Abstract
Objective
Antibiotic exposure and timing of pneumonia onset influence ventilator-associated pneumonia (VAP) isolates. The first goal of this investigation was to evaluate whether trauma also influences prevalence of microorganisms.
Design
A retrospective, single-center, observational cohort study.
Setting
Multidisciplinary teaching ICU.
Patients
Adult patients requiring mechanical ventilation identified as having VAP.
Interventions
Retrospective evaluation of a prospective manual database.
Measurements and main results
VAP isolates in a multidisciplinary ICU documented by quantitative respiratory cultures and recorded in a 42-month database were compared, based on the presence or absence of trauma. Causative microorganisms were classified in four groups, based on mechanical ventilation duration (> 5 days), and previous antibiotic exposure. One hundred eighty-three patients developed 196 episodes of VAP (98 trauma). Methicillin-sensitive Staphylococcus aureus (MSSA) was more frequent (34.5% vs. 11.5%, p < 0.01) in trauma, whereas methicillin-resistant Staphylococcus aureus (MRSA) was more frequent (2% vs. 11.5%, p < 0.01) in non-trauma. No significant differences were found between trauma and non-trauma patients regarding prevalence of other microorganisms. In trauma patients, MSSA episodes were equally distributed between early- and late-onset VAP (51% vs. 49%), but no MRSA episode occurred in the early-onset group.
Conclusions
Trauma influences the microbiology of pneumonia and it should be considered in the initial antibiotic regimen choice. Our data demonstrate that patients with trauma had a higher prevalence of MSSA, but the overall prevalence was sufficiently high to warrant S. aureus coverage for both groups. On the other hand, since no MRSA was isolated during the first 10 days of mechanical ventilation on trauma patients, MRSA coverage in these patients becomes necessary only 10 days after admission.
Similar content being viewed by others
Introduction
Ventilator-associated pneumonia (VAP) is the leading infection encountered in intensive care units (ICU) [1], prolonging hospital stay and contributing to mortality [2, 3]. Prompt initiation of appropriate therapy is a cornerstone in management, and even short delays in administering adequate antibiotic regimen are associated with worsened outcomes [4, 5]. Therefore, current management strategies recommend an early start of broad-spectrum antibiotic regimen, followed by de-escalation [6, 7].
Several factors are associated with the presence of multiresistant pathogens in VAP, but duration of mechanical ventilation (or hospitalization, in patients not admitted from the emergency department) and prior antibiotic exposure appear to be the most important [8–10]. Indeed, MRSA and non-fermentative Gram-negative bacilli are usually considered in episodes with these factors. The descriptive findings from the Assessment of Local Antimicrobial Resistance Measures (ALARM) study [11] found that combination therapy with three antibiotics to cover these organisms in late-onset pneumonia is a usual initial choice. However, three antibiotics may not always be needed, and the contribution of other risk factors—such as the reason for mechanical ventilation—has not been sufficiently investigated. Prior reports suggested that trauma patients may have different causative organisms and outcomes.
The first goal of this study was to evaluate whether trauma influences the prevalence of microorganisms. Considering that trauma patients now account for a substantial portion of all admissions to our multidisciplinary ICU, we compared episodes of VAP in the presence or absence of trauma. Our hypothesis was that trauma patients have different prevalence of microorganisms in VAP, independently of antibiotic exposure and pneumonia onset, and that this information may help to guide the choice of initial antibiotic therapy.
Methods
Study population and design
A retrospective observational cohort study was conducted in a multidisciplinary (medical, surgical and trauma) ICU, at the Joan XXIII University Hospital, Tarragona. The prospectively recorded database for nosocomial infection surveillance from January 2003 to June 2006 was reviewed and all consecutive episodes of VAP with identified isolates were documented. All patients were managed following a standardized protocol if VAP was suspected. Management was guided by `The Tarragona Strategy', described elsewhere [6, 12, 13]. Selective decontamination of digestive tract and antibiotic prophylaxis for pneumonia are not performed in this ICU. Fiberoptic bronchoscopic examination using a protected specimen brush (PSB) or bronchoalveolar lavage (BAL) was performed in all patients within 6 h of the onset of a new pulmonary infiltrate on weekdays from 8 a.m. to 5 p.m. Samples in episodes that developed after 5 p.m. or at the weekend were always collected using quantitative tracheal aspirates. The etiological diagnosis of VAP was upheld only when PSB yielded ≥ 1,000 colony-forming units (cfu)/ml, BAL ≥ 10,000 cfu/ml, or quantitative tracheal aspirate ≥ 100,000 cfu/ml of at least one microorganism. Episodes with microorganisms under these thresholds were excluded because of low specificity [14].
