by a secondary infection with S pneumoniae. In one study of patients admitted with serologically diagnosed C pneumoniae pneumonia, 45% of patients were infected with other pathogens, the most common copathogen being S pneumoniae. 38 The incidence of mixed infection varied from 2 to 11% ( Diagnostic methods  BC, SC, LC,  BC, SC, VC, Ser BC, SC, MpC, BC, SC, LC,  BC, SC, Ser, BC, SC, LUA, BC,SC,LC,  BC,SC, NAC,  Ser, LUA,  ClC, LC, LUA, VC, LUA, PCR, NPVA, †Listed as "aspiration". Data are total proportion of cases, ie, both definitive and presumptive diagnoses; number in parentheses is proportion of definitive diagnoses. Definitive diagnosis assigned by one of the following criteria: CAP pathogen cultured from a normally sterile site; a noncommensal organism (eg, Mycobacterium tuberculosis, Legionella spp) was identified from any site; a positive urinary antigen, a positive PCR test, or when paired serological testing revealed a significant increase in antibody titre. A presumptive diagnosis was assigned when growth of a pathogen in sputum culture was accompanied by a gram stain showing a compatible organism or when one high serum antibody titre was noted for a pathogen. Although Ruiz-Gonzales 26 did not specifically define the status of diagnostic criteria as definite or presumptive, the methods used can be accepted as representing definite diagnosis criteria. 

In a study of ambulatory patients with CAP, median time to resolution of fever was 3 days; 5 days for myalgia, 6 days for dyspnoea, and 14 days for both cough and fatigue. 39 Symptoms can last even longer in seriously ill patients. Fine and colleagues 32 have noted that 86% of patients had at least one persisting pneumonia-related symptom at 30 days. Patients should be informed that symptoms can last for this long to allow them a better awareness of their illness and expected clinical course.

Death rates associated with CAP have not changed greatly over the past two decades-in part because of the increased number of patients at risk of the disease, such as elderly people and patients with multiple comorbid conditions. In a prospective study 40 of prognostic factors of CAP caused by bacteraemic pneumococcal disease in five countries, death rates ranged from 6% in Canada to 20% in the USA and Spain (13% in the UK and 8% in Sweden). Independent predictors of death were age greater than 65 years, residence in a nursing home, presence of chronic lung disease, high acute physiology and chronic health evaluation (APACHE) score, and need for mechanical ventilation. Disease severity and frequency of underlying conditions were factors that affected outcome. Mortensen and colleagues 41 noted that about half of deaths in patients with CAP were attributable to the worsening of pre-existing conditions.

Diagnostic evaluation of patients with symptoms suggestive of pneumonia is important for several reasons: the accurate diagnosis of CAP, appropriate assessment of severity of illness, and appropriate use of microbiological analyses to establish the cause of the illness.

Adult patients who are immunocompetent should be assessed for pneumonia if they present with symptoms that include cough, sputum production, laboured breathing (including altered breath sounds and rales), or fever. These symptoms are non-specific and might also be present in patients with upper respiratory-tract infections, other lower respiratory-tract infections such as acute bronchitis and chronic bronchitis, and non-infectious diseases-eg, reactive airways disease, atelectasis, congestive heart failure, vasculitis, pulmonary embolism, and malignant disease.

Although guidelines vary with respect to the emphasis placed on obtaining a chest radiograph for ambulatory patients, this study is usually necessary to establish the diagnosis of CAP and to differentiate it from other respiratory illnesses. 42, 43 A CAP diagnosis is important to ensure appropriate use of antimicrobial agents, especially since most cases of upper respiratory-tract infection and acute bronchitis are of viral origin and do not merit treatment with antibacterial agents. Spiral CT scans are much more sensitive in detecting pulmonary infiltrates in patients admitted with CAP, but the clinical significance of this finding is unclear. 44 Illness severity and site of care A key decision for a clinician is whether to admit a patient with CAP to hospital. 45 The general consensus is that most patients can be safely treated as outpatients. 6 However, selected patients should be admitted if they have special requirements such as the need for close observation, respiratory support, intravenous antibiotics, or other concerns. This decision about whether or not a patient should be admitted might have an effect on the extent of diagnostic testing as well as the choice of empirical antimicrobial treament. The advantages of not admitting patients for CAP are great and include decreased cost, patient preference, and avoidance of iatrogenic complications in hospital. 46, 47 For elderly patients in particular, a reduction in immobilisation time (ie, time in a hospital bed) can facilitate better convalescence.

