Published online Jun 26, 2018.
https://doi.org/10.3947/ic.2018.50.2.160
Guideline for Antibiotic Use in Adults with Community-acquired Pneumonia
Abstract
Community-acquired pneumonia is common and important infectious disease in adults. This work represents an update to 2009 treatment guideline for community-acquired pneumonia in Korea. The present clinical practice guideline provides revised recommendations on the appropriate diagnosis, treatment, and prevention of community-acquired pneumonia in adults aged 19 years or older, taking into account the current situation regarding community-acquired pneumonia in Korea. This guideline may help reduce the difference in the level of treatment between medical institutions and medical staff, and enable efficient treatment. It may also reduce antibiotic resistance by preventing antibiotic misuse against acute lower respiratory tract infection in Korea.
Introduction
1. Background of guidelines
Clinical practice guidelines based on evidence-based medicine promote evidence-based, objective, and efficient medical practices. Numerous evidence-based clinical practice guidelines have also been developed, including the treatment guideline for community-acquired pneumonia developed in 2009. Additional data about the distribution of the causative bacteria of community-acquired pneumonia and antibiotic resistance have been obtained since then, and various guidelines about the diagnosis, treatment, and prevention of pneumonia have also been developed abroad. It has therefore become necessary to revise the current guideline on community-acquired pneumonia in Korea.
Antibiotic resistance has recently been raised as a serious public health issue worldwide. This is because whereas resistant bacteria that cannot be removed with existing antibiotics are increasing in number, less and less novel antibiotics are being developed. The issue of antibiotic resistance is much more serious in Korea than in other countries, with major causative bacteria having the highest antibiotic resistance in the former worldwide. Antibiotic resistance is proportional to the level of antibiotic misuse. The level of antibiotic use in Korea is higher than the average level of antibiotic use worldwide. The rate of prescribing antibiotics for infections that do not require antibiotic treatment is also higher in Korea than in other countries.
The present clinical practice guideline provides revised recommendations on the appropriate diagnosis, treatment, and prevention of community-acquired pneumonia. This guideline may help reduce the difference in the level of treatment between medical institutions and medical staff, and enable efficient treatment. It may also reduce antibiotic resistance by preventing antibiotic misuse against acute lower respiratory tract infection in Korea.
2. Development process of diagnosis and treatment guidelines
1) Guideline development committee
An antibiotic treatment guideline development committee for lower respiratory tract infection in adults was formed in November 2016. The committee included as many associated medical institutions as possible.
Committee members recommended by the Korean Society for Chemotherapy, the Korean Society of Infectious Diseases, the Korea Academy of Tuberculosis and Respiratory Diseases, the Korean Association of Family Medicine, the Korean Medical Practitioners Association, and the National Evidence-based Healthcare Collaborating Agency participated in the development of this guideline.
2) Guideline target and scope
This guideline sets forth fundamental principles of antibiotic use against community-acquired pneumonia in adults aged 19 years or older, taking into account the current situation regarding community-acquired pneumonia in Korea as of March 2017.
3) Method of literature search
Studies published in English in the last 10 years were searched. OVID-MEDLINE and OVID-EMBASE were used to search for foreign studies, and KMBase and KoreaMed were used to search domestic studies. Clinical practice guidelines were searched on NGC, G-I-N, and KoMGI. The search date is February 10th, 2017.
4) Recommendation and evidence levels
The level of recommendation was divided into “Strong, Weak”, and the level of evidence was divided into “High, Moderate, Low, Very low”. The level of recommendation and the level of evidence were determined using an unofficially agreed method. A consensus was deemed reached if over 70% of the participating committee members agreed.
(1) Level of recommendation
① Strong: Benefits evidently outweigh costs or loss, or costs and loss evidently outweigh benefits.
② Weak: Level of evidence is low, or there is no clear difference between benefits and loss.
(2) Level of evidence
① High: The possibility that the level of certainty about the estimated value of an effect will change in future studies is very low.
② Moderate: Future studies will have an important influence on the level of certainty about the estimated value of an effect, and the value may change.
③ Low: Future studies are highly likely to affect the level of certainty about the estimated value of an effect, and the value is highly likely to change.
④ Very low: An effect cannot be estimated with certainty.
5) Guideline developmental process
This clinical practice guideline was developed using the adaptation method. First, 22 key questions (KQ) to be included in the guideline were selected. The key questions followed the population intervention, comparison, and outcome (PICO) principle. During the literature search process, experts used systematic search equations to search a total of 1,699 studies based on their contents. Experts reviewed the titles and abstracts of studies whose original copies were available, and selected 17 studies. Of these, a total of four clinical practice guidelines that addressed the key questions to be included in this guideline extensively were selected.
The qualities of these four domestic and foreign clinical practice guidelines were assessed using an assessment scale developed by the Clinical Practice Guideline Expert Committee of the Korean Academy of Medical Sciences, namely, the K-AGREE 2.0 (Korean version of AGREE 2.0). Twelve committee members who were educated on the assessment method through a workshop run by experts assessed the selected studies. Two guidelines which the British Thoracic Society (BTS) guidelines for the management of community acquired pneumonia in adults (updated in 2009) and the guidelinea for the management of adult lower respiratory tract infections (updated in 2011) by the Joint Taskforce of the European Respiratory Society and European Society for Clinical Microbiology and Infectious Diseases were selected for review. Ultimately a total of four clinical practice guidelines including a domestic guideline published in 2009 and a consensus guideline on the management of community-acquired pneumonia in adults published by the Infectious Diseases Society of America/American Thoracic Society (IDSA/ATS) in 2007, which were the adaptation targets for domestic guidelines, were selected as adaptation targets.
The guideline developed by the Guideline Development Committee through internal meetings was presented in the spring academic conferences held by the Korean Society for Chemotherapy and the Korean Society of Infectious Diseases in 2017. The guideline was revised and improved based on what was discussed at the conferences. Further revisions were made based on expert opinions gathered during a public hearing participated in by experts from each related association to complete the guideline development.
6) Limitations and future to do’s
This guideline has been developed using the adaptation method due to time limitations. Although some of the foreign clinical practice guidelines from which this guideline was adapted were scheduled for revisions in the near future, they were not presented during the developmental period, and could not be used in the development of this guideline. This guideline will undergo minor revisions as soon as the revised versions of these guidelines are published. This guideline will also be revised every 4-5 years to reflect recent study results both outside and inside Korea.
7) Support
This guideline has been developed with funds from the Government’s Policy Research Projects of the Disease Control Centre in 2016. The committee members who participated in the guideline development were not influenced by any government branches, academic societies, pharmaceutical companies, or interest groups.
Summary of guidelines on antibiotic use for community-acquired pneumonia
Guideline for Antibiotic Use in Adults with Community-acquired Pneumonia
Current status regarding causative bacteria of pneumonia
1. Causative bacteria of community-acquired pneumonia
Most antibiotic treatments for pneumonia depend on the empirical method. Since the distribution of causative bacteria and antibiotic resistance vary between countries, it is necessary to develop an appropriate antibiotic treatment guideline based on domestic epidemiological data [1, 2]. This guideline summarizes domestic research findings on the causative bacteria of community-acquired pneumonia affecting Korean adults, and the current level of antibiotic resistance in Korea.
Community-acquired pneumonia is caused by various bacteria. Similar distributions of these bacteria are seen between Korea and other countries. Bacteria such as Streptococcus pneumoniae, and Haemophilus influenzae, and Mycoplasma pneumoniae, Chlamydophila pneumoniae, and Legionella pneumophila, which are classified as causative bacteria of atypical pneumonia, and respiratory bacteria can cause pneumonia. However, it is difficult to differentiate between these causative bacteria in the early period after hospital admission. Study findings about the major causative bacteria of community-acquired pneumonia in Korea are summarized in Table 1. The most important causative bacteria of bacterial pneumonia are S. pneumoniae. They account for 27-69% of all causative bacteria of bacterial pneumonia [3, 4, 5, 6, 7, 8, 9, 10]. Haemophilus or Moraxella, which are respiratory pathogens, commonly cause pneumonia in patients with a lung disease. The prevalence of these bacteria varies greatly in domestic data possibly because the separation and identification of these bacteria are difficult. Staphylococcus aureus are also relatively common causative bacteria. They commonly occur after an influenza epidemic. Enteric Gram negative bacilli or Pseudomonas aeruginosa pneumonia commonly occur in patients who have underlying lung diseases, who have alcohol addiction, or who have frequently undergone antibiotic treatment. Domestic data show the ratio of Gram-negative bacteria including Klebsiella pneumoniae and P. aeruginosa to be relatively high. This may be because most domestic studies have been conducted in tertiary university hospitals, and therefore, a large number of patients who are frequently admitted to a hospital for chronic respiratory diseases were included. Studies have reported mixed infections caused by two or more microorganisms to be relatively common. These infections include mixed infections caused by atypical causative bacteria of pneumonia. Distributions of causative bacteria may change depending on underlying diseases and risk factors.
Table 1
The distribution of the major causative bacteria of community-acquired pneumonia in Korean adults
M. pneumoniae, C. pneumoniae, and L. pneumophila are the major causative bacteria of atypical pneumonia. Of the recently published studies on community-acquired pneumonia in Korea, very few have investigated the incidence of atypical pneumonia and its causative bacteria. A large number of published studies have been conducted at a single institution, or use a retrospective design. Therefore, the prevalence of atypical pneumonia in Korea and clinical significance can only be assessed with limited accuracy. In a domestic study on pneumonia, Mycoplasma, C. pneumoniae, and Legionella accounted for 6.3-9.2%, 7.1-13.2%, and 0.5-3% of all cases of pneumonia [11, 12, 13]. Legionella were especially more common for cases of moderate to severe pneumonia requiring ICU admission compared with other atypical pneumococcal bacteria.
Respiratory virus induces pneumonia in children, as well as community-acquired pneumonia in adults. Rapid antigen tests for influenzas and respiratory syncytial virus (RSV) have recently been introduced and used in clinical settings. Multiplex reverse transcriptase polymerase chain reaction (RT-PCR) has also been used against various respiratory viruses. In a recent study involving 456 adults with community-acquired pneumonia, multiplex RT-PCR was performed for 327 patients. Respiratory viruses were detected in 60 patients (18.3%) [5]. Influenza virus was the most common (n = 23, 38%), followed by RSV (n = 9, 15%), rhinovirus (n = 7, 12%), coronavirus (n = 6, 10%), adenovirus (n = 6, 10%), metapneumovirus (n = 5, 8%), parainfluenza virus (n = 3, 5%) [6]. When a respiratory virus test was performed on patients with community-acquired pneumonia hospitalized in ICU, more than one type of respiratory virus was detected in 72 of 198 patients (36.4%) for whom RT-PCR was performed [14]. Rhinovirus was the most common (n = 17, 23.6%), followed by parainfluenza (n = 15, 20.8%), metapneumovirus (n = 13, 18.1%), influenza virus (n = 12, 16.7%), RSV (n = 10, 13.9%), coronavirus (n = 4. 5.6%), and adenovirus (n = 1, 1.4%) [14]. Other causative bacteria of atypical pneumonia in Korea include Mycobacterium tuberculosis, non-tuberculous mycobacteria, Orientia tsutsugamushi, Leptospira, Coxiella burnetii. Since the prevalence of tuberculosis is still quite high, the possibility of tuberculosis being one of the causes of pneumonia must always be considered. When a patient shows delayed response to antibiotic treatment, or has underlying diseases such as diabetes, chronic obstructive respiratory disease, chronic kidney diseases, and long-term steroid use, tuberculosis must be considered as a possible cause of pneumonia. In addition, pneumonia caused by M. tuberculosis can occur as typical bacterial pneumonia or atypical pneumonia. Since tsutsugamushi disease and leptospirosis, which are febrile illnesses that usually occur in the fall, are sometimes accompanied by atypical pneumonia, when a patient has a febrile illness accompanied by pneumonia in the fall, pneumonia must be differentiated with the possibility of febrile illnesses in mind. Furthermore, as there have been reports of pneumonia caused by C. burnetii in Korea, it is necessary to differentiate C. burnetii, which may possibly be the causative bacteria of pneumonia in persons who come in close direct or indirect contact with livestock. Table 2 lists common causative bacteria of community-acquired pneumonia by epidemiological characteristics and risk factors [15]. Table 3 summarizes common clinical characteristics associated with certain causative bacteria [16].