Isolates were classified in six groups: (1) Non-fermentative Gram-negative bacteria (including Pseudomonas aeruginosa and Acinetobacter baumannii); (2) methicillin-resistant Staphylococcus aureus (MRSA); (3) Enterobacteriaceae (including Escherichia coli, Klebsiella pneumoniae, Klebsiella oxytoca, Proteus vulgaris, Enterobacter aerogenes, Enterobacter cloacae, Morganella morgagni, and Serratia marcescens); (4) methicillin-sensitive Staphylococcus aureus (MSSA); (5) Streptococcus species (including S. pneumoniae, S. viridans, and S. pyogenes); (6) Haemophilus influenzae and Moraxella catarrhalis.
The patient's underlying disease and its severity, presence of shock, acute respiratory distress syndrome (ARDS), coma on admission, chronic obstructive pulmonary disease (COPD), immunodepression status, diabetes mellitus and recent steroid use were recorded. Duration of mechanical ventilation prior to the development of VAP and recent antibiotic exposure status were also recorded for each episode.
Definitions
Trauma was defined as presence of injury to more than one body area or system or the presence of major cranial trauma alone. The non-trauma group included postoperative states and all medical conditions. Pneumonia was diagnosed when new, persistent pulmonary infiltrates, not otherwise explained appeared on chest X-rays plus the presence of local (purulent respiratory secretions) and systemic signs of inflammatory response (WBC count > 10,000/mm3, rise in WBC count > 20% or fever). Patients with documented massive gastric aspiration were excluded. Pneumonia was considered early-onset when it occurred within 5 days (episodes within the first 48 h—very early-onset pneumonia—were included if related to intubation) and defined as late-onset if it started at least 5 days after admission, in accordance with the guidelines of the Centers for Disease Control [15]. Moreover, we decided to evaluate late-onset episodes with an additional breakpoint of 10 days, as suggested elsewhere [16]. Fever was defined as two or more consecutive measurements of temperature > 38 °C. Underlying diseases were aggregated as trauma or absence of trauma. Severity of underlying disease was evaluated with APACHE II score for each patient in the first 24 h after ICU admission. Recent antibiotic therapy was considered when a patient received antimicrobial agents for more than 48 h during the 15 days preceding the episode of VAP [17]. COPD was diagnosed using criteria consistent with those recommended by the American Thoracic Society (ATS). Coma was diagnosed when the Glasgow Coma Scale (GCS) score was lower than 9 (both sedation and non-sedation) for more than 24 h [18]. ARDS was diagnosed according to the criteria of the American–European Consensus Conference Committee [19]. Shock was described as systolic blood pressure < 90 mmHg despite adequate fluid resuscitation and need for vasopressor agents. Polytransfusion was described as the need for > 10 units of packed red cell within 24 h. Immunocompromise, recent steroid use and diabetes mellitus have been defined elsewhere [20] as have our bacteriologic processing and identification methods [21].
Definition of the four groups of episodes
Four groups were created on the basis of days of mechanical ventilation (> 5 days) before pneumonia onset and recent antibiotic exposure. Group 1: early-onset episodes without recent antibiotic exposure; group 2: early-onset episodes with recent antibiotic exposure; group 3: late-onset episodes without recent antibiotic exposure; group 4: late-onset episodes with recent antibiotic exposure. Isolates were compared in each of these four groups based on presence or absence of trauma. Late-onset episodes were also evaluated with a breakpoint of 10 days.
Statistical analysis
Continuous variables were described as median values (interquartile ranges 25 to 75) and compared using Student's t-test (when not appropriate, the Mann–Whitney U-test was used). Categorical variables were compared with Pearson χ2 and, if appropriate, Fisher's exact test. Multiple logistic regression was used to assess variables associated with trauma and non-trauma groups. The dependent variable was trauma. Variables which were significant in the univariate analysis were entered in the multivariate model, as were variables which have been previously reported in the literature. Differences between the groups were significant for variables yielding a p-value ≤ 0.05. SPSS software (version 11.0; Chicago, IL, USA) was used for all the calculations.