The decision to admit a patient with CAP depends on many variables, including the severity of illness, associated disease, adequacy of home support, and probability of adherence to treatment. Recognised risk factors for increased mortality of patients with CAP include extremes of age, comorbid illnesses such as malignant disease, congestive heart failure, coronary artery disease, alcoholism, abnormality of vital signs, and several laboratory and radiographic findings. 16 The admission decision relies on a clinician's judgment; however, prognostic scoring rules have been developed that provide support for this decision. 15, 48, 54 A pneumonia severity of index score, the "pneumonia prediction rule", has been developed from studies of the pneumonia Patient Outcomes Research Team (PORT). 48 The prediction rule stratifies patients to one of five categories with a point system based on several variables after an initial evaluation of three factors: age, presence of comorbid conditions, and vital signs and mental status. This process has been validated as a method for identifying patients at risk of death, which is low for risk classes I-III (0·1-2·8%), intermediate for class IV (8·2-9·3%), and high for class V (27-31%). It is also an effective method for triaging patients and, in particular, for identifying low-risk patients who can be safely treated as outpatients. [49] [50] [51] [52] Subsequent recommendations by the pneumonia PORT are that, before calculation of the severity of index score, patients should first be assessed for any pre-existing condition that might compromise the safety of home care, including haemodynamic instability, active co-existing conditions that would necessitate admission, acute hypoxaemia, social or psychiatric problems compromising home care, or the inability to take oral medication. 53 By contrast, the British Thoracic Society guidelines recommend an assessment of severity based on the presence of "adverse prognostic features". 15 Such adverse features include, age greater than 50 years, coexisting disease, and four additional specific core features, remembered by the acronym CURB: mental Confusion, elevated Urea nitrogen, Respiratory rate greater or equal to 30 breaths per min, and low Blood pressure. Additional adverse prognostic features include hypoxaemia and bilateral or multilobar pulmonary infiltrates on chest radiographs. Patients who have none of the features listed are at low risk of death and do not usually require inpatient care, whereas those who display two or more core adverse prognostic features should be admitted. A scoring method based on this British Thoracic Society assessment has been developed; this system was assessed with use of a compilation of data from three prospective studies of CAP done in the UK, New Zealand, and the Netherlands. 54 A six point score (one point for any of confusion, urea >7 mmol/L, respiratory rate >30, low blood pressure, and age >65 years) enabled patients to be stratified in accordance with risk of death (score 0=0·7% increase in risk of death; 1=2·1%; 2=9·2%; 3=14·5%; у4=40%). This simple scoring system can be used to stratify patients with CAP into different groups for management purposes.

Prediction rules might oversimplify the interpretation of important variables, and, therefore, these scoring systems SEMINAR THE LANCET • Vol 362 • December 13, 2003 • www.thelancet.com and guidelines are meant to contribute to, rather than supersede, clinicians' judgment. Additional limitations of the severity of illness scoring systems include a potential overemphasis on age and the perception by some healthcare workers that the systems are not practical for everyday routine patient management.

There are no universally accepted criteria for severe CAP requiring admission to an intensive care unit. One set of variables that has been proposed as a reliable predictor defines severe CAP as the presence of two out of three possible minor criteria (systolic BP <90 mm Hg, multilobar disease, PaO 2 /FiO 2 <250), or one of two major criteria (need for mechanical ventilation or septic shock). 9, 55 However, an assessment by the pneumonia PORT study group noted that these criteria had only a modest predictive value. 56 Identification of the causative agent The use of diagnostic studies to establish the causative agents of CAP is controversial because there is not a rapid, easily done, accurate, cost-effective method to allow immediate results for most patients at the point of service (ie, the initial assessment by a clinician in an office or acute-care setting). [6] [7] [8] [9] 15, [57] [58] [59] [60] Nevertheless, there is a good rationale for establishing the causative agent in the disease to allow the selection of antibiotics that permit optimum selection of agents against a specific pathogen and limit the misuse of antibiotics and its consequences, and to identify pathogens associated with notifiable diseases such as Legionnaires' disease or tuberculosis. 6 Despite these good reasons, there is an absence of solid, documented benefit with respect to establishing the causative agent.

Routine microbiological tests are not recommended by most guidelines for patients managed in the community. However, if a patient has purulent sputum, it is reasonable to send a sample to the laboratory for gram stain and culture on the basis that the information could be of use in directing specific treatment if the patient fails to respond to initial empirical treatment. 6 Investigations that are recommended for patients who require admission include: blood cultures, sputum gram stain and culture, and thoracentesis if pleural fluid is present. About 11% of patients with CAP will have positive blood cultures, more commonly associated with severe illness. 6 Although the usefulness of blood cultures for all patients admitted to hospital is questioned, [61] [62] [63] investigators in one study 64 noted that if results of blood cultures were obtained within 24 h of admission, survival rates were improved. The yield of clinically useful information is greater if the culture specimen is collected before antibiotics are administered. 62 The value of routinely doing a sputum gram stain and culture has long been debated. [6] [7] [8] [9] 15, 57, 58, 65 These tests are limited by the fact that many patients cannot produce a good specimen, patients often receive antimicrobial agents before assessment, and many specimens yield inconclusive results. The validity of the gram stain is related directly to the experience of the interpreter. Indeed, some discrepant findings about the sputum gram stain are presumably explained by the quality of specimens and technical expertise; and when stringent criteria are applied, although the sensitivity drops, the specificity for pneumococcal pneumonia can approach 90%. 65 Sputum culture for other pathogens (ie, Legionella spp, fungi, viruses, Mycobacterium spp) should be considered to identify unusual pathogens or notifiable diseases. However, because the early administration of treatment is important for the outcome of CAP, an attempt to obtain expectorated sputum should never delay the prompt start of antimicrobial treatment.

Other tests that might be useful in patients admitted to hospital include the urinary antigen assays for Legionella spp and S pneumoniae and a direct stain (ie, acid-fast) for detection of mycobacterial infections in patients who are in high-risk categories for tuberculosis. The urine antigen assays for L pneumophila serogroup 1 (LgUA) and for pneumococcus (SpUA) can be done easily and rapidly. The LgUA has a sensitivity of 70% and a specificity greater than 90% for infections caused by serogroup 1 and should be especially useful in the USA and Europe since about 85% of isolates are serogroup 1. 66, 67 Since Legionella spp are a common cause of severe CAP, this test should be routinely considered for patients requiring admission to an intensive care unit. An assay approved by the Food and Drug Administration (FDA) for pneumococcal urinary antigen has been assessed in several studies. [68] [69] [70] [71] The sensitivity in defining invasive pneumococcal disease in adults is 60-90% with a specificity close to 100%. In one of the largest published studies to date, Gutierrez and colleagues 71 used this assay on concentrated urine samples obtained from 452 adults with CAP. Pneumococcal antigen was detected in 19 (70%) of 27 patients with proven pneumococcal pneumonia. Of the 269 patients who had pneumonia with no pathogen identified, antigen was detected in 69 (26%), which suggests that an important proportion of cases that are presently undiagnosed by standard tests can be identified with this assay. However, 16 (10%) of 156 samples from patients with pneumonia caused by other agents were positive, indicating potential problems with specificity.

