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Emergence of community-acquired meticillin-resistant Staphylococcus aureus strain USA300 as a cause of necrotising community-onset pneumonia
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Emergence of community-acquired meticillin-resistant Staphylococcus aureus strain USA300 as a cause of necrotising community-onset pneumonia Alicia I Hidron, Cari E Low, Eric G Honig, Henry M Blumberg Lancet Infect Dis 2009; 9: 384–92 Division of Infectious Diseases (A I Hidron MD, H M Blumberg MD), Division of Medicine (C E Low MD), and Division of Pulmonary and Critical Care Medicine (E G Honig MD), Department of Medicine, Emory University School of Medicine, Atlanta, GA, USA; and Epidemiology Department, Grady Memorial Hospital, Atlanta (H M Blumberg) Correspondence to: Alicia I Hidron, Division of Infectious Diseases, Emory University School of Medicine, 49 Jesse Hill Jr Drive, Atlanta, GA 30303, USA [email protected]
Meticillin-resistant Staphylococcus aureus (MRSA), usually known as a nosocomial pathogen, has emerged as the predominant cause of skin and soft-tissue infections in many communities. Concurrent with the emergence of community-acquired MRSA (CA-MRSA), there have been increasing numbers of reports of community-acquired necrotising pneumonia in young patients and others without the classic health-care-associated risk factors. Community-onset necrotising pneumonia due to CA-MRSA is now recognised as an emerging clinical entity with distinctive clinical features and substantial morbidity and mortality. A viral prodrome (eg, influenza or influenza-like illness) followed by acute onset of shortness of breath, sepsis, and haemoptysis is the most frequent clinical presentation. The best treatment of this partly toxin-mediated disease has not been clearly defined. Whereas cases of CA-MRSA pneumonia have now been reported from almost every continent, the overall burden of disease of this emerging syndrome remains incompletely described. We report two related cases of community-onset pneumonia due to the MRSA USA300 genotype and review the literature regarding the emergence of CA-MRSA pneumonia.
Introduction Staphylococcus aureus has long been recognised as a cause, albeit an infrequent one, of community-acquired pneumonia.1 Estimated to represent 1–10% of community-acquired pneumonia and 20–50% of nosocomial pneumonia,2–5 it had been uncommon in healthy children and adults from high-income countries except when seen in the post-influenza setting.1,6–8 Historically, pneumonia due to meticillin-resistant S aureus (MRSA) has been confined to health-care settings, representing 10–20% of pathogens that cause hospital and ventilator-associated pneumonia.5 In 1999, four paediatric deaths were reported due to community-acquired MRSA (CA-MRSA) necrotising
pneumonia; these infections were caused by strains that differed from typical nosocomial strains in their antibiotic susceptibility patterns and pulsed field gel electrophoresis (PFGE) characteristics.9 3 years later, an association was found between the presence of Panton-Valentine leucocidin (PVL)—a staphylococcal toxin known to be associated with tissue necrosis—and this previously described syndrome of acute haemorrhagic necrotising pneumonia among otherwise healthy patients presenting with staphylococcal pneumonia from the community.10 Since then, many case reports and series have been described.9–30 However, the overall incidence of CA-MRSA pneumonia remains unknown. We describe two related cases of CA-MRSA necrotising pneumonia, and review the origins, pathophysiology, clinical features, outcomes, and treatment options for this emerging entity.
Case presentation Case 1
Figure 1: Chest radiograph of case 1 on admission Bilateral opacities with a right middle lobe dense consolidation are shown.
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A 45-year-old white woman presented to the hospital during the height of the influenza season with complaints of shortness of breath, fever, chills, and a cough that produced brown sputum of 1 week’s duration. She denied haemoptysis, but gave a history of recurrent folliculitis for the past several months. She reported a preceding influenza-like illness (fever, myalgias, headache, and upper respiratory symptoms) 5 days before the onset of her current symptoms. Her medical history was notable for asthma, hypertension, hypothyroidism, adrenal insufficiency, and methadone maintenance for previous opiate dependence. She denied a history of alcohol use, but said that she smoked cigarettes. She had not received an influenza vaccination. On admission, her blood pressure was 166/99 mm Hg, pulse rate was 103 beats per min, respiratory rate was 19 breaths per min, and temperature was 38·2°C. She www.thelancet.com/infection Vol 9 June 2009
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seemed to be in moderate respiratory distress. On cardiopulmonary examination she was found to have diffuse rhonchi and crackles, but no heart murmurs. No skin lesions were noted. The rest of her examination was unrevealing. Laboratory data included a white blood cell count of 8·7×10⁹ cells per L (87% neutrophils), haematocrit of 43%, and platelet count of 299×10⁹/L. Her chest radiograph showed bilateral opacities with a right middle lobe dense consolidation (figure 1). The patient was admitted with presumed communityacquired pneumonia. Several hours later, her dyspnoea worsened, and she required intubation and mechanical ventilatory support. Broad spectrum antibiotic coverage with piperacillin–tazobactam and vancomycin were initiated after initial blood cultures were drawn. HIV serology and a legionella urinary antigen test were negative. Multiple sets of blood cultures (including the initial set obtained on admission) were culture negative. A culture of respiratory secretions obtained by mini bronchoalveolar lavage from the day of admission grew MRSA that was resistant to β-lactam antibiotics and erythromycin, but susceptible to clindamycin, fluoroquinolones, rifampicin, co-trimoxazole (trimethoprim-sulfamethoxazole), and tetracycline. The D-test for inducible clindamycin resistance was negative. PFGE by use of methods previously described revealed the isolate to be the USA300 genotype of MRSA.31 Other molecular tests by PCR showed that the isolate contained the genes for PVL and the staphylococcal chromosomal cassette mec (SCCmec) element type IV.32,33 On hospital day 4, the patient was continuing to require ventilatory support with 60–70% inspired oxygen. A bronchoscopy done on day 6 of her hospital stay revealed haemorrhagic vesicles (figure 2). An infectious diseases consultation was obtained on that day; clindamycin was added to her antibiotic regimen, vancomycin was continued, and piperacillin–tazobactam was discontinued. A repeat bronchoscopy on day 11 (5 days after the addition of clindamycin) showed resolution of these bronchial lesions. The patient began to improve clinically within 48 h after the addition of clindamycin and was extubated on hospital day 11. Respiratory herpes simplex virus culture and influenza cultures were negative. After 23 days in hospital, the patient eventually recovered and was discharged home. 2 years after presentation, the patient remains with mild residual dyspnoea on exertion, which has been attributed to secondary lung scarring; she is otherwise symptom free.
Figure 2: Bronchoscopy of case 1 on hospital day 6 Haemorrhagic vesicles are shown.
current symptoms, and a history of recurrent episodes of folliculitis. On admission, his blood pressure was 107/65 mm Hg, pulse rate was 82 beats per min, respiratory rate was 16 breaths per min, oxygen saturation was 96% on room air, and temperature was 37·4°C. Lung examination revealed diffuse crackles with left-sided egophony. No heart murmurs or skin lesions were noted. The rest of his physical examination was normal. Laboratory tests revealed a white blood cell count of 17·9×10¹² cells per L (89% neutrophils), a haematocrit of 37%, and a platelet count of 283×10⁹/L. A CT scan of the chest revealed a multi-loculated cystic consolidation in the left upper lobe with cavitations and a right upper lobe consolidation (figure 3). HIV serological and legionella urinary antigen tests were negative.
Case 2 The partner of case 1, a 36-year-old white man with a past medical history of schizophrenia, hepatitis C virus infection, and methadone maintenance for previous opiate dependence, was admitted to hospital 5 days later with similar symptoms (shortness of breath, fever, chills, and productive cough). He also reported a preceding influenza-like illness 1 week before the onset of his www.thelancet.com/infection Vol 9 June 2009
Figure 3: Chest CT scan of case 2 Left lower lobe, multi-loculated consolidation with cavitations are shown.
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Treatment with ceftriaxone and doxycycline was initiated after initial blood cultures had been drawn. However, due to persistent fevers, antibiotics were switched to vancomycin and piperacillin–tazobactam on hospital day 3. An infectious diseases consultation was obtained on hospital day 7 because of persistent fever, prompting the addition of clindamycin to the antibiotic regimen; vancomycin was continued and piperacillin–tazobactam was discontinued at this time. Three sets of blood cultures obtained on separate days were negative (including the initial set drawn on admission). Bronchoscopy was done on hospital day 7 and a bronchoalveolar lavage culture grew MRSA, which had the same antibiogram as the isolate recovered from case 1. Molecular studies revealed the isolate recovered from this patient was identical to that recovered from his partner (MRSA USA300, SCCmec IV, and PVL positive). The patient had resolution of fever and symptomatic improvement within 48 h of clindamycin initiation. He was discharged after 14 days to complete a 21-day course of antibiotics. 2 years after this episode, he remains in good health.