Table 2
Common causative bacteria of community-acquired pneumonia by epidemiological characteristics and risk factors
Table 3
Common clinical characteristics associated with specific causative bacteria
2. Antibiotic resistance of the major causative bacteria of community-acquired pneumonia in Korea
S. pneumoniae isolated in Korea have been reported to be highly resistant against penicillin. In an investigation on antibacterial resistance measured according to the antimicrobial susceptibility testing standards, S. pneumoniae were moderately or highly resistant to penicillin [17]. However, as experts claimed that there is no association between clinical outcomes of pneumonia caused by penicillin-resistant S. pneumoniae and antibiotic resistance against penicillin, the antimicrobial susceptibility testing standards by the Clinical and Laboratory Standards Institute (CLSI) of the United States were revised in January 2008. According to the previous standards, S. pneumoniae are deemed to be susceptible to penicillin if MIC ≤0.06 μg/mL, moderately resistant if MIC=0.1-1.0 μg/mL, and highly resistant if MIC ≥2.0 μg/mL. The revised standards deem the bacteria to be susceptible if MIC ≤2.0 μg/mL, moderately resistant if MIC=4.0 μg/mL, and highly resistant if MIC ≥8.0 μg/mL. When the revised standards are used, the antibacterial resistance against pencilling drops to below 10%. Table 4 summarizes the current antibiotic resistance of S. pneumoniae strains isolated in Korea. While then antibiotic resistance against penicillin and ceftriaxone is reported to be low at 10% or below, that against erythromycin and azithromycin are still high at 73-81% [18, 19, 20, 21, 22]. Antibiotic resistance against fluoroquinolones is still quite low, but gradually increasing. Antibiotic resistance against levofloxacin and moxifloxacin is reported at 0.8-8.2%, and 0.9-1.0%, respectively [18, 20].
Resistance against ampicillin due β-lactamase production is common in H. influenzae. In a domestic study that analysed 544 bacterial strains, the antibiotic resistance against ampicillin, cefuroxime, clarithromycin, cefaclor, and amoxicillin/clavulanate was 58.5%, 23.3%, 18.7%, 17.0%, and 10.4%, respectively [23]. This study did not identify bacterial strains that are resistant to levofloxacin and cefotaxime. In another study that analysed 229 bacterial strains, the antibiotic resistance against ampicillin high at 58.1%, and that against cefaclor, clarithromycin, amoxicillin/clavulanate, cefixime, and levofloxacin was 41.4%, 25.8%, 13.5%, 10.9%, and 1.3%, respectively [24].
Not many studies have analysed the antibiotic susceptibility of M. pneumoniae in Korea. In a study that examined M. pneumoniae isolated from respiratory organ samples of pediatric patients in 2000-2011, genes related to macrolide resistance was detected in 31.4% of the samples, and this rate was reported to increase every year [25]. In another study using respiratory organ samples from pediatric patients, genes related to macrolide resistance were found in 17.6% of the samples of M. pneumoniae [26]. Although the ratio of methicillin-resistant S. aureus (MRSA) in community-acquired S. aureus infection has been increasing in Korea, systematic research on the role of MRSA in community-acquired pneumonia is lacking [27, 28, 29].
Table 4
Antibiotic resistance of Streptococcus pneumoniae isolated in Korea.
New method of diagnosing pneumonia
1. Respiratory virus PCR
Methods of respiratory virus testing include the culture test, rapid antigen test, immunofluorescence, enzyme immunoassay test, and PCR. PCR is more sensitive than the culture test, or the enzyme immunoassay test [30]. This strength of PCR makes it advantageous for adult patients with a smaller number of nasopharyngeal virus compared with pediatric patients [31, 32]. Multiplex RT-PCR is useful for simultaneously testing various respiratory viruses, and is frequently used today [33].
PCR can test various respiratory organ samples including nasopharyngeal samples, sputum, airway aspirates, and bronchoalveolar lavage fluid [31, 32]. In most studies on pneumonia caused by respiratory viruses, virus testing was performed using samples from the upper airway. Nasal swabs are the most commonly used method to detect viruses, and are more sensitive than throat swabs in adults [31].
In 20-40% of patients with community-acquired pneumonia, respiratory viruses are detected by PCR [34, 35, 36, 37]. Rhinovirus is the most commonly detected, and other respiratory viruses such as influenza, metapneumovirus, RSV, parainfluenza virus, and coronavirus are also relatively commonly detected [38, 39].
However, positive results of upper airway samples do not necessarily indicate viral infection, and positive PCR results do not indicate that pneumonia was caused by a respiratory virus. Furthermore, although respiratory viruses can induce pneumonia by themselves, they may simple be a predisposing factor of pneumonia [40]. Therefore, the possibility of bacterial pneumonia cannot be disregarded simply because respiratory bacteria were detected in the PCR test. In fact, respiratory viruses are detected in 20% of patients diagnosed with bacterial pneumonia [40].
It is unclear whether the use of antiviral agents is necessary or not when respiratory viruses aside from influenza are detected, and it is difficult to diagnose viral pneumonia based on positive results only [33]. With the costs of tests and various factors taken into consideration [33], it may be useful to perform the PCR test to detect respiratory viruses when a patient is suspected of having pneumonia caused by respiratory viruses based on clinical symptoms or radiographic findings.
2. Legionella, Mycoplasma, Chlamydophila PCR
1) Legionella PCR
Whereas the Legionella urinary antigen test can only diagnose the L. pneumophila serogroup 1, PCR can diagnose all serogroups, and thus has higher sensitivity for Legionella diagnosis. In a recent systematic review, the sensitivity of the Legionella PCR test using respiratory organ samples was 97.4%, and its specificity was 98.6% [41]. Legionella PCR may be performed using nasopharyngeal samples or nasal swabs when no sputum is secreted even in the induced sputum analysis, but this testing method has a lower diagnosis rate compared with when sputum samples are used [42, 43].
2) Mycoplasma PCR
Various serological tests have been traditionally used to diagnose Mycoplasma. These tests may fail to detect antibodies in the early period after infection [44, 45], and IgM antibody reactions may not occur in adults aged 40 years or older [46]. Mycoplasma PCR, which uses various respiratory organ samples has higher sensitivity, has higher sensitivity than serological tests [47], and has similar sensitivity to that of Legionella PCR [48]. Just as Legionella PCR, Mycoplasma PCR has a lower diagnosis rate with nasopharyngeal samples than with sputum samples [49].
3) Chlamydophila PCR
Serological tests for Chlmydophila have lower specificity compared with PCR [50], and may report false negative in the early period after infection as is the case with Mycoplasma infection [51]. For this reason, PCR may be more useful than serological tests for diagnosing Chlmydophila infection. Although the sensitivity of Chlamydophila PCR has not been accurately measured, Chlamydophila PCR is reported to have high specificity [52].
3. Chest CT
Chest computed tomography (CT) is the most accurate test for assessing parenchymal anomalies. Radiographic findings indicative of pneumonia may be observed even when no anomalies are observed on chest X-rays [53]. Chest CT is more accurate than chest X-rays in the diagnosis of complications such as pleuritis and pulmonary necrosis [54, 55] and in the exclusive diagnosis and differential diagnosis of non-infectious lung diseases such as atelectasis, pulmonary infarction, tumor, and interstitial lung disease that may exhibit similar characteristics as those of pneumonia on X-rays [56, 57, 58, 59]. Since CT findings can vary depending on the identity of the causative bacteria of pneumonia, CT is useful for identifying causative bacteria [56, 60, 61, 62]. CT findings suggestive of mycobacteria that must be differentiated from common pneumonia, and of fungal lung infection can also be obtained [56, 63, 64].
However, due to the relatively high cost and danger of irradiation compared with those of chest X-rays [65], CT must be selectively performed in cases where the differentiation of accompanying diseases such as pulmonary embolism is necessary, fungal infection is suspected, it is difficult to check for lung infiltration on chest X-rays due to other underlying lung diseases, and it is difficult to check for pneumonia complications due to lack of response to pneumonia treatment [33].
4. Chest ultrasounds
Chest ultrasounds are used in the diagnosis of various lung diseases such as pneumothorax, hydrothorax, and pulmonary enema, as well as pneumonia [66]. According to a recent systematic review and meta-analysis using the data of 1,172 patients diagnosed with pneumonia, chest ultrasounds had excellent sensitivity and specificity of 94% and 96%, respectively, in the diagnosis of pneumonia [67].
Compared to chest X-rays, chest ultrasounds do not pose the burden of radiation exposure, can be performed right next to the patient, can be performed on pregnant women, and can more accurately diagnose lung consolidation and hydrothorax [66, 67, 68]. It is also useful for evaluating hydrothorax, which can occur as a complication of pneumonia. It can diagnose septation within hydrothorax more accurately than CT [69]. Septation is indicative of birous strands between the parietal and visceral pleura, as well as inefficient drainage through the drainage tube [56].
A trained examiner must perform ultrasounds to obtain accurate results. Although a problem of interexaminer reproducibility may arise [70], chest ultrasounds may be useful for diagnosing and assessing pneumonia in situations where it is impossible to take chest X-rays (i.e. it is difficult to transfer a patient to the examination room because the patient is pregnant or immobile).
Diagnosis of pneumonia
KQ 1. For adults who may have contracted community-acquired pneumonia, are the tests used to identify causative helpful for selecting therapeutic antibiotics?
Recommendation
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Key points
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<Summary of Evidence>
When a patient is diagnosed with moderate or severe community-acquired pneumonia, appropriate testing methods are used to identify the causative bacteria of pneumonia. The main reason for performing microbial tests for community-acquired pneumonia is that appropriate, individualized treatment can be performed based on the test results, and unnecessary use of wide-spectrum antibiotics can be avoided. Detection is necessary since some microorganisms hold epidemiological significance in public health and infection control. It is also important to obtain information about common causative microorganisms of pneumonia and their antibiotic sensitivity.
However, microbial tests lack sensitivity, and are often not very useful in early treatment [71]. Despite being prospective tests for diagnosing causative microorganisms, they fail to detect causative microorganisms in 25-60% of patients [72, 73]. They lack sensitivity especially for patients who have pneumonia of low severity, who have not contract any diseases, or who have already been treated. Although a study has demonstrated a correlation between the severity of community-acquired pneumonia and the rate of blood culture positivity [74], another has reported no such correlation [75].
1. Appropriate methods of causative bacteria detection in outpatients
When treating outpatients with community-acquired pneumonia of low severity, tests are selectively performed according to age, underlying diseases, severity markers, epidemiological factors, and current history of antibiotic use. Sputum gram smear and culture may be performed when antibiotic-resistant bacteria or bacteria that are difficult to treat with common empirical antibiotics are suspected. If tuberculosis is suspected based on clinical or radiographic findings, a sputum stain and tuberculosis test are performed. It is also recommended to perform diagnostic tests when Legionella infection or influenza are suspected based on clinical and epidemiological findings.
2. Appropriate methods of causative bacteria detection in inpatients
For inpatients with pneumonia, it is advisable to perform blood culture, and sputum Gram smear and culture tests before antibiotic administration as long as they are indicated. Sputum tests must be done using sputum samples obtained before antibiotic administration, and should only be performed when sufficient amounts of sputum are released, collected, transferred, and treated [76]. For patients with moderate community-acquired pneumonia, a blood culture, Legionella, S. pneumoniae urinary antigen test, and sputum gram smear and culture must be performed [77, 78, 79]. For patients with airway intubation, a test using trans-tracheal aspirate samples must be performed. For immunodeficient patients, or patients for whom common treatments have failed, invasive tests such as airway endoscopy and percutaneous pulmonary aspiration are useful [80, 81].
KQ 2. For adults who may have contracted community-acquired pneumonia, is the urinary S. pneumoniae antigen test useful for selecting therapeutic antibiotics?
Recommendation
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Summary
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<Summary of Evidence>
A S. pneumoniae urinary antigen test is performed for all patients with community-acquired pneumonia who require hospitalization. The urinary antigen test for S. pneumoniae detection produces results within 15 minutes, and can give positive results even when antibiotics are administered. It is reported to have sensitivity of 50-80% and specificity of over 90% for adults [82, 83, 84]. The drawbacks of this test are that it is expensive to perform, and it does not assess antibiotic susceptibility. It can also produce false positive results in pediatric patients with chronic lung diseases characterized by S. pneumoniae colonization, and patients who suffered from community-acquired pneumonia in the last four months [85, 86]. The test is unaffected by the normal bacterial flora in patients with chronic obstructive pulmonary disease [78, 85]. The positivity rate of the S. pneumoniae urinary antigen test and the severity of pneumonia are reported to be correlated [87]. In 80-90% of patients who tested positive in the S. pneumoniae urinary antigen test, positivity continue until 7 days after treatment was begun [88], and the test can be performed using other bodily fluids such as pleural fluid [89]. Among studies on the effects of the results of S. pneumoniae urinary antigen test on treatment, a retrospective study has reported that pneumonia caused by S. pneumoniae was safely and effectively treated by high-dose penicillin administration in patients who tested positive in the S. pneumoniae urinary antigen test [90].