Many rapid diagnostic tests such as nucleic acid amplification tests (ie, PCR) assays are still in early stages of development, or are not commonly available, or are not sufficiently accurate. [72] [73] [74] The role of these new tools is under investigation and they are not yet in routine use; however, they could offer the potential for rapid diagnosis and have been shown to be useful in clinical situations. 72, 74 Serological tests are not usually helpful in the early management of CAP since acute and convalescent concentrations are needed before ascribing the cause of the disease to a specific pathogen.

Percutaneous transthoracic needle aspiration (PTNA) has been advocated as a valuable, safe method to increase the chance of establishing the causative agent in the disease. [75] [76] Nevertheless, PTNA or other invasive testing (including bronchoscopy and biopsy) are not routinely recommended for the assessment of patients with CAP. 6 Clinical settings that might warrant the use of such tests include pneumonia in immunocompromised hosts, suspected tuberculosis in the absence of productive cough, selected cases of chronic pneumonia, pneumonia associated with suspected neoplasm or foreign body, suspected Pneumocystis carinii pneumonia, some cases in which intubation is required, and suspected conditions which necessitate lung biopsy.

Antimicrobials are the mainstay of treatment for most patients with CAP. 6 Decisions about antimicrobial treatment are guided by factors such as spectrum of activity, pharmacokinetics, efficacy, safety profile, cost, and whether or not a specific pathogen is identified (ie, empirical vs pathogen-directed treatment). The emergence of resistant respiratory pathogens, especially drug-resistant strains of S pneumoniae, is becoming an important concern that has complicated initial empirical management of CAP.

Surveillance studies indicate that the prevalence of drug resistant S pneumoniae continues to increase worldwide. [77] [78] [79] [80] [81] In two recent multinational studies, the worldwide prevalence of penicillin-resistant and macrolide-resistant S pneumoniae ranged from 18·2 to 22·1% and from 24·6% to 31·8%, respectively. 80, 81 The dominant factor in the emergence of drug resistant S pneumoniae in one US study has been human-to-human spread of only a few clonal groups that harbour resistance determinants to multiple classes of antibiotics (including cephalosporins, macrolides, doxycycline, trimethoprim/sulfamethoxazole). 82 Despite the rapid increase in the prevalence of drug resistant S pneumoniae, its clinical relevance in the outcome of CAP remains controversial and depends on the class of antimicrobial agent being considered. Most studies suggest that current levels of ␤ lactam resistance do not usually result in treatment failures for patients with CAP. [83] [84] [85] [86] [87] [88] While the present breakpoints for S pneumoniae susceptibility to penicillin (р0·06 g/mL, susceptible; 0·1-1·0 g/mL, intermediate susceptibility; у2·0 g/mL, resistant) are relevant for meninigitis, they do not reliably predict clinical outcome for CAP. 5, 89 On the basis of established pharmacokinetic and pharmacodynamic principles, adequate drug concentrations in serum and tissue should be achieved with appropriate doses of parenteral ␤ lactams or oral amoxicillin to treat effectively many pneumococcal strains that are thought to be nonsusceptible to penicillin by the present criteria. 5, 89 Furthermore, an analysis of nine controlled trials of a high-dose oral formulation of amoxicillin-clavulanate noted a good clinical response for respiratory infections (mostly outpatients) caused by S pneumoniae with penicillin minimal inhibitory concentrations (MIC) up to 8 g/mL. 90 Although most studies have not shown an adverse effect of ␤ lactam resistance on the outcome of pneumococcal pneumonia, most clinicians remain concerned that clinical failures will become more frequent if the proportion of resistance strains and their MICs increase. Moreover, in controlled studies of pneumococcal bacteraemia, Feikin and colleagues 91 noted an increased risk of death in patients with high-level resistance (penicillin MIC у4 g/mL) and Metlay and colleagues 92 showed an increase risk of suppurative complications for non-susceptible infections. Risk factors for penicillinresistant S pneumoniae have been identified (ie, age <2 years or >65 years, ␤ lactam treatment within 3 months, alcoholism, medical comorbidities, immunosuppressive illness or treatment, and exposure to a child in a day-care centre. 93 The clinical relevance of macrolide resistant S pneumoniae might be dependent on the type of resistance expressed by a particular strain. The most common mechanisms of resistance include methylation of a ribosomal target encoded by erm gene and efflux of the macrolides by cell membrane protein transporter, encoded by mef gene. 94 S pneumoniae strains with mef are resistant at a lower level (with MICs usually 1-16 g/mL) than erm-resistant strains; and it is possible that such strains (especially with MIC<8 g/mL) might be inhibited if sufficiently high concentrations of macrolide can be obtained within infected tissue (such as could arise with newer macrolides-clarithromycin or azithromycin). [96] [97] [98] [99] However, there is recent evidence that the MICs of these strains are increasing and this could affect the effectiveness of these macrolides. 100 The "mef-resistant" strains are usually susceptible to clindamycin. Most ermresistant isolates have an MIC greater than 32 g/mL for erythromycin and are thought to be highly resistant to all macrolides and clindamycin. Until recently, reports of failure of CAP treated with macrolides have been rare, particularly for patients at low risk of drug-resistant strains. However, since 2000, anecdotal reports and one controlled study have documented failures attributable to macrolide-resistant S pneumoniae in patients treated with an oral macrolide who have subsequently required admission with S pneumoniae bacteraemia. Currently, mef-associated resistance predominates in North America. erm-associated resistance predominates in Europe and is common in Japan. 105 Although the worldwide prevalence of pneumococcal resistance to the newer fluoroquinolones (levofloxacin, gatifloxacin, moxifloxacin) remains low (fewer than 2% of cases), in some countries resistance has increased substantially. The overall prevalence of fluoroquinolone resistance (levofloxacin >4 g/mL) in Hong Kong in 2000 had increased to 13·3% because of the dissemination of a fluoroquinolone-resistant clone. 107 Treatment failures have already been reported, most often in patients who have previously been treated with fluoroquinolones. 109, 110 Risk factors for levofloxacin resistance were identified as previous exposure to a fluoroquinolone, residence in a nursing home, nosocomial infection, and chronic obstructive pulmonary disease. 111 In view of the emerging resistance of the pneumococcus to existing drugs, alternative agents need to be considered. Although glycopeptides (ie, vancomycin, teicoplanin) are almost certain to provide antibiotic coverage for drug resistant S pneumoniae, they are not active against other key respiratory pathogens (ie, atypicals, H influenzae) and there is a strong reason not to use these drugs until needed because of fear of emergence of other resistant organisms such as vancomycin-resistant enterococci, vancomycin resistant S aureus. Other agents effective against drug-resistant S pneumoniae include quinupristin/dalfopristin, linezolid, and the ketolides. The focus of treatment of quinupristin/dalfopristin and linezolid is more for nosocomial infections (and especially for vancomycin-resistant enterococci or macrolideresistant S pneumoniae). The ketolides (telithromycin is the first to be marketed) are a novel addition to the macrolide group of antibacterials and have an efficacy against key respiratory pathogens (including penicillin-resistant and erythromycin-resistant strains). 112 Empirical antimicrobial treatment Until rapid diagnostic methods improve, most patients will be treated empirically. Although some authorities propose a syndromic approach to treatment (ie, counting on the predictability of a causative agent based on the presenting clinical manifestations), most data indicate that the presenting clinical features are not specific enough to predict reliably the causative agent of CAP. [6] [7] [8] [9] 15 Thus, unless there is a specific epidemiological factor (such as an influenza epidemic), the empirical approach to initial therapy is usually based on the likelihood that one of the key pathogens is responsible for disease. Specific recommendations for empirical therapy for CAP as included in recently published guidelines from North America, UK, and Japan are shown in table 3 .

