Opening Pandora’s box: the potential benefit of the expanded FAST exam is partially confounded by the unknowns regarding the significance of the occult pneumothorax
© Springer-Verlag 2010
Received: 12 December 2009
Accepted: 5 March 2010
Published: 7 April 2010
Point of care (POC) ultrasound brings another powerful dimension to the physical examination of the critically ill. A contemporary challenge for all care providers, however, is how to best incorporate ultrasound into contemporary algorithms of care. When POC ultrasound corroborates pre-examination clinical suspicion, incorporation of the findings into decision-making is easier. When POC ultrasound generates new or unexpected findings, decision-making may be more difficult, especially with conditions that were previously not appreciated with older diagnostic technologies. Pneumothoraces (PTXs), previously seen only on computed tomography and not on supine chest radiographs known as occult pneumothoraces (OPTXs), which are now increasingly appreciated on POC ultrasound, are such an example.
The relevant literature concerning POC ultrasound and PTXs was reviewed after an electronic search using PubMed supplemented by ongoing research by the Canadian Trauma Trials Collaborative of the Trauma Association of Canada.
OPTXs are frequently encountered in the critically injured who often require mechanical ventilation with positive pressure breathing (PPB). Standard recommendations for post-traumatic PTXs and the setting of PPB mandate chest drainage, recognizing a significant rate of complications related to this procedure itself. Whether these standard recommendations generated in response to obvious overt PTXs apply to these more subtle OPTXs is currently unknown, and evidence-based recommendations regarding appropriate therapy are impossible due to the lack of clinical studies.
OPTXs are a condition that illustrates how incorporation of POC ultrasound findings brings further responsibilities to critically appraise the significance of these findings in terms of patient outcomes and overall care. Adequately powered and adequately followed-up clinical trials addressing the treatment are required.
The examination: the expanded FAST examination
The focused assessment with sonography for trauma (FAST) has become a widely accepted and valuable tool for resuscitating patients with traumatic injury [14, 15]. A benefit of the increasing adoption of ultrasound (US) as an everyday tool used by clinicians to assess the critically ill and injured has been a natural curiosity to expand the scope of conditions being sought [2, 16]. The use of US to diagnose the presence of pneumothoraces (PTX) is one such example, leading to the concept of the expanded or EFAST [9, 17]. The healthy lung itself is not an obvious target organ for examination with US. As air has a very high acoustic reflectance, only artifacts are normally identified deep–normal pleural surfaces . Thus, the majority of life-threatening post-traumatic thoracic trauma is pleural based. These include rib fractures, flail chests, hemothoraces, and PTX [19, 20]. The physiologic pleural movements that occur with respiration, either spontaneous or assisted, are therefore accurately and quickly depicted using simple bedside US [21–23].
The concept of employing US to exclude or infer the presence of a PTX relies on the fact that if the pleural surfaces are proven to be in apposition, then by definition an intra-pleural collection of air is excluded. For this physiologic “lung sliding” (LS) to be seen, both pleural surfaces must be accessible to be imaged, and thus must be either contiguous or separated by a layer of fluid [9, 21, 23–25]. In PTX, the intra-pleural air will separate the two pleural surfaces and lung sliding will not be identified since the visceral pleura are inaccessible to the US beam. With a PTX, the images seen are horizontal reverberation artifacts with no evidence of LS. Besides LS, another US finding also affects the confidence of diagnosis. “Comet tail” artifacts (CTA) are reverberations believed to arise from distended water-filled interlobular septae under the visceral pleura. These are presumed to be the US equivalents of the “Kerley B lines” seen on CXR [26, 27] as they can only be seen when the visceral pleura is in apposition to the parietal pleura.
