Pulmonary contusion natural history, complications and prognosis

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Editor-In-Chief: C. Michael Gibson, M.S., M.D. [1]

Natural History

The severity ranges from mild to deadly—small contusions may have little or no impact on the patient's health—yet pulmonary contusion is the most common type of potentially lethal chest trauma. It occurs in 30–75% of severe chest injuries. With an estimated mortality rate of 14–40%, pulmonary contusion plays a key role in determining whether an individual will die or suffer serious ill effects as the result of trauma. Pulmonary contusion is usually accompanied by other injuries. Although associated injuries are often the cause of death, pulmonary contusion is thought to cause death directly in a quarter to half of cases. Children are at especially high risk for the injury because the relative flexibility of their bones prevents the chest wall from absorbing force from an impact, causing it to be transmitted instead to the lung. Pulmonary contusion is associated with complications including pneumonia and acute respiratory distress syndrome, and it can cause long-term respiratory disability.

Complications

Pulmonary contusion can result in respiratory failure—about half of such cases occur within a few hours of the initial trauma.[1] Other severe complications, including infections and acute respiratory distress syndrome (ARDS) occur in up to half of cases.[2] Elderly people and those who have heart, lung, or kidney disease prior to the injury are more likely to stay longer in a hospital and have complications from the injury. Complications occur in 55% of people with heart or lung disease and 13% of those without.[3] Of people with pulmonary contusion alone, 17% develop ARDS, while 78% of people with at least two additional injuries develop the condition.[4] A larger contusion is associated with an increased risk. In one study, 82% of people with 20% or more of the lung volume affected developed ARDS, while only 22% of people with less than 20% did so.[5]

Pulmonary contusion is the most common cause of death among vehicle occupants involved in accidents, and it is thought to contribute significantly in about a quarter of deaths resulting from vehicle collisions. As vehicle use has increased, so has the number of auto accidents, and with it the number of chest injuries. However an increase in the number of airbags installed in modern cars may be decreasing the incidence of pulmonary contusion. Use of child restraint systems has brought the approximate incidence of pulmonary contusion in children in vehicle accidents from 22% to 10%.

A chest X-ray showing acute respiratory distress syndrome

Pneumonia, another potential complication, develops in as many as 20% of people with pulmonary contusion.[6] Contused lungs are less able to remove bacteria than uninjured lungs, predisposing them to infection.[7] Intubation and mechanical ventilation further increase the risk of developing pneumonia; the tube is passed through the nose or mouth into the airways, potentially tracking bacteria from the mouth or sinuses into them. Also, intubation prevents coughing, which would clear bacteria-laden secretions from the airways, and secretions pool near the tube's cuff and allow bacteria to grow.[8] The sooner the endotracheal tube is removed, the lower the risk of pneumonia, but if it is removed too early and has to be put back in, the risk of pneumonia rises. People who are at risk for pulmonary aspiration (e.g. those with lowered level of consciousness due to head injuries) are especially likely to get pneumonia.[8] As with ARDS, the chances of developing pneumonia increase with the size of the contusion. Children and adults have been found to have similar rates of complication with pneumonia and ARDS.[2]

Bleeding and Edema

In contusions, torn capillaries leak fluid into the tissues around them.[9] The membrane between alveoli and capillaries is torn; damage to this capillary–alveolar membrane and small blood vessels causes blood and fluids to leak into the alveoli and the interstitial space (the space surrounding cells) of the lung.[10] With more severe trauma, there is a greater amount of edema, bleeding, and tearing of the alveoli.[11] Pulmonary contusion is characterized by microhemorrhages (tiny bleeds) that occur when thealveoli are traumatically separated from airway structures and blood vessels. Blood initially collects in the interstitial space, and then edema occurs by an hour or two after injury. An area of in the contused lung is commonly surrounded by an area of edema. In normal gas exchange, carbon dioxide diffuses across the endothelium of the capillaries, the interstitial space, and across the alveolar epithelium; oxygen diffuses in the other direction. Fluid accumulation interferes with gas exchange,[12] and can cause the alveoli to fill with proteins and collapse due to edema and bleeding. The larger the area of the injury, the more severe respiratory compromise will be.