Several observational studies have assessed the effect of empirical antimicrobial regimens on patients' outcomes. Although limited by their retrospective design, these studies show that use of macrolides as part of an initial combination treatment (usually with a cephalosporin agent) or monotherapy with a fluoroquinolone for SEMINAR THE LANCET • Vol 362 • December 13, 2003 • www.thelancet.com patients who require admission seems to be associated with decreased risk of death or a shorter hospital stay than with a cephalosporin alone. The specific causative agent of infection was not estalished in these studies; however, it is possible that the added coverage for atypical pathogens might, in part, explain this observation. Results of additional retrospective studies suggest that the benefit of combination therapy that includes a macrolide applies not only to CAP in general but also to CAP specifically associated with S pneumoniae bacteraemia. 117, 118 The possible coexistence of atypical pathogens or the immunomodulating effect of the macrolides might, in part, be responsible for this finding. However, interpretation of these studies is subject to limitations inherent in their retrospective study design; and, since they only assessed empirical treatment, the findings are not necessarily applicable for pathogendirected treatment that usually is started 24-48 h after initial therapy. 119 Recommendations for empirical therapy of outpatients North American guidelines variably recommend macrolides, doxycycline, an antipneumococcal fluoroquinolone (eg, levofloxacin, gatifloxacin, moxifloxacin), or the combination of a ␤ lactam plus macrolide as treatment options for patients who are mildly ill and can be treated as outpatients. [5] [6] [7] [8] [9] In general, the North American guidelines recommend a macrolide as first-line treatment for outpatients with no comorbidity or risk factors for drugresistant S pneumoniae. The rationale is that the macrolides provide effective therapy for the most common bacterial pathogens for such patients, primarily S pneumoniae (that has, until now, been mostly responsive to macrolide in North America) as well as the atypical organisms (especially M pneumoniae and C pneumoniae, which are common in outpatients). The positioning of the macrolides as prominent first-line agents in the North American guidelines is partly based on the presumption that the newer macrolides (azithromycin or clarithromycin) can be effective against macrolide-resistant S pneumoniae strains in which lower-level resistance results from increased drug efflux with resulting MIC often less than 8 g/mL. However, because recent data indicate that mef-mediated resistance is becoming associated with higher MICs (from a median of 4 µg/mL to 8 µg/mL), it is reasonable to consider alternative treatment (ie, "respiratory fluoroquinolone", or high dose amoxicillin plus macrolide) if risk factors for drug-resistant S pneumoniae are present. The Centers for Disease Control and Prevention (CDC) statement emphasises that the fluoroquinolones should be reserved for cases associated with failure, or allergy to other agents, or documented drug-resistant S pneumoniae. 5 The rationale is that widespread use would lead to the development of fluoroquinolone resistance in the respiratory pathogens (as well as other pathogens colonising the treated patients).