KQ 3. Is the Legionella urinary antigen test helpful for selecting therapeutic antibiotics for adults who may have contracted community-acquired pneumonia?
Recommendation
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Key points
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<Summary of Evidence>
A Legionella urinary antigen test is performed for patients with moderate or severe community-acquired pneumonia (level of recommendation: strong, level of evidence: moderate). The Legionella urinary antigen test is an appropriate testing method for patients hospitalized for idiopathic pneumonia, and is recommended in cases of moderate pneumonia, in cases where epidemiological evidence of the disease is available, and in cases of no response to β-lactam antibiotics [77, 78, 79]. The Legionella urinary antigen test has high sensitivity (~80%) and specificity (>95%) for diagnosing type 1 L. pneumophila infection [91]. The test gives positive results starting on the first day a disease occurs, and the positivity continues for several weeks [84, 85, 86, 87, 88, 89, 90, 91, 92]. The introduction of the Legionella urinary antigen test has enabled rapid diagnosis and treatment of Legionella in epidemic situations, and has improved treatment outcomes and fatality [93]. In another study, early diagnosis of Legionella infection using the Legionella urinary antigen test in patients with community-acquired pneumonia in non-epidemic situations, the test results positively affected the treatment of seven of nine patients who tested positive [94].
KQ 4. Is a blood culture useful for choosing therapeutic antibiotics for adults who may have contracted community-acquired pneumonia?
Recommendation
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Key points
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<Summary of Evidence>
A blood culture test is performed before antibiotic administration for all patients with moderate or severe community-acquired pneumonia. S. pneumoniae is the most commonly detected causative bacteria of community-acquired pneumonia in blood culture tests. It has a high diagnostic value compared with other culture testes once the bacteria grow, and provides important information about antibiotic resistance. However, it has low bacterial detection rates of 5-14% for community-acquired pneumonia [75, 95], and it has a limited influence on treatment even when positive results are obtained [74, 75]. In a systematic analysis using data of 3,898 patients with community-acquired pneumonia from 15 observational studies, blood culture results had almost no effect on the changes in the selection of empirical antibiotic, and even when they did, they did not significantly affect treatment outcomes [96]. However, since immunodeficient patients and other high-risk groups were excluded in this analysis, its results cannot be generalized to moderate community-acquired pneumonia. There is an overlap between the predictors of blood culture positivity and the risk factors of severe community-acquired pneumonia [97]. For this reason, a blood culture test is indicated and must be performed for patients with severe community-acquired pneumonia. The test is also recommended for patients with immunodeficiency disorders such as alienia and complement deficiencies, chronic liver disease, and leukopenia [74].
Hospitalization criteria for pnemonia
KQ 5. For adults who may have contracted community-acquired pneumonia, does making a hospitalization decision according to hospitalization criteria produce good prognoses?
Recommendation
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Key points
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<Summary of Evidence>
One of the most important decisions in the treatment of community-acquired pneumonia is the one of hospitalization. Hospitalization of patients who do not require hospitalization causes an unnecessary increase in medical costs. Treating patients with mild pneumonia in outpatient clinics instead of hospitalizing them will allow these patients to return to their normal life and workplace faster [98]. Hospitalization increases the risk of thrombosis [99], and the risk of infection by more pathogenic or resistant bacteria. On the other hand, treating a patient requiring hospitalization in an outpatient clinic, and later hospitalizing him/her after symptoms have worsened can increase the risk of death [100]. Higher mortalities have been reported among moderate community-acquired pneumonia are treated in general wards and are later admitted to ICU than among those who are treated in ICU from the beginning [101]. Therefore, it is important to appropriate decide whether a patient needs outpatient care or hospitalization depending on the severity of the disease and risk of death, and if the patient is hospitalized, whether he/she should be treated in a general ward or ICU.
The rate of hospitalization of patients with community-acquired pneumonia largely varies between hospitals and physicians [15]. It has been reported that physicians generally tend to overestimate the severity of pneumonia, and cause unnecessary hospitalization [102]. In one study, 845 of 1,889 patients (44.7%) with low-risk pneumonia admitted to an emergency department required hospitalization, and at least 1/5 of these patients did not meet the criteria for hospitalization, and were hospitalized for unnecessary reasons [103]. In Korea, there are many patients with community-acquired pneumonia who have been hospitalized for no clear reasons [104]. Objective markers that can be used by clinicians to predict the death of patients with community-acquired pneumonia, or the severity of pneumonia in outpatient clinics, outpatient departments of medical institutions at the level of a hospital, and emergency departments may be useful for deciding whether to request hospitalization in a medical institution or to hospitalize a patient or not.
KQ 6. Of CURB-65 and PSI, which are hospital and intensive care unit (ICU) admission criteria, which one will lead to better prognoses for adults who may have contracted community-acquired pneumonia?
Recommendation
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Key points
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<Summary of Evidence>
The two markers for assessing the severity of pneumonia that have been the most extensively studied and widely used include the pneumonia severity index developed in the United States using the data from Pneumonia Patient Outcome Research Team (PORT)’s research [105], and the CURB-65 and CRB-65 based on the death prediction model proposed by the British Thoracic Society (BTS) in 1987 [106].
The PSI is a scoring system developed to identify low-risk patients among patients with community-acquired pneumonia. It was derived from the data of 14,199 inpatients with community-acquired pneumonia. Its validity has been verified using data of 38,039 inpatients with community-acquired pneumonia, and in a prospective cohort involving 2,287 patients [15] (Table 5). The PSI scores 20 variables. The total scores are used to predict the 30-day mortality, with which patients are divided into five groups. The predicted mortality of each group is shown in Table 6. In general, outpatient treatment is recommended for PSI I-II groups, PSI III group is recommended outpatient treatment or hospitalization for short-term monitoring depending on the situation, and IV-V groups are recommended hospitalization [15, 104].
Table 5
Pneumonia severity index (PSI)
Table 6
Predicted mortality rates, risks, and recommendations according to the pneumonia severity index (PSI)
The CURB-65 and CRB-65 are pneumonia severity scoring systems developed using data prospectively collected from four hospitals across England, New Zealand, and the Netherlands [106] (Table 7). The data of 80% of the 1,068 patients included in this study were used in the guideline development, and the remaining 20% were used for validating the indices. The CURB-65 assigns six scores. One point is given for satisfying each of the following conditions: C: Confusion; U: Urea >7 mmol/L (= BUN >19 mg/dl); R: Respiratory rate ≥30/min; B: Blood pressure, systolic pressure <90 mmHg or diastolic pressure ≤60 mmHg; and 65: age≥65 years. The total resulting score ranges from 0 to 5 points. The CRB-65 is essentially the CURB-65 with the blood urea parameter requiring a blood test removed, and it assigns 0 to 4 points. The higher the CURB-65 and CRB-65 scores, the higher the mortality as shown in Table 7. The CURB-65 and CRB-65 are reported to be on a par with one another in terms of their clinical usefulness [107, 108, 109, 110, 111, 112, 113], and discriminatory power [110, 113].
Table 7
Stratification of mortality rate using the CURB-65 and CRB-65
However, it is unclear whether the use of these pneumonia severity markers can improve treatment outcomes or not. Although treatment outcomes have been reported to improve in various aspects when guidelines that include patient characteristics and severity assessments as part of the hospitalization decision-making process such as the PSI is used [114], these guidelines also consider other factors that can affect not only the hospitalization decision, but also antibiotic recommendations and treatment outcomes, and it is difficult to determine the impact of these factors on hospitalization decisions using severity markers. However, using these objective standards can reduce the rate of hospitalization among patients with pneumonia [115, 116, 117, 118].
It is unclear between the PSI and CURB-65 or CRB-65, which is superior. There have not been any randomized studies that compare these two scoring systems. In addition, studies that have compared the predictive power of the two scoring systems using identical patient groups have reported similar predictive power between the two systems [113, 119, 120, 121, 122], and thus, one cannot say one is superior to the other. In some studies, the PSI showed more excellent results. According to a study in which the developer of the PSI participated as a co-researcher, the PSI classifies a larger number of patients as the low-risk group compared with the CURB-65 (PSI I-III, 68% vs. CURB-65 <2, 61%), similar mortality rates are observed between the two groups, and the CURB-65 had significantly higher predictive power measured in terms of AUC than the PSI [107].
However, the PSI measures 20 parameters, and many blood test results are included in the score calculation. This works as a serious disadvantage in outpatient or emergency departments in Korea where patients must be examined as quickly as possible. Therefore, for patients who have been diagnosed with pneumonia for the first time in an outpatient department of a medical institution at the level of a clinic or hospital, it is recommended to assess the patients with the CRB-65, and consider the transfer to another hospital that can accommodate inpatients, or hospitalization for those whose CRB-65 scores at not 0. However, outpatient treatment may be considered for patients who satisfy the age condition of the CRB-65 (65 years or older) and whose other physiological indices are stable. In addition, in the case of patients whose blood test results can be used in emergency or outpatient treatment, the CURB-65 can be used for the same purpose, and physicians are recommended to refer to the CURB-65 results when making clinical decisions (Table 7).
A decision regarding a patient’s need for hospitalization cannot always be perfect even when an objective severity scoring system with high predictive power is used. Severity scoring systems are mere tools to help clinicians make decisions, not absolute standards, and cannot replace health professionals’ ‘clinical decisions’. For instance, a patient may be placed in a low-risk group according to a severity scoring system, but may still require hospitalization in the following situations: 1) the patient developed complications of pneumonia; 2) the patient’s underlying diseases have worsened due to pneumonia; 3) the patient cannot take oral medications; and 4) the patient has been placed in a low-risk group because he/she slightly did not meet the conditions for being classified as high-risk [15]. When determining a patient’s need for hospitalization, the patient’s social situations and his/her physician must be considered together. For instance, a patient of advanced age who lives alone, and has reduced mobility may require hospitalization until he/she recovers from pneumonia even if his/her severity scores are low.
KQ 7. For adults who may have contracted community-acquired pneumonia, does making an ICU admission decision according to hospitalization criteria produce good prognoses?
Recommendation
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Key points
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<Summary of Evidence>
Patients who require mechanical ventilation or have septic shock require ICU admission.
Although the CURB-65 or the IDSA/ATS definition of severe pneumonia (2007) may be used, these standards do not have perfect predictive power, and their clinical usefulness has not been verified. Therefore, an ICU admission decision must be made after considering various situations.
It is traditionally accepted that patients who require mechanical ventilation due to respiratory failure, or have septic shock must be admitted and treated in an ICU. However, it is a challenge to determine whether to admit a patient who do not have such needs to an ICU or not.
The community-acquired pneumonia guideline developed by the ATS/IDSA in 2007 proposes the new definition of severe pneumonia that requires ICU admission modified from the earlier definition proposed by the ATS in 2001 [15, 123] (Table 8). This standard consists of main and minor standards. The main standard includes dependence on mechanical ventilation, and septic shock that requires vasopressors. The minor standard consists of seven conditions, which include the factors included in the 2001 ATS standard [123], plus clinical factors from the CURB-65. A patient is diagnosed with severe pneumonia if he/she satisfies one of the conditions from the main standard, or three of the seven conditions from the minor standard. This standard is reported to have higher predictive power than the PSI ≥4 or CURB-65 ≥3 [124]. However, although the predictive power of the standard is improved relative to that of the PSI or CURB-65 when only the minor conditions are used (excluding patients who satisfy the main conditions for ICU admission), and the standard has good specificity, it has moderate sensitivity [125]. It has also been reported that since some of the factors included in the minor standard (leukopenia, thrombocytopenia, and hypothermia) are rarely observed in patients, the predictive power of the minor standard does not change even after these factors are excluded, and that adding other factors can increase its predictive power [126]. There are other scoring systems such as the SMART-COP [127], and the SCAP [128] that are used to predict ICU admission, but they also have similar limitations.
