Anatomy and Pathophysiology

Subcutaneous emphysema in the presence of chest wall trauma usually indicates a more serious thoracic injury. Although the presence of air in the tissues is a benign condition, in the context of chest trauma it usually represents serious injury to any air-containing structure within the thorax. Air enters the tissues either extrapleurally or intrapleurally. Extrapleural tears in the tracheobronchial tree allow air to leak into the mediastinum and soft tissues of the anterior neck, producing a pneumomediastinum, which rarely may progress to a tension pneumomediastinum. This most often occurs in patients who are undergoing positive-pressure ventilation and have a pneumopericardium visible on chest x-ray examination. They may also have Hamman’s crunch, which is a crackling sound with each heartbeat, heard on cardiac auscultation. Intrapleural lesions, however, usually produce a pneumothorax by allowing air to escape the lung through the visceral pleura into the pleural space and then through the parietal pleura into the thoracic wall.

An esophageal tear resulting from Boerhaave’s syndrome or penetrating injury may also produce a pneumomediastinum manifested by subcutaneous emphysema over the supraclavicular area and anterior neck. An additional cause of subcutaneous emphysema, which may or may not be indicative of intrathoracic injury, is found immediately adjacent to a penetrating wound of the thorax. A small amount of air may be introduced into the adjacent subcutaneous tissues from the outside at the time of penetration. However, it is assumed that this is secondary to a pneumothorax or pneumomediastinum, and appropriate diagnostic and therapeutic maneuvers to rule out or treat the intrathoracic injury should be carried out.

The presence of localized subcutaneous emphysema over the chest wall in the presence of blunt trauma is usually indicative of the presence of a traumatic pneumothorax, whereas the presence of subcutaneous emphysema over the supraclavicular area and anterior neck usually indicates a pneumomediastinum.

Management

Tension pneumothorax is considered and treated appropriately. If a tension pneumopericardium is suspected, then immediate pericardiocentesis with aspiration of air from the pericardial space may be lifesaving.

Although subcutaneous emphysema is a benign condition, massive accumulations can be uncomfortable to the patient. The underlying cause, such as pneumothorax, ruptured bronchus, or ruptured esophagus, is treated appropriately. Benign pneumomediastinum secondary to a Valsalva maneuver is treated with observation and high-flow oxygen to facilitate the reabsorption of nitrogen from tissues because the volume of nitrogen causes the discomfort.

Epidemiology

Pulmonary contusion is reported to be present in 30 to 75% of patients with significant blunt chest trauma, most often from MVCs with rapid deceleration.¹ Pulmonary contusion can also be caused by high-velocity missile wounds and the high-energy shock waves of an explosion in air or water. Pulmonary contusion is the most common significant chest injury in children, and it is most commonly caused by an MVC or an automobile versus pedestrian accident.²¹

Anatomy and Pathophysiology

Pulmonary contusion is a direct bruise of the lung parenchyma followed by alveolar edema and hemorrhage but without an accompanying pulmonary laceration, as first described by Morgagni in 1761.²⁶

The early diagnosis of pulmonary contusion is important if treatment is to be successful. The onset may be insidious, and therefore it should be suspected from the history of the mechanism of injury rather than the initial chest radiograph. Great force is required to produce pulmonary contusion, such as from a fall from height, an MVC, and other forms of significant trauma.

Clinical Features

The clinical manifestations include dyspnea, tachypnea, cyanosis, tachycardia, hypotension, and chest wall bruising. There are no specific signs for pulmonary contusion, but hemoptysis may be seen sometime during the patient’s course, and moist rales or absent breath sounds may be heard on auscultation. Palpation of the chest wall commonly reveals fractured ribs. If flail chest is discovered, pulmonary contusion is commonly present.

Surprisingly, many of the worst contusions occur in patients without rib fractures. It has been theorized that the more elastic chest wall, as in younger individuals, transmits increased force to the thoracic contents. Although isolated pulmonary contusions can exist, they are associated with extrathoracic injuries in the majority of patients.²⁷

Diagnostic Strategies

Care is taken not to focus exclusively on more dramatic injuries at the expense of failing to recognize the evolving pulmonary contusion. This is particularly true with the initial x-ray studies when overlying rib fracture, pneumothorax, aspiration pneumonitis, or poor radiograph quality may mask the contusion.