By contrast, the primary agents recommended in the recently published British Thoracic Society guidelines are ␤ lactams-mostly penicillins-and not macrolides. 15 The rationale is that these agents are effective against S pneumoniae, and when given in high doses they are even effective for most strains with decreased sensitivity to penicillin. Since most of the macrolide resistance in Europe is erm-mediated, high-level resistance, the macrolides are not regarded as optimum first line empirical agents to treat this pathogen if S pneumoniae is [5] [6] [7] [8] [9] or or use fluoroquinolone § plus High-dose amoxicillin (3 g/day) or Antipneumococcal fluoroquinolone § alone clindamycin) amoxicillin/clavulanate plus macrolide

In the case of (if amoxicillin is used and there is a structural lung disease: concern for H influenzae, use agent antipseudomonal agent (piperacillin/ active for ␤ lactamase producing tazobactam, carbapenem, or strains ‡ cefepime) plus antipseudomonal fluoroquinolone (high dose ciprofloxacin or levofloxacin)

Japanese Respiratory (Specified as mild or moderate (Specified as severe pneumonia) Not specified Society (2000) 12 pneumonia) Consider as for other inpatients, for elderly, or underlying illness When bacterial pneumonia suspected:

For younger patients without underlying a penicillin type (with a ␤ lactamase illness: injection use fluoroquinolone inhibitor (orally), or penicillin type For elderly or underlying illness: pneumococcal activity plus (alternative--antipneum fluoroquinolone) benzylpenicillin as alternative) If parenteral appropriate: (ampicillin or benzylpenicillin) plus (erythromycin or clarithromycin) (alternative--IV levofloxacin) ICU= intensive care unit. DRSP=drug resistant S pneumoniae. *␤ lactam treatment within the past 3 months, admission within the past month, alcoholism, immunesuppressive illness (including treatment with corticosteroids), medical comorbidities, exposure to a child in a day-care centre. †Canadian Infectious Disease Society and Canadian Thoracic Society. ‡If chronic obstructive pulmonary disease, use a macrolide active against ␤ lactamase producing H influenzae (ie, azithromycin, clarithromycin). §Gatifloxacin, levofloxacin, moxifloxacin. Table 3 : Comparison of recommendations of guidelines for empirical antimicrobial therapy of community-acquired pneumonia in adults likely. Additionally, the British statement places less importance on the need to treat the atypical pathogens empirically in ambulatory patients (mild disease). Rather, the statement suggests that since M pneumoniae exhibits epidemic periodicity every 4-5 years and chiefly affects younger people, a policy for initial empirical treatment that aims always to cover this pathogen was unnecessary.

The two approaches represented by the North American and the British Thoracic Society statements differ because of the greater emphasis in North America to treat routinely the atypical pathogens and the fact that macrolide-resistant S pneumoniae in Europe is of higher level resistance than in North America. Future studies are needed to address the issue of whether routine treatment should be able to treat atypical pathogens. The Japanese statement advocates initial therapy based on a syndromic approach (ie, macrolides or tetracycline for likely atypical pneumonia and a penicillin-type agent for bacterial pneumonia). 12 Recommendations for empirical therapy of inpatients North American guidelines recommend treatment with a ␤ lactam plus a macrolide or monotherapy with a fluoroquinolone for patients admitted to the general ward (in part, because of results showing that these regimens are associated with a substantial reduction in deaths compared with that noted with cephalosporin alone). [5] [6] [7] [8] [9] Recommendations in the British Thoracic Society guidelines are similar to those from North America. Workers from two recent studies in Europe noted that most patients who were admitted with CAP were successfully treated with penicillin alone. The Japanese statement stratifies patients on the basis of age and the presence of underlying illness, with an injected fluoroquinolone being recommended for the first category and a combination regimen for the second category.

For patients with severe CAP who require admission to an intensive care unit, all guidelines recommend comprehensive antimicrobial therapy to cover S pneumoniae (including drug-resistant S pneumoniae), Legionella spp and the possibility of Pseudomonas spp. Australian guidelines advocate empirical therapy for Burkholderia pseudomallei for patients in tropical areas, acknowledging the relevant local pathogens. 11 Pathogen-directed therapy Treatment options are obviously simplified if the causative agent is established or strongly suspected (table 4). Diagnostic procedures that provide identification of a specific cause within 24-72 h can still be useful for guiding continued treatment. If, for example, an appropriate culture shows the isolation of penicillinsusceptible S pneumoniae, treatment can be specified by selecting a narrow spectrum agent (such as penicillin or amoxicillin), which will hopefully reduce the selective pressure for resistance. This information is often available at the time for consideration when the patient is switched from parenteral to oral therapy.

There are no controlled trials that have specifically assessed the optimum duration of anitmicrobial treatment in CAP. The decision is usually based on the causative pathogen, response to treatment, comorbid illness, and complications. Until further data are available, it seems reasonable to treat bacterial infections such as those caused by S pneumoniae until a patient is afebrile for 72 h. 6 Most randomised clinical trials for the new fluoroquinolones or newer macrolides have shown good outcomes with 7-10 days of treatment, and shorter courses could even be possible with the use of these agents (azithromycin could be used for shorter courses of treatment in ambulatory patients because of its longer half-life in tissue).

For many pathogens, there is no clear advantage of intravenous therapy over oral therapy; however, for most patients admitted to hospital the common practice is to begin therapy with intravenous drugs. Changing from intravenous to oral therapy when the patient is clinically stable or improving and is able to ingest drug is associated with several economic, care, and social benefits. 122, 123 This approach has been shown to be appropriate, even for patients with pneumococcal bacteraemia. 124 Most patients can be safely discharged without inhospital observation after switch to oral treatment. 125, 126 Ideally, parenteral drugs should be given in an oral formulation with adequate bioavailability; if no oral formulation is available, then an oral agent with a similar spectrum of activity should be selected on the basis of in vitro or predicted susceptibility patterns of the established or probable pathogen.