Table 8
ISDA/ATS criteria for severe community-acquired pneumonia
As there is not yet a tool that can be used to accurately predict a patient’s need for ICU care, a patient must be considered for ICU admission if he/she has CURB-65 ≥3, exhibits ancillary signs of severe pneumonia as defined by the ATS/IDSA, has pneumonia based on clinical signs, and has had his/her underlying diseases worsen.
Treatment of pneumonia
1. Pneumonia treatment for outpatients
KQ 8. What are the first choices of antibiotics in the outpatient treatment of patients who may have contracted community-acquired pneumonia?
Recommendation
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Recommendation
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<Summary of Evidence>
For patients who do not require hospitalization, the use of β-lactam alone, the combined use of β-lactam and macrolide, or the use of respiratory fluoroquinolones as empirical antibiotics is recommended. The following antibiotics are recommended (in alphabetical order).
β-lactam: amoxicillin, amoxicillin-clavulanate, cefditoren, cefpodoxime
Macrolide: azithromycin, clarithromycin, roxithromycin
Respiratory fluoroquinolone: gemifloxacin, levofloxacin, moxifloxacin
Macrolide or tetracycline monotherapy is not recommended due to the high antibiotic resistance of S. pneumoniae. β-lactam and macrolide may be used together if atypical pneumonia is suspected. Macrolides such as azithromycin, clarithromycin, and roxithromycin are recommended.
There is a controversy regarding whether or not antibiotics that target the causative bacterial of atypical pneumonia should be used in the treatment of mild community-acquired pneumonia that does not require hospitalization. In a retrospective study secondarily conducted using the Community-Acquired Pneumonia Organization (CAPO) database registered at the multi-institutional phase-three clinical trial conducted in various countries, antibiotics that were effective against the causative bacteria of atypical pneumonia showed more excellent outcomes in terms of mortality rate and clinical progress [129]. The study reported that the antibiotic treatment of the causative bacteria of atypical pneumonia is advisable for all patients with community-acquired pneumonia in terms of their mortality rates and treatment outcome. In addition, the IDSA/ATS guideline on pneumonia treatment developed in the United States in 2007 also gives the same recommendation. However, in a meta-analysis of patients with mild community-acquired pneumonia, use of a single antibiotic targeting the causative bacteria of atypical pneumonia had poorer clinical results than the use of β-lactam alone [130], and similar results were also reported by the 2010 Cochrane review on patients hospitalized due to community-acquired pneumonia [131]. In a study published in 2015, the β-lactam monotherapy was not inferior to the β-lactam + macrolide combination therapy [132]. Therefore, this guideline recommends using macrolide in addition to β-lactam only in cases of suspected atypical pneumonia.
Of the β-lactams that are classified as penicillin, amoxicillin, and or amoxicillin/clavulanic acid are recommended. This recommendation is based on a research finding S. pneumoniae isolated in Korea have low penicillin resistance when the antibacterial susceptibility standard developed by the CLSI (revised in January 2008), which has stricter criteria for the penicillin antibiotics of S. pneumoniae for patients without meningitis, is used. The 2007 IDSA/ATS guideline, the 2009 BTS guideline, and the 2011 ERS/ESCMID guideline all recommended to use amoxicillin as the main antibiotic.
Of oral cephalosporins, cefpodoxime recommended by the 2007 IDSA/ATS guideline, and the 2011 ERS/ESCMID guideline, and cefditoren recommended by the 2011 ERS/ESCMID guideline with available data regarding the antibiotic susceptibility of the causative bacteria of pneumonia in Korea have been included in this guideline [133]. On the other hand, cefuroxime has been excluded since S. pneumoniae isolated in Korea are highly resistant against the antibiotic. The 2011 ERS/ESCMID guideline has also mentioned a study that reported an association between increased mortality rates and cefuroxime use in patients with S. pneumoniae pneumonia accompanied by bacteremia [134].
The 2007 IDSA/ATS guideline, 2009 BTS guideline, and 2011 ERS/ESCMID guidelines recommend use of macrolide or tetracycline alone. However, this recommendation has not been included in this guideline. This is because S. pneumoniae isolated in Korea show high resistance against these antibiotics.
The fluoroquinolone monotherapy shows excellent antibacterial activities against tuberculosis bacilli. For this reason, it may delay the diagnosis of tuberculosis in patients with community-acquired pneumonia whose tuberculosis has been misdiagnosed as a type of bacterial pneumonia, and can allow tuberculosis bacilli to develop resistance against fluoroquinolones. Therefore, in cases where tuberculosis cannot be eliminated, it is recommended to avoid the empirical use of fluoroquinolones.
For levofloxacin, it has been reported that the once-daily administration of levofloxacin 750 mg is pharmacodynamically more ideal than the same therapy using 500 mg levofloxacin [135]. A clinical study reported that once-daily administration of levofloxacin 750 mg for five days has excellent therapeutic effects, and this therapy has settled as the standard method of treatment for pneumonia since then [136]. A study has also reported that the five-day Gemifloxacin therapy is not inferior to its seven-day counterpart in terms of therapeutic effects [137].
2. Treatment of pneumonia in patients hospitalized in general wards
KQ 9. For patients who may have contracted community-acquired pneumonia, and are hospitalized in an ICU, does the β-lactam /macrolide (or respiratory fluoroquinolone) combination therapy produce better prognoses than the β-lactam monotherapy?
Recommendation
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Key points
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<Summary of Evidence>
Empirical antibiotics for patients admitted to general wards are selected based on the severity of the disease; in other words, they are selected based on whether the patient has mild pneumonia (CURB-65 0-1 points, PSI 1-2 points), moderate pneumonia (CURB-65 2 points, PSI 3-4 points), or severe pneumonia (CURB-65 3 points, PSI 5 points). Empirical antibiotics and the method of administration are chosen based on health professionals’ judgment on the patient’s clinical situations and the selected antibiotics, antibiotic resistance, medication allergy, compliance, previous antibiotic use (penicillin, macrolide, fluoroquinolone, etc.), cost, and potential side effects. Isolation and susceptibility results of causative bacteria that are later reported must be considered along with the clinical progress to readjust the antibiotic selection.
Use of β-lactams or respiratory fluoroquinolone alone is recommended for the empirical treatment of mild or moderate pneumonia. The 2007 IDSA/ATS guideline and the 2009 Korean guideline on community-acquired pneumonia recommend the administration of β-lactams alone or in conjunction with macrolide, or the administration of respiratory fluoroquinolones alone [15, 104]. Most of the studies on combined antibiotic administration included in these guidelines were either retrospective or observational studies [138, 139, 140, 141]. In prospective comparative studies conducted after these studies, the β-lactam and macrolide combination therapy for mild-moderate pneumonia showed no difference from the β-lactam monotherapy in terms of treatment outcomes (cure rate, incidence of side effects, mortality rates, etc.) [130, 131, 132, 142, 143]. In a meta-analysis on 18 studies that compare the therapeutic effects of β-lactams, and those of macrolide or fluoroquinolone which have the effect to atypical pathogens, in the treatment of mild-moderate pneumonia, there were no significant differences in the clinical progress between the two antibiotic groups (relative risk, 0.97; 95% confidence interval 0.87-1.07) [130]. In a prospective CAP-START study conducted by Postma et al., patients hospitalized in general wards were subjected to β-lactam administration (656 patients), β-lactam + macrolide administration (739 patients), and fluoroquinolone administration (888 patients), and therapeutic effects were compared among the groups. The 90-day mortality rate was 9.0% in the β-lactam group, 11.1% in the β-lactam + macrolide group, and 8.8% in the fluoroquinolone group. Therefore, the treatment outcomes observed in the β-lactam group were on a par with those observed in the other groups [144]. In a study by Grain et al. that prospectively compares β-lactam administration, and β-lactam + macrolide administration in the treatment of patients with severe pneumonia, 41.2% and 33.6% of the patients in the β-lactam group, and the β-lactam + macrolide group did not reach a clinically stable state after seven days, respectively (P = 0.07). Although there was no difference in the rate of reaching clinical stability between the patients without atypical bacterial infection (relative risk, 0.99; 95% CI, 0.80-1.22) and with pneumonia corresponding to PSI 1-3 points in the β-lactam, and β-lactam + macrolide groups, when patients with atypical pneumonia (relative risk, 0.33; 95% confidence interval, 0.13-0.85) or severe pneumonia corresponding to PSI 5 points (relative risk, 0.81; 95% confidence interval, 0.59-1.10) were considered, the rate of reaching clinical stability was lower in the β-lactam group. The rate of readmission within 30 days was higher in the β-lactam group (7.9%, 3.1%, P = 0.01), and there were no significant differences in other clinical markers including the 90-day mortality rate, rate of ICU admission, incidence of complications, duration of hospital stay, and rate of pneumonia recurrence between the two administration groups [142].
Therefore, the present revised guideline on the treatment of community-acquired pneumonia in Korea recommends the administration of β-lactam or respiratory fluoroquinolone alone for patients with mild-moderate pneumonia who are hospitalized in general wards. In addition, considering inpatients’ characteristics, the guideline recommends intravenous injections of β-lactams including amoxicillin/clavulanic acid, ampicillin/sulbactam, cefotaxime, and ceftriaxone, or respiratory fluoroquinolones including gemifloxacin, levofloxacin, and moxifloxacin over oral antibiotics [expert opinion] [143, 144]. Combined administration of β-lactams and macrolides is recommended for treating atypical bacterial infections (Mycoplasma spp., Chlamydophila spp., Legionella spp.), for which the antibiotics have been reported to reduce the mortality rates of the infections, and for treating severe pneumonia [143, 144]. Oral macrolides must be used with care as they are associated with increased cardiovascular risks in patients of advanced age. These antibiotics are not recommended as there have been reports of low oral bioavailability of erythromycin, increased QT interval, and increased cardiovascular risks associated with macrolides [145, 146].
For patients who show severe adverse reactions to penicillin, and cannot use β-lactams, respiratory fluoroquinolones such as gemifloxacin, levofloxacin, and moxifloxacin are recommended. As studies have reported that use of fluoroquinolones is associated with delayed tuberculosis diagnosis, and increased drug tolerance, fluoroquinolones must be used with caution in Korea where the prevalence of tuberculosis is not low [147, 148, 149]. A prospective randomized controlled clinical report has reported that the therapeutic effects of the moxifloxacin monotherapy are not inferior to those of the ceftriaxone and levofloxacin combination therapy [150]. It has also been reported that similar results were observed between a group that was orally administered gemifloxacin, and another that was administered cefuroxime followed by ceftriaxone, and that gemifloxacin was better in terms of costs [151].
KQ 10. What is the adequate duration of antibiotic treatment for patients who may have contracted community-acquired pneumonia?
Recommendation
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Key points
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<Summary of Evidence>
Although antibiotics are generally administered for 7-10 days, the adequate duration of the administration period may change depending on the causative bacteria, patient’s conditions, types of antibiotics, treatment response, accompanying diseases and complications of pneumonia the patient has [15, 152]. In general, antibiotics are administered for at least five days. For a treatment to be terminated, a patient must not have a fever for 48-72 hours, and must show one or more of the signs of clinical stable shown in Table 9 before the treatment completion [15]. A study has reported that for gemifloxaicn and levofloxacin (750 mg/d), five-day administration is sufficient [138, 153]. Antibiotics with long half-lives (e.g. azithromycin) may be used for 3-5 days [153, 154, 155]. In the cases of S. aureus pneumonia accompanied by bacteremia, enteric Gram-negative bacilli pneumonia, pneumonia accompanied by infections of other organs, and early treatment failures, short-term antibiotic treatment may be insufficient [15]. Patients who have formed cavities, or show signs of tissue necrosis may require long-term treatment [15]. Legionella pneumonia must be treated for at least 14 days [152].
Table 9
Criteria for clinical stability
KQ 11. For patients who may have contracted community-acquired pneumonia, when is it appropriate to switch from intravenous antibiotics to oral antibiotics?
Recommendation
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<Summary of Evidence>
Patients hospitalized in an ICU, who do not have severe pneumonia, show clinical improvements, are hemodynamically stable, can perform normal oral ingestion, and have normal digestive functions, maybe switch to oral treatment (Table 10). The criteria for switching to oral treatment are: 1) reduced cough and dyspnea; 2) fever: body temperature in the last eight hours <37.8°C; 3) normal leukocyte count in a blood test; and 4) sufficient oral ingestion and normal gastrointestinal absorption [156, 157]. In a prospective study that used these criteria, 133 of 200 patients (67%) hospitalized due to pneumonia satisfied these criteria within three days, and could switch to oral treatment [157]. Only one patient had a clinical treatment failure [157]. These criteria may also be applied to pneumonia caused by S. pneumoniae accompanied by bacteremia, which is known to have poor prognoses [158].