Using this diagnostic approach, numerous investigators have begun to use ultrasound to diagnose the presence of pneumothoraces. Initial studies explored the potential of US to infer the presence of pneumothoraces in veterinary settings , after lung biopsies [18, 34, 35], and in a mixed group that included three stable trauma patients . Much of the pioneering work arose from Dr. Lichtenstein’s [21, 24, 26] group in Paris. North American interest in this technique was greatly facilitated by specific space medicine-related needs arising from the presence aboard the International Space Station of a high quality ultrasound capability, without any other medical diagnostic capabilities. NASA-associated research thus examined basic science and clinical questions both in terrestrial- and space-analog environments [23, 29, 36–42]. In the course of these investigations it became apparent that there were frequently cases whereby ultrasound appeared to be more sensitive in detecting pneumothoraces after trauma than the supine chest radiograph [8–10, 23, 43]. One study utilizing the EFAST during acute trauma resuscitations found that in patients with CT corroboration, the expanded FAST was more than twice as sensitive as supine chest X-ray . Since this study, other authors have also reported remarkably high accuracies for detecting OPTXs [8, 44], and have even documented good correlation between the estimated PTX size and the CT findings (Spearman’s rank correlation 0.82) using the relative thoracic topography of lung sliding .
The condition: occult pneumothoraces
It should not be surprising that ultrasound appears to out perform the supine chest radiograph in terms of diagnosing post-traumatic pneumothoraces. This is because of the ever increasingly recognized phenomenon of the occult pneumothorax (OPTX) . This term describes a pneumothorax (PTX) that while not suspected on the basis of either clinical examination or plain radiograph, but is ultimately detected with thoraco-abdominal computed tomogram (CT) [3, 4, 6, 7, 45, 46]. This situation is increasingly common with the increased use of CT. The incidence appears to approximate 5% in injured populations presenting to hospital [45, 47–52], with CT revealing at least twice as many PTXs as suspected on plain radiographs [43, 47, 50, 52–56].
The clinical quandary: what to do with occult pneumothoraces?
The EFAST technique provides a means of detecting many OPTXs that would have been missed if only supine CXRs were being obtained, or diagnosed in a delayed fashion if CT scans were obtained in all traumatized patients. An earlier diagnosis might be especially beneficial in pre-hospital and air transport environments [17, 57]. Though the patient is admitted to a hospital setting, the importance of detecting OPTXs remains largely unknown because the clinical importance of OPTXs themselves remains somewhat unclear and controversial [3, 58]. While PTXs are a common and treatable cause of mortality and morbidity, there is clinical equipoise regarding the appropriate treatment of the OPTX [3, 58]. This is especially true in those who are critically ill and require positive pressure ventilation (PPV). This is also the group for whom the highest rates of chest tube complications have been reported . More specifically, complication rates related to tube thoracostomy have been reported in up to 21% of cases [11, 12, 59, 60]. While the patient undergoing PPV is at the greatest risk, proper management of an OPTX is extremely controversial and based on little scientific evidence. Many of these patients are already compromised due to acquired or pre-existing pulmonary pathology, and clinical respiratory distress may be masked by concomitant respiratory support and sedation. Conversely, these patients are constantly monitored and cared for in settings where immediate medical intervention is possible. Kolleff  also reported that ventilated patients with PTXs were statistically more likely to develop tension pneumothoraces when the diagnosis was missed or delayed. The guidelines of the Advanced Trauma Life Support Course state that general anesthesia or positive pressure ventilation should never be administered to a patient who has sustained a traumatic pneumothorax, or who is at risk for an unexpected pneumothorax, without chest tube insertion . The potential risk of progression of a known PTX, to a tension PTX, is thus a significant concern, with many opinions recommending prophylactic chest tube placement for the patient who is subjected to positive pressure ventilation [45, 47, 53, 54, 62–64].
However, other sources differ. In one review, the size of the OPTX and number of rib fractures indirectly affected outcome by influencing when clinicians placed chest tubes . If an OPTX was less than 5 mm × 80 mm, and associated with two or less rib fractures, patients were managed conservatively, irrespective of the need for ventilation. Ten of 17 (59%) total patients managed without chest tubes were intubated and ventilated with positive pressures. None required emergency chest tube, although three of these ten (30%) ultimately required tube thoracostomy for progression of their PTX . Another retrospective review of 26 patients compared the characteristics and outcomes of 13 who were observed with repeated chest radiography and 11 who underwent early chest tube . Ten of the 26 were ventilated, of which six were managed without a chest tube. Despite the fact that one of these (17%) failed observation (PTX progression), they concluded that there was no indication of an OPTX warranted a prophylactic chest tube prior to positive pressure ventilation . Wolfman observed OPTX’s in 36 patients. Thirteen of 16 “miniscule” occult PTXs, and 11 of 20 moderate (anterior) PTXs were managed successfully without chest tube for a 11% failure rate of observation, including one tension pneumothorax . The eight remaining antero-lateral PTXs were all treated with tube thoracostomy, whether intubated or not. They concluded that only small and moderate occult PTXs without mechanical ventilation could be safely observed based on their results as they had not randomized the larger OPTXs . Guerrero-Lopez  stated that OPTXs did not always necessitate treatment despite mechanical ventilation, if they were “small and without complications”.