Discussion and review of the published work CA-MRSA Meticillin resistance in S aureus emerged roughly 45 years ago, but MRSA infections were primarily confined to the health care setting until recently.9,20,34–36 The first report of community-onset infections with MRSA came from Australia in 1993.37 In the USA, reports of CA-MRSA necrotising pneumonia in healthy children appeared in the late 1990s,9 and were followed by reports of outbreaks of CA-MRSA skin and soft-tissue infections among prison inmates, homosexual men, native Americans, and sports teams.9,34–36,38–41 Transmission of CA-MRSA infections among these high-risk groups, from infected patients to household contacts, and transmission of nasal colonisation within families were then reported.34–36,42,43 As a result, CA-MRSA infections are no longer restricted to certain risk groups or to the geographic areas where outbreaks first occurred. They now occur widely both in the community as well as health care facilities, and have been reported in nearly every continent.44–47 The spectrum of disease caused by CA-MRSA occurs worldwide and primarily encompasses skin and soft-tissue infections,44,47–50 but deep-seated infections such as pyomyositis, osteomyelitis, septic arthritis, and severe infections such as necrotising pneumonia and bacteraemia have also been reported.51 The prevalence and incidence of invasive CA-MRSA infections probably varies geographically. In the USA, for example, 6% of CA-MRSA infections cause invasive disease (pneumonia accounting for 2% overall),52 and 14% of all invasive MRSA infections are due to CA-MRSA (14% of these invasive infections are CA-MRSA pneumonia).53 386
Differences between health-care-associated MRSA and CA-MRSA Genotypic characterisation of MRSA isolates by lineage, the type of genetic element that encodes meticillin resistance, and toxin production profile are important for epidemiological purposes to differentiate between health-care-associated MRSA (HA-MRSA) and CA-MRSA. The predominant lineage of MRSA isolates, as characterised by multilocus sequence typing (MLST) or PFGE, and toxin gene expression varies geographically, whereas SCCmec does not. Typing for SCCmec, the mobile genetic element that carries the mecA gene that encodes meticillin resistance,54,55 is usually done worldwide to describe MRSA isolates. SCCmec is classified into types I–VII (based on the mec and ccr complex) and each type is further classified into subtypes based on differences in the junkyard (J) region.56,57 HA-MRSA usually carry SCCmec types that are larger (types I, II, and III),54 whereas CA-MRSA isolates carry a much smaller staphylococcal cassettes (SCCmec types IV, V, or VII).57–59 The smaller size of SCCmec elements in CA-MRSA isolates may represent an evolutionary advantage, allowing horizontal spread of this element across bacterial species.58 However, the larger SCCmec elements associated with HA-MRSA isolates represent additional carriage of non-β-lactam resistance genes that probably confer their ability to survive in the hospital environment.58 With the exception of SCCmec VI, which seems to be confined to one geographic area (Portugal), the different MRSA SCCmec types associated to either HA-MRSA or CA-MRSA have all been initially isolated from a specific region and subsequently spread worldwide.57 Characterisation of the genetic lineage of MRSA can be done mainly by MLST or PFGE. Outside the USA, description of MRSA isolates is done by their sequence type based on MLST. In Europe, the predominant CA-MRSA clone reported has been sequence type ST80,46,60–62 whereas ST30 is an important clone in Asia and Oceania.46,62–64 In Denmark, for example, ST80 causes 60% of community-onset infections compared with 28% of health-care-associated infections.49 In the USA, molecular typing has often been done using PFGE, which has shown that USA300, USA400, USA1000, and USA1100 (which correlate with sequence types ST8, ST1, ST59, and ST30, respectively) are the most common genotypes recovered among patients with CA-MRSA infections,31,46,65 with MRSA USA300 accounting for up to 97–99% of cases.44,47 By contrast, traditional HA-MRSA genotypes in the USA most commonly include USA100 and USA200.31 The presence of PVL genes is more common among CA-MRSA than HA-MRSA isolates.32,46 However, the prevalence of PVL among CA-MRSA isolates varies geographically. In the USA, PVL genes are present in 40–95% of CA-MRSA isolates and nearly all USA300 www.thelancet.com/infection Vol 9 June 2009
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isolates contain PVL.47,66 However, the prevalence of PVL-positive CA-MRSA in the UK is significantly lower than in the USA,66 and in Japan, Korea, and Western Australia, the predominant CA-MRSA clones are PVL negative.67–69 Finally, from a clinical standpoint, CA-MRSA infections most commonly involve skin and soft tissues,34–36,40,44,70 and tend to affect younger patients than does HA-MRSA.9,34–36,38–41,71 CA-MRSA isolates are also characteristically susceptible to a greater number of non-β-lactam antibiotics such as clindamycin, macrolides, co-trimoxazole, tetracyclines, and fluoroquinolones.52,71 However, carriage of antimicrobial resistance genes may vary by the sequence type of CA-MRSA isolate and therefore susceptibility to these non-β-lactam antibiotics cannot be implied.62
ventilatory support (table). By contrast with other bacterial pneumonias in which leucocytosis is a prominent feature, leucopenia can be observed in a substantial proportion of cases and has been found to be one of the predictors of poor outcome (in addition to erythroderma and airway bleeding; table).14–16,19 More than a quarter of patients with CA-MRSA pneumonia are reported to have multilobar infiltrates and/or cavitation in imaging studies (table),9,12,14–18,20 which correlates with pathological examination that usually reveals a haemorrhagic necrotising pneumonia with high bacterial counts.9,11,14,16,20,23,72 Substantial morbidity and mortality have thus been reported due to CA-MRSA pneumonia, but mortality varies widely.10–16,18,20 However, despite reporting bias, many reports from the USA and Europe have noted mortalities greater than 50%.9,12,14
Clinical presentation, laboratory findings, radiological features, and outcomes of patients with CA-MRSA pneumonia
Pathophysiology
CA-MRSA pneumonia generally affects young and previously healthy patients.9–13,15–21,25,27–30,32,72 Severe cases of CA-MRSA pneumonia have been reported during influenza seasons, or associated with a preceding influenza illness in 33–71% of patients.12,20 Clinical presentation is usually that of a severe pneumonia with high fever, hypotension, and haemoptysis followed by rapid progression to septic shock and requirement for Patients Patients Median age of patients with (n) with pneumonia MRSA (years) (n)
Number and percentage of patients with condition among patients with community-acquired Staphylococcus aureus pneumonia
Haemoptysis
CDC (1999)9
The initial epithelial damage in S aureus pneumonia has historically been attributed to a prodromal viral infection.11,14,15,18–20 S aureus does not bind to intact airway epithelium but has an increased affinity for basement membrane type I and II collagen when exposed,73 and adheres to cell monolayers infected with influenza A virus to a greater degree than to uninfected cell monolayers.74 PVL, a S aureus toxin that creates pores on host cell membranes, may mediate this initial injury.75,76 However, S aureus supernatants are able to disrupt the
Influenza-like prodrome
Leucopenia Shock
Ventilatory Multilobar Necrotising PVL positive pneumonia* support infiltrates on imaging
Mortality
4
4
4
1 (25%)
··
··
4 (100%)
2 (50%)†
1 (25%)
4 (100%)
··
Naimi et al (2001)10
12
12
16‡
··
··
··
1 (8%)
1 (8%)
··
··
··
Gillet et al (2002)11
16§
1
15
6 (38%)
··¶
13 (81%)
12 (75%)
10 (63%)
3 (19%)||
Dufour et al (2002)12
2
2
42
··
··
··
··
··
··
2 (100%)
2 (100%)
2 (100%)
Mongkolrattanothai et al (2003)13
4
2
··
··
··
4 (100%)
··
··
··
4 (100%)
1 (25%) 2 (66%)
0·7
12 (75%)
16 (100%)
4 (100%) 1 (8%) 12 (75%)
Boussaud et al (2003)14
3
1
38
3 (100%)
1 (33%)
3 (100%)
3 (100%)
3 (100%)
3 (100%)
1 (33%)||
3 (100%)
Francis et al (2005)15
4
4
32
3 (75%)
2 (50%)
3 (75%)
4 (100%)
4 (100%)
4 (100%)
4 (100%)
4 (100%)
1 (25%)
23
21
··
··
··
··
··
··
3 (13%)
23 (100%)**
3 (13%)
··
3 (75%)
Gonzalez et al (2005)16 Micek et al (2005)17
4
Hageman et al (2006)18 17††
2·1
4
40
··
3 (75%)
15
21
··
12 (71%)
Gillet et al (2007)19
50
6
CDC (2007)20
10
10
14·5¶¶ 17·5
22 (44%) ··
33 (67%)|||| 6 (60%)
4 (25%)‡‡ 16 (93%) 26 (54%)*** ··
·· ··
3 (75%)
2 (50%)
2 (50%)
8 (50%)‡‡
4 (25%)‡‡
4 (25%)‡‡
11 (85%)§§
5 (29%)
38 (79%)
··
50 (100%)
28 (56%)
7 (70%)
··
10 (100%)
6 (60%)
39 (78%)*** ··
4 (100%)
0
CDC=Centers for Disease Control and Prevention; ··=data not available. *As shown by pathology or radiographic imaging. †The other two patients died before ventilatory support. ‡All community-acquired MRSA (CA-MRSA) infections (median age for cases of pneumonia was not specified). §Panton-Valentine leucocidin (PVL)-positive Staphylococcus aureus community-acquired pneumonia cases (16 PVL-positive vs 36 PVL-negative). ¶Median number of patients with leucopenia not reported, but median nadir leucocyte count was 1·85 cells×109/L. ||Data only available for the percentage of patients shown and may not indicate the total number of patients with this condition. **100% of CA-MRSA pneumonia isolates were PVL positive and 78% of meticillin-sensitive S aureus isolates were PVL positive. ††Includes four patients described by Frazee et al.21 ‡‡Data available for 16 patients. §§Data available for 13 patients. ¶¶All patients with PVL-positive S aureus pneumonia. ||||Data available for 49 patients. ***Data available for 48 patients.