Many studies have assessed processes of care-ie, interventions undertaken to assess, diagnose, or treatwith the clinical outcome of patients (table 5) . In a metaanalysis from a structured review of 4531 published reports, Rhew 127 identified several quality indicators that were judged to be valid on the basis of published evidence or professional consensus and that were associated with a beneficial effect on outcome in elderly patients with CAP. These indicators were: use of pneumococcal and influenza vaccines (for prevention of CAP); administration of antimicrobials in a timely matter (within 8 h of arrival at the hospital); advice to cease smoking for patients who smoke; drainage of a pleural empyema; conversion from parenteral to oral antimicrobial treatment when the patient is improving, haemodynamically stable, and able to take oral medications; and use of appropriate discharge criteria (ensuring that patients are clinically stable at the time of release from hospital). 127 Whereas the studies reviewed by Rhew supported 8 h as the target time for appropriate initiation of antimicrobial agents, more recent data have shown that starting therapy within 4 h was associated with better outcomes for patients who needed to be admitted. 128 Although one study of CAP patients who were admitted to academic medical centers did not show a benefit of many of these indicators, implementation of a pneumonia practice guideline that promote some or all of these quality indicators has been shown in many other studies to be associated with better outcomes (including a reduced risk of death). Prevention of CAP Despite controversies over efficacy of the polysaccharide pneumococcal vaccine (PPV), both this vaccine and the influenza vaccines are recommended in current guidelines by the CDC. 137, 138 In a meta-analysis of 14 trials that included more than 48 000 patients, polysaccharide pneumococcal vaccine prevented definite pneumonia by 71% and mortality by 32% (but not all-cause death). 139 However, this vaccine has not been consistently effective in controlled trials in elderly patients. An important advance has been the development and licensure of the pneumococcal conjugate vaccine in infants which not only reduces serious pneumococcal infections in children but also the colonisation of vaccine strains. 140, 141 Although the benefits of this vaccine have yet to be directly proven in clinical trials in adults, its use in children has been shown to reduce the rate of pneumococcal disease in adults. 140 This reduction is probably due to decreased transmission of pneumococci from children; and thus could provide an effective method for reducing disease caused by drugresistant strains.

Future challenges CAP will continue to represent an important threat to patients in the future as the number of patients at risk (elderly people and those with comorbid conditions) increase. Accucrate and rapid diagnostic methods to define causative pathogens are needed to allow more specific, directed therapy. If the specific causative pathogen is known, it seems reasonable to presume that patients will respond better and that antibiotics could be used more appropriately; but studies to assess this approach are needed. Although not discussed in this review, a greater understanding of the pathogenesis and host response should lead to new approaches to treatment. As the complexities of the host response are revealed, therapeutic benefits are likely to be realised. The optimum approach to management will need to be constantly reassessed as new information is generated. Hospital admission Admission of low-risk patients decision [47] [48] [49] [50] 132 associated with unnecessary cost and diminished patient satisfaction Timing of initial Earlier administration associated antibiotics 64, 128 with improved survival Choice of antibiotic If according to guidelines, associated therapy [132] [133] [134] [135] with better outcome Switch to oral therapy 124, 125, 132 Associated with decrease length of time in hospital and cost. Appropriate even for Strep pneumoniae bacteraemia Discharge criteria 127, 131, 132 Associated with decrease cost and readmission rates

Use of critical pathway [130] [131] [132] [133] [134] 136 Decrease number of patients admitted to hospital, duration of admission, and mortality Modified from Metersky. 122 Table 5 : Selected CAP processes of care-outcome link

Community-acquired pneumonia

Working Groups of the South African Pulmonology Society and the Antibiotic Study Group of South Africa. Management of communityacquired pneumonia in adults

Diagnostico y tratamiento de la neumonia adquirida en la comunidad

Philippine Practice Guidelines Group in Infectious Diseases. Community-acquired pneumonia: clinical practice guideline. PPGG-ID Philippine Society for Microbiology and Infectious Diseases

Management of community-acquired pneumonia in the era of pneumococcal resistance: a report from the drug-resistant Streptococcus pneumoniae Therapeutic Working Group

Guidelines from the Infectious Diseases Society of America. Practice guidelines for the management of community-acquired pneumonia in adults

Update of practice guidelines for the management of community-acquired pneumonia in immunocompetent adults

Canadian guidelines for the initial management of community-acquired pneumonia: an evidence-based update by the canadian infectious diseases society and the canadian thoracic society

Guidelines for the management of adults with community-acquired pneumonia

and Paul Ehrlich Society for Chemotherapy and the German Respiratory Association. Rational treatment of bacterial respiratory tract infections

Therapeutic Guidelines: antibiotic (version 11)

and the Japanese Respiratory Society Community-Acquired Pneumonia Treatment Guideline Creation Committee. Diagnostic and treatment guideline for community-acquired pneumonia. Tokyo: Japanese Respiratory Society, General Managing Director Ando Massayuki

Grupo de Trabajo de la Asociacion Latinoamericana del Torax (ALAT)

What should the initial antibiotherapy for acute community-acquired pneumonia be? How should it be reassessed in case of failure, given the evolution of responsible pathogens and the resistance of pneumococci? Should combined treatment be used?