The best, although very limited, evidence guiding management of occult PTXs in ventilated patients originates from two small prospective randomized studies. Enderson  randomized 40 patients with occult PTXs to chest tube  or observation , regardless of mechanical ventilation. Fifteen observed patients were ventilated, as were 12 with early chest tubes. Eight of the 15 (53%) had pneumothorax progression with ventilation, three suffering tension PTXs. As none of the patients with tube thoracostomy suffered any major complication, they recommended that all patients with OPTX, who require mechanical ventilation, have chest tubes placed. They felt that the size of the initial OPTX was not predictive of the risk of a tension PTX. Conversely, in 1999, Brasel  reported on a prospective randomized trial in 39 blunt trauma patients with 44 occult PTX’s. Nine patients in each group were ventilated, and there was no statistical difference in the sizes of OPTX’s. There were no differences in complications, and no patients in either group required emergent tube thoracostomy for respiratory compromise. Given the small numbers, this neither reach statistical significance, nor was there any association between size of the OPTX and failure of conservative treatment . They concluded, however, that OPTX’s could be safely observed in ventilated patients. When critically appraised, the power of these small studies was insufficient to truly detect differences . If a true difference existed between these studies, another explanation for the potential discordance might also involve differences in ventilatory management, as most of latter patients were in the intensive care unit and most of former were in the operative suite. Approaches to ventilation strategies in general also changed significantly over the last decade. Decreased airway pressures and tidal volumes became routine in the critically ill, wherein ventilatory management stressed careful attention to controlling peak and mean airway pressures, and limiting pressures below those considered routine previously [67–69]. To further address this clinical question, the Canadian Trauma Trials Collaborative of the Trauma Association of Canada has initiated a multi-center prospective randomized trial of treating or observing selected mechanically ventilated patients with OPTXs .
Is POC ultrasound the hope at the bottom of Pandora’s box?
Pandora had been given a large jar (rather than a box) and instruction by Zeus to keep it closed, but she had also been given the gift of curiosity, and ultimately opened it. When she did so, all of the evils, ills, diseases, and burdensome labor that mankind had not known previously, escaped from the jar, but it is said, that at the very bottom of her jar, there lay hope . We do believe that there definitely is hope, at the bottom of the unknowns, potential misdiagnoses, and iatrogenic harm that may occur from knowing without understanding, and that POC ultrasound is simply the latter—understanding our patients better. This understanding occurs on many levels, however, such as having a greater fidelity of imaging. No longer does a PTX need to be simply there or not there. POC ultrasound has the ability to discern in real-time how big in terms of chest topography the PTX is, and whether it is expanding or decreasing in size [44, 72]. This understanding also requires detailed studies on outcomes; now that we will know more about our patients; we need to know what maters and what does not. It is in this realm that evidence-based medicine becomes critical.
At the present time, the EFAST examination is able to identify previously undetected pneumothoraces after injury in our sickest patients. The question remains though, how does this help them? Are occult pneumothoraces important or will we injure more patients by acting on this information and draining all the pleural spaces concerned? Only well constructed and conducted prospective research appropriately related to the overall clinical needs of the patient can answer this . Until these results are available, however, we would suggest that awareness and respect for the power of ultrasound as knowledge rather than ignorance of the unknown are the first and hopeful step in understanding.
This work has been supported in part by the Derek Thompson Memorial grant from the Canadian Intensive Care Foundation and in part by the Research Committee of the Trauma Association of Canada.
Conflict of interest
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