Consolidation and Collapse

Pulmonary contusion can cause parts of the lung to consolidate, alveoli to collapse, and atelectasis (partial or total lung collapse) to occur.[13] Consolidation occurs when the parts of the lung that are normally filled with air fill with material from the pathological condition, such as blood.[14] Over a period of hours after the injury, the alveoli in the injured area thicken and may become consolidated. A decrease in the amount of surfactant produced also contributes to the collapse and consolidation of alveoli; inactivation of surfactant increases their surface tension. Reduced production of surfactant can also occur in surrounding tissue that was not originally injured.

Inflammation of the lungs, which can result when components of blood enter the tissue due to contusion, can also cause parts of the lung to collapse. Macrophages, neutrophils, and other inflammatory cells and blood components can enter the lung tissue and release factors that lead to inflammation, increasing the likelihood of respiratory failure.[3] In response to inflammation, excess mucus is produced, potentially plugging parts of the lung and leading to their collapse. Even when only one side of the chest is injured, inflammation may also affect the other lung.[3] Uninjured lung tissue may develop edema, thickening of the septa of the alveoli, and other changes. If this inflammation is severe enough, it can lead to dysfunction of the lungs like that seen in acute respiratory distress syndrome.

Ventilation/Perfusion Mismatch

Normally, the ratio of ventilation to perfusion is about one-to-one; the volume of air entering the alveoli (ventilation) is about equal to that of blood in the capillaries around them (perfusion).[15] This ratio is reduced in pulmonary contusion; fluid-filled alveoli cannot fill with air, oxygen does not fully saturate the hemoglobin, and the blood leaves the lung without being fully oxygenated.[16] Insufficient inflation of the lungs, which can result from inadequate mechanical ventilation or an associated injury such as flail chest, can also contribute to the ventilation/perfusion mismatch. As the mismatch between ventilation and perfusion grows, blood oxygen saturation is reduced. Pulmonary hypoxic vasoconstriction, in which blood vessels near the hypoxic alveoli constrict (narrow their diameter) in response to the lowered oxygen levels, can occur in pulmonary contusion. The vascular resistance increases in the contused part of the lung, leading to a decrease in the amount of blood that flows into it, directing blood to better-ventilated areas. Although reducing blood flow to the unventilated alveoli is a way to compensate for the fact that blood passing unventilated alveoli is not oxygenated, the oxygenation of the blood remains lower than normal. If it is severe enough, the hypoxemia resulting from fluid in the alveoli cannot be corrected just by giving supplemental oxygen; this problem is the cause of a large portion of the fatalities that result from trauma.

Associated Injuries

Severe pulmonary contusion with pneumothorax and hemothorax following severe chest trauma[17]

A large amount of force is required to cause pulmonary contusion; a person injured with such force is likely to have other types of injuries as well, and pulmonary contusion can be used to gauge the severity of trauma.[18] Up to three quarters of cases are accompanied by other chest injuries,[19] the most common of these being hemothorax and pneumothorax.[20] Flail chest is usually associated with pulmonary contusion,[21] and the contusion, rather than the chest wall injury, is often the main cause of respiratory failure in people with these injuries.[22] Other indications of thoracic trauma may be associated, including fracture of the sternum and bruising of the chest wall. Over half of the fractures of the scapula are associated with pulmonary contusion. The contusion is frequently found underlying fracture sites. When accompanied by a fracture, it is usually concentrated into a specific location—the contusion is more diffuse when there is no fracture.[21] Pulmonary lacerations may result from the same blunt or penetrating forces that cause pulmonary contusion. Lacerations can result in pulmonary hematomas; these are reported to develop in 4–11% of pulmonary contusions.