Results
One hundred ninety-six episodes of VAP were documented in 183 patients. Ninety-one patients were admitted for trauma (T) and 92 for non-trauma reasons (AT). Demographic characteristics of patients and outcomes are compared in Table 1. Although trauma patients were younger, disease severity was similar. ICU mortality was higher (34.8% vs. 15.4%, p < 0.01) in the AT group, but in survivors median length of stay was similar (13 vs. 11.5 days). Significant differences between these cohorts are detailed in Table 2. In addition, no significant differences were associated with polytransfusion, ARDS, or prior antibiotic exposure. The independent variables included in the model were: APACHE II score on admission, age, coma, COPD, steroid use, immunosuppression, diabetes mellitus, ARDS, cirrhosis, vasopressor use, multiple transfusion, previous antibiotic exposure and surgery. The multivariate analysis revealed that coma was associated with the trauma group (OR 5.4, 95% CI 2.8–10.4), while vasopressor use (OR 3.1, 95% CI 1.2–7.8), age > 40 years (OR 10.4, 95% CI 4.7–23.2) and COPD (OR 16.1, 95% CI 2.1–125.6) were associated with the non-trauma group. Indications for mechanical ventilation in non-trauma patients are shown in Table 3.
In both groups there were 98 episodes of VAP, with 1.08 vs. 1.07 episodes per patient in the T and AT groups respectively. Thirty-two episodes in the T group (32.7%) and 38 (38.8%) in the AT group occurred in patients with recent antibiotic exposure (p > 0.20), whereas 50 (51.0%) in the T group and 57 (58.2%) in the AT group were late-onset VAP (p > 0.20). Eighty-four polymicrobial episodes were recorded, more frequently in trauma than in non-trauma patients. Overall, 278 microorganisms were isolated: 148 in the T group and 130 in the AT group. MSSA was the most frequent pathogen with 66 (23.7%) isolates, followed by Enterobacteriaceae with 59 (21.2%), H. influenzae 50 (18.0%), non-fermentative Gram-negative bacilli 48 (17.3%), Streptococcus species 37 (13.3%) and MRSA 18 (6.5%). The distribution of pathogens is detailed in Table 4.
In patients with trauma and early-onset infection, MSSA was the most frequently isolated pathogen. MSSA distribution in trauma and non-trauma patients at different periods of mechanical ventilation is shown on Fig. 1. Pathogens occurring more frequently in late-onset pneumonia included MSSA and non-fermentative Gram-negative bacilli. The non-fermentative Gram-negative bacilli were significantly more frequent in late-onset than in early-onset episodes. No difference in prevalence between early- and late-onset episodes was found for Enterobacteriaceae, Haemophilus or Streptococcus species.
In patients without trauma, Streptococcus species were the most frequent pathogen and significantly associated with early-onset infection. Haemophilus influenzae and MSSA tended to occur more frequently in early-onset episodes. Pathogens occurring more frequently in late-onset pneumonia were non-fermentative Gram-negative bacilli and Enterobacteriaceae.
In group 1 (early onset, no antibiotic) MSSA was significantly more frequent in trauma than in non-trauma patients (37.3% vs. 19.1%, p < 0.05). In these two subgroups, non-fermentative Gram-negative bacilli were rare. Among the four subgroups with early-onset pneumonia, MRSA was isolated (27.3%) only in non-trauma group 2 patients (early onset with antibiotic exposure). Although not statistically significant, an association was found between MRSA presence and non-trauma (OR = 5.2, 95% CI 0.8–41.8). In fact, all MRSA isolates were in non-trauma subgroups, except for a 10.3% prevalence in trauma group 4 (late onset with recent antibiotic exposure). Prevalence of other isolates was similar in the different subgroups. No MRSA isolates were documented in trauma patients within the first 10 days of ventilation.