Typical radiographic findings begin to appear within minutes of injury and range from patchy, irregular, alveolar infiltrate to frank consolidation (Fig. 45-4). Usually, these changes are present on the initial examination, and they are almost always present within 6 hours. The rapidity of changes on chest x-ray visualization usually correlates with the severity of the contusion. Pulmonary contusion should be differentiated from acute respiratory distress syndrome (ARDS), with which it is often confused because the radiographic appearance of the two conditions may be similar. The contusion usually manifests within minutes of the initial injury, is usually localized to a segment or a lobe, is often apparent on the initial chest study, and tends to last 48 to 72 hours. ARDS is diffuse, and its development is usually delayed, with onset typically between 24 and 72 hours after injury.²⁸

The increased frequency of CT scans for blunt trauma patients has resulted in a corresponding increase in the diagnosis of pulmonary contusion. CT scans have been shown to detect twice as many pulmonary contusions as plain radiographs.⁷ Some authors suggest that pulmonary contusions visible only on CT scan and not on plain radiographs may not be clinically significant.²⁹

Chest CT scan is particularly valuable to identify a pulmonary contusion in the acute phase after injury because plain chest x-ray films have a low sensitivity.⁷ Although CT scan may not be necessary to make the diagnosis of a pulmonary contusion that is evident on plain chest radiography, it may be helpful to further define the extent of the contusion and to identify other thoracic injuries. Infectious complications, sternoclavicular joint dislocation, pneumothorax, misplaced endotracheal tube, intraperitoneal air, and vertebral fracture have all been identified by CT scan in the trauma patient. Occult pulmonary contusions are those that are visible only on CT scan, not plain radiographs, and usually involve more than 20% of the lung volume. These “occult” pulmonary contusions are not associated with a worse clinical outcome as compared with blunt trauma patients without pulmonary contusion.²⁹ Patients with pulmonary contusion visible on both conventional chest radiographs and the CT scan frequently have a higher contusion volume and a worse outcome than patients with occult pulmonary contusion. Thus pulmonary contusions that are visible on plain chest radiographs have a higher morbidity and mortality and should therefore receive special medical attention as compared with contusions only seen on the chest CT scan.

Arterial blood gases may be helpful in making the diagnosis of pulmonary contusion because most patients are hypoxemic at the time of admission. A low partial pressure of oxygen (PO₂) alone may be reason to suspect pulmonary contusion. A widening alveolar-arterial oxygen difference indicates a decreasing pulmonary diffusion capacity of the patient’s contused lung, and it is one of the earliest and most accurate means of assessing the current status, progress, and prognosis.

Management

Treatment for pulmonary contusion is primarily supportive.²⁹ When only one lung has been severely contused and has caused significant hypoxemia, consideration should be given to intubating and ventilating each lung separately with a dual-lumen endotracheal tube and two ventilators. This allows for the difference in compliance between the injured and the normal lung and prevents hyperexpansion of one lung and gradual collapse of the other.³⁰ As with flail chest, however, intubation and mechanical ventilation should be avoided if possible because they are associated with an increase in morbidity, including pneumonia, sepsis, pneumothorax, hypercoagulability, and longer hospitalization.³¹ The need for mechanical ventilation increases significantly when the area of pulmonary contusion exceeds 20% of total lung volume.³²

Certain patients may benefit from a trial of noninvasive positive-pressure ventilation with BPAP or CPAP to avoid intubation and mechanical ventilation. In those patients most severely injured with extensive pulmonary contusions and the development of ARDS with severe hypoxia refractory to conventional therapy, some small studies suggest a possible role for extracorporeal membrane oxygenation.³³

Certain procedures may ameliorate the pulmonary contusion, including the restriction of intravenous fluids to maintain intravascular volume within strict limits and aggressive supportive care consisting of vigorous tracheobronchial toilet, suctioning, and pain relief. These maneuvers may preclude the need for ventilator support and allow a more selective approach to flail chest and pulmonary contusion.

Another area of controversy in the management of pulmonary contusions is the appropriate use of crystalloid versus colloid solutions in resuscitation of the multiply injured patient with suspected contusion. Because of the potential for colloid sequestration within the pulmonary alveoli as a result of capillary leak, colloids are not recommended for use in treating these patients.

Pneumonia is the most common complication of pulmonary contusions, and it significantly worsens the prognosis. It develops insidiously, especially in patients treated with prophylactic antibiotics. Antibiotics should be reserved for use with specific organisms rather than given prophylactically.

Epidemiology

Pneumothorax, which is the accumulation of air in the pleural space, is a common complication of chest trauma. It is reported to be present in 15 to 50% of patients who sustain significant chest trauma, and it is invariably present in those with transpleural penetrating injuries.¹

Anatomy and Pathophysiology

Pneumothorax can be divided into three types depending on whether air has direct access to the pleural cavity: simple, communicating, and tension. A pneumothorax is considered simple (Fig. 45-5) when there is no communication with the atmosphere or any shift of the mediastinum or hemidiaphragm resulting from the accumulation of air. It can be graded according to the degree of collapse as visualized on the chest radiograph. A small pneumothorax occupies 15% or less of the pleural cavity, a moderate one 15 to 60%, and a large pneumothorax more than 60%. Traumatic pneumothorax is most often caused by a fractured rib that is driven inward, lacerating the pleura. It may also occur without a fracture when the impact is delivered at full inspiration with the glottis closed, leading to a tremendous increase in intra-alveolar pressure and the subsequent rupture of the alveoli. A penetrating injury, such as a gunshot or stab wound, may also produce a simple pneumothorax if there is no free communication with the atmosphere (Fig. 45-6).