Table: Demographics, clinical characteristics, laboratory and radiology findings, and clinical outcomes of patients with community-acquired Staphylococcus aureus pneumonia
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integrity of the airway epithelium, whereas recombinant PVL alone cannot.73 Thus, either pre-existing airway damage is required or an unknown staphylococcal exotoxin must mediate the initial epithelial damage for bacterial adhesion to take place. The inflammatory cascade is then mediated by binding of protein A to a receptor for tumour necrosis factor (TNFR1), which is widely distributed in the airway epithelium.77 Protein A is a major staphylococcal surface protein that has been implicated in pathogenicity in other infection models.78 It induces production of interleukin 8 (a polymorphonuclear neutrophil chemokine), binds to TNFR1, and causes the receptor’s mobilisation and shedding to the epithelial surface; the shed receptor binds tumour necrosis factor and protein A to generate a negative feedback loop and protects the host’s airway from further damage caused by the inflammatory cascade.77 This protein A–TNFR1 pathway has been shown to mediate the inflammatory response and virulence in murine models of pneumonia.77 Both TNFR1-null mice and mice infected with protein A-null mutant S aureus had substantially less pneumonia, bacteraemia, and mortality.77
Role of PVL and other virulence factors The staphylococcal toxin that has received the most interest is PVL, which is present in most CA-MRSA isolates but is rarely (<5%) present in HA-MRSA isolates.32,46 PVL has been shown to cause lysis and apoptosis of neutrophils,79 tissue necrosis,76 and has been found in the pulmonary lesions in murine models of pneumonia.79,80 Its role as a potential virulence factor in severe pneumonia has been postulated since 2002.10 Patients with community-onset pneumonia who harbour PVL-positive S aureus isolates were found to have more sepsis and haemoptysis (probably as a surrogate marker of the degree of necrosis),18 and higher mortality. However, only recently has its role in the pathogenesis of invasive S aureus infections been studied in detail.80 In a murine model of acute primary MRSA pneumonia, mice infected with the PVL-positive strains showed evidence of inflammation and tissue necrosis compared with neutrophil infiltration alone for mice infected with PVL-negative strains.80 When plasmid-encoded PVL was introduced to the PVL-negative strains, massive tissue damage and substantial mortality was observed within 24 h. In addition, administration of the toxin components LukS-PV and LukF-PV caused tissue necrosis and mortality in a dose-dependent fashion. PVL was also shown to induce the expression of protein A and downregulate the expression of secreted proteins.80 Thus, the ability of PVL to lyse neutrophils and boost the inflammatory cascade could partly explain the progressive tissue necrosis observed. Despite these observations, PVL’s direct role in the pathogenesis of CA-MRSA infections has been under debate.81 Relative insensitivity of murine poly388
morphonuclear leucocytes to the lytic effect of PVL has been recognised compared with that of human cells, making controversial the findings of mouse model-based studies. By contrast with previous findings, a rabbit model failed to show PVL’s contribution to CA-MRSA virulence by altering global gene or protein regulatory networks of S aureus.82 In addition, in murine sepsis and abscess models, PVL-positive strains have been shown to be as virulent as PVL-negative strains.83 The quantity of PVL produced in vitro from CA-MRSA strains obtained from patients with clinical infections also did not correlate with disease severity.84 Other virulence factors have also been postulated as responsible for mediating the virulence of this organism.81,85 For example, production of phenol-soluble modulins has been found to be higher in CA-MRSA than in HA-MRSA isolates. These toxins have been shown to recruit, activate, and lyse neutrophils; loss of their expression was found to reduce the virulence of CA-MRSA USA300 and USA400 strains in murine models of bacteraemia and abscess.85 Thus, although some data suggest an important pathogenetic role of PVL in MRSA pneumonia, debate remains about the importance of this toxin in the pathogenesis of CA-MRSA pneumonia or whether PVL is merely a marker of CA-MRSA infections.
Treatment The use of vancomycin or linezolid has been recommended for empirical treatment of communityacquired pneumonia in cases in which CA-MRSA is a consideration.86 However, reported treatment failures for MRSA infections with minimum inhibitory concentrations (MICs) of vancomycin in both the susceptible and non-susceptible range remain an important concern.87–89 Whether optimisation of vancomycin pharmacokinetic parameters will improve outcomes for patients with MRSA pneumonia is not clear,90 but the American Thoracic Society/Infectious Disease Society of America guidelines for pneumonia recommend aiming for vancomycin trough concentrations of 15–20 mg/mL.86 Responses in patients with MRSA bacteraemia, for example, have been found to be better among those with isolates that have vancomycin MICs of at least 0·5 μg/mL compared with those with 1–2 μg/mL.91 Slightly contrasting with this observation, patients with MRSA pneumonia who attained vancomycin serum trough concentrations four times the MIC had improved responses at 72 h but not at the end of therapy.92 The optimum treatment for nosocomial and CA-MRSA pneumonia thus remains incompletely defined because of the lack of prospective clinical trials.86,90 Claims that linezolid is superior to vancomycin for the treatment of nosocomial MRSA pneumonia have been controversial,93 and criticised due to use of subgroup or post-hoc analysis.94,95 Ongoing prospective trials comparing linezolid versus vancomycin for the treatment of MRSA pneumonia will hopefully address and resolve this issue. www.thelancet.com/infection Vol 9 June 2009
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Among other available agents with MRSA activity, daptomycin should not be used for the treatment of staphylococcal pulmonary infections because the drug’s activity is inhibited by pulmonary surfactant and clinical data suggest that it is inferior to other antibiotics in the treatment of community-acquired pneumonia.96 The lack of data on the efficacy of tigecycline for MRSA pneumonia limit the use of this drug.90 Finally, the role of newer agents, including enhanced glycopeptides (dalbavancin, oritavancin, and telavancin) and anti-MRSA cephalosporins (ceftobiprole and ceftaroline fosamil), in the treatment of these infections will need to be studied in prospective trials before any recommendations on their use can be made.90,97 Concomitant use of antibiotics that suppress toxin production has been advocated for the treatment of severe and invasive CA-MRSA infections including pneumonia.98 The rationale for their use in CA-MRSA pneumonia includes (1) the presumed role of PVL (and perhaps other toxins) in pathogenesis, and (2) the striking morbidity and mortality observed. For example, clindamycin has been shown to decrease production of staphylococcal exotoxins in vitro and in vivo,99,100 enhance the organism’s phagocytosis,100 and selectively inhibit the transcription of spa and hla exoprotein genes.101 If consideration is given to its use, inducible clindamycin resistance should be ruled out by doing a D-test, because a substantial proportion of erythromycin-resistant isolates have shown clindamycin resistance despite appearing susceptible on initial testing.102 Another example is linezolid, which has been shown to potentiate the opsonisation and phagocytosis of S aureus at concentrations below the MIC.103 By contrast, β-lactam antibiotics have the potential to increase exoprotein synthesis, specifically that of PVL.104–106 Some clinicians therefore advocate the treatment of patients with CA-MRSA pneumonia with agents that suppress toxin production, and urge the avoidance of agents (ie, β lactams) that can lead to increased production of PVL and other exotoxins.98 A second adjunctive approach is the targeting of toxin production directly with anti-toxin antibodies. Intravenous immunoglobulin possesses anti-PVL antibodies that are able to prevent PVL-mediated cytopathic effects on cells in vitro.107 However, no clinical data exist to guide its use in vivo, but a higher dose of immunoglobulin might be required to neutralise staphylococcal toxins than for those of Streptococcus pyogenes.108 To date there is only one report of the successful use of intravenous immunoglobulin as salvage therapy.109 Given the potential severity of CA-MRSA infections, another important question is whether screening and treating of household contacts that are found to be colonised with MRSA should be advocated. Nasal colonisation with S aureus is a known risk factor for subsequent infection with this organism,110 a risk that seems higher with CA-MRSA.111 However, there are no formal recommendations for the surveillance and www.thelancet.com/infection Vol 9 June 2009
decolonisation of household contacts of patients presenting with CA-MRSA infections. Whereas antimicrobial/antiseptic regimens that were intended for the eradication of S aureus colonisation have been used in some community settings to prevent autoinfection of colonised patients and transmission to contacts, the effectiveness of this approach has not been established.112 Reports have indicated that the prevalence of household colonisation with CA-MRSA is higher than that among the general population.43 However, direct transmission probably does not account for all cases of household colonisation because only 50% of colonised household members carry the same strain as the contact.43 Therefore, treatement decisions are often made on an individual basis by the physicians who provide care to the patients and their families to prevent recurrent disease or intrafamilial spread. In summary, there are no prospective clinical trials or evidence-based guidelines to direct the treatment of patients with CA-MRSA pneumonia. Options for therapy include vancomycin, which still remains the drug of choice, or linezolid. Given the high morbidity and mortality associated with the disease, adjunctive use of an antibiotic that suppresses protein synthesis or anti-toxin antibody (intravenous immunoglobulin) has been advocated in patients with severe disease.