Prognosis

Pulmonary contusion usually resolves itself without causing permanent complications;[23] however it may also have long-term ill effects on respiratory function.[24] Most contusions resolve in five to seven days after the injury. Signs detectable by radiography are usually gone within 10 days after the injury—when they are not, other conditions, such as pneumonia, are the likely cause. Chronic lung disease correlates with the size of the contusion and can interfere with an individual's ability to return to work. Fibrosis of the lungs can occur, resulting in dyspnea (shortness of breath), low blood oxygenation, and reduced functional residual capacity for as long as six years after the injury. As late as four years post-injury, decreased functional residual capacity has been found in most pulmonary contusion patients studied.[1] During the six months after pulmonary contusion, up to 90% of people suffer difficulty breathing.[1] In some cases, dyspnea persists for an indefinite period. Contusions can also permanently reduce the compliance of the lungs.[25]

References

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  2. 2.0 2.1 Allen GS, Cox CS (1998). "Pulmonary contusion in children: diagnosis and management". South Med J. 91 (12): 1099–106. PMID 9853720.
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  7. Fry DE (2007). "Surgical infection". In O'Leary JP, Tabuenca A, Capote LR. The Physiologic Basis of Surgery. Hagerstown, MD: Lippincott Williams & Wilkins. p. 241. ISBN 0-7817-7138-2.
  8. 8.0 8.1 Sutyak JP, Wohltmann CD, Larson J (2007). "Pulmonary contusions and critical care management in thoracic trauma". Thorac Surg Clin. 17 (1): 11–23, v. doi:10.1016/j.thorsurg.2007.02.001. PMID 17650693.
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  15. Prentice D, Ahrens T (1994). "Pulmonary complications of trauma". Critical Care Nursing Quarterly. 17 (2): 24–33. PMID 805535. Unknown parameter |month= ignored (help)
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  17. Konijn AJ, Egbers PH, Kuiper MA (2008). "Pneumopericardium should be considered with electrocardiogram changes after blunt chest trauma: a case report". J Med Case Reports. 2: 100. doi:10.1186/1752-1947-2-100. PMC 2323010. PMID 18394149.
  18. Stern EJ, White C (1999). Chest Radiology Companion. Hagerstown, MD: Lippincott Williams & Wilkins. p. 80. ISBN 0-397-51732-7.
  19. Sutyak JP, Wohltmann CD, Larson J (2007). "Pulmonary contusions and critical care management in thoracic trauma". Thoracic Surgical Clinics. 17 (1): 11–23. doi:10.1016/j.thorsurg.2007.02.001. PMID 17650693.
  20. Klein Y, Cohn SM, Proctor KG (2002). "Lung contusion: Pathophysiology and management" (PDF). Current Opinion in Anaesthesiology. 15 (1): 65–68. PMID 17019186. Unknown parameter |month= ignored (help)
  21. 21.0 21.1 Johnson SB (2008). "Tracheobronchial injury". Seminars in Thoracic and Cardiovascular Surgery. 20 (1): 52&ndash, 57. doi:10.1053/j.semtcvs.2007.09.001. PMID 18420127.
  22. Hemmila MR, Wahl WL (2005). "Management of the injured patient". In Doherty GM. Current Surgical Diagnosis and Treatment. McGraw-Hill Medical. p. 214. ISBN 0-07-142315-X.
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  24. Cohn SM, Zieg PM (1996). "Experimental pulmonary contusion: Review of the literature and description of a new porcine model". Journal of Trauma. 41 (3): 565–571. PMID 8810987. Unknown parameter |month= ignored (help)
  25. Heck HA, Levitzky MG (2007). "The respiratory system". In O'Leary JP, Tabuenca A, Capote LR. The The Physiologic Basis of Surgery. Hagerstown, MD: Lippincott Williams & Wilkins. p. 463. ISBN 0-7817-7138-2.

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