Hospital-acquired pneumonia, particularly ventilator-associated pneumonia (VAP), is one of the leading causes of infection and death in the healthcare setting.1 VAP is associated with prolonged hospitalization and increased health care costs.2 The incorrect or delayed treatment of VAP in the first few hours gives rise to a worse prognosis.3 VAP should thus be considered a microbiological emergency, yet in many institutions a microbiological diagnosis of VAP is not available around the clock. Information from the microbiology department serves to shorten the period of broad-spectrum empirical treatment and thus ensure a more restricted use of antimicrobial agents.4

Current VAP guidelines are imprecise about many issues related to its microbiological diagnosis5•8 such as the most suitable type of specimen, sample preservation, transport to the laboratory, attention given to these samples or results interpretation.

In addition, there is little information on present microbiological practices and their relative capacity to diagnose VAP.9,10 Individual studies suggest that practice often differs very much from literature recommendations.

The present study surveys several issues regarding the microbiological diagnosis of VAP in ICUs in Spanish hospitals from the perspective of both intensivists and microbiologists. The data collected in questionnaires were used to better define the approach taken in clinical practice and to pinpoint deficiencies that will help improve current guidelines on this important topic.

Thirty-four microbiology (42.5%) and thirty-seven ICU (46.3%) departments belonging to thirty-five Spanish hospitals agreed to participate in the study. Of these, 94% were public or mixed (public-private) institutions (only 2 were private centers). The population covered by the participating hospitals was approximately 10million inhabitants (range 50,819•750,000 per cent). The total number of available beds was 21,524 (range 110•1575 per center). Hospital admissions in the previous year were 857,631 and these generated 5,432,443 days of stay. Participating ICUs had 673 beds in total (range 6•48 per ICU); and 32,020 admissions and 173,820 days of stay over the whole year. Questionnaires were answered by attending physicians in 94% and 89% of the Microbiology and ICU departments, respectively, thus reflecting present working practices in those units. The locations and characteristics of the participating departments are shown in Tables 1 and 2 and Fig. 1. The median VAP incidence density was 8.7 episodes per 1000 ventilator-days (IQR 6.5•13.9).

Fig. 1.

Participating centers in Spain. Intensive care units (white diamonds) and microbiology departments (black diamonds).

(0.09MB).

Relevant information from the microbiology (Tables 1 and 2) and ICU (Tables 3 and 4) departments is indicated below.

Participating microbiology departments received 27,048 lower respiratory tract (LRT) samples during the previous year from adult ICUs, representing 15.3% of all LRT samples received, 844.7 LRT samples per 1000 ICU admissions and 1556.1 LRT samples per 10,000 days of ICU stay. These samples were immediately processed only in 29.4% of the hospitals, all of which had microbiology services available on a 24/7 basis. Most LRT samples were tracheal aspirates (82.9%). According to the microbiologists questioned, Gram staining was available in 88.2% of the laboratories but only 47.1% reported results immediately; in 5.9% of cases, Gram staining results were never reported. Molecular diagnostic techniques were routinely directly applied to LRT samples in 4 institutions (11.8%); if specifically requested, this could be done in a timely manner in a further 35.3% of centers. Only one center routinely undertook direct antimicrobial susceptibility testing on LRT samples from ICU patients with suspicion of VAP when microorganisms were seen in the Gram stain. This practice was nevertheless feasible in a further 17.6% of centers if requested by the intensivist. LRT samples were not usually tested for filamentous fungi, but when this was done, direct microscopy exams were not performed on a regular basis. The detection of galactomannan antigen in bronchoalveolar lavage (BAL) samples was available only in 26.5% of the microbiology departments. The diagnosis of herpesvirus in LRT samples was available in 50% of participating hospitals.

Quantitation of LRT samples was performed in 73.5% of the cases, mostly using a calibrated loop or pipette to plate serial dilutions (85.3%). Candida spp. were reported quantitatively and high counts (those above the diagnostic threshold) were considered significant in 38.2% of the departments.