Conclusion CA-MRSA pneumonia has emerged as a cause of community-acquired pneumonia, generally after influenza or influenza-like illness and most often among previously healthy patients. The pathophysiology is incompletely understood, although some data suggest that PVL or other toxins, or both, might play an important part in the pathogenesis of the disease. CA-MRSA pneumonia manifests as a severe, necrotising pneumonia, associated with substantial morbidity and mortality. This entity should be suspected in patients presenting from the community with sepsis, haemoptysis, multilobar infiltrates, and leucopenia. In such patients, standard treatment of community-acquired pneumonia will be
Search strategy and selection criteria We searched PubMed for English or Spanish language references published as of July, 2007, using combinations of the following terms: “Staphylococcus aureus”, “methicillin resistance”, “CA-MRSA”, “HA-MRSA”, “community acquired”, “hospital acquired”, “healthcare associated”, “Panton Valentine leukocidin”, “PVL”, “community acquired pneumonia”, “pneumonia”, “necrotizing pneumonia”, “epidemiology”, “influenza”, “pathogenesis”, “virulence”, and “treatment”. The bibliographies of the articles herein obtained, as well as those of review articles were also reviewed for inclusion of relevant publications. Spelling variants of the search terms were used.
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inappropriate, and an antibiotic with activity against MRSA (ie, vancomycin or linezolid) should be included in the empirical regimen until culture results are available. The two patients described in this report seemed to have failed to improve until treatment geared towards toxin suppression was instituted (ie, addition of clindamycin). Despite the lack of clinical trials to support such measures, in-vitro data coupled with a high case-fatality rate suggest the use of an antibiotic that decreases toxin production, and the adjunctive use of intravenous immunoglobulin may be indicated. Finally, since the emergence of CA-MRSA USA300 in hospitals, it is unclear whether severe health-care-associated pneumonias due to MRSA USA300 will also emerge. Conflicts of interest We declare that we have no conflicts of interest. References 1 Chickering HT, Park JH. Staphylococcus aureus pneumonia. J Am Med Assoc 1919; 72: 617–26. 2 Bradley SF. Staphylococcus aureus pneumonia: emergence of MRSA in the community. Semin Respir Crit Care Med 2005; 26: 643–49. 3 Laupland KB, Church DL, Mucenski M, Sutherland LR, Davies HD. Population-based study of the epidemiology of and the risk factors for invasive Staphylococcus aureus infections. J Infect Dis 2003; 187: 1452–59. 4 Lynch J. Hospital-acquired pneumonia: risk factors, microbiology, and treatment. Chest 2001; 119 (suppl 2): 373S–84S. 5 Kollef MH, Shorr A, Tabak YP, Gupta V, Liu LZ, Johannes RS. Epidemiology and outcomes of health-care-associated pneumonia: results from a large US database of culture-positive pneumonia. Chest 2005; 128: 3854–62. 6 Kaye MG, Fox MJ, Bartlett JG, Braman SS, Glassroth J. The clinical spectrum of Staphylococcus aureus pulmonary infection. Chest 1990; 97: 788–92. 7 Martin CM, Kunin CM, Gottlieb LS, Finland M. Asian influenza A in Boston, 1957–1958. II. Severe staphylococcal pneumonia complicating influenza. Arch Intern Med 1959; 103: 532–42. 8 Schwarzmann SW, Adler JL, Sullivan RJ Jr, Marine WM. Bacterial pneumonia during the Hong Kong influenza epidemic of 1968–1969. Arch Intern Med 1971; 127: 1037–41. 9 Centers for Disease Control and Prevention. Four pediatric deaths from community-acquired methicillin-resistant Staphylococcus aureus, Minnesota and North Dakota, 1997–1999. MMWR Morb Mortal Wkly Rep 1999; 48: 707–10. 10 Naimi TS, LeDell KH, Boxrud DJ, et al. Epidemiology and clonality of community-acquired methicillin-resistant Staphylococcus aureus in Minnesota, 1996–1998. Clin Infect Dis 2001; 33: 990–96. 11 Gillet Y, Issartel B, Vanhems P, et al. Association between Staphyloccocus aureus strains carrying gene for Panton-Valentine leukocidin and highly lethal necrotising pneumonia in young immunocompetent patients. Lancet 2002; 359: 753–59. 12 Dufour P, Gillet Y, Bes M, et al. Community-acquired methicillin-resistant Staphylococcus aureus infections in France: emergence of a single clone that produces Panton-Valentine leukocidin. Clin Infect Dis 2002; 35: 819–24. 13 Mongkolrattanothai K, Boyle S, Kahana MD, Daum RS. Severe Staphylococcus aureus infections caused by clonally related community-acquired methicillin-susceptible and methicillin-resistant isolates. Clin Infect Dis 2003; 37: 1050–58. 14 Boussaud V, Parrot A, Mayaud C, et al. Life-threatening hemoptysis in adults with community-acquired pneumonia due to Panton-Valentine leukocidin-secreting Staphylococcus aureus. Intensive Care Med 2003; 29: 1840–43. 15 Francis JS, Doherty MC, Lopatin U, et al. Severe community-onset pneumonia in healthy adults caused by methicillin-resistant Staphylococcus aureus carrying the Panton-Valentine leukocidin genes. Clin Infect Dis 2005; 40: 100–07.
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Finck-Barbancon V, Duportail G, Meunier O, Colin DA. Pore formation by a two-component leukocidin from Staphylococcus aureus within the membrane of human polymorphonuclear leukocytes. Biochim Biophys Acta 1993; 1182: 275–82. Ward PD, Turner WH. Identification of staphylococcal Panton-Valentine leukocidin as a potent dermonecrotic toxin. Infect Immun 1980; 28: 393–97. Gomez MI, Lee A, Reddy B, et al. Staphylococcus aureus protein A induces airway epithelial inflammatory responses by activating TNFR1. Nat Med 2004; 10: 842–48. Palmqvist N, Foster T, Tarkowski A, Josefsson E. Protein A is a virulence factor in Staphylococcus aureus arthritis and septic death. Microb Pathog 2002; 33: 239–49. Genestier AL, Michallet MC, Prevost G, et al. Staphylococcus aureus Panton-Valentine leukocidin directly targets mitochondria and induces Bax-independent apoptosis of human neutrophils. J Clin Invest 2005; 115: 3117–27. Labandeira-Rey M, Couzon F, Boisset S, et al. Staphylococcus aureus Panton-Valentine leukocidin causes necrotizing pneumonia. Science 2007; 315: 1130–33. Wardenburg JB, Bae T, Otto M, Deleo FR, Schneewind O. Poring over pores: alpha-hemolysin and Panton-Valentine leukocidin in Staphylococcus aureus pneumonia. Nat Med 2007; 13: 1405–06. Diep BA, Palazzolo-Ballance AM, Tattevin P, et al. Contribution of Panton-Valentine leukocidin in community-associated methicillin-resistant Staphylococcus aureus pathogenesis. PLoS ONE 2008; 3: e3198. Voyich JM, Otto M, Mathema B, et al. Is Panton-Valentine leukocidin the major virulence determinant in community-associated methicillin-resistant Staphylococcus aureus disease? J Infect Dis 2006; 194: 1761–70. Hamilton SM, Bryant AE, Carroll KC, et al. In vitro production of panton-valentine leukocidin among strains of methicillin-resistant Staphylococcus aureus causing diverse infections. Clin Infect Dis 2007; 45: 1550–58. Wang R, Braughton KR, Kretschmer D, et al. Identification of novel cytolytic peptides as key virulence determinants for community-associated MRSA. Nat Med 2007; 13: 1510–14. Mandell LA, Wunderink RG, Anzueto A, et al. 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): S27–72. Moise PA, Schentag JJ. Vancomycin treatment failures in Staphylococcus aureus lower respiratory tract infections. Int J Antimicrob Agents 2000; 16 (suppl 1): S31–34. Geisel R, Schmitz FJ, Thomas L, et al. Emergence of heterogeneous intermediate vancomycin resistance in Staphylococcus aureus isolates in the Dusseldorf area. J Antimicrob Chemother 1999; 43: 846–48. Hiramatsu K, Aritaka N, Hanaki H, et al. Dissemination in Japanese hospitals of strains of Staphylococcus aureus heterogeneously resistant to vancomycin. Lancet 1997; 350: 1670–73. Skrupky LP, Micek ST, Kollef MH. Optimizing therapy for MRSA pneumonia. Semin Respir Crit Care Med 2007; 28: 615–23. Moise-Broder PA, Sakoulas G, Eliopoulos GM, Schentag JJ, Forrest A, Moellering RC Jr. Accessory gene regulator group II polymorphism in methicillin-resistant Staphylococcus aureus is predictive of failure of vancomycin therapy. Clin Infect Dis 2004; 38: 1700–05. Hidayat LK, Hsu DI, Quist R, Shriner KA, Wong-Beringer A. High-dose vancomycin therapy for methicillin-resistant Staphylococcus aureus infections: efficacy and toxicity. Arch Intern Med 2006; 166: 2138–44. Wunderink RG, Cammarata SK, Oliphant TH, Kollef MH. Continuation of a randomized, double-blind, multicenter study of linezolid versus vancomycin in the treatment of patients with nosocomial pneumonia. Clin Ther 2003; 25: 980–92.
