Trauma

The area of most extensive study regarding prehospital ultrasound is the Focused Assessment with Sonography in Trauma (FAST) examination to detect traumatic cardiac tamponade and intraperitoneal bleeding [6,9–13]. The current standard is for the FAST exam to be performed immediately upon arrival to the trauma center during advanced trauma life support physical examination surveys. However, Walcher et al. demonstrated that performing prehospital FAST (PFAST) ultrasounds at the trauma scene changed management in 30% of patients with a 93% sensitivity and 99% specificity for detecting intraperitoneal free fluid [6]. Identification of free fluid enabled providers to reduce patient blood loss by providing permissive hypotension, and non-essential therapies were avoided to shorten time to surgery. Advance notification of PFAST results was provided to receiving hospitals, which then activated surgical teams when needed. In 22% of patients, the choice of receiving hospital was changed based on the ultrasound findings. Due to the results of this study, one major German air rescue provider incorporated PFAST into its algorithm for trauma management [6]. Other studies have demonstrated successful paramedic performance of the PFAST exam while en route, on ground or in air, without prolonging time to transport [4,10,14].

Of note, ultrasound cannot distinguish blood from ascitic fluid or pinpoint exact areas of bleeding. It is not sensitive in the detection of retroperitoneal fluid, organ injury, or hollow viscus injury. These limitations of ultrasound may cause delayed or missed fluid detection on out-of-hospital or triage FAST exam [15–17]. It remains to be seen whether positive findings on a PFAST exam in the United States would alter management as illustrated in the Walcher study [6], since many trauma centers in the US have immediate response by trauma teams and protocols in place to mobilize operating theaters quickly.

The FAST detection of pericardial fluid may have more potential for prehospital intervention. A dramatic case report details the course of a 17-year-old 26-week pregnant female suffering from a stab injury. Despite field chest tube placement with evacuation of air and blood, the patient’s vital signs declined. Ultrasound revealed a significant amount of pericardial fluid, which was immediately drained in the field and again in the emergency department. The patient ultimately survived, largely due to prehospital intervention [18]. Similarly, another report describes how in-ambulance paramedic detection of traumatic pericardial effusion and subsequent alerting of the receiving team facilitated direct operative intervention [11]. These cases highlight the potential for the PFAST exam to change prehospital practice and guide on-scene resuscitative therapies.

Pulmonary

While the Extended FAST exam (eFAST), including evaluation of pleural sliding, has been imprinted into emergency department and trauma protocols, it has not become standard in the prehospital environment. Adoption of sonographic pneumothorax evaluation may be invaluable in the trauma setting, as physical exam findings and ancillary monitoring have proven insensitive or difficult to discern in a noisy ambulance or helicopter [5,7,8,19]. Detection may facilitate prehospital needle thoracostomy and prevent development of tension pneumothorax. Additionally, ruling out pneumothorax avoids unnecessary procedures and their sequelae, allowing focus on other resuscitative efforts [5].

Equally, assessments of lung sliding and pleural effusion have become useful adjuncts in the management of acute dyspnea. Zechner et al. report a common scenario encountered by prehospital personnel: a patient with a history of both chronic obstructive pulmonary disease (COPD) and congestive heart failure (CHF) presenting in severe respiratory distress with wheezing. When pulmonary edema was discovered via on-ambulance sonographic B-lines, treatment was immediately altered to discontinue terbutaline and proceed with urapidil (an alpha₁-antagonist), enabling rapid improvement in the patient’s clinical status [20]. Subsequently, a German group developed a prehospital chest protocol to evaluate undifferentiated dyspnea. Using the subxiphoid cardiac view, bilateral coronal views, and bilateral anterior intercostal views, this protocol investigates pericardial or pleural effusion, pneumothorax, and right heart distension for pulmonary embolus. Providing supportive information in 68% of their patients and most useful for finding pleural effusion in decompensated CHF, prehospital ultrasound guided emergency physician management at the hospital [8].

Another area of rising interest is sonographic confirmation of endotracheal tube placement as an adjunct to capnometry. Brun et al. describe verification of tube position during cardiopulmonary resuscitation (CPR) by viewing bilateral pleural sliding when there was sudden absence of end-tidal CO₂ detection and limited ability to perform auscultation due to noise in the vehicle [21].

Prehospital lung ultrasound appears useful in revealing the presence or absence of pneumothorax, detecting pulmonary edema, narrowing diagnosis among differing respiratory disease processes, identifying pleural effusion, and as a supplement to current respiratory monitoring techniques.