Mean turnaround times (TAT) were 1.7 (SD 0.7) days for a microbiological report of a negative result and 2.2 (SD 0.6) for a positive result. These figures were increased by a mean 1.6 (SD 0.7) days if there was a weekend involved. Microbiological results were issued exclusively as a printed report in 52.9% of the departments. Telephone/in-person information about culture results of LRT samples from ICUs was offered by 64.7% of the hospitals. In 73.5% of the institutions, an epidemiological report for ICUs was provided on a regular basis.

The perceived quality of the microbiologists
tm) own microbiological diagnosis of VAP was rated on a scale from 0 (very poor) to 10 (excellent) as a median of 7 points (IQR 7•8). The perceived clinical impact of this diagnosis was awarded a median score of 8 (IQR 7•8). When asked about the opinion that their ICU colleagues had about the microbiological diagnosis of VAP, 8 points (IQR 6•8) were given. Microbiologists considered that the main factors hindering a microbiological diagnosis of VAP were a lack of staff/technicians (median 7 points, IQR 2.8•8), lack of resources (median 7 points, IQR 3•8) and lack of a microbiology service 24/7 (median 8 points, IQR 4.8•10). Almost half (47.1%) of the microbiologists considered that present recommendations for the microbiological diagnosis of VAP are insufficient and mentioned they would be willing to form part of a work group to establish a revised consensus approach to the etiological and microbiological diagnosis of VAP.

The data from the questionnaire administered to ICU departments (Tables 3 and 4) revealed that tracheal aspirates were the first samples most frequently collected for VAP diagnosis (89.2%). Bronchoscopy was only used in patients when a non-invasive sample had not provided an etiologic diagnosis, or with complicated or non-responding VAP.

Only 38% of the ICU departments admitted they performed surveillance LRT cultures once or twice per week. When asked about sample delivery to the microbiology department, intensivists reported this was done within one hour of collection in a median of 77.5% (IQR 40•90) of the ICUs. Sample submission to the laboratory was delayed in the evenings/nights in 22.9% of the departments, mainly (39.3%) due to limited reception hours in the Microbiology Department. In these cases, samples were improperly stored (room temperature, incubated at 35°C) in 40% of the ICUs.

Intensivists used the following bacterial thresholds for a diagnosis of VAP: >105cfu/mL for tracheal and bronchial aspirates (61.8% and 50%, respectively), >104cfu/mL for BAL (65.6%) and >103cfu/mL for a protected brush specimen (61.3%). As many as 85.7% of intensivists considered that quantitative culture results were very useful and 89.2% highly valued microbiological information for a diagnosis of VAP.

According to intensivists, the median TAT for preliminary susceptibility testing results was 2.5 days (IQR 2•3). The median time for a positive culture result was 4 days (IQR 3•5) and this increased to a median of 2 days (IQR 1•2) if there was a weekend involved.

Intensivists agreed with the microbiologists questioned that Candida spp. are responsible for pneumonia only in very few patients and when recovered from truly invasive samples (36.1%). The isolation of Aspergillus spp. was only considered significant in immunosuppressed patients (55.6% of cases). Most intensivists (62.8%) consider that the pathogenicity of herpesvirus in VAP in immunocompetent patients is uncertain, although 25.7% prescribed specific treatment when herpes virus was diagnosed.

In 52.8% of the hospitals, VAP episodes were routinely managed by intensivists alone without infectious disease (ID) consultation.

The questionnaires completed by intensivists revealed that no written procedures on sample collection and microbiological result interpretation were available in 50% of the departments. When written procedures were available, these were based on different guidelines (ATS 33.3%, national 16.7% and locally adapted 23.3%).