Table 10
Criteria for switching to oral antibiotics
Another method to reduce the duration of antibiotic administration for inpatients is to start with oral treatment from the beginning, or to perform intravenous treatment for a certain period, and then switch to oral treatment. The latter has been reported to produce the same treatment outcomes as existing methods, while shortening the duration of hospital stay [159]. However, more detailed research is needed to investigate which patient groups may benefit from this approach, and what the most appropriate duration of administration is.
It is not necessary to monitor a hospitalized patient’s conditions after he/she switches to oral antibiotics. In a retrospective study on 5,248 patients of advanced age who had pneumonia, there was no difference in the 14-day readmission rate, and the 30-day mortality rate between the patients who were discharged on the day that they switched to oral antibiotics, and those who were monitored for one more day after the switch [160].
Generally, it is recommended to use identical antibiotics when switching from intravenous to oral treatment. If the same antibiotics are not available, it is recommended to use antibiotics of the same class. In areas such as the United States where the rate of high-level macrolide resistance is low in S. pneumoniae, oral administration of macrolide is recommended if 1) there are no isolated bacteria or the causative bacteria are S. pneumoniae; and 2) β-lactam and macrolide have been intravenously injected as empirical antibiotics [15]. However, in areas where the rate of high-level macrolide resistance is high in S. pneumoniae such as Korea, there is insufficient evidence to accept these principles as they are. For this reason, it is recommended to use oral antibiotics that are of the same class as that of the starting intravenous antibiotics for a sufficient period.
KQ 12. For patients who may have contracted community-acquired pneumonia, when is the appropriate time to be discharged?
Recommendation
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<Summary of Evidence>
If patient does not require treatment for underlying diseases, and does not require diagnostic tests, and a social environment in which the patient can be taken care of is established, discharge may be considered [136, 157, 161] (Table 11). However, a discharge decision cannot be made solely based on objective criteria. Ultimately, the clinician in charge must make the decision after considering the patient’s clinical and social situations. There is a controversy regarding whether or not a patient must satisfy all conditions of clinical stability in the PSI before discharge. However, the more conditions the patient does not satisfy, the more likely he/she is likely to have poor prognoses [162, 163]. According to a prospective study that monitored 680 inpatients with pneumonia, the rate of mortality or readmission was 10.5% when a patient satisfied all conditions of clinical stability shown in Table 9 in the last 24 hours before discharge, but it increased to 13.7% with the odds ratio at 1.6 when the patient did not meet one of the conditions, and to 46.2% with the odds ratio at 5.4 if the patient did not satisfy two or more conditions [162]. A recently published prospective study has also reported that as the number of unsatisfied conditions increases, the 30-day mortality rate increases, and that fever is the most highly associated with prognosis [163].
Table 11
Discharge criteria
As the PSI increases, the time until clinical stability increases [104], and this leads to longer recovery time required for elderly patients who have various accompanying diseases [164]. In addition, underlying diseases are the most common cause of readmission for patients who are discharged after undergoing treatment for pneumonia. Therefore, when determining the timing for discharge in elderly patients with various underlying diseases, it is advisable to assess whether or not the patients require additional interventions including early rehabilitative therapy.
KQ 13. For patients who may have contracted community-acquired pneumonia, are oxygen therapy, low-molecular-weight heparin therapy, and early ambulation helpful?
Recommendation
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<Summary of Evidence>
Oxygen therapy: High concentrations of oxygen may be safely applied if a patient requires oxygen therapy to maintain the arterial partial oxygen pressure at over 8 kPa, and oxygen saturation level at 94-98%, and the risk of hypercapnic respiratory failure is not high. For patients at high risk of hypercapnic respiratory failure, treatment must begin with 24-28% low concentration oxygen therapy, followed by oxygen infusion with the oxygen saturation maintained at 88-92% and pH ≥7.35 while the arterial blood gas test results are being repeatedly checked [165]
Low-molecular-weight heparin therapy: Patients with pneumonia accompanied by acute respiratory failure are classified into the high-risk group, and must be administered low-molecular-weight heparin [166, 167]. Administration of appropriate antibiotics at appropriate time, and use of a guideline on heparin administration for the prevention of thromboembolism have been observed to reduce mortality rates [168].
Early ambulation: Early ambulation show good clinical prognoses. In a prospective study involving 458 subjects, the duration of hospital stay was shorter by 1.1 days for patients who came out of bed and maintained an upright posture for at least 20 minutes in the first 24 hours after their hospital admission, and gradually increased the level of physical activity [169].
3. Treatment of patients with pneumonia in ICU
KQ 14. For patients who may have contracted community-acquired pneumonia and are admitted to ICU for treatment, does the β-lactam/macrolide (or respiratory fluoroquinolone) combination therapy lead to better prognoses than the β-lactam monotherapy?
KQ 15. For patients who may have contracted community-acquired pneumonia and who are in admitted to ICU for treatment, does the β-lactam/macrolide (or respiratory fluoroquinolone) combination therapy lead to better prognoses than the respiratory fluoroquinolone monotherapy?
Recommendation
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Key points
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<Summary of Evidence>
There are not many domestic clinical studies on the causative bacteria of antibiotic treatment of severe community-acquired pneumonia. According to foreign research, S. pneumoniae, Legionella spp., H. influenzae, Enterbacteriaceae spp., S. aureus, and Pseudomonas spp. are the major causative bacteria of community-acquired pneumonia, and about 20% cases of community-acquired pneumonia are due to atypical bacteria [170, 171]. Because Legionella are especially important in severe pneumonia caused by atypical bacteria, antibiotics that have antibacterial activities against these bacteria must be included in the early empirical treatment [172]. In clinical studies that have been conducted up to date, combination therapy has been not more beneficial than monotherapy for treating mild pneumonia; however, combination therapy has produced better results for patients with severe pneumonia [142, 173, 174].
1) P. aeruginosa infection is not suspected
(a) β-lactam+azithromycin or
(b) β-lactam+fluoroquinolone combination therapy is performed. The following antibiotics are recommended (in alphabetical order)
β-lactam: ampicillin/sulbactam, cefotaxime, ceftriaxone
Macrolide: azithromycin
Respiratory fluoroquinolone: gemifloxacin, levofloxacin, moxifloxacin (Respiratory fluoroquinolone+aztreonam are recommended if a patient is hypersensitive to penicillin.)
In a randomized controlled clinical trial involving patients with community-acquired pneumonia not accompanied by shock, combination therapy had no significant effects; however, the combination therapy showed better outcomes than the fluoroquinolone monotherapy for patients who were on mechanical ventilation [173]. In another retrospective study, the β-lactam + macrolide combination therapy led to higher survival rates than the fluoroquinolone monotherapy for patients with severe pneumonia [175]. Most patients who are admitted to an ICU experience shock, or require mechanical ventilation. Therefore, combination therapy is recommended over the fluoroquinolone monotherapy for these patients. The effectiveness of the fluoroquinolone monotherapy in pneumonia accompanied by meningitis caused by S. pneumoniae is unclear. In a recent noninferiority trial, the β-lactam + macrolide combination therapy produced better outcomes than the β-lactam monotherapy in severe pneumonia or pneumonia caused by atypical bacteria [142]. In a prospective observational study involving patients with S. pneumoniae bacteremia, the combination therapy (β-lactam + macrolide or β-lactam + fluoroquinolone) also led to higher survival rates compared with the β-lactam monotherapy, and this result was observed not in patients with mild pneumonia, but patients with severe pneumonia [176]. Some studies have also reported better treatment outcomes from combination therapy than from monotherapy even in patients treated with effective antibiotics [177, 178, 179]. Therefore, for the empirical antibiotic treatment of patients with severe community-acquired pneumonia requiring ICU admission, combination therapy is recommended over monotherapy.
2) Suspected P. aeruginosa infection
The following combination therapies may be performed. Anti-pneumococcal, anti-pseudomonal β-lactams, such as cefepime, piperacillin/tazobactam, imipenem, and meropenem may be used.
(a) Anti-pneumococcal, anti-pseudomonal β-lactam + ciprofloxacin or levofloxacin
(b) Anti-pneumococcal, anti-pseudomonal β-lactam + aminoglycoside + azithromycin
(c) Anti-pneumococcal, anti-pseudomonal β-lactam + aminoglycoside + anti-pneumococcal fluoroquinolone (gemifloxacin, levofloxacin, moxifloxacin)
The risk factors of P. aeruginosa infection include alcohol consumption, structural lung diseases such as bronchodilation, frequent use of steroids due to acute worsening of chronic obstructive pulmonary disease, and use of antibiotics in the last three months. If there is a possibility that a patient has pneumonia caused by P. aeruginosa, antibiotics that are effective against and highly sensitive to S. pneumoniae must be selected. Examples of these antibiotics include cefepime, piperacillin/tazobactam, imipenem, and meropenem. In a prospective observational study, gram-negative bacillus infections including those caused by P. aeruginosa were associated with high mortality rates [180]. In a multi-institutional study conducted in Asian, gram-negative bacilli accounted for 10.1% of all cases of deaths, were the most common causative bacteria of severe pneumonia, and were a risk factor of death [181]. Of these bacteria, P. aeruginosa may exhibit various levels of antibiotic resistance. Therefore, more than two empirical combination therapies are needed against these bacteria, and it is recommended to readjust the antibiotic selection once the bacteria are isolated and their susceptibility results are obtained [180].
3) Suspected MRSA infection
Although community-acquired MRSA have been usually detected in skin and soft tissue infections, they are rarely a cause of severe community-acquired pneumonia [182]. They occur in healthy adults who are not associated with the common risk factors of hospital-acquired infection, and have been reported to occur in association with new influenza viruses [183]. They produce Panton-Valentine Leucocidin (PVL) toxins, cause necrotic pneumonia and are associated with high mortality rates.
Unlike in the case of hospital-acquired MRSA, community-acquired MRSA may be susceptible to sulfamethoxazole (TMP-SMX) or clindamycin. Vancomycin cannot reduce toxin production, and it is not yet clear if TMP-SMX and fluoroquinolones can reduce toxin production. Although there is no established method of treatment, clindamycin, which can reduce toxin production, and rifampin, which has bactericidal activities against S. aureus may be used [184, 185]. Among novel antibiotics, daptomycin is effective for soft tissue infection caused by MRSA or bacteremia. However, its effectiveness may be reduced due to surfactants of the lungs, and are therefore not recommended [186]. There is not enough evidence regarding the effectiveness of tigecycline in pneumonia [187].
KQ 16. For patients who may have contracted community-acquired pneumonia and who are admitted to ICU for treatment, does a treatment against Legionella lead to better prognoses?
Recommendation
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Key points
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<Summary of Evidence>
All patients admitted to an ICU must be subjected to treatment against S. pneumoniea and Legionella spp. [171, 188]. According to foreign studies, infections caused by atypical bacteria account for over 20% of all cases of severe community-acquired pneumonia, and of these, Legionella plays the main role [170, 171, 172]. In domestic studies, Legionella accounted for 0-5.3% of the causative bacteria of pneumonia, but they were more common compared with other atypical pathogens in patients with severe pneumonia requiring ICU admission [11, 12, 13].
KQ 17. For patients who may have contracted community-acquired pneumonia and who are admitted to ICU for treatment, does steroid therapy lead to good prognoses?
Recommendation
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Key points
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<Summary of Evidence>
Study results regarding the use of steroids for severe community-acquired pneumonia vary greatly. In a recently-conducted large-scale study, use of steroids in addition to pneumonia treatment led to faster bacteriological conversion, shortened the time until clinical stability, and shortened the duration of hospital stay [189, 190, 191, 192]. In a small-scale randomized study involving patients admitted to an ICU, seven-day use of hydrocortisone reduced the duration of hospital stay and mortality rate [193]. In two small-scale studies, use of steroids produced better treatment outcomes as opposed to when they were not used [194, 195]. However, these studies are small in scale, and differ in the characteristics of their patient groups. In a relatively recently conducted randomized controlled study, the duration of hospital stay was reduced by 1-1.5 days in the steroid group, but no difference in the mortality rate was observed [190, 193]. In addition, when steroids were additionally used for patients with pneumonia, no significant differences in symptom improvements, overall cure rate, complications, rate of ICU admission, and mortality rate were observed compared with the other group that was not subjected to steroid administration, and the rates of hyperglycemia and side effects were higher in the steroid group [189, 190, 191, 192]. However, in a randomized controlled study involving patients with septic shock, seven-day use of low-dose hydrocortisone reduced mortality rates in patients who had hypoadrenalism [196], and reduced mortality rates and the number of days on mechanical ventilation in patients with acute respiratory failure in addition to hypoadrenalism [197]. Therefore, patients with severe community-acquired pneumonia accompanied by shock that requires vasopressors, use of steroids may be considered.