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Powers JH, Ross DB, Lin D, Soreth J. Linezolid and vancomycin for methicillin-resistant Staphylococcus aureus nosocomial pneumonia: the subtleties of subgroup analyses. Chest 2004; 126: 314–16. Powers JH, Lin D, Ross D. FDA evaluation of antimicrobials: subgroup analysis. Chest 2005; 127: 2298–301. Silverman JA, Mortin LI, Vanpraagh AD, Li T, Alder J. Inhibition of daptomycin by pulmonary surfactant: in vitro modeling and clinical impact. J Infect Dis 2005; 191: 2149–52. Ge Y, Biek D, Talbot GH, Sahm DF. In vitro profiling of ceftaroline against a collection of recent bacterial clinical isolates from across the United States. Antimicrob Agents Chemother 2008; 52: 3398–407. Wenzel RP, Bearman G, Edmond MB. Community-acquired methicillin-resistant Staphylococcus aureus (MRSA): new issues for infection control. Int J Antimicrob Agents 2007; 30: 210–12. van Langevelde P, van Dissel JT, Meurs CJ, Renz J, Groeneveld PH. Combination of flucloxacillin and gentamicin inhibits toxic shock syndrome toxin 1 production by Staphylococcus aureus in both logarithmic and stationary phases of growth. Antimicrob Agents Chemother 1997; 41: 1682–85. Gemmell CG, O’Dowd A. Regulation of protein A biosynthesis in Staphylococcus aureus by certain antibiotics: its effect on phagocytosis by leukocytes. J Antimicrob Chemother 1983; 12: 587–97. Herbert S, Barry P, Novick RP. Subinhibitory clindamycin differentially inhibits transcription of exoprotein genes in Staphylococcus aureus. Infect Immun 2001; 69: 2996–3003. Siberry GK, Tekle T, Carroll K, Dick J. Failure of clindamycin treatment of methicillin-resistant Staphylococcus aureus expressing inducible clindamycin resistance in vitro. Clin Infect Dis 2003; 37: 1257–60. Gemmell CG, Ford CW. Virulence factor expression by gram-positive cocci exposed to subinhibitory concentrations of linezolid. J Antimicrob Chemother 2002; 50: 665–72. Ohlsen K, Ziebuhr W, Koller KP, Hell W, Wichelhaus TA, Hacker J. Effects of subinhibitory concentrations of antibiotics on alpha-toxin (hla) gene expression of methicillin-sensitive and methicillin-resistant Staphylococcus aureus isolates. Antimicrob Agents Chemother 1998; 42: 2817–23. Dumitrescu O, Boisset S, Badiou C, et al. Effect of antibiotics on Staphylococcus aureus producing Panton-Valentine leukocidin. Antimicrob Agents Chemother 2007; 51: 1515–19. Stevens DL, Ma Y, Salmi DB, McIndoo E, Wallace RJ, Bryant AE. Impact of antibiotics on expression of virulence-associated exotoxin genes in methicillin-sensitive and methicillin-resistant Staphylococcus aureus. J Infect Dis 2007; 195: 202–11. Gauduchon V, Cozon G, Vandenesch F, et al. Neutralization of Staphylococcus aureus Panton Valentine leukocidin by intravenous immunoglobulin in vitro. J Infect Dis 2004; 189: 346–53. Darenberg J, Soderquist B, Normark BH, Norrby-Teglund A. Differences in potency of intravenous polyspecific immunoglobulin G against streptococcal and staphylococcal superantigens: implications for therapy of toxic shock syndrome. Clin Infect Dis 2004; 38: 836–42. Hampson FG, Hancock SW, Primhack RA. Disseminated sepsis due to a Panton-Valentine leukocidin producing strain of community acquired meticillin resistant Staphylococcus aureus and use of intravenous immunoglobulin therapy. Arch Dis Child 2006; 91: 201. von Eiff C, Becker K, Machka K, Stammer H, Peters G. Nasal carriage as a source of Staphylococcus aureus bacteremia. N Engl J Med 2001; 344: 11–16. Ellis MW, Hospenthal DR, Dooley DP, Gray PJ, Murray CK. Natural history of community-acquired methicillin-resistant Staphylococcus aureus colonization and infection in soldiers. Clin Infect Dis 2004; 39: 971–79. Loeb M, Main C, Walker-Dilks C, Eady A. Antimicrobial drugs for treating methicillin-resistant Staphylococcus aureus colonization. Cochrane Database Syst Rev 2003; 4: CD003340.
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Emergence of community-acquired meticillin-resistant Staphylococcus aureus strain USA300 as a cause of necrotising community-onset pneumonia Alicia I Hidron, Cari E Low, Eric G Honig, Henry M Blumberg Lancet Infect Dis 2009; 9: 384–92 Division of Infectious Diseases (A I Hidron MD, H M Blumberg MD), Division of Medicine (C E Low MD), and Division of Pulmonary and Critical Care Medicine (E G Honig MD), Department of Medicine, Emory University School of Medicine, Atlanta, GA, USA; and Epidemiology Department, Grady Memorial Hospital, Atlanta (H M Blumberg) Correspondence to: Alicia I Hidron, Division of Infectious Diseases, Emory University School of Medicine, 49 Jesse Hill Jr Drive, Atlanta, GA 30303, USA [email protected]
Meticillin-resistant Staphylococcus aureus (MRSA), usually known as a nosocomial pathogen, has emerged as the predominant cause of skin and soft-tissue infections in many communities. Concurrent with the emergence of community-acquired MRSA (CA-MRSA), there have been increasing numbers of reports of community-acquired necrotising pneumonia in young patients and others without the classic health-care-associated risk factors. Community-onset necrotising pneumonia due to CA-MRSA is now recognised as an emerging clinical entity with distinctive clinical features and substantial morbidity and mortality. A viral prodrome (eg, influenza or influenza-like illness) followed by acute onset of shortness of breath, sepsis, and haemoptysis is the most frequent clinical presentation. The best treatment of this partly toxin-mediated disease has not been clearly defined. Whereas cases of CA-MRSA pneumonia have now been reported from almost every continent, the overall burden of disease of this emerging syndrome remains incompletely described. We report two related cases of community-onset pneumonia due to the MRSA USA300 genotype and review the literature regarding the emergence of CA-MRSA pneumonia.
Introduction Staphylococcus aureus has long been recognised as a cause, albeit an infrequent one, of community-acquired pneumonia.1 Estimated to represent 1–10% of community-acquired pneumonia and 20–50% of nosocomial pneumonia,2–5 it had been uncommon in healthy children and adults from high-income countries except when seen in the post-influenza setting.1,6–8 Historically, pneumonia due to meticillin-resistant S aureus (MRSA) has been confined to health-care settings, representing 10–20% of pathogens that cause hospital and ventilator-associated pneumonia.5 In 1999, four paediatric deaths were reported due to community-acquired MRSA (CA-MRSA) necrotising
pneumonia; these infections were caused by strains that differed from typical nosocomial strains in their antibiotic susceptibility patterns and pulsed field gel electrophoresis (PFGE) characteristics.9 3 years later, an association was found between the presence of Panton-Valentine leucocidin (PVL)—a staphylococcal toxin known to be associated with tissue necrosis—and this previously described syndrome of acute haemorrhagic necrotising pneumonia among otherwise healthy patients presenting with staphylococcal pneumonia from the community.10 Since then, many case reports and series have been described.9–30 However, the overall incidence of CA-MRSA pneumonia remains unknown. We describe two related cases of CA-MRSA necrotising pneumonia, and review the origins, pathophysiology, clinical features, outcomes, and treatment options for this emerging entity.
Case presentation Case 1
Figure 1: Chest radiograph of case 1 on admission Bilateral opacities with a right middle lobe dense consolidation are shown.
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A 45-year-old white woman presented to the hospital during the height of the influenza season with complaints of shortness of breath, fever, chills, and a cough that produced brown sputum of 1 week’s duration. She denied haemoptysis, but gave a history of recurrent folliculitis for the past several months. She reported a preceding influenza-like illness (fever, myalgias, headache, and upper respiratory symptoms) 5 days before the onset of her current symptoms. Her medical history was notable for asthma, hypertension, hypothyroidism, adrenal insufficiency, and methadone maintenance for previous opiate dependence. She denied a history of alcohol use, but said that she smoked cigarettes. She had not received an influenza vaccination. On admission, her blood pressure was 166/99 mm Hg, pulse rate was 103 beats per min, respiratory rate was 19 breaths per min, and temperature was 38·2°C. She www.thelancet.com/infection Vol 9 June 2009
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seemed to be in moderate respiratory distress. On cardiopulmonary examination she was found to have diffuse rhonchi and crackles, but no heart murmurs. No skin lesions were noted. The rest of her examination was unrevealing. Laboratory data included a white blood cell count of 8·7×10⁹ cells per L (87% neutrophils), haematocrit of 43%, and platelet count of 299×10⁹/L. Her chest radiograph showed bilateral opacities with a right middle lobe dense consolidation (figure 1). The patient was admitted with presumed communityacquired pneumonia. Several hours later, her dyspnoea worsened, and she required intubation and mechanical ventilatory support. Broad spectrum antibiotic coverage with piperacillin–tazobactam and vancomycin were initiated after initial blood cultures were drawn. HIV serology and a legionella urinary antigen test were negative. Multiple sets of blood cultures (including the initial set obtained on admission) were culture negative. A culture of respiratory secretions obtained by mini bronchoalveolar lavage from the day of admission grew MRSA that was resistant to β-lactam antibiotics and erythromycin, but susceptible to clindamycin, fluoroquinolones, rifampicin, co-trimoxazole (trimethoprim-sulfamethoxazole), and tetracycline. The D-test for inducible clindamycin resistance was negative. PFGE by use of methods previously described revealed the isolate to be the USA300 genotype of MRSA.31 Other molecular tests by PCR showed that the isolate contained the genes for PVL and the staphylococcal chromosomal cassette mec (SCCmec) element type IV.32,33 On hospital day 4, the patient was continuing to require ventilatory support with 60–70% inspired oxygen. A bronchoscopy done on day 6 of her hospital stay revealed haemorrhagic vesicles (figure 2). An infectious diseases consultation was obtained on that day; clindamycin was added to her antibiotic regimen, vancomycin was continued, and piperacillin–tazobactam was discontinued. A repeat bronchoscopy on day 11 (5 days after the addition of clindamycin) showed resolution of these bronchial lesions. The patient began to improve clinically within 48 h after the addition of clindamycin and was extubated on hospital day 11. Respiratory herpes simplex virus culture and influenza cultures were negative. After 23 days in hospital, the patient eventually recovered and was discharged home. 2 years after presentation, the patient remains with mild residual dyspnoea on exertion, which has been attributed to secondary lung scarring; she is otherwise symptom free.