Clinical Features

Shortness of breath and chest pain are the most common presenting complaints of pneumothorax. The patient’s appearance is highly variable, ranging from acutely ill with cyanosis and tachypnea to misleadingly healthy. The signs and symptoms are not always correlated with the degree of pneumothorax. The physical examination may reveal decreased or absent breath sounds and hyper-resonance over the involved side as well as subcutaneous emphysema, but small pneumothoraces may not be detectable on physical examination.

Patients with tension pneumothorax become acutely ill within minutes and develop severe cardiovascular and respiratory distress. They are dyspneic, agitated, restless, cyanotic, tachycardic, and hypotensive and display decreasing mental activity. The cardinal signs of tension pneumothorax are tachycardia, jugular venous distention (JVD), and absent breath sounds on the ipsilateral side. However, JVD may not reliably be present with massive blood loss. Hypotension will not occur as early as hypoxia and may represent a preterminal event.

Diagnostic Strategies

Because intrapleural air tends to collect at the apex of the lung, the initial chest radiograph should be an upright full inspiratory film if the patient’s condition permits. An upright film will often reveal small pleural effusions that are not visible on supine films, and it also allows better visualization of the mediastinum. Although the chest radiograph has traditionally been the preferred initial study for diagnosing a simple pneumothorax, emerging literature suggests that a simple pneumothorax can be identified during the initial US examination of the trauma patient as part of the extended focused assessment with sonography in trauma (E-FAST) examination. Because FAST is becoming part of the routine initial evaluation of trauma patients, evaluation for the presence of a pneumothorax should be included in this rapid bedside examination, especially because this is performed before chest radiography. In fact, several studies have found that the US has greater sensitivity for pneumothorax than chest radiography.34–36

If a pneumothorax is suspected but not visualized on the initial inspiratory film, an expiratory film should be obtained because it makes the pneumothorax more apparent by reducing the lung volume. Notably, as many as one third of initial chest x-ray films will not detect a pneumothorax in trauma patients.⁷ Although it is not recommended as a primary method of diagnosing pneumothorax, CT is very sensitive in finding small pneumothoraces even in supine patients. When CT scans are obtained to evaluate the abdomen, it may be helpful to take a few low cuts into the chest to exclude the presence of a small pneumothorax.

Occult Pneumothorax

A pneumothorax that is absent on the initial chest radiograph but is identified on subsequent chest or abdominal CT is called an occult pneumothorax. Occult pneumothorax is being diagnosed more frequently given the increased use of CT.37,38 Studies have found rates as high as 75% for diagnosis on CT scan of occult pneumothorax that was absent on initial chest radiographs (Fig. 45-10).^7,37–39

The diagnosis and treatment of tension pneumothorax should not be delayed. Although tension pneumothorax usually occurs dramatically, the clinical diagnosis is occasionally obscure, and chest x-ray examination may be required to suggest the diagnosis, particularly in patients on mechanical ventilation. This film will show complete lung collapse and shift of the mediastinum to the opposite side. Ideally, the diagnosis and treatment should be completed without a chest x-ray examination because the delay in obtaining this radiograph may adversely affect patient outcome. As previously stated, tension pneumothorax will typically cause significant hemodynamic compromise and therefore remains a clinical diagnosis.

Management

In the setting of penetrating trauma in which the patient is asymptomatic and the initial chest x-ray study is negative, the patient can be safely observed and the x-ray examination repeated. Previously, it was thought that if the patient was still asymptomatic and the radiograph negative after 6 hours, the patient could be discharged. Recent experience indicates that 3 hours is probably effective and safe for observation, with repeat x-ray film before discharge for patients with penetrating trauma.⁴⁰ Patients with blunt trauma in whom clinical suspicion for pneumothorax is high should still undergo a 6-hour delayed chest x-ray examination before discharge. However, if the stable patient undergoes initial screening chest CT that is negative for pneumothorax or hemothorax, the literature suggests that obtaining a delayed chest x-ray film is unnecessary, and these patients may be discharged from the ED.⁴¹

Epidemiology

Hemothorax, which is the accumulation of blood in the pleural space after blunt or penetrating chest trauma, is a common complication that may produce hypovolemic shock and dangerously reduce vital capacity. It is commonly associated with pneumothorax (25% of cases) as well as extrathoracic injuries (73% of cases).⁵⁰

Anatomy and Pathophysiology

Hemorrhage from injured lung parenchyma is the most common cause of hemothorax, but this tends to be self-limited unless there is a major laceration. Specific vessels are less often the source of hemorrhage, with intercostal and internal mammary arteries causing hemothorax more often than hilar or great vessels. Bleeding from the intercostal arteries may be brisk, however, because they branch directly from the aorta.