The distribution of MRSA and MSSA prevalence in VAP episodes differed depending on the presence of trauma, recent antibiotic exposure, and time of pneumonia onset. MSSA was the most frequent isolate in all trauma subgroups. MSSA was associated with trauma (52.0% vs. 15.3%, p < 0.01), early onset (40.4% vs. 28.0%, p = 0.07) and absence of recent antibiotic exposure (40.5% vs. 21.4%, p < 0.01) whereas MRSA was associated with absence of trauma (15.3% vs. 3.1%, p < 0.01), late onset (14.0% vs. 3.4%, p = 0.01) and recent antibiotic exposure (17.1% vs. 4.8%, p < 0.01).
Discussion
This study demonstrates that trauma is a major determinant of the prevalence of microorganisms, epidemiology and outcomes in VAP. This suggest that the underlying disease should be considered in the initial decision on antibiotic choice in VAP. A unique feature of this study is that it analyzed pathogens in VAP comparing trauma with non-trauma in a multidisciplinary unit. MSSA was a major pathogen in VAP, with a notably higher occurrence in trauma patients, even in the presence of predisposing factors for multiresistant bacteria, whereas MRSA was found only rarely. Moreover, no episodes of early-onset VAP were caused by MRSA.
Our data demonstrated that different subsets of trauma and non-trauma patients were more likely to be infected by MSSA. However, the overall incidence of these pathogens was sufficiently high to warrant the use of empiric therapy likely to be active against these pathogens. Therefore, our data support the use of the currently recommended empiric therapy [7] for both trauma and non-trauma VAP.
Several studies have demonstrated an association between inadequate antibiotic therapy and mortality [4, 5]. Indeed, prompt initiation effective antibiotic regimen is the cornerstone of management and the role for combination therapy is to increase the likelihood that potential multiresistant pathogens will be adequately treated. Current guidelines [7] suggest that initial therapy for late onset pneumonia will usually require three antibiotics: two drugs of different classes active against non-fermentative Gram-negative bacilli, and a third for MRSA. In our institution, we found no MRSA in VAP episodes during the first 10 days in trauma patients, even in those episodes with recent antibiotic exposure. The addition of an antibiotic active against MRSA was unnecessary, and therapy without vancomycin or linezolid would have been adequate.
In trauma patients, most reports regarding microorganisms indicate that H. influenzae and MSSA are the most prevalent [22, 23]. These studies also report MSSA as a frequent isolate in late-onset episodes. In the current study, trauma patients were younger and 79.1% had coma; this condition significantly increased the risk of VAP due to MSSA. Other studies reported that comatose patients were more susceptible to early-onset pneumonia, particularly due to MSSA [24–28]. On the other hand, MRSA VAP has been associated with previous antibiotic exposure, COPD [29], or older age [30]. Our findings were consistent with these observations.
In our cohort, MSSA was the most frequent pathogen in trauma patients, but this did not involve a difference in therapy. The association between MSSA and trauma was described by Rello et al. [25] in 1992. Head trauma and coma are associated with MSSA VAP episodes. Nasal carriage and tracheal colonization of S. aureus on admission and within 24 h of intubation are known risk factors for early-onset pneumonia [31, 32]. Several studies have confirmed this finding, and in these patients antibiotic coverage for MSSA is mandatory [33, 34].
Pseudomonas aeruginosa and Acinetobacter baumannii were isolated in episodes with risk factors (late onset and prior antibiotics), whereas Enterobacteriaceae were isolated in all subsets. As expected, late-onset episodes have different rates of pathogens in T and AT groups, but this difference does not affect empirical antibiotic therapy because the same pathogens should be covered.