Figure 2: Bronchoscopy of case 1 on hospital day 6 Haemorrhagic vesicles are shown.
current symptoms, and a history of recurrent episodes of folliculitis. On admission, his blood pressure was 107/65 mm Hg, pulse rate was 82 beats per min, respiratory rate was 16 breaths per min, oxygen saturation was 96% on room air, and temperature was 37·4°C. Lung examination revealed diffuse crackles with left-sided egophony. No heart murmurs or skin lesions were noted. The rest of his physical examination was normal. Laboratory tests revealed a white blood cell count of 17·9×10¹² cells per L (89% neutrophils), a haematocrit of 37%, and a platelet count of 283×10⁹/L. A CT scan of the chest revealed a multi-loculated cystic consolidation in the left upper lobe with cavitations and a right upper lobe consolidation (figure 3). HIV serological and legionella urinary antigen tests were negative.
Case 2 The partner of case 1, a 36-year-old white man with a past medical history of schizophrenia, hepatitis C virus infection, and methadone maintenance for previous opiate dependence, was admitted to hospital 5 days later with similar symptoms (shortness of breath, fever, chills, and productive cough). He also reported a preceding influenza-like illness 1 week before the onset of his www.thelancet.com/infection Vol 9 June 2009
Figure 3: Chest CT scan of case 2 Left lower lobe, multi-loculated consolidation with cavitations are shown.
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Treatment with ceftriaxone and doxycycline was initiated after initial blood cultures had been drawn. However, due to persistent fevers, antibiotics were switched to vancomycin and piperacillin–tazobactam on hospital day 3. An infectious diseases consultation was obtained on hospital day 7 because of persistent fever, prompting the addition of clindamycin to the antibiotic regimen; vancomycin was continued and piperacillin–tazobactam was discontinued at this time. Three sets of blood cultures obtained on separate days were negative (including the initial set drawn on admission). Bronchoscopy was done on hospital day 7 and a bronchoalveolar lavage culture grew MRSA, which had the same antibiogram as the isolate recovered from case 1. Molecular studies revealed the isolate recovered from this patient was identical to that recovered from his partner (MRSA USA300, SCCmec IV, and PVL positive). The patient had resolution of fever and symptomatic improvement within 48 h of clindamycin initiation. He was discharged after 14 days to complete a 21-day course of antibiotics. 2 years after this episode, he remains in good health.
Discussion and review of the published work CA-MRSA Meticillin resistance in S aureus emerged roughly 45 years ago, but MRSA infections were primarily confined to the health care setting until recently.9,20,34–36 The first report of community-onset infections with MRSA came from Australia in 1993.37 In the USA, reports of CA-MRSA necrotising pneumonia in healthy children appeared in the late 1990s,9 and were followed by reports of outbreaks of CA-MRSA skin and soft-tissue infections among prison inmates, homosexual men, native Americans, and sports teams.9,34–36,38–41 Transmission of CA-MRSA infections among these high-risk groups, from infected patients to household contacts, and transmission of nasal colonisation within families were then reported.34–36,42,43 As a result, CA-MRSA infections are no longer restricted to certain risk groups or to the geographic areas where outbreaks first occurred. They now occur widely both in the community as well as health care facilities, and have been reported in nearly every continent.44–47 The spectrum of disease caused by CA-MRSA occurs worldwide and primarily encompasses skin and soft-tissue infections,44,47–50 but deep-seated infections such as pyomyositis, osteomyelitis, septic arthritis, and severe infections such as necrotising pneumonia and bacteraemia have also been reported.51 The prevalence and incidence of invasive CA-MRSA infections probably varies geographically. In the USA, for example, 6% of CA-MRSA infections cause invasive disease (pneumonia accounting for 2% overall),52 and 14% of all invasive MRSA infections are due to CA-MRSA (14% of these invasive infections are CA-MRSA pneumonia).53 386
Differences between health-care-associated MRSA and CA-MRSA Genotypic characterisation of MRSA isolates by lineage, the type of genetic element that encodes meticillin resistance, and toxin production profile are important for epidemiological purposes to differentiate between health-care-associated MRSA (HA-MRSA) and CA-MRSA. The predominant lineage of MRSA isolates, as characterised by multilocus sequence typing (MLST) or PFGE, and toxin gene expression varies geographically, whereas SCCmec does not. Typing for SCCmec, the mobile genetic element that carries the mecA gene that encodes meticillin resistance,54,55 is usually done worldwide to describe MRSA isolates. SCCmec is classified into types I–VII (based on the mec and ccr complex) and each type is further classified into subtypes based on differences in the junkyard (J) region.56,57 HA-MRSA usually carry SCCmec types that are larger (types I, II, and III),54 whereas CA-MRSA isolates carry a much smaller staphylococcal cassettes (SCCmec types IV, V, or VII).57–59 The smaller size of SCCmec elements in CA-MRSA isolates may represent an evolutionary advantage, allowing horizontal spread of this element across bacterial species.58 However, the larger SCCmec elements associated with HA-MRSA isolates represent additional carriage of non-β-lactam resistance genes that probably confer their ability to survive in the hospital environment.58 With the exception of SCCmec VI, which seems to be confined to one geographic area (Portugal), the different MRSA SCCmec types associated to either HA-MRSA or CA-MRSA have all been initially isolated from a specific region and subsequently spread worldwide.57 Characterisation of the genetic lineage of MRSA can be done mainly by MLST or PFGE. Outside the USA, description of MRSA isolates is done by their sequence type based on MLST. In Europe, the predominant CA-MRSA clone reported has been sequence type ST80,46,60–62 whereas ST30 is an important clone in Asia and Oceania.46,62–64 In Denmark, for example, ST80 causes 60% of community-onset infections compared with 28% of health-care-associated infections.49 In the USA, molecular typing has often been done using PFGE, which has shown that USA300, USA400, USA1000, and USA1100 (which correlate with sequence types ST8, ST1, ST59, and ST30, respectively) are the most common genotypes recovered among patients with CA-MRSA infections,31,46,65 with MRSA USA300 accounting for up to 97–99% of cases.44,47 By contrast, traditional HA-MRSA genotypes in the USA most commonly include USA100 and USA200.31 The presence of PVL genes is more common among CA-MRSA than HA-MRSA isolates.32,46 However, the prevalence of PVL among CA-MRSA isolates varies geographically. In the USA, PVL genes are present in 40–95% of CA-MRSA isolates and nearly all USA300 www.thelancet.com/infection Vol 9 June 2009
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isolates contain PVL.47,66 However, the prevalence of PVL-positive CA-MRSA in the UK is significantly lower than in the USA,66 and in Japan, Korea, and Western Australia, the predominant CA-MRSA clones are PVL negative.67–69 Finally, from a clinical standpoint, CA-MRSA infections most commonly involve skin and soft tissues,34–36,40,44,70 and tend to affect younger patients than does HA-MRSA.9,34–36,38–41,71 CA-MRSA isolates are also characteristically susceptible to a greater number of non-β-lactam antibiotics such as clindamycin, macrolides, co-trimoxazole, tetracyclines, and fluoroquinolones.52,71 However, carriage of antimicrobial resistance genes may vary by the sequence type of CA-MRSA isolate and therefore susceptibility to these non-β-lactam antibiotics cannot be implied.62
ventilatory support (table). By contrast with other bacterial pneumonias in which leucocytosis is a prominent feature, leucopenia can be observed in a substantial proportion of cases and has been found to be one of the predictors of poor outcome (in addition to erythroderma and airway bleeding; table).14–16,19 More than a quarter of patients with CA-MRSA pneumonia are reported to have multilobar infiltrates and/or cavitation in imaging studies (table),9,12,14–18,20 which correlates with pathological examination that usually reveals a haemorrhagic necrotising pneumonia with high bacterial counts.9,11,14,16,20,23,72 Substantial morbidity and mortality have thus been reported due to CA-MRSA pneumonia, but mortality varies widely.10–16,18,20 However, despite reporting bias, many reports from the USA and Europe have noted mortalities greater than 50%.9,12,14