Guidelines for the management of community-acquired pneumonia in adults

Prognosis and outcomes of patients with community-acquired pneumonia

Cigarette smoking and invasive pneumococcal disease

and the CBPIS Study Group. Incidence of community-acquired pneumonia requiring hospitalization: results of a population-based active surveillance study in Ohio

Microbial aetiology of community-acquired pneumonia in the adult population of four municipalities in eastern Finland

Respiratory syncytial virus is an important cause of community-acquired lower respiratory infection among hospitalized adults

Parainfluenza virus infection among adults hospitalized for lower respiratory tract infection

Coronavirus as a possible cause of severe acute respiratory syndrome

Community-acquired pneumonia due to gram-negative bacteria and Pseudomonas aeruginosa

The aetiology of community-acquired pneumonia at an urban public hospital: influence of immunodeficiency virus infection and initial severity of illness

Aetiology of community-acquired pneumonia requiring hospitalization in Japan

Is Streptococcus pneumoniae the leading cause of pneumonia of unknown aetiology? A microbiologic study of lung aspirates in consecutive patients with community-acquired pneumonia

Community-acquired pneumonia: aetiology, epidemiology, and outcome at a teaching hospital in Argentina

Aetiology, outcome, and risk factors for mortality among adults with acute pneumonia in Kenya

Study of community acquired pneumonia aetiology in adults admitted to hospital: implications for management guidelines

Community-acquired pneumonia in southeast Asia

The role of atypical pathogens: Mycoplasma pneumoniae, Chlamydia pneumoniae, and Legionella pneumophila in respiratory infection

Processes and outcomes of care for patients with community-acquired pneumonia: results from the Pneumonia Patient Outcomes Research Team (PORT) cohort study

Legionella as a cause of severe pneumonia

Distribution of Legionella species and serogroups isolated by culture in patients with sporadic community-acquired legionellosis: an international collaborative survey

Community-acquired pneumonia. A prospective outpatient study

Non-severe communityacquired pneumonia: correlation between cause and severity or comorbidity

Legionnaire's disease with bacteremic coinfection

Clinical characteristics of Chlamydia pneumoniae infection as the sole cause of community-acquired pneumonia

Time course of symptom resolution in patients with community-acquired pneumonia

Prospective study of prognostic factors in community-acquired bacteremic pneumococcal disease in 5 countries

Does this patient have communityacquired pneumonia?

High-resolution computed tomography for the diagnosis of community-acquired pneumonia

How should we make the admission decision in community-acquired pneumonia?

The cost of treating community-acquired pneumonia

Preference for home vs hospital care among low-risk patients with community-acquired pneumonia

A prediction rule to identify low-risk patients with community-acquired pneumonia

Assessing prognosis and selecting an initial site of care for adults with community-acquired pneumonia

Safely increasing the proportion of patients with community-acquired pneumonia treated as outpatients: an interventional trial

Applying a prediction rule to identify low-risk patients with community-acquired pneumonia

Communityacquired pneumonia-implementation of a prediction rule to guide selection of patients for outpatient treatment

Testing strategies in the initial management of patients with community-acquired pneumonia

Defining communityacquired pneumonia severity on presentation to hospital: an international derivation and validation study

Severe community-acquired pneumonia: assessment of severity criteria

Use of intensive care services and evaluation of American and British Thoracic Society diagnostic criteria

Nonvalue of the initial microbiological studies in the management of nonsevere community-acquired pneumonia

Appropriate Microbiological Testing in Community-Acquired Pneumonia

Applying sputum as a diagnostic tool in pneumonia: limited yield, minimal impact on treatment decisions

Intensified microbiological investigations in adult patients admitted to hospital with lower respiratory tract infections

The impact of blood cultures on antibiotic therapy in pneumococcal pneumonia

Utility of blood cultures in community-acquired pneumonia requiring hospitalization: influence of antibiotic treatment before admission

Ackroyd-Stolarz S. The contribution of blood cultures to the clinical management of adult patients admitted to the hospital with community-acquired pneumonia

Quality of care, process, and outcomes in elderly patients with pneumonia

Prospective study of the usefulness of sputum gram stain in the initial approach to communityacquired pneumonia requiring hospitalization

Legionella and community-acquired pneumonia: a review of current diagnostic tests from a clinician's viewpoint

Detection of Streptococcus pneumoniae Antigen by a rapid immunochromatographic assay in urine samples

Evaluation of a rapid immunochromatographic assay for detection of Streptococcus pneumoniae antigen in urine samples

Evaluation of a rapid immunochromatographic test for detection of Streptococcus pneumoniae antigen in urine samples from adults with community-acquired pneumonia

Evaluation of the immunochromatographic Binax NOW assay for detection of Streptococcus pneumoniae urinary antigen in a prospective study of community-acquired pneumonia in Spain

Diagnosis of Legionella pneumophila, Mycoplasma pneumoniae or Chlamydia pneumoniae lower respiratory infection using the polymerase chain reaction on a single throat swab specimen

Multiplex polymerase chain reaction for the simultaneous detection of Mycoplasma pneumoniae, Chlamydia pneumoniae, and Chlamydia psittaci in respiratory samples

Value of the polymerase chain reaction assay in noninvasive respiratory samples for diagnosis of community-acquired pneumonia

The value and complications of percutaneous transthoracic lung aspiration for the etiologic diagnosis of communityacquired pneumonia

Efficacy of transthoracic needle aspiration in communityacquired pneumonia

Antimicrobial resistance among clinical isolates of Streptococcus pneumoniae in the United States during 1999-2000, including a comparison or resistance rates since 1994-1995

Increasing Prevalence of Multidrug-Resistant Streptococcus pneumoniae in the United States

Worldwide prevalence of antimicrobial resistance in Streptococcus pneumoniae, Haemophilus influenzae and Moraxella catarrhalis in the SENTRY Antimicrobial Surveillance Program, 1997-1999

Evolving Resistance Patterns in Community-acquired Respiratory Tract Pathogens: First Results from the PROTEKT Global Surveillance Study

Gruneberg RN and the Alexander project Group. The Alexander Project 1998-2000: susceptibility of pathogens isolated from community-acquired lower respiratory tract infection to commonly used antimicrobial agents

The molecular epidemiology of penicillin-resistant Streptococcus pneumoniae in the United States

Treatment of drug-resistant pneumococcal pneumonia

A comparative clinical study of pneumonia by penicillin-resistant and sensitive Streptococcus pneumoniae in a community hospital