Intensivists mentioned that the main factors hindering a microbiological diagnosis of VAP were the lack of 24/7 microbiology services (median 6 points, IQR 2•8) and the long turnaround times of microbiological reports (median 5 points, IQR 2.8•7). One third (36.1%) of the intensivists reported that present recommendations for a microbiological diagnosis of VAP are imprecise and like the microbiologists stated they would be more than willing to help establish a set of detailed consensus guidelines for the etiological and microbiological diagnosis of VAP.

The results of our survey reveal different approaches to the diagnosis of VAP in ICUs across Spain and serve to identify areas for improvement. As reported in the literature, diagnostic techniques for VAP vary widely10 and guidelines for its diagnosis clarifying the role of the Microbiology Department are urgently required.

Unfortunately, we still lack a gold standard for VAP diagnosis. In this age of evidence-based medicine, guidelines play an important role in the diagnosis and management of life threatening diseases such as VAP. Guidelines for VAP have two primary goals: to reduce its overall incidence through preventive strategies, and to improve its morbidity and mortality by recommending appropriate management and treatment.11

When making a rapid microbiological diagnosis of VAP, only a third of ICUs had access to a laboratory with a 24/7 schedule. A Gram stain result was immediately obtained only in half of the hospitals. This contradicts present guidelines, which warn that LRT samples from patients with a suspicion of VAP should be analyzed within 2•4h of collection8 and that Gram stain findings should be immediately reported to aid in the diagnosis and management of VAP.12 Most clinicians argue that the average turnaround time for ID screening to have an impact on medical practice is about 2h for inpatients.13 The availability of a microbiology service on a 24/7 basis is therefore an essential requirement.

The most frequent LRT sample identified in the survey was a blind tracheal aspirate, consistent with most published reports.14•16 Invasive samples were reserved for patients in whom VAP diagnosis was difficult or whenever non-invasive samples had failed to provide an etiology. A microbiological diagnostic standard for VAP is still missing, reflecting the particularly poor quality of evidence in this area. No differences in mortality were detected when invasive or non-invasive samples were used to diagnose VAP.9,17 However, the invasive approach almost consistently prompts changes in the antibiotic regimen resulting in de-escalation and shorter antibiotic courses.18•20 Still, until better evidence emerges, the use of invasive bronchoscopic techniques is not recommended for the routine diagnosis of VAP.21

In the majority of hospitals, LRT samples were quantitatively plated. According to the thresholds put into practice, 18.8% of intensivists considered 104•105cfu/mL positive for a tracheobronchial sample and 15.6% considered 103•104cfu/mL positive for a protected brush specimen (PBS), likely overdiagnosing this disease. In a recent review of published data regarding the use of quantitative versus qualitative LRT cultures in patients with VAP published by the Cochrane Database of Systematic Reviews, no evidence was found that quantitative cultures resulted in reduced mortality, reduced ICU stay and time on mechanical ventilation, or in higher rates of antibiotic change.22 Similar results were obtained when invasive strategies were compared with non-invasive strategies.

The diagnostic approach to VAP seems up to the discretion of the clinician responsible for the patient. Factors to consider include local experience, expertise, availability, and cost. What does seem clear is that a timely microbiological diagnosis helps establish adequate antibiotic therapy, de-escalation,23 and reduces costs, as therapy may be tailored to less expensive antibiotics once culture results are available.1

The value of surveillance cultures has also been called into question. This practice is performed in half the hospitals of our survey. Existing evidence of the value of surveillance cultures is far from conclusive. The few studies addressing this question, besides including small patient numbers, have involved varying methods and different frequencies of sampling.24,25 In the studies by Delclaux and Boots, the sensitivity, specificity, and positive and negative predictive values of surveillance cultures ranged from 67 to 84%, 28.5 to 50%, 31 to 89% and 60 to 93%, respectively.26,27 In a study by Bouza and co-workers in patients undergoing heart surgery,28 the sensitivity of surveillance cultures was unacceptably low to justify their systematic use. It remains to be seen whether surveillance cultures allow for better empirical antibiotic therapy than the use of current treatment guidelines for this entity. As more reports solidify their clinical usefulness, cost is still probably the most important factor preventing the general use of systematic surveillance cultures.