Assessment of effectiveness of pneumonia treatment
KQ 18. For patients who may have contracted community-acquired pneumonia, are follow-up chest-X-rays useful for assessing treatment response?
Recommendation
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Recommendation
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<Summary of Evidence>
In general, radiological anomalies of pneumonia manifest more slowly than clinical symptoms.
In a study that prospectively observed 288 inpatients with severe pneumonia, 56% of the patients showed clinical improvements at seven days, but only 25% radiologically showed improvements. At 28 days, 78% patients completely recovered based on clinical findings, but only 53% had complete lesion loss based on chest X-rays [198]. In a study that monitored chest X-rays of 81 patients with community-acquired pneumonia in emergency and outpatient departments for 24 weeks, 50.6% of the patients had complete lesion loss at two weeks, and only 66.7% had complete lesion loss at four weeks [199]. Radiological improvements were usually observed slowly in multilobar pneumonia, and the rate of improvement in chest X-rays changed depending on the patient’s age and underlying lung diseases [199, 200]. Most patients who were 50 years old or younger, and had no underlying lung diseases show lesion improvement on chest X-rays within four weeks; however, patients who are 50 years or older, and have underlying lung diseases may not show radiological improvements until after 12 weeks [200]. In addition, treatment outcome of pneumonia is not associated with signs of worsening on chest X-rays taken during a follow-up period [198]. Therefore, repeatedly taking chest X-rays from patients with pneumonia who have shown clinical improvements may not have any additional benefits.
However, it is necessary to take follow-up chest X-rays to eliminate the possibility of underlying diseases such as pneumonia for patients who are 50 years old or older, male, and smokers. In a large-scale cohort study involving 3,000 patients, 1.1% patients diagnosed with community-acquired pneumonia were newly diagnosed with pneumonia within 90 days, and age of 50 years or older (adjusted HR 19.0, 95% CI 5.7-63.6), male gender (adjusted HR 1.8, 95% CI 1.1-2.9), and smoking (adjusted HR 1.7, 95% CI 1.0-3.0) were significant risk factors of pneumonia [201]. Of 236 patients with community-acquired pneumonia, 10 were diagnosed with pneumonia, and high proportion (17%) of these patients was aged 60 years or older. Therefore, it is necessary to take follow-up chest X-rays from patients with community-acquired pneumonia [72]. In addition, to eliminate the possibility of pneumonia and underlying diseases in patients who do not show sufficient clinical improvements at 4-5 weeks after treatment, chest X-rays may be repeatedly obtained [202].
KQ 19. For patients who may have contracted community-acquired pneumonia, is the C-reactive protein (CRP) test useful for assessing therapeutic effects?
Recommendation
|
Key points
|
<Summary of Evidence>
Based on the findings of prospective studies that have analyzed inpatients with community-acquired pneumonia, repeated CRP measurement at three or four days of treatment helped identify patients at risk of treatment failure or at increased risk of complications [203, 204, 205, 206]. CRP levels >10 mg/dL at four days of treatment were significantly associated with the incidence of complications [207]. On the other hand, patients with CRP levels <3 mg/dL at three days after treatment were at low risk of complications [205]. In addition, patients whose CRP levels did not decrease by over 50% at four days of treatment had a higher 30-day mortality rate, higher risk of ventilator and vasopressor use, and higher risk of complications of pneumonia such as pyothorax [204]. Therefore, although repeated CRP measurement is not significantly beneficial in clinical aspects for patients whose symptoms are worsening, CRP monitoring may help identify patients at risk of treatment failure or complications among those who do not show clear signs of clinical improvements or worsening in the early period of hospitalization.
KQ 20. For patients who may have contracted community-acquired pneumonia, is the procalcitonin test useful for assessing therapeutic effects?
Recommendation
|
Key points
|
<Summary of Evidence>
Repeated procalcitonin measurement may help predict a patient’s prognosis. When procalcitonin levels of 100 patients admitted to an ICU due to severe community-acquired pneumonia were measured at one and three days of hospitalization, an increase in procalcitonin levels at three days was identified as a significant prognostic factor indicative of poor prognoses [208]. In another study, of 394 patients hospitalized due to community-acquired pneumonia, those who clinically stabilized within 72 hours, and whose procalcitonin levels repeatedly measured at 72 hours were below 0.25 ng/mL did not develop serious complications [205]. When procalcitonin, CRP, mild regional pro-atrial natriuretic peptide (MR pro-ANP) levels were continuously measured in 75 patients with pneumonia, high levels of MR pro-ANP and procalcitonin levels were consistently observed in patients who developed complications or died [209].
Numerous randomized controlled clinical studies have been conducted to determine whether or not procalcitonin can be used as criteria for beginning or ceasing antibiotic use. According to a meta-analysis that analysed 4,221 patients 14 different acute respiratory infections, using procalcitonin as the criteria for antibiotic use did not lead to significant differences in the risk of treatment failure and mortality rate compared with when existing treatment guidelines were used, but significantly reduced the number of days of antibiotic use [210]. When the meta-analysis analysed patients with community-acquired pneumonia separately, there was no significant difference in the mortality rate between the procalcitonin and control groups (9.2% and 10.8%, respectively; adjusted odds ratio (OR) 0.89 (95% CI 0.64-1.23). However, the rate of treatment failure was lower in the procalcitonin group compared with the existing treatment group (19.0% and 23.4%, respectively; adjusted OR 0.77 (95% CI 0.62-0.96, P <0.05)), and the median number of days of antibiotic use decreased by 3.9 days from 10 to 6 days (P <0.01) [211]. A prospective multi-institutional randomized controlled clinical study has recently published its findings regarding the use of the procalcitonin test as the criteria for cessation of antibiotic use in patients who are administered antibiotics within 24 hours after ICU admission due to an infection [212]. Of the 1,575 patients included in this study, 792 (50.3%) had community-acquired pneumonia. In the procalcitonin group, cessation of antibiotic use was recommended if the procalcitonin level has decreased by over 80% relative to the level at the time of admission, or if the level is below 0.5 µg/L. Consistent with previous studies, the doses of antibiotics used and the duration of antibiotic use significantly decreased in the procalcitonin group compared with the control group. The mortality rate at 28 days decreased by 5.4% (P = 0.0122), and the one-year mortality rate decreased by 6.1% (P = 0.0158) in the procalcitonin group compared with the control group. However, most of studies have been published in Europe, and the patient groups included in the studies are heterogeneous in terms of diseases. In addition, the ratio of patients in the procalcitonin group varied depending on the research algorithm (47-81%). Further studies are needed to investigate the cost-effectiveness of the procalcitonin test in reducing the cost of antibiotic prescriptions, and it is yet too early to recommend antibiotic treatment according to procalcitonin test results in an actual clinical practice guideline.
Adjuvant treatment and prevention of pneumonia
KQ 21. For adults who have contracted community-acquired pneumonia, and have the risk factors of S. pneumoniae infection, can vaccination against S. pneumoniae prevent community-acquired pneumonia?
Recommendation
|
Key points
|
<Summary of Evidence>
The risk factors of invasive pneumococcal diseases caused include age of 65 years or older, residence in long-term care facilities, dementia, convulsive diseases, congestive heart failure, cardiovascular diseases, chronic obstructive pulmonary diseases, previous history of pneumonia, chronic liver diseases, diabetes, alienia, and chronic cerebrospinal fluid leakage.
According to previous literatures, the 23-valent polysaccharide pneumococcal vaccine prevented invasive pneumococcal diseases in 44-47% of older adults aged 65 years or older [213, 214], and its effectiveness was slightly reduced in patients with chronic diseases [215]. Numerous cohort studies have recently demonstrated that the vaccine can reduce the incidence of pneumonia, pneumococcal pneumonia, hospitalization due to pneumonia, and deaths by pneumonia [216, 217, 218, 219, 220, 221]. However, some have reported that the vaccine has no preventive effects against pneumonia, or hospitalization due to pneumonia [222, 223]. Patients who have asplenia, who are of advanced age, or who are in a high-risk group must be revaccinated after five years. The safety and immunogenicity of the vaccine have been verified in numerous studies [224, 225, 226].
In a recent large-scale study, the 13-valent protein conjugate pneumococcal vaccine prevented 45% of pneumococcal pneumonia, and 75% of invasive pneumococcal diseases. However, the vaccine had no preventive effects against other types of pneumonia [222].
The preventive effects of the polysaccharide pneumococcal vaccine against invasive pneumococcal diseases, as well as those of the protein conjugate pneumococcal vaccine against pneumococcal infections have been verified. Accordingly, a domestic pneumococcal vaccination guideline recommends performing a combined injection of the protein conjugate and polysaccharide vaccines in patients who are of advanced age, or who have the risk factors of pneumococcal infections.
KQ 22. Does smoking cessation education prevent community-acquired pneumonia among adults who have contracted community-acquired pneumonia?
Recommendation
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Key points
|
<Summary of Evidence>
Smoking is known to be a risk factor of invasive pneumococcal diseases even in young people who are not immunosuppressed [227]. Both direct and indirect smoking is a risk factor of community-acquired pneumonia [228, 229]. In addition, smoking is a risk factor of Legionella infections [230]. Smoking cessation education is needed to prevent pneumonia, and for smokers who are hospitalized due to pneumonia, the education must begin during the hospitalization [231].
Supplementary material
Supplementary material can be found with this article online http://www.icjournal.org/src/sm/ic-Guideline Korean Version
Conflict of Interest:No conflicts of interest.
Acknowledgement
This research was supported by a fund (2017-E21002-00) by Research of Korea Centers for Disease Control and Prevention. This manuscript was translated from the original Korean version.
References
-
Chong YP, Jung KS, Lee KH, Kim MN, Moon SM, Park S, Hur J, Kim DM, Jeon MH, Woo JH. The bacterial etiology of community-acquired pneumonia in Korea: A nationwide prospective multicenter study. Infect Chemother 2010;42:397–403.
-
-
Song JH, Oh WS, Kang CI, Chung DR, Peck KR, Ko KS, Yeom JS, Kim CK, Kim SW, Chang HH, Kim YS, Jung SI, Tong Z, Wang Q, Huang SG, Liu JW, Lalitha MK, Tan BH, Van PH, Carlos CC, So T, Asian Network for Surveillance of Resistant Pathogens Study GroupEpidemiology and clinical outcomes of community-acquired pneumonia in adult patients in Asian countries: a prospective study by the Asian network for surveillance of resistant pathogens. Int J Antimicrob Agents 2008;31:107–114.
-
-
Lee SJ, Lee MG, Jeon MJ, Jung KS, Lee HK, Kishimoto T. Atypical pathogens in adult patients admitted with community-acquired pneumonia in Korea. Jpn J Infect Dis 2002;55:157–159.
-
-
Choi SH, Hong SB, Ko GB, Lee Y, Park HJ, Park SY, Moon SM, Cho OH, Park KH, Chong YP, Kim SH, Huh JW, Sung H, Do KH, Lee SO, Kim MN, Jeong JY, Lim CM, Kim YS, Woo JH, Koh Y. Viral infection in patients with severe pneumonia requiring intensive care unit admission. Am J Respir Crit Care Med 2012;186:325–332.
-
-
Mandell LA, Wunderink RG, Anzueto A, Bartlett JG, Campbell GD, Dean NC, Dowell SF, File TM Jr, Musher DM, Niederman MS, Torres A, Whitney CG, Infectious Diseases Society of AmericaAmerican Thoracic Society. Infectious Diseases Society of America/American Thoracic Society consensus guidelines on the management of community-acquired pneumonia in adults. Clin Infect Dis 2007;44 Suppl 2:S27–S72.
-
-
Lim WS, Baudouin SV, George RC, Hill AT, Jamieson C, Le Jeune I, Macfarlane JT, Read RC, Roberts HJ, Levy ML, Wani M, Woodhead MA, Pneumonia Guidelines Committee of the BTS Standards of Care CommitteeBTS guidelines for the management of community acquired pneumonia in adults: update 2009. Thorax 2009;64 Suppl 3:iii1–iii55.