Clinical outcomes of bacteremic pneumococcal pneumonia in the era of antibiotic resistance

Streptococcus pneumoniae respiratory tract infections

Update on community-acquired pneumonia: impact of antibiotic resistance on clinical outcomes

Appropriate use of antimicrobials for drug-resistant pneumonia: focus on the significance of B-lactam-resistant Streptococcus pneumoniae

A fresh look at the definition of susceptibility of Streptococcus pneumoniae to ␤ lactam antibiotics

557 and 592 Clinical Study Groups. Outcome of treatment of respiratory tract infections due to Streptococcus pneumoniae, including drug-resistant strains, with pharmacokinetically enhanced amoxicillin/clavulanate

Mortality from invasive pneumococcal pneumonia in the era of antibiotic resistance, 1995-1997

Impact of penicillin susceptibility on medical outcomes for adult patients with bacteremic pneumococcal pneumonia

Drug-resistant Streptococcus pneumoniae

Resistance to macrolides and related 95 antibiotics in Streptococcus pneumoniae

Pneumococcal macrolide resistance-myth or reality?

The in vivo-in vitro paradox in pneumococcal respiratory tract infections

Clinical relevance of macrolide-resistant Streptococcus pneumoniae for community-acquired pneumonia

The significance of serum vs tissue levels of antibiotics in the treatment of penicillin-resistant Streptococcus pneumoniae and community-acquired pneumonia. Are we looking in the wrong place?

Intrapulmonary steady-state concentrations of clarithromycin and azithromycin in healthy adult volunteers

Macrolide resistance among invasive Streptococcus pneumoniae isolates

Bacteremic pneumonia due to multidrug-resistant pneumococci in 3 patients treated unsuccessfully with azithromycin and successfully with levofloxacin

Breakthrough pneumococcal bacteremia in patients being treated with azithromycin and clarithromycin

Emergence of macrolide resistance during treatment of pneumococcal pneumonia

Failure of macrolide antibiotic treatment in patients with bacteremia due to erythromycin-resistant Streptococcus pneumoniae

Distribution of mefE and ermB genes in macrolide-resistant strains of Streptococcus pneumoniae and their variable susceptibility to various antibiotics

Decreased susceptibility of Streptococcus pneumoniae to fluoroquinolones in Canada

Increasing resistance of Streptococcus pneumoniae to fluoroquinolones: results of a Hong Kong multicentre study in 2000

Fluoroquinolone resistance among clinical isolates of Streptococcus pneumoniae belonging to international multiresistant clones

Levofloxacin treatment failures of pneumococcal pneumonia in association with resistance

Levofloxacin treatment failure in a patient with fluoroquinolone resistant Streptococcus pneumoniae pneumonia

Risk factors for acquisition of levofloxacin-resistant Streptococcus pneumoniae: a case-control study

Overcoming antimicrobial resistance: profile of a new ketolide antibacterial, telithromycin

Effect of macrolides as part of initial empiric therapy on length of stay in patients hospitalized with community-acquired pneumonia

Association between initial antimicrobial therapy and medical outcomes for hospitalized elderly patients with pneumonia

Antimicrobial selection for hospitalized patients with presumed community-acquired pneumonia: a survey of nonteaching US community hospitals

Empiric antibiotic therapy and mortality among medicare pneumonia inpatients in 10 western states

Monotherapy may be suboptimal for severe bacteremic pneumococcal pneumonia

Addition of a macrolide to a ␤-lactam-based empirical antibiotic regimen is associated with lower in-hospital mortality for patients with bacteremic pneumococcal pneumonia

What is optimal antimicrobial therapy for bacteremic pneumococcal pneumonia?

Management of patients with community-acquired pneumonia treated in hospital in Sweden

Penicillin as empirical therapy for patients hospitalized with community acquired pneumonia at a Danish hospital

Community-acquired pneumonia: process of care studies

Early switch and early discharge strategies in patients with community-acquired pneumonia: a metaanalysis

Early switch from intravenous to oral antibiotics in hospitalized patients with bacteremic communityacquired Streptococcus pneumoniae pneumonia

The clinical benefit of inhospital observation in 'low-risk' pneumonia patients after conversion from parenteral to oral antimicrobial therapy

Instability on hospital discharge and the risk of adverse outcomes in patients with pneumonia

Quality indicators for the management of pneumonia in vulnerable elders

Initial processes of care and outcomes in elderly patients with pneumonia

Processes of care, illness severity, and outcomes in the management of communityacquired pneumonia at academic hospitals

Effects of a pneumonia clinical pathway on time to antibiotic treatment, length of stay, and mortality

A controlled trial of a critical pathway for treatment of community-acquired pneumonia

Decreased mortality after implementation of a treatment guideline for community-acquired pneumonia

Rapid antibiotic delivery and appropriate antibiotic selection reduce length of hospital stay of patients with community-acquired pneumonia

The efficacy of an antibiotic protocol for community-acquired pneumonia

Influence of deviation from guidelines on the outcome of community-acquired pneumonia

Do guidelines for community-acquired pneumonia improve the cost-effectiveness of hospital care?

Centers for Disease Control and Prevention. General recommendations on immunization. Recommendations of the Advisory Committee on Immunization Practices (ACIP) and the American Academy of Family Practice Physicians

Guidelines for quality standards for immunization

Efficacy of pneumococcal polysaccharide vaccine in immunocompetent adults: a meta-analysis of randomized trials

Efficacy of pneumococcal conjugate vaccines and their effect on carriage and antimicrobial resistance

Decline in invasive pneumococcal disease after the introduction of protein-polysaccharide conjugate vaccine

I thank James Tan for his critical review of the manuscript.