Some limitations should be noted in this study. First, this was a retrospective observational analysis. However, the data were collected prospectively by specialists trained in nosocomial infection surveillance. Second, the distribution of other potentially important predisposing factors, such as COPD, recent steroid use, coma, age, diabetes, surgery and vasopressor use, differed between trauma and non-trauma patients, and this may be partly responsible for the differences found between the two groups. Third, the influence of specific classes of prior antibiotics administered and particular resistance phenotypes was not analyzed. Information on exposure to specific antibiotic classes would also help the choice of specific empiric therapy, by avoiding the repetition of the same antimicrobial [35, 36]. Fourth, some reports regarding trauma patients suggest that some non-fermentative Gram-negative bacilli, such as Acinetobacter baumannii, may be more frequent in late-onset episodes [22, 37, 38]. We recognize that the relatively small size of this cohort may not have sufficient statistical power to identify differences regarding certain isolates with low prevalence, particularly in groups 2 and 4, or to perform a multi-variate analysis identifying potential confusion biases in the association between trauma and MSSA. Further studies in larger cohorts should clarify whether the documented association was due to trauma by itself or associated with the different comorbidities founded. Fifth, the study is from a single center and therefore institution-specific variables may have influenced the findings. Our results may not be generalizable to settings with a high MRSA prevalence. We used the duration of mechanical ventilation as a clinical parameter to categorize timing of pneumonia, because most of our patients (88% of trauma and 78% of non-trauma patients, p = 0.1) are admitted directly from the emergency department. We were unable to analyze our patients with VAP according to duration of hospitalization, as the ATS guidelines suggest [7]. We were also unable to analyze antibiotic treatment and prior hospitalization in the previous 3 months. The high number of patients admitted directly from the emergency department may reduce the potential impact of this limitation. Finally, some epidemics/outbreaks of colonization pressure by exogenous organisms (S. maltophilia, MRSA, etc.) and antibiotic exposure vary from institution to institution and this may limit the generalizability of our findings to other settings [39, 40]. We are aware that the specificity of BAL/PSB specimens is higher than that of quantitative tracheal aspirates, and specificity could be improved if only bronchoscopic studies were performed. However, recent studies [41, 42] did not find better results for mortality or de-escalation rates in patients with bronchoscopic studies.
In summary, the findings of this study indicate that trauma influences prevalence of pathogens in VAP. The differences in the microbiologic findings in early-onset VAP episodes between trauma and non-trauma patients—that is, the absence of MRSA in our trauma group—has clear implications for therapy. Restriction of glycopeptides or linezolid in empiric therapy to only those trauma patients with late-onset pneumonia and prior antibiotic exposure would mean avoiding the use of these antibiotics in 80% of episodes of VAP in trauma patients. In addition to reducing antibiotic-associated costs, this may help to reduce selection pressures for the emergence of antimicrobial resistance in the hospital.
References
Vincent JL, Bihari DJ, Suter PM, Bruining HA, White J, Nicolas-Chanoin MH, Wolff M, Spencer RC, Hemmer M (1995) The prevalence of nosocomial infection in intensive care units in europe. Results of the European prevalence of infection in intensive care (EPIC) study. Epic international advisory committee. JAMA 274:639–644
Fagon JY, Chastre J, Vuagnat A, Trouillet JL, Novara A, Gibert C (1996) Nosocomial pneumonia and mortality among patients in intensive care units. JAMA 275:866–869
Heininger A, Krueger WA, Doring G, Unertl K (2002) Ventilator-associated pneumonia. Curr Opin Anaesthesiol 15(2):153–159