With regards to the pathogenicity of specific microorganisms, for instance in the case of Candida spp., the American Society of Microbiology recommends their isolation be reported only if there is a heavy amount of pure growth from BAL or PBS cultures in certain immunocompromised patients (e.g., leukemia patients, solid organ transplant recipients or neonates).29 Despite this, a third of the microbiologists participating in our survey routinely informed of its isolation in a quantitative manner, and intensivists also took this information into account.

There are studies in which the isolation of Aspergillus spp. from LRT samples in ICU patients is representative of pulmonary aspergillosis in only half of the patients, as in our study.30•32 The diagnosis of pulmonary aspergillosis is not easy in this population, and there is no universally accepted definition, apart from the histologic diagnosis in lung tissue. In a recent multicenter Spanish study that prospectively collected data on ICU-acquired infections related to invasive devices, ICU patients were considered to have a pulmonary aspergillosis if Aspergillus spp. was isolated from two or more respiratory samples, patients presented with risk factors for this infection (mainly immunosuppression), and they did not respond to treatment with broad-spectrum antibiotics.33 In this study, it was found that up to 25% of patients with isolation of Aspergillus spp. from TRI samples received no antifungal treatment (or this had not been recorded), probably reflecting colonization/contamination and not a true infection. It is evident that for the diagnosis of this entity is not enough to have positive LRT cultures, given the ubiquity of this microorganism and its ability to colonize clinical samples and to contaminate culture plates.

The role of respiratory viruses in VAP remains uncertain. Some published data provide evidence that Herpesviridae could be associated with a more severe disease and adverse clinical outcome,34,35 though their specific role in the development of VAP remains to be defined. These qualms are reflected in our survey, in which few centers rarely attempted their diagnosis in these patients.

Our survey revealed that microbiology results were only sent as a printed report in the majority of hospitals, contributing to long turnaround times. Reporting selected results by telephone together with reasonably fast results is considered important for a quality service.36 In the centers included in our survey, turnaround times were significantly lengthened when microbiology services were interrupted by a weekend and could be extended to 6 days.

We should highlight that half the participating ICUs had no written protocols for the diagnosis and management of patients with VAP. Written procedures have shown their usefulness in preventing and therefore decreasing rates of VAP,37 catheter-related bloodstream infection38 or surgical site infection.39 Such standard procedures also serve to unify practices in settings such as VAP patient management.40

The microbiologists questioned here considered that the quality of the microbiological diagnosis of VAP at their centers was good having a high clinical impact, and believed that intensivists were satisfied with this quality. They considered that major hurdles for an adequate and timely diagnosis were a lack of personnel and resources and the absence of a microbiology department open 24/7. Microbiologists also considered that turnaround times for LRT samples were too long. Intensivists concurred with these views. Both stated that there is definitely room for improvement and that they would be willing to collaborate in an initiative to help improve the microbiological diagnosis of VAP. The role of microbiologists in the diagnosis and management of VAP is yet to be defined.

A robust diagnosis of VAP is required for patient management, for epidemiology surveillance programs, to measure the effectiveness of preventive measures and for clinical trials. VAP diagnosis has effectively been identified as a key area susceptible to substantial improvement.12

Guidelines play a significant role in improving the diagnosis and management of hospital-acquired infections such as VAP. Guideline implementation is difficult and requires multiple efforts. In a survey investigating why ICU physicians do not follow evidence-based guidelines for VAP, the reasons given were mainly disagreement with the interpretation of clinical trials, lack of resources and costs. The overall non adherence rate was 37%.41

This article is a plea for the more effective implementation of more-to-the-point guidelines that will ultimately benefit patients with VAP.

The authors declare no conflict of interest.