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Tracheobronchial injury

August 26, 2023

Tracheobronchial injury is damage to the tracheobronchial tree (the airway structure involving the trachea and bronchi).[2] It can result from blunt or penetrating trauma to the neck or chest,[3] inhalation of harmful fumes or smoke, or aspiration of liquids or objects.[4]

Tracheobronchial injury
Reconstruction of the trachea and bronchi with x-ray computed tomography showing disruption of the right main bronchus with abnormal lucency (arrow)[1]
SpecialtyEmergency medicine

Though rare, TBI is a serious condition; it may cause obstruction of the airway with resulting life-threatening respiratory insufficiency.[2] Other injuries accompany TBI in about half of cases.[5] Of those people with TBI who die, most do so before receiving emergency care, either from airway obstruction, exsanguination, or from injuries to other vital organs. Of those who do reach a hospital, the mortality rate may be as high as 30%.[6]

TBI is frequently difficult to diagnose and treat.[7] Early diagnosis is important to prevent complications, which include stenosis (narrowing) of the airway, respiratory tract infection, and damage to the lung tissue. Diagnosis involves procedures such as bronchoscopy, radiography, and x-ray computed tomography to visualize the tracheobronchial tree. Signs and symptoms vary based on the location and severity of the injury; they commonly include dyspnea (difficulty breathing), dysphonia (a condition where the voice can be hoarse, weak, or excessively breathy), coughing, and abnormal breath sounds. In the emergency setting, tracheal intubation can be used to ensure that the airway remains open. In severe cases, surgery may be necessary to repair a TBI.[3]

Signs and symptoms Edit

 
Pneumothoraces of both lungs (large arrows), pneumomediastinum (small arrow) and subcutaneous emphysema in a patient with complete disruption of the right bronchus. Air leak was continual despite suction.[1]

Signs and symptoms vary depending on what part of the tracheobronchial tree is injured and how severely it is damaged.[6] There are no direct signs of TBI, but certain signs suggest the injury and raise a clinician's suspicion that it has occurred.[8] Many of the signs and symptoms are also present in injuries with similar injury mechanisms such as pneumothorax.[9] Dyspnea and respiratory distress are found in 76–100% of people with TBI, and coughing up blood has been found in up to 25%.[10] However, isolated TBI does not usually cause profuse bleeding; if such bleeding is observed it is likely to be due to another injury such as a ruptured large blood vessel.[2] The patient may exhibit dysphonia or have diminished breath sounds, and rapid breathing is common.[3] Coughing may be present,[11] and stridor, an abnormal, high-pitched breath sound indicating obstruction of the upper airway can also occur.[12]

Damage to the airways can cause subcutaneous emphysema (air trapped in the subcutaneous tissue of the skin) in the abdomen, chest, neck, and head.[2] Subcutaneous emphysema, present in up to 85% of people with TBI,[10] is particularly indicative of the injury when it is only in the neck.[13] Air is trapped in the chest cavity outside the lungs (pneumothorax) in about 70% of TBI.[4][10] Especially strong evidence that TBI has occurred is failure of a pneumothorax to resolve even when a chest tube is placed to rid the chest cavity of the air; it shows that air is continually leaking into the chest cavity from the site of the tear.[11] Air can also be trapped in the mediastinum, the center of the chest cavity (pneumomediastinum).[4] If air escapes from a penetrating injury to the neck, a definite diagnosis of TBI can be made.[10] Hamman's sign, a sound of crackling that occurs in time with the heartbeat, may also accompany TBI.[14]

Causes Edit

Injuries to the tracheobronchial tree within the chest may occur due to penetrating forces such as gunshot wounds, but are more often the result of blunt trauma.[6] TBI due blunt forces usually results from high-energy impacts such as falls from height and motor vehicle accidents; the injury is rare in low-impact mechanisms.[2] Injuries of the trachea cause about 1% of traffic-related deaths.[4] Other potential causes are falls from high places and injuries in which the chest is crushed.[15] Explosions are another cause.[16]

Gunshot wounds are the commonest form of penetrating trauma that cause TBI.[15] Less commonly, knife wounds and shrapnel from motor vehicle accidents can also penetrate the airways.[6] Most injuries to the trachea occur in the neck,[3] because the airways within the chest are deep and therefore well protected; however, up to a quarter of TBI resulting from penetrating trauma occurs within the chest.[10] Injury to the cervical trachea usually affects the anterior (front) part of the trachea.[17]