Iregui M, Ward S, Sherman G, Fraser VJ, Kollef MH (2002) Clinical importance of delays in the initiation of appropriate antibiotic treatment for ventilator-associated pneumonia. Chest 122:262–268
Dupont H, Mentec H, Sollet JP, Bleichner G (2001) Impact of appropriateness of initial antibiotic therapy on the outcome of ventilator-associated pneumonia. Intensive Care Med 27:355–362
Sandiumenge A, Diaz E, Bodi M, Rello J (2003) Therapy of ventilator-associated pneumonia. A patient-based approach based on the ten rules of “The Tarragona Strategy”. Intensive Care Med 29:876–883
American Thoracic Society (2005) Guidelines for the management of adults with hospital-acquired, ventilator-associated, and healthcare-associated pneumonia. Am J Respir Crit Care Med 171:388–416
Rello J, Jubert P, Valles J, Artigas A, Rue M, Niederman MS (1996) Evaluation of outcome for intubated patients with pneumonia due to Pseudomonas aeruginosa. Clin Infect Dis 23:973–978
Rello J, Ausina V, Ricart M, Puzo C, Quintana E, Net A, Prats G (1994) Risk factors for infection by Pseudomonas aeruginosa in patients with ventilator-associated pneumonia. Intensive Care Med 20:193–198
Antonelli M, Moro ML, Capelli O, De Blasi RA, D'Errico DA, Conti G (1994) Risk factors for early-onset pneumonia in trauma patients. Chest 105:224–228
Kollef MH, Morrow LE, Niederman MS, Leeper KV, Anzueto A, Benz-Scott L, Rodino FJ (2006) Clinical characteristics and treatment patterns among patients with ventilator-associated pneumonia. Chest 129:1210–1218
Vidaur L, Gualis B, Rodriguez A, Ramirez R, Sandiumenge A, Sirgo G, Diaz E, Rello J (2005) Clinical resolution in patients with suspicion of ventilator-associated pneumonia: A cohort study comparing patients with and without acute respiratory distress syndrome. Crit Care Med 33:1248–1253
Rello J, Vidaur L, Sandiumenge A, Rodriguez A, Gualis B, Boque C, Diaz E (2004) De-escalation therapy in ventilator-associated pneumonia. Crit Care Med 32:2183–2190
Meduri GU, Chastre J (1992) The standardization of bronchoscopic techniques for ventilator-associated pneumonia. Chest 102:557S–564S
Centers for Disease Control (1989) CDC definitions for nosocomial infections. Am Rev Respir Dis 139:1058–1059
Beardsley J, Williamson J, Johnson J, Ohl C, Karchmer T, Bowton D (2006) Using local microbiologic data to develop institution-specific guidelines for the treatment of hospital-acquired pneumonia. Chest 130:787–793
Rello J, Sa-Borges M, Correa H, Leal SR, Baraibar J (1999) Variations in etiology of ventilator-associated pneumonia across four treatment sites: implications for antimicrobial prescribing practices. Am J Respir Crit Care Med 160:608–613
Rimel RW, Tyson GW (1979) The neurologic examination in patients with central nervous system trauma. J Neurosurg Nurs 11:148–155
Bernard GR, Artigas A, Brigham KL, Carlet J, Falke K, Hudson L, Lamy M, Legall JR, Morris A, Spragg R (1994) The American–European consensus conference on ARDS. Definitions, mechanisms, relevant outcomes, and clinical trial coordination. Am J Respir Crit Care Med 149:818–824
Lujan M, Gallego M, Fontanals D, Mariscal D, Rello J (2004) Prospective observational study of bacteremic pneumococcal pneumonia: Effect of discordant therapy on mortality. Crit Care Med 32:625–631
Rello J, Mariscal D, Gallego M, Valles J (2002) Effect of enriched thioglycolate on direct examination of respiratory specimens and guiding initial empirical therapy in intubated patients with pneumonia: a prospective, randomized study. Crit Care Med 30:311–314
Rincon-Ferrari MD, Flores-Cordero JM, Leal-Noval SR, Murillo-Cabezas F, Cayuelas A, Munoz-Sanchez MA, Sanchez-Olmedo JI (2004) Impact of ventilator-associated pneumonia in patients with severe head injury. J Trauma 57:1234–1240
Bochicchio GV, Joshi M, Bochicchio K, Tracy K, Scalea TM (2004) A time-dependent analysis of intensive care unit pneumonia in trauma patients. J Trauma 56:296–301
Espersen F, Gabrielsen J (1981) Pneumonia due to Staphylococcus aureus during mechanical ventilation. J Infect Dis 144:19–23
Rello J, Ausina V, Castella J, Net A, Prats G (1992) Nosocomial respiratory tract infections in multiple trauma patients. Influence of level of consciousness with implications for therapy. Chest 102:525–529