Clinical presentation, laboratory findings, radiological features, and outcomes of patients with CA-MRSA pneumonia
Pathophysiology
CA-MRSA pneumonia generally affects young and previously healthy patients.9–13,15–21,25,27–30,32,72 Severe cases of CA-MRSA pneumonia have been reported during influenza seasons, or associated with a preceding influenza illness in 33–71% of patients.12,20 Clinical presentation is usually that of a severe pneumonia with high fever, hypotension, and haemoptysis followed by rapid progression to septic shock and requirement for Patients Patients Median age of patients with (n) with pneumonia MRSA (years) (n)
Number and percentage of patients with condition among patients with community-acquired Staphylococcus aureus pneumonia
Haemoptysis
CDC (1999)9
The initial epithelial damage in S aureus pneumonia has historically been attributed to a prodromal viral infection.11,14,15,18–20 S aureus does not bind to intact airway epithelium but has an increased affinity for basement membrane type I and II collagen when exposed,73 and adheres to cell monolayers infected with influenza A virus to a greater degree than to uninfected cell monolayers.74 PVL, a S aureus toxin that creates pores on host cell membranes, may mediate this initial injury.75,76 However, S aureus supernatants are able to disrupt the
Influenza-like prodrome
Leucopenia Shock
Ventilatory Multilobar Necrotising PVL positive pneumonia* support infiltrates on imaging
Mortality
4
4
4
1 (25%)
··
··
4 (100%)
2 (50%)†
1 (25%)
4 (100%)
··
Naimi et al (2001)10
12
12
16‡
··
··
··
1 (8%)
1 (8%)
··
··
··
Gillet et al (2002)11
16§
1
15
6 (38%)
··¶
13 (81%)
12 (75%)
10 (63%)
3 (19%)||
Dufour et al (2002)12
2
2
42
··
··
··
··
··
··
2 (100%)
2 (100%)
2 (100%)
Mongkolrattanothai et al (2003)13
4
2
··
··
··
4 (100%)
··
··
··
4 (100%)
1 (25%) 2 (66%)
0·7
12 (75%)
16 (100%)
4 (100%) 1 (8%) 12 (75%)
Boussaud et al (2003)14
3
1
38
3 (100%)
1 (33%)
3 (100%)
3 (100%)
3 (100%)
3 (100%)
1 (33%)||
3 (100%)
Francis et al (2005)15
4
4
32
3 (75%)
2 (50%)
3 (75%)
4 (100%)
4 (100%)
4 (100%)
4 (100%)
4 (100%)
1 (25%)
23
21
··
··
··
··
··
··
3 (13%)
23 (100%)**
3 (13%)
··
3 (75%)
Gonzalez et al (2005)16 Micek et al (2005)17
4
Hageman et al (2006)18 17††
2·1
4
40
··
3 (75%)
15
21
··
12 (71%)
Gillet et al (2007)19
50
6
CDC (2007)20
10
10
14·5¶¶ 17·5
22 (44%) ··
33 (67%)|||| 6 (60%)
4 (25%)‡‡ 16 (93%) 26 (54%)*** ··
·· ··
3 (75%)
2 (50%)
2 (50%)
8 (50%)‡‡
4 (25%)‡‡
4 (25%)‡‡
11 (85%)§§
5 (29%)
38 (79%)
··
50 (100%)
28 (56%)
7 (70%)
··
10 (100%)
6 (60%)
39 (78%)*** ··
4 (100%)
0
CDC=Centers for Disease Control and Prevention; ··=data not available. *As shown by pathology or radiographic imaging. †The other two patients died before ventilatory support. ‡All community-acquired MRSA (CA-MRSA) infections (median age for cases of pneumonia was not specified). §Panton-Valentine leucocidin (PVL)-positive Staphylococcus aureus community-acquired pneumonia cases (16 PVL-positive vs 36 PVL-negative). ¶Median number of patients with leucopenia not reported, but median nadir leucocyte count was 1·85 cells×109/L. ||Data only available for the percentage of patients shown and may not indicate the total number of patients with this condition. **100% of CA-MRSA pneumonia isolates were PVL positive and 78% of meticillin-sensitive S aureus isolates were PVL positive. ††Includes four patients described by Frazee et al.21 ‡‡Data available for 16 patients. §§Data available for 13 patients. ¶¶All patients with PVL-positive S aureus pneumonia. ||||Data available for 49 patients. ***Data available for 48 patients.
Table: Demographics, clinical characteristics, laboratory and radiology findings, and clinical outcomes of patients with community-acquired Staphylococcus aureus pneumonia
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integrity of the airway epithelium, whereas recombinant PVL alone cannot.73 Thus, either pre-existing airway damage is required or an unknown staphylococcal exotoxin must mediate the initial epithelial damage for bacterial adhesion to take place. The inflammatory cascade is then mediated by binding of protein A to a receptor for tumour necrosis factor (TNFR1), which is widely distributed in the airway epithelium.77 Protein A is a major staphylococcal surface protein that has been implicated in pathogenicity in other infection models.78 It induces production of interleukin 8 (a polymorphonuclear neutrophil chemokine), binds to TNFR1, and causes the receptor’s mobilisation and shedding to the epithelial surface; the shed receptor binds tumour necrosis factor and protein A to generate a negative feedback loop and protects the host’s airway from further damage caused by the inflammatory cascade.77 This protein A–TNFR1 pathway has been shown to mediate the inflammatory response and virulence in murine models of pneumonia.77 Both TNFR1-null mice and mice infected with protein A-null mutant S aureus had substantially less pneumonia, bacteraemia, and mortality.77
Role of PVL and other virulence factors The staphylococcal toxin that has received the most interest is PVL, which is present in most CA-MRSA isolates but is rarely (<5%) present in HA-MRSA isolates.32,46 PVL has been shown to cause lysis and apoptosis of neutrophils,79 tissue necrosis,76 and has been found in the pulmonary lesions in murine models of pneumonia.79,80 Its role as a potential virulence factor in severe pneumonia has been postulated since 2002.10 Patients with community-onset pneumonia who harbour PVL-positive S aureus isolates were found to have more sepsis and haemoptysis (probably as a surrogate marker of the degree of necrosis),18 and higher mortality. However, only recently has its role in the pathogenesis of invasive S aureus infections been studied in detail.80 In a murine model of acute primary MRSA pneumonia, mice infected with the PVL-positive strains showed evidence of inflammation and tissue necrosis compared with neutrophil infiltration alone for mice infected with PVL-negative strains.80 When plasmid-encoded PVL was introduced to the PVL-negative strains, massive tissue damage and substantial mortality was observed within 24 h. In addition, administration of the toxin components LukS-PV and LukF-PV caused tissue necrosis and mortality in a dose-dependent fashion. PVL was also shown to induce the expression of protein A and downregulate the expression of secreted proteins.80 Thus, the ability of PVL to lyse neutrophils and boost the inflammatory cascade could partly explain the progressive tissue necrosis observed. Despite these observations, PVL’s direct role in the pathogenesis of CA-MRSA infections has been under debate.81 Relative insensitivity of murine poly388
morphonuclear leucocytes to the lytic effect of PVL has been recognised compared with that of human cells, making controversial the findings of mouse model-based studies. By contrast with previous findings, a rabbit model failed to show PVL’s contribution to CA-MRSA virulence by altering global gene or protein regulatory networks of S aureus.82 In addition, in murine sepsis and abscess models, PVL-positive strains have been shown to be as virulent as PVL-negative strains.83 The quantity of PVL produced in vitro from CA-MRSA strains obtained from patients with clinical infections also did not correlate with disease severity.84 Other virulence factors have also been postulated as responsible for mediating the virulence of this organism.81,85 For example, production of phenol-soluble modulins has been found to be higher in CA-MRSA than in HA-MRSA isolates. These toxins have been shown to recruit, activate, and lyse neutrophils; loss of their expression was found to reduce the virulence of CA-MRSA USA300 and USA400 strains in murine models of bacteraemia and abscess.85 Thus, although some data suggest an important pathogenetic role of PVL in MRSA pneumonia, debate remains about the importance of this toxin in the pathogenesis of CA-MRSA pneumonia or whether PVL is merely a marker of CA-MRSA infections.