-
-
Song JH, Jung SI, Ki HK, Shin MH, Ko KS, Son JS, Chang HH, Kim SW, Lee H, Kim YS, Oh WS, Peck KR, Chongthaleong A, Lalitha MK, Perera J, Yee TT, Jamal F, Kamarulzaman A, Carlos CC, So T, Asian Network for Surveillance of Resistant Pathogens Study GroupClinical outcomes of pneumococcal pneumonia caused by antibiotic-resistant strains in Asian countries: a study by the Asian Network for Surveillance of Resistant Pathogens. Clin Infect Dis 2004;38:1570–1578.
-
-
Kim SH, Song JH, Chung DR, Thamlikitkul V, Yang Y, Wang H, Lu M, So TM, Hsueh PR, Yasin RM, Carlos CC, Pham HV, Lalitha MK, Shimono N, Perera J, Shibl AM, Baek JY, Kang CI, Ko KS, Peck KR, ANSORP Study GroupChanging trends in antimicrobial resistance and serotypes of Streptococcus pneumoniae isolates in Asian countries: an Asian Network for Surveillance of Resistant Pathogens (ANSORP) study. Antimicrob Agents Chemother 2012;56:1418–1426.
-
-
Kim SH, Song SA, Yi J, Song D, Chang CL, Park DC, Urm SH, Kim HR, Shin JH. Distribution and antimicrobial resistance of Streptococcus pneumoniae at four university hospitals in Busan and Gyeongnam. Ann Clin Microbiol 2016;19:48–53.
-
-
Kim T, Park SJ, Chong YP, Park KH, Lee YM, Hong HL, Kim HS, Kim ES, Lee S, Choi DR, Kim SH, Jeong JY, Lee SO, Choi SH, Woo JH, Kim YS. Fluoroquinolone resistance of Streptococcus pneumoniae isolates causing invasive disease: special focus on zabofloxacin. Diagn Microbiol Infect Dis 2016;86:181–183.
-
-
Torumkuney D, Chaiwarith R, Reechaipichitkul W, Malatham K, Chareonphaibul V, Rodrigues C, Chitins DS, Dias M, Anandan S, Kanakapura S, Park YJ, Lee K, Lee H, Kim JY, Lee Y, Lee HK, Kim JH, Tan TY, Heng YX, Mukherjee P, Morrissey I. Results from the survey of antibiotic resistance (SOAR) 2012-14 in Thailand, India, South Korea and Singapore. J Antimicrob Chemother 2016;71 Suppl 1:i3–i19.
-
-
Jain S, Self WH, Wunderink RG, Fakhran S, Balk R, Bramley AM, Reed C, Grijalva CG, Anderson EJ, Courtney DM, Chappell JD, Qi C, Hart EM, Carroll F, Trabue C, Donnelly HK, Williams DJ, Zhu Y, Arnold SR, Ampofo K, Waterer GW, Levine M, Lindstrom S, Winchell JM, Katz JM, Erdman D, Schneider E, Hicks LA, McCullers JA, Pavia AT, Edwards KM, Finelli L, CDC EPIC Study TeamCommunity-acquired pneumonia requiring hospitalization among U.S. adults. N Engl J Med 2015;373:415–427.
-
-
Avni T, Bieber A, Green H, Steinmetz T, Leibovici L, Paul M.. Diagnostic accuracy of PCR alone and compared to urinary antigen testing for detection of Legionella spp.: a systematic review. Clin Microbiol 2016;54:401–411.
-
-
Uldum SA, Jensen JS, Søndergård-Andersen J, Lind K. Enzyme immunoassay for detection of immunoglobulin M (IgM) and IgG antibodies to Mycoplasma pneumoniae. J Clin Microbiol 1992;30:1198–1204.
-
-
Parrott GL, Kinjo T, Fujita J. A compendium for Mycoplasma pneumoniae. Front Microbiol 2016;7:513.
-
-
Loens K, Beck T, Ursi D, Overdijk M, Sillekens P, Goossens H, Ieven M. Evaluation of different nucleic acid amplification techniques for the detection of M. pneumoniae, C. pneumoniae and Legionella spp. in respiratory specimens from patients with community-acquired pneumonia. J Microbiol Methods 2008;73:257–262.
-
-
Syrjst H, Broas M, Suramo I, Ojala A, Lähde S. High-resolution computed tomography for the diagnosis of community-acquired pneumonia. Clin Infect Dis 1998;27:358–363.
-
-
Arenas-Jiménez J, Alonso-Charterina S, Sánchez-Payá J, Fernández-Latorre F, Gil-Sánchez S, Lloret-Llorens M.. Evaluation of CT findings for diagnosis of pleural effusions. Eur Radiol 2000;10:681–690.
-
-
Miller WT Jr, Mickus TJ, Barbosa E Jr, Mullin C, Van Deerlin VM, Shiley KT. CT of viral lower respiratory tract infections in adults: comparison among viral organisms and between viral and bacterial infections. Am J Roentgenol 2011;197:1088–1095.
-
-
Volpicelli G, Elbarbary M, Blaivas M, Lichtenstein DA, Mathis G, Kirkpatrick AW, Melniker L, Gargani L, Noble VE, Via G, Dean A, Tsung JW, Soldati G, Copetti R, Bouhemad B, Reissig A, Agricola E, Rouby JJ, Arbelot C, Liteplo A, Sargsyan A, Silva F, Hoppmann R, Breitkreutz R, Seibel A, Neri L, Storti E, Petrovic T, International Liaison Committee on Lung Ultrasound (ILC-LUS) for International Consensus Conference on Lung Ultrasound (ICC-LUS)International evidence-based recommendations for point-of-care lung ultrasound. Intensive Care Med 2012;38:577–591.
-
-
Menéndez R, Córdoba J, de La Cuadra P, Cremades MJ, López-Hontagas JL, Salavert M, Gobernado M. Value of the polymerase chain reaction assay in noninvasive respiratory samples for diagnosis of community-acquired pneumonia. Am J Respir Crit Care Med 1999;159:1868–1873.
-
-
Rosón B, Fernández-Sabé N, Carratalà J, Verdaguer R, Dorca J, Manresa F, Gudiol F. Contribution of a urinary antigen assay (Binax NOW) to the early diagnosis of pneumococcal pneumonia. Clin Infect Dis 2004;38:222–226.
-
-
Domínguez J, Galí N, Blanco S, Pedroso P, Prat C, Matas L, Ausina V.. Detection of Streptococcus pneumoniae antigen by a rapid immunochromatographic assay in urine samples. Chest 2001;119:243–249.
-
-
Gutiérrez F, Masiá M, Rodríguez JC, Ayelo A, Soldán B, Cebrián L, Mirete C, Royo G, Hidalgo AM. Evaluation of the immunochromatographic Binax NOW assay for detection of Streptococcus pneumoniae urinary antigen in a prospective study of community-acquired pneumonia in Spain. Clin Infect Dis 2003;36:286–292.
-
-
Navarro D, García-Maset L, Gimeno C, Escribano A, García-de-Lomas J, Spanish Pneumococcal Infection Study NetworkPerformance of the Binax NOW Streptococcus pneumoniae urinary antigen assay for diagnosis of pneumonia in children with underlying pulmonary diseases in the absence of acute pneumococcal infection. J Clin Microbiol 2004;42:4853–4855.
-
-
Smith MD, Derrington P, Evans R, Creek M, Morris R, Dance DA, Cartwright K. Rapid diagnosis of bacteremic pneumococcal infections in adults by using the Binax NOW Streptococcus pneumoniae urinary antigen test: a prospective, controlled clinical evaluation. J Clin Microbiol 2003;41:2810–2813.
-
-
Helbig JH, Uldum SA, Lück PC, Harrison TG. Detection of Legionella pneumophila antigen in urine samples by the BinaxNOW immunochromatographic assay and comparison with both Binax Legionella urinary enzyme immunoassay (EIA) and Biotest Legionella urin antigen EIA. J Med Microbiol 2001;50:509–516.
-
-
Alvarez J, Domínguez A, Sabrià M, Ruiz L, Torner N, Cayla J, Barrabeig I, Sala MR, Godoy P, Camps N, Minguell S. Impact of the Legionella urinary antigen test on epidemiological trends in community outbreaks of legionellosis in Catalonia, Spain, 1990-2004. Int J Infect Dis 2009;13:e365–70.
-
-
Song JH, Jung KS, Kang MW, Kim DJ, Pai H, Suh GY, Shim TS, Ahn JH, Ahn CM, Woo JH, Lee NY, Lee DG, Lee MS, Lee SM, Lee YS, Lee H, Chung DR. A Joint Committee for CAP Treatment Guideline. Treatment guidelines for community-acquired pneumonia in Korea: An evidence-based approach to appropriate antimicrobial therapy. Tuberc Respir Dis 2009;67:281–301.
-
-
España PP, Capelastegui A, Gorordo I, Esteban C, Oribe M, Ortega M, Bilbao A, Quintana JM. Development and validation of a clinical prediction rule for severe community-acquired pneumonia. Am J Respir Crit Care Med 2006;174:1249–1256.
-
-
España PP, Capelastegui A, Quintana JM, Soto A, Gorordo I, García-Urbaneja M, Bilbao A. A prediction rule to identify allocation of inpatient care in community-acquired pneumonia. Eur Respir J 2003;21:695–701.
-
-
Kim HI, Kim SW, Chang HH, Cha SI, Lee JH, Ki HK, Cheong HS, Yoo KH, Ryu SY, Kwon KT, Lee BK, Choo EJ, Kim DJ, Kang CI, Chung DR, Peck KR, Song JH, Suh GY, Shim TS, Kim YK, Kim HY, Moon CS, Lee HK, Park SY, Oh JY, Jung SI, Park KH, Yun NR, Yoon SH, Sohn KM, Kim YS, Jung KS. Mortality of community-acquired pneumonia in Korea: assessed with the pneumonia severity index and the CURB-65 score. J Korean Med Sci 2013;28:1276–1282.
-
-
Niederman MS, Mandell LA, Anzueto A, Bass JB, Broughton WA, Campbell GD, Dean N, File T, Fine MJ, Gross PA, Martinez F, Marrie TJ, Plouffe JF, Ramirez J, Sarosi GA, Torres A, Wilson R, Yu VL, American Thoracic SocietyGuidelines for the management of adults with community-acquired pneumonia. Diagnosis, assessment of severity, antimicrobial therapy, and prevention. Am J Respir Crit Care Med 2001;163:1730–1754.
-
-
Chalmers JD, Taylor JK, Mandal P, Choudhury G, Singanayagam A, Akram AR, Hill AT. Validation of the Infectious Diseases Society of America/American Thoratic Society minor criteria for intensive care unit admission in community-acquired pneumonia patients without major criteria or contraindications to intensive care unit care. Clin Infect Dis 2011;53:503–511.
-
-
Charles PG, Wolfe R, Whitby M, Fine MJ, Fuller AJ, Stirling R, Wright AA, Ramirez JA, Christiansen KJ, Waterer GW, Pierce RJ, Armstrong JG, Korman TM, Holmes P, Obrosky DS, Peyrani P, Johnson B, Hooy M, Australian Community-Acquired Pneumonia Study CollaborationGrayson ML. SMART-COP: a tool for predicting the need for intensive respiratory or vasopressor support in community-acquired pneumonia. Clin Infect Dis 2008;47:375–384.
-
-
Arnold FW, Summersgill JT, Lajoie AS, Peyrani P, Marrie TJ, Rossi P, Blasi F, Fernandez P, File TM Jr, Rello J, Menendez R, Marzoratti L, Luna CM, Ramirez JA, Community-Acquired Pneumonia Organization (CAPO) InvestigatorsA worldwide perspective of atypical pathogens in community-acquired pneumonia. Am J Respir Crit Care Med 2007;175:1086–1093.
-
-
Eliakim-Raz N, Robenshtok E, Shefet D, Gafter-Gvili A, Vidal L, Paul M, Leibovici L. Empiric antibiotic coverage of atypical pathogens for community-acquired pneumonia in hospitalized adults. Cochrane Database Syst Rev 2012;(9):CD004418
-
-
Postma DF, van Werkhoven CH, van Elden LJ, Thijsen SF, Hoepelman AI, Kluytmans JA, Boersma WG, Compaijen CJ, van der Wall E, Prins JM, Oosterheert JJ, Bonten MJ, CAP-START Study GroupAntibiotic treatment strategies for community-acquired pneumonia in adults. N Engl J Med 2015;372:1312–1323.