Rello J, Quintana E, Ausina V, Puzo C, Net A, Prats G (1990) Risk factors for Staphylococcus aureus nosocomial pneumonia in critically ill patients. Am Rev Respir Dis 142:1320–1324
Pickworth KK, Falcone RE, Hoogeboom JE, Santanello SA (1993) Occurrence of nosocomial pneumonia in mechanically ventilated trauma patients: a comparison of sucralfate and ranitidine. Crit Care Med 21:1856–1862
Koulenti D, Myrianthefs P, Dimopoulos G, Baltopoulos G (2005) Hospital-acquired pneumonia caused by methicillin-resistant Staphylococcus aureus. Enferm Infecc Microbiol Clin S3:37–45
Rello J, Torres A, Ricart M, Valles J, Gonzalez J, Artigas A, Rodriguez-Roisin R (1994) Ventilator-associated pneumonia by Staphylococcus aureus. Comparison of methicillin-resistant and methicillin-sensitive episodes. Am J Respir Crit Care Med 150:1545–1549
Kuehnert MJ, Hill HA, Kupronis BA, Tokars JI, Solomon SL, Jernigan DB (2005) Methicillin-resistant-Staphylococcus aureus hospitalizations, United States. Emerg Infect Dis 11:868–872
Campbel W, Hendrix E, Schwalbe R, Fattom A, Edelman R (1999) Head-injured patients who are nasal carriers of Staphylococcus aureus are at high risk for Staphylococcus aureus pneumonia. Crit Care Med 27:798–801
Brochard R, Albaladejo P, Brezac A, Geffroy P, Seince F, Morris W, Branger C, Marty J (2004) Early-onset pneumonia: risk factors and consequences in head trauma patients. Anesthesiology 100:234–239
Sirvent J, Torres A, Vidaur L, Armengol J, de Batle J, Bonet A (2000) Tracheal colonisation within 24h of intubation in patients with head trauma: risk factor for developing early-onset ventilator-associated pneumonia. Intensive Care Med 26:1369–1372
Ewig S, Torres A, El-Ebiary M, Fabregas N, Hernandez C, Gonzales J, Nicolas JM, Soto L (1999) Bacterial colonization patterns in mechanically ventilated patients with traumatic and medical head injury. Incidence, risk factors, and association with ventilator-associated pneumonia. Am J Respir Crit Care Med 159:188–198
Navon-Venezia S, Ben-Ami R, Carmeli Y (2005) Update on Pseudomonas aeruginosa and Acinetobacter baumannii infections in the healthcare setting. Curr Opin Infect Dis 18:306–313
Falagas ME, Kopterides P (2006) Risk factors for the isolation of multi-drug-resistant Acinetobacter baumannii and Pseudomonas aeruginosa: a systematic review of the literature. J Hosp Infect 64:7–15
Baraibar J, Correa H, Mariscal D, Gallego M, Valles J, Rello J (1997) Risk factors for infection by Acinetobacter baumanii in intubated patients with nosocomial pneumonia. Chest 112:1050–1054
Garnacho-Montero J, Ortys-Leiba C, Fernandez-Hinojosa E, Aldabo-Pallas T, Cayuela A, Marquez-Vacaro JA, Garcia-Curiel A, Jimenez-Jimenez FJ (2005) Acinetobacter baumanii ventilatior-associated pneumonia: epidemiological and clinical findings. Intensive Care Med 31:649–655
Eveillard M, Lancien E, Barnaud G, Hidri N, Gaba S, Benlolo JA, Joly-Guillou ML (2005) Impact of screening for MRSA carriers at hospital admission on risk-adjusted indicators according to the imported MRSA colonization pressure. J Hosp Infect 59:254–258
Muller AA, Mauny F, Bertin M, Cornette C, Lopez-Lozano JM, Viel JF, Talon DR, Bertrand X (2003) Relationship between spread of methicillin-resistant Staphylococcus aureus and antimicrobial use in a French university hospital. Clin Infect Dis 36:971–978
Heyland D, Cook D, Dodek P, Muscedere J, Day A, The Canadian Critical Care Trials Group (2006) A randomized trial of diagnostic techniques for ventilator-associated pneumonia. N Engl J Med 355:2619–2630
Shorr A, Sherner J, Jackson W, Kollef M (2005) Invasive approaches to the diagnosis of ventilator-associated pneumonia: a meta-analysis. Crit Care Med 33:46–53
Acknowledgements
We are indebted to Mr. Michael Maudsley for editing our English.
Author information
Authors and Affiliations
Corresponding author
Additional information
Supported by Fondo de Investigaciones Sanitarias (CIBERes 06/06/0036 and PI05/2410) and AGAUR (2005/SGR/920).
Rights and permissions
About this article
Cite this article
Agbaht, K., Lisboa, T., Pobo, A. et al. Management of ventilator-associated pneumonia in a multidisciplinary intensive care unit: does trauma make a difference?. Intensive Care Med 33, 1387–1395 (2007). https://doi.org/10.1007/s00134-007-0729-5
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s00134-007-0729-5