Treatment The use of vancomycin or linezolid has been recommended for empirical treatment of communityacquired pneumonia in cases in which CA-MRSA is a consideration.86 However, reported treatment failures for MRSA infections with minimum inhibitory concentrations (MICs) of vancomycin in both the susceptible and non-susceptible range remain an important concern.87–89 Whether optimisation of vancomycin pharmacokinetic parameters will improve outcomes for patients with MRSA pneumonia is not clear,90 but the American Thoracic Society/Infectious Disease Society of America guidelines for pneumonia recommend aiming for vancomycin trough concentrations of 15–20 mg/mL.86 Responses in patients with MRSA bacteraemia, for example, have been found to be better among those with isolates that have vancomycin MICs of at least 0·5 μg/mL compared with those with 1–2 μg/mL.91 Slightly contrasting with this observation, patients with MRSA pneumonia who attained vancomycin serum trough concentrations four times the MIC had improved responses at 72 h but not at the end of therapy.92 The optimum treatment for nosocomial and CA-MRSA pneumonia thus remains incompletely defined because of the lack of prospective clinical trials.86,90 Claims that linezolid is superior to vancomycin for the treatment of nosocomial MRSA pneumonia have been controversial,93 and criticised due to use of subgroup or post-hoc analysis.94,95 Ongoing prospective trials comparing linezolid versus vancomycin for the treatment of MRSA pneumonia will hopefully address and resolve this issue. www.thelancet.com/infection Vol 9 June 2009
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Among other available agents with MRSA activity, daptomycin should not be used for the treatment of staphylococcal pulmonary infections because the drug’s activity is inhibited by pulmonary surfactant and clinical data suggest that it is inferior to other antibiotics in the treatment of community-acquired pneumonia.96 The lack of data on the efficacy of tigecycline for MRSA pneumonia limit the use of this drug.90 Finally, the role of newer agents, including enhanced glycopeptides (dalbavancin, oritavancin, and telavancin) and anti-MRSA cephalosporins (ceftobiprole and ceftaroline fosamil), in the treatment of these infections will need to be studied in prospective trials before any recommendations on their use can be made.90,97 Concomitant use of antibiotics that suppress toxin production has been advocated for the treatment of severe and invasive CA-MRSA infections including pneumonia.98 The rationale for their use in CA-MRSA pneumonia includes (1) the presumed role of PVL (and perhaps other toxins) in pathogenesis, and (2) the striking morbidity and mortality observed. For example, clindamycin has been shown to decrease production of staphylococcal exotoxins in vitro and in vivo,99,100 enhance the organism’s phagocytosis,100 and selectively inhibit the transcription of spa and hla exoprotein genes.101 If consideration is given to its use, inducible clindamycin resistance should be ruled out by doing a D-test, because a substantial proportion of erythromycin-resistant isolates have shown clindamycin resistance despite appearing susceptible on initial testing.102 Another example is linezolid, which has been shown to potentiate the opsonisation and phagocytosis of S aureus at concentrations below the MIC.103 By contrast, β-lactam antibiotics have the potential to increase exoprotein synthesis, specifically that of PVL.104–106 Some clinicians therefore advocate the treatment of patients with CA-MRSA pneumonia with agents that suppress toxin production, and urge the avoidance of agents (ie, β lactams) that can lead to increased production of PVL and other exotoxins.98 A second adjunctive approach is the targeting of toxin production directly with anti-toxin antibodies. Intravenous immunoglobulin possesses anti-PVL antibodies that are able to prevent PVL-mediated cytopathic effects on cells in vitro.107 However, no clinical data exist to guide its use in vivo, but a higher dose of immunoglobulin might be required to neutralise staphylococcal toxins than for those of Streptococcus pyogenes.108 To date there is only one report of the successful use of intravenous immunoglobulin as salvage therapy.109 Given the potential severity of CA-MRSA infections, another important question is whether screening and treating of household contacts that are found to be colonised with MRSA should be advocated. Nasal colonisation with S aureus is a known risk factor for subsequent infection with this organism,110 a risk that seems higher with CA-MRSA.111 However, there are no formal recommendations for the surveillance and www.thelancet.com/infection Vol 9 June 2009
decolonisation of household contacts of patients presenting with CA-MRSA infections. Whereas antimicrobial/antiseptic regimens that were intended for the eradication of S aureus colonisation have been used in some community settings to prevent autoinfection of colonised patients and transmission to contacts, the effectiveness of this approach has not been established.112 Reports have indicated that the prevalence of household colonisation with CA-MRSA is higher than that among the general population.43 However, direct transmission probably does not account for all cases of household colonisation because only 50% of colonised household members carry the same strain as the contact.43 Therefore, treatement decisions are often made on an individual basis by the physicians who provide care to the patients and their families to prevent recurrent disease or intrafamilial spread. In summary, there are no prospective clinical trials or evidence-based guidelines to direct the treatment of patients with CA-MRSA pneumonia. Options for therapy include vancomycin, which still remains the drug of choice, or linezolid. Given the high morbidity and mortality associated with the disease, adjunctive use of an antibiotic that suppresses protein synthesis or anti-toxin antibody (intravenous immunoglobulin) has been advocated in patients with severe disease.
Conclusion CA-MRSA pneumonia has emerged as a cause of community-acquired pneumonia, generally after influenza or influenza-like illness and most often among previously healthy patients. The pathophysiology is incompletely understood, although some data suggest that PVL or other toxins, or both, might play an important part in the pathogenesis of the disease. CA-MRSA pneumonia manifests as a severe, necrotising pneumonia, associated with substantial morbidity and mortality. This entity should be suspected in patients presenting from the community with sepsis, haemoptysis, multilobar infiltrates, and leucopenia. In such patients, standard treatment of community-acquired pneumonia will be
Search strategy and selection criteria We searched PubMed for English or Spanish language references published as of July, 2007, using combinations of the following terms: “Staphylococcus aureus”, “methicillin resistance”, “CA-MRSA”, “HA-MRSA”, “community acquired”, “hospital acquired”, “healthcare associated”, “Panton Valentine leukocidin”, “PVL”, “community acquired pneumonia”, “pneumonia”, “necrotizing pneumonia”, “epidemiology”, “influenza”, “pathogenesis”, “virulence”, and “treatment”. The bibliographies of the articles herein obtained, as well as those of review articles were also reviewed for inclusion of relevant publications. Spelling variants of the search terms were used.
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inappropriate, and an antibiotic with activity against MRSA (ie, vancomycin or linezolid) should be included in the empirical regimen until culture results are available. The two patients described in this report seemed to have failed to improve until treatment geared towards toxin suppression was instituted (ie, addition of clindamycin). Despite the lack of clinical trials to support such measures, in-vitro data coupled with a high case-fatality rate suggest the use of an antibiotic that decreases toxin production, and the adjunctive use of intravenous immunoglobulin may be indicated. Finally, since the emergence of CA-MRSA USA300 in hospitals, it is unclear whether severe health-care-associated pneumonias due to MRSA USA300 will also emerge. Conflicts of interest We declare that we have no conflicts of interest. References 1 Chickering HT, Park JH. Staphylococcus aureus pneumonia. J Am Med Assoc 1919; 72: 617–26. 2 Bradley SF. Staphylococcus aureus pneumonia: emergence of MRSA in the community. Semin Respir Crit Care Med 2005; 26: 643–49. 3 Laupland KB, Church DL, Mucenski M, Sutherland LR, Davies HD. Population-based study of the epidemiology of and the risk factors for invasive Staphylococcus aureus infections. J Infect Dis 2003; 187: 1452–59. 4 Lynch J. Hospital-acquired pneumonia: risk factors, microbiology, and treatment. Chest 2001; 119 (suppl 2): 373S–84S. 5 Kollef MH, Shorr A, Tabak YP, Gupta V, Liu LZ, Johannes RS. Epidemiology and outcomes of health-care-associated pneumonia: results from a large US database of culture-positive pneumonia. Chest 2005; 128: 3854–62. 6 Kaye MG, Fox MJ, Bartlett JG, Braman SS, Glassroth J. The clinical spectrum of Staphylococcus aureus pulmonary infection. Chest 1990; 97: 788–92. 7 Martin CM, Kunin CM, Gottlieb LS, Finland M. Asian influenza A in Boston, 1957–1958. II. Severe staphylococcal pneumonia complicating influenza. Arch Intern Med 1959; 103: 532–42. 8 Schwarzmann SW, Adler JL, Sullivan RJ Jr, Marine WM. Bacterial pneumonia during the Hong Kong influenza epidemic of 1968–1969. Arch Intern Med 1971; 127: 1037–41. 9 Centers for Disease Control and Prevention. Four pediatric deaths from community-acquired methicillin-resistant Staphylococcus aureus, Minnesota and North Dakota, 1997–1999. MMWR Morb Mortal Wkly Rep 1999; 48: 707–10. 10 Naimi TS, LeDell KH, Boxrud DJ, et al. Epidemiology and clonality of community-acquired methicillin-resistant Staphylococcus aureus in Minnesota, 1996–1998. Clin Infect Dis 2001; 33: 990–96. 11 Gillet Y, Issartel B, Vanhems P, et al. Association between Staphyloccocus aureus strains carrying gene for Panton-Valentine leukocidin and highly lethal necrotising pneumonia in young immunocompetent patients. Lancet 2002; 359: 753–59. 12 Dufour P, Gillet Y, Bes M, et al. Community-acquired methicillin-resistant Staphylococcus aureus infections in France: emergence of a single clone that produces Panton-Valentine leukocidin. Clin Infect Dis 2002; 35: 819–24. 13 Mongkolrattanothai K, Boyle S, Kahana MD, Daum RS. Severe Staphylococcus aureus infections caused by clonally related community-acquired methicillin-susceptible and methicillin-resistant isolates. Clin Infect Dis 2003; 37: 1050–58. 14 Boussaud V, Parrot A, Mayaud C, et al. Life-threatening hemoptysis in adults with community-acquired pneumonia due to Panton-Valentine leukocidin-secreting Staphylococcus aureus. Intensive Care Med 2003; 29: 1840–43. 15 Francis JS, Doherty MC, Lopatin U, et al. Severe community-onset pneumonia in healthy adults caused by methicillin-resistant Staphylococcus aureus carrying the Panton-Valentine leukocidin genes. Clin Infect Dis 2005; 40: 100–07.
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