-
-
Yu VL, Chiou CC, Feldman C, Ortqvist A, Rello J, Morris AJ, Baddour LM, Luna CM, Snydman DR, Ip M, Ko WC, Chedid MB, Andremont A, Klugman KP, International Pneumococcal Study GroupAn international prospective study of pneumococcal bacteremia: correlation with in vitro resistance, antibiotics administered, and clinical outcome. Clin Infect Dis 2003;37:230–237.
-
-
Noreddin AM, Marras TK, Sanders K, Chan CK, Hoban DJ, Zhanel GG. Pharmacodynamic target attainment analysis against Streptococcus pneumoniae using levofloxacin 500 mg, 750 mg and 1000 mg once daily in plasma (P) and epithelial lining fluid (ELF) of hospitalized patients with community acquired pneumonia (CAP). Int J Antimicrob Agents 2004;24:479–484.
-
-
Garin N, Genné D, Carballo S, Chuard C, Eich G, Hugli O, Lamy O, Nendaz M, Petignat PA, Perneger T, Rutschmann O, Seravalli L, Harbarth S, Perrier A. β-lactam monotherapy vs β-lactam-macrolide combination treatment in moderately severe community-acquired pneumonia: a randomized noninferiority trial. JAMA Intern Med 2014;174:1894–1901.
-
-
Woodhead M, Blasi F, Ewig S, Garau J, Huchon G, Ieven M, Ortqvist A, Schaberg T, Torres A, van der Heijden G, Read R, Verheij TJ, Joint Taskforce of the European Respiratory Society and European Society for Clinical Microbiology and Infectious DiseasesGuidelines for the management of adult lower respiratory tract infections--full version. Clin Microbiol Infect 2011;17 Suppl 6:E1–59.
-
-
Torres A, Garau J, Arvis P, Carlet J, Choudhri S, Kureishi A, Le Berre MA, Lode H, Winter J, Read RC. MOTIV (MOxifloxacin Treatment IV) Study Group. Moxifloxacin monotherapy is effective in hospitalized patients with community-acquired pneumonia: the MOTIV study--a randomized clinical trial. Clin Infect Dis 2008;46:1499–1509.
-
-
Woodhead M, Blasi F, Ewig S, Huchon G, Ieven M, Ortqvist A, Schaberg T, Torres A, van der Heijden G, Verheij TJ, European Respiratory SocietyEuropean Society of Clinical Microbiology and Infectious Diseases. Guidelines for the management of adult lower respiratory tract infections. Eur respir J 2005;26:1138–1180.
-
-
Schönwald S, Skerk V, Petricevic I, Car V, Majerus-Misic L, Gunjaca M. Comparison of three-day and five-day courses of azithromycin in the treatment of atypical pneumonia. Eur J Clin Microbiol Infect Dis 1991;10:877–880.
-
-
Ramirez JA, Vargas S, Ritter GW, Brier ME, Wright A, Smith S, Newman D, Burke J, Mushtaq M, Huang A. Early switch from intravenous to oral antibiotics and early hospital discharge: a prospective observational study of 200 consecutive patients with community-acquired pneumonia. Arch Intern Med 1999;159:2449–2454.
-
-
Castro-Guardiola A, Viejo-Rodríguez AL, Soler-Simon S, Armengou-Arxé A, Bisbe-Company V, Peñarroja-Matutano G, Bisbe-Company J, García-Bragado F. Efficacy and safety of oral and early-switch therapy for community-acquired pneumonia: a randomized controlled trial. Am J Med 2001;111:367–374.
-
-
Nathan RV, Rhew DC, Murray C, Bratzler DW, Houck PM, Weingarten SR. In-hospital observation after antibiotic switch in pneumonia: a national evaluation. Am J Med 2006;119:512.e1–512.e7.
-
-
Halm EA, Fine MJ, Kapoor WN, Singer DE, Marrie TJ, Siu AL. Instability on hospital discharge and the risk of adverse outcomes in patients with pneumonia. Arch Intern Medicine 2002;162:1278–1284.
-
-
O'Driscoll BR, Howard LS, Davison AG. BTS guideline for emergency oxygen use in adult patients. Thorax 2008;63 Suppl 6:vi1–68.
-
-
Mismetti P, Laporte-Simitsidis S, Tardy B, Cucherat M, Buchmüller A, Juillard-Delsart D, Decousus H. Prevention of venous thromboembolism in internal medicine with unfractionated or low-molecular-weight heparins: a meta-analysis of randomised clinical trials. Thromb Haemost 2000;83:14–19.
-
-
Baddour LM, Yu VL, Klugman KP, Feldman C, Ortqvist A, Rello J, Morris AJ, Luna CM, Snydman DR, Ko WC, Chedid MB, Hui DS, Andremont A, Chiou CC, International Pneumococcal Study GroupCombination antibiotic therapy lowers mortality among severely ill patients with pneumococcal bacteremia. Am J Respir Crit Care Med 2004;170:440–444.
-
-
Martínez JA, Horcajada JP, Almela M, Marco F, Soriano A, García E, Marco MA, Torres A, Mensa J. Addition of a macrolide to a beta-lactam-based empirical antibiotic regimen is associated with lower in-hospital mortality for patients with bacteremic pneumococcal pneumonia. Clin Infect Dis 2003;36:389–395.
-
-
Weiss K, Low DE, Cortes L, Beaupre A, Gauthier R, Gregoire P, Legare M, Nepveu F, Thibert D, Tremblay C, Tremblay J. Clinical characteristics at initial presentation and impact of dual therapy on the outcome of bacteremic Streptococcus pneumoniae pneumonia in adults. Can Respir J 2004;11:589–593.
-
-
Meijvis SC, Hardeman H, Remmelts HH, Heijligenberg R, Rijkers GT, van Velzen-Blad H, Voorn GP, van de Garde EM, Endeman H, Grutters JC, Bos WJ, Biesma DH. Dexamethasone and length of hospital stay in patients with community-acquired pneumonia: a randomised, double-blind, placebo-controlled trial. Lancet 2011;377:2023–2030.
-
-
Torres A, Sibila O, Ferrer M, Polverino E, Menendez R, Mensa J, Gabarrús A, Sellarés J, Restrepo MI, Anzueto A, Niederman MS, Agustí C. Effect of corticosteroids on treatment failure among hospitalized patients with severe community-acquired pneumonia and high inflammatory response: a randomized clinical trial. JAMA 2015;313:677–686.
-
-
Blum CA, Nigro N, Briel M, Schuetz P, Ullmer E, Suter-Widmer I, Winzeler B, Bingisser R, Elsaesser H, Drozdov D, Arici B, Urwyler SA, Refardt J, Tarr P, Wirz S, Thomann R, Baumgartner C, Duplain H, Burki D, Zimmerli W, Rodondi N, Mueller B, Christ-Crain M. Adjunct prednisone therapy for patients with community-acquired pneumonia: a multicentre, double-blind, randomised, placebo-controlled trial. Lancet 2015;385:1511–1518.
-
-
Montón C, Ewig S, Torres A, El-Ebiary M, Filella X, Rañó A, Xaubet A. Role of glucocorticoids on inflammatory response in nonimmunosuppressed patients with pneumonia: a pilot study. Eur Respir J 1999;14:218–220.
-
-
Annane D, Sébille V, Charpentier C, Bollaert PE, François B, Korach JM, Capellier G, Cohen Y, Azoulay E, Troché G, Chaumet-Riffaud P, Bellissant E. Effect of treatment with low doses of hydrocortisone and fludrocortisone on mortality in patients with septic shock. JAMA 2002;288:862–871.
-
-
Bruns AH, Oosterheert JJ, Prokop M, Lammers JW, Hak E, Hoepelman AI. Patterns of resolution of chest radiograph abnormalities in adults hospitalized with severe community-acquired pneumonia. Clin Infec Dis 2007;45:983–991.
-
-
Menéndez R, Cavalcanti M, Reyes S, Mensa J, Martinez R, Marcos MA, Filella X, Niederman M, Torres A. Markers of treatment failure in hospitalised community acquired pneumonia. Thorax 2008;63:447–452.
-
-
Menéndez R, Martinez R, Reyes S, Mensa J, Polverino E, Filella X, Esquinas C, Martinez A, Ramirez P, Torres A.. Stability in community-acquired pneumonia: one step forward with markers? Thorax 2009;64:987–992.
-
-
Schuetz P, Wirz Y, Sager R, Christ-Crain M, Stolz D, Tamm M, Bouadma L, Luyt CE, Wolff M, Chastre J, Tubach F, Kristoffersen KB, Burkhardt O, Welte T, Schroeder S, Nobre V, Wei L, Bucher HC, Bhatnagar N, Annane D, Reinhart K, Branche A, Damas P, Nijsten M, de Lange DW, Deliberato RO, Lima SS, Maravić-Stojković V, Verduri A, Cao B, Shehabi Y, Beishuizen A, Jensen JS, Corti C, Van Oers JA, Falsey AR, de Jong E, Oliveira CF, Beghe B, Briel M, Mueller B. Procalcitonin to initiate or discontinue antibiotics in acute respiratory tract infections. Cochrane Database Syst Rev 2017:CD007498
-
-
de Jong E, van Oers JA, Beishuizen A, Vos P, Vermeijden WJ, Haas LE, Loef BG, Dormans T, van Melsen GC, Kluiters YC, Kemperman H, van den Elsen MJ, Schouten JA, Streefkerk JO, Krabbe HG, Kieft H, Kluge GH, van Dam VC, van Pelt J, Bormans L, Otten MB, Reidinga AC, Endeman H, Twisk JW, van de Garde EMW, de Smet AMGA, Kesecioglu J, Girbes AR, Nijsten MW, de Lange DW. Efficacy and safety of procalcitonin guidance in reducing the duration of antibiotic treatment in critically ill patients: a randomised, controlled, open-label trial. Lancet Infect Dis 2016;16:819–827.
-
-
Moberley S, Holden J, Tatham DP, Andrews RM. Vaccines for preventing pneumococcal infection in adults. Cochrane Database Syst Rev 2008:CD000422
-
-
Maruyama T, Taguchi O, Niederman MS, Morser J, Kobayashi H, Kobayashi T, D'Alessandro-Gabazza C, Nakayama S, Nishikubo K, Noguchi T, Takei Y, Gabazza EC. Efficacy of 23-valent pneumococcal vaccine in preventing pneumonia and improving survival in nursing home residents: double blind, randomised and placebo controlled trial. BMJ 2010;340:c1004.
-
-
Vila-Córcoles A, Ochoa-Gondar O, Hospital I, Ansa X, Vilanova A, Rodríguez T, Llor C, EVAN Study GroupProtective effects of the 23-valent pneumococcal polysaccharide vaccine in the elderly population: the EVAN-65 study. Clin Infect Dis 2006;43:860–868.
-
-
Mykietiuk A, Carratalà J, Domínguez A, Manzur A, Fernández-Sabé N, Dorca J, Tubau F, Manresa F, Gudiol F. Effect of prior pneumococcal vaccination on clinical outcome of hospitalized adults with community-acquired pneumococcal pneumonia. Eur J Clin Microbiol Infect Dis 2006;25:457–462.
-
-
Jackson LA, Neuzil KM, Whitney CG, Starkovich P, Dunstan M, Yu O, Nelson JC, Feikin DR, Shay DK, Baggs J, Carste B, Nahm MH, Carlone G. Safety of varying dosages of 7-valent pneumococcal protein conjugate vaccine in seniors previously vaccinated with 23-valent pneumococcal polysaccharide vaccine. Vaccine 2005;23:3697–3703.
-
-
Törling J, Hedlund J, Konradsen HB, Ortqvist A. Revaccination with the 23-valent pneumococcal polysaccharide vaccine in middle-aged and elderly persons previously treated for pneumonia. Vaccine 2003;22:96–103.
-
-
Almirall J, Bolíbar I, Serra-Prat M, Roig J, Hospital I, Carandell E, Agustí M, Ayuso P, Estela A, Torres A, Community-Acquired Pneumonia in Catalan Countries (PACAP) Study GroupNew evidence of risk factors for community-acquired pneumonia: a population-based study. Eur Respira J 2008;31:1274–1284.
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MeSH Terms
Tables
ORCID IDs
Funding Information
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Korea Centers for Disease Control and Prevention
2017-E21002-00