Management

Close monitoring of the initial and ongoing rate of blood loss is performed. Immediate drainage of more than 1500 mL of blood from the pleural cavity is usually considered an indication for urgent thoracotomy. Perhaps even more predictive of the need for thoracotomy is a continued output of at least 200 mL/hr for 3 hours. General considerations for urgent thoracotomy are outlined in Box 45-2.⁵¹

Clinical Features

Depending on the rate and quantity of hemorrhage, varying degrees of hypovolemic shock will be manifested. Tactile fremitus is decreased, and breath sounds are diminished or absent.

Diagnostic Strategies

The upright chest radiograph remains the primary diagnostic study in the acute evaluation of hemothorax. A hemothorax is noted as meniscus of fluid blunting the costophrenic angle and tracking up the pleural margins of the chest wall when viewed on the upright chest x-ray film. Blunting of the costophrenic angles on upright chest radiograph requires at least 200 to 300 mL of fluid. The supine view chest film is less accurate, and it may be more difficult to make the diagnosis with the patient in this position. Unfortunately, this is often the only film available because of the patient’s unstable condition. In the supine patient, blood layers posteriorly, creating a diffuse haziness that can be rather subtle, depending on the volume of the hemothorax (Fig. 45-11).With a massive hemothorax, the large volume of blood can create a tension hemothorax, with signs and symptoms of both obstructive and hemorrhagic shock (Fig. 45-12).

As is the case with pneumothoraces, US has much greater sensitivity than chest radiography in the detection of a small hemothorax, but CT scanning has the highest sensitivity, with some studies reporting up to a 25% incidence of hemothoraces diagnosed by CT that were not detected on chest radiography (Fig. 45-13).⁷ Perhaps more important, almost half of these occult hemothoraces underwent drainage with tube thoracostomy.⁵² Furthermore, one drawback of ultrasonography for the identification of traumatic hemothorax is that associated injuries readily seen on chest radiographs in the trauma patient, such as fractures or a widened mediastinum, are not readily identifiable on chest ultrasonography (Fig. 45-14). However, chest radiography and early bedside ultrasonography usually detect clinically significant hemothoraces and should routinely be performed. Delayed hemothorax may be associated with significant morbidity because the residual blood may serve as a nidus for the development of empyema or fibrothorax.

Management

Treatment of hemothorax consists of restoring the circulating blood volume, controlling the airway as necessary, and evacuating the accumulated blood. Tube thoracostomy allows constant monitoring of the blood loss, and serial chest radiographs help monitor lung reexpansion. A large-bore tube (36-F to 40-F) should be inserted in the fifth interspace at the anterior axillary line and connected to underwater seal drainage and suction (20-30 mL H₂O).

Although small hemothoraces may be observed in stable patients, a moderate hemothorax or any hemothorax in an unstable or symptomatic patient requires tube thoracostomy. Severe or persistent hemorrhage requires thoracostomy or open thoracotomy. Studies are required to better delineate the size of a hemothorax detected on CT scan that requires tube thoracostomy drainage.

Autotransfusion has been successfully used in tube thoracostomy. Recent simplification and commercial availability of the equipment have made autotransfusion feasible in most EDs. Autotransfusion also eliminates the risk of incompatibility reactions and transmission of certain diseases such as hepatitis C. Because the majority of blood loss occurs immediately after tube thoracostomy placement, autotransfusion apparatus should be immediately available in the ED.

As a result of the increasing frequency of chest CT scans, it has been found that there may be a greater frequency of misplaced thoracostomy tubes than is evident on conventional chest radiographs. Almost 25% of patients in one series subsequently required operative intervention as a result of complications from penetration of the lung parenchyma from tube thoracostomies.⁵³ However, the true incidence of complications that require some surgical intervention remains unknown (Fig. 45-15).

Although beyond the scope of emergency medicine, mention is made of the role of thoracoscopy. Video-assisted thoracic surgery (VATS) is particularly useful for evaluation and evacuation of retained hemothorax, control of bleeding from intercostal vessels, and diagnosis and repair of diaphragmatic injuries.54,55 As surgeons gain more experience with the technique, VATS will likely become more widely used for other indications as well, given the decreased morbidity and length of hospital stay compared with open thoracotomy.⁵⁶