Certain medical procedures can also injure the airways; these include tracheal intubation, bronchoscopy, and tracheotomy.[4] The back of the trachea may be damaged during tracheotomy.[18] TBI resulting from tracheal intubation (insertion of a tube into the trachea) is rare, and the mechanism by which it occurs is unclear.[19] However, one likely mechanism involves an endotracheal tube catching in a fold of membrane and tearing it as it is advanced downward through the airway.[20] When an endotracheal tube tears the trachea, it typically does so at the posterior (back) membranous wall.[17] Unlike TBI that results from blunt trauma, most iatrogenic injuries to the airway involve longitudinal tears to the back of the trachea or tears on the side that pull the membranous part of the trachea away from the cartilage.[20] Excessive pressure from the cuff of an endotracheal tube can reduce blood supply to the tissues of the trachea, leading to ischemia and potentially causing it to become ulcerated, infected, and, later, narrowed.[4]

The mucosal lining of the trachea may also be injured by inhalation of hot gases or harmful fumes such as chlorine gas.[17] This can lead to edema (swelling), necrosis (death of the tissue), scar formation, and ultimately stenosis.[17] However, TBI due to inhalation, foreign body aspiration, and medical procedures is uncommon.[17]

Mechanism Edit

The structures in the tracheobronchial tree are well protected, so it normally takes a large amount of force to injure them.[6] In blunt trauma, TBI is usually the result of violent compression of the chest.[5][10] Rapid hyperextension of the neck, usually resulting from vehicle crashes, can also injure the trachea, and trauma to the neck can crush the trachea against the vertebrae.[10] A crush injury of the larynx or cervical trachea can occur in head-on collisions when the neck is hyperextended and strikes the steering wheel or dashboard; this has been called a "dashboard injury".[10] The larynx and cervical trachea may also be injured in front-on collisions by the seat belt.[10]

Although the mechanism is not well understood, TBI due to blunt trauma is widely thought to be caused by any combination of three possible mechanisms: an increase in pressure within the airways, shearing, and pulling apart.[11] The first type of injury, sometimes called an "explosive rupture", may occur when the chest is violently compressed, for example when a driver strikes the steering wheel in a vehicle accident[4] or when the chest is crushed.[21] The pressure in the airways, especially the larger airways (the trachea and bronchi), quickly rises as a result of the compression,[22] because the glottis reflexively closes off the airways.[2] When this pressure exceeds the elasticity of the tissues, they burst; thus the membranous part of the trachea is more commonly affected by this mechanism of injury than cartilaginous portions.[22]

The second mechanism may occur when the chest is suddenly decelerated, as occurs in vehicle accidents, producing a shearing force.[22] The lungs are mobile in the chest cavity but their movement is more restricted near the hilum.[22] Areas near the cricoid cartilage and carina are fixed to the thyroid cartilage and the pericardium respectively; thus if the airways move, they can tear at these points of fixation.[2]

The third mechanism occurs when the chest is compressed from front to back, causing it to widen from side to side.[10] The lungs adhere to the chest wall because of the negative pressure between them and the pleural membranes lining the inside of the chest cavity; thus when the chest widens, they are pulled apart.[10] This creates tension at the carina; the airway tears if this tensile force exceeds its elasticity.[10] This mechanism may be the cause of injury when the chest is crushed.[22] Most TBI are probably due to a combination of these three mechanisms.[6]

When airways are damaged, air can escape from them and be trapped in the surrounding tissues in the neck (subcutaneous emphysema) and mediastinum (pneumomediastinum); if it builds up to high enough pressures there, it can compress the airways.[2] Massive air leaks from a ruptured airway can also compromise the circulation by preventing blood from returning to the heart from the head and lower body; this causes a potentially deadly reduction in the amount of blood the heart is able to pump out.[7] Blood and other fluids can build up in the airways, and the injury can interfere with the patency of the airway and interfere with its continuity.[2] However, even if the trachea is completely transected, the tissues surrounding it may hold it together enough for adequate air exchange to occur, at least at first.[4]

Anatomy Edit

 
Diagram of the larynx, trachea and bronchi

The trachea and bronchi form the tracheobronchial tree. The trachea is situated between the lower end of the larynx and the center of the chest, where it splits into the two bronchi at a ridge called the carina. The trachea is stabilized and kept open by rings made of cartilage that surround the front and sides of the structure; these rings are not closed and do not surround the back, which is made of membrane.[21] The bronchi split into smaller branches and then to bronchioles that supply air to the alveoli, the tiny air-filled sacs in the lungs responsible for absorbing oxygen. An arbitrary division can be made between the intrathoracic and cervical trachea at the thoracic inlet, an opening at the top of the thoracic cavity.[17] Anatomical structures that surround and protect the tracheobronchial tree include the lungs, the esophagus, large blood vessels, the rib cage, the thoracic spine, and the sternum.[17] Children have softer tracheas and a more elastic tracheobronchial trees than adults; this elasticity, which helps protect the structures from injury when they are compressed, may contribute to the lower incidence of TBI in children.[21]

Diagnosis Edit

 
A patient with traumatic complete disruption of the right bronchus. Computed tomography scan following emergency chest tube drainage. Axial 1.25 mm thick sections with a lung window. (a) Persistent bilateral pneumothorax, pneumomediastinum and extensive subcutaneous emphysema. (b) Multiple lucencies around the right bronchial tree (curved arrow) precluding the correct recognition of the bronchial rupture. (c) The Macklin effect around the right lower pulmonary vein (white arrow). (d) Coronal view demonstrating multiple areas of alveolar consolidation in the right upper and lower lobes: intraparenchymal lucencies resulting from lung lacerations are visible on the right side (thick arrows).

Rapid diagnosis and treatment are important in the care of TBI;[6] if the injury is not diagnosed shortly after the injury, the risk of complications is higher.[11] Bronchoscopy is the most effective method to diagnose, locate, and determine the severity of TBI,[6][10] and it is usually the only method that allows a definitive diagnosis.[23] Diagnosis with a flexible bronchoscope, which allows the injury to be visualized directly, is the fastest and most reliable technique.[8] In people with TBI, bronchoscopy may reveal that the airway is torn, or that the airways are blocked by blood, or that a bronchus has collapsed, obscuring more distal (lower) bronchi from view.[3]

Chest x-ray is the initial imaging technique used to diagnose TBI.[17] The film may not have any signs in an otherwise asymptomatic patient.[15] Indications of TBI seen on radiographs include deformity in the trachea or a defect in the tracheal wall.[17] Radiography may also show cervical emphysema, air in the tissues of the neck.[2] X-rays may also show accompanying injuries and signs such as fractures and subcutaneous emphysema.[2] If subcutaneous emphysema occurs and the hyoid bone appears in an X-ray to be sitting unusually high in the throat, it may be an indication that the trachea has been severed.[4] TBI is also suspected if an endotracheal tube appears in an X-ray to be out of place, or if its cuff appears to be more full than normal or to protrude through a tear in the airway.[17] If a bronchus is torn all the way around, the lung may collapse outward toward the chest wall (rather than inward, as it usually does in pneumothorax) because it loses the attachment to the bronchus which normally holds it toward the center.[6] In a person lying face-up, the lung collapses toward the diaphragm and the back.[23] This sign, described in 1969, is called fallen lung sign and is pathognomonic of TBI (that is, it is diagnostic for TBI because it does not occur in other conditions); however it occurs only rarely.[6] In as many as one in five cases, people with blunt trauma and TBI have no signs of the injury on chest X-ray.[23] CT scanning detects over 90% of TBI resulting from blunt trauma,[3] but neither X-ray nor CT are a replacement for bronchoscopy.[6]

At least 30% of TBI are not discovered at first;[4] this number may be as high as 50%.[24] In about 10% of cases, TBI has no specific signs either clinically or on chest radiography, and its detection may be further complicated by concurrent injuries, since TBI tends to occur after high-energy accidents.[2] Weeks or months may go by before the injury is diagnosed, even though the injury is better known than it was in the past.[22]

Classification Edit

Lesions can be transverse, occurring between the rings of the trachea, longitudinal or spiral. They may occur along the membranous part of the trachea, the main bronchi, or both.[2] In 8% of ruptures, lesions are complex, occurring in more than one location, with more than one type of lesion, or on both of the main bronchi and the trachea.[2] Transverse tears are more common than longitudinal or complex ones.[17] The laceration may completely transect the airway or it may go only partway around. Partial tears that do not go all the way around the circumference of the airway do not allow a lacerated airway to become completely detached; tears that encircle the whole airway can allow separation to occur.[23] Lacerations may also be classified as complete or incomplete.[4] In an incomplete lesion, a layer of tissue surrounding the bronchus remains intact and can keep the air in the airway, preventing it from leaking into the areas surrounding the airways.[14] Incomplete lacerations may require closer scrutiny to detect[24] and may not be diagnosed right away.[14]

Bronchial injuries are divided into those that are accompanied by a disruption of the pleura and those that are not; in the former, air can leak from the hole in the airway and a pneumothorax can form.[15] The latter type is associated with more minor signs; pneumothorax is small if it occurs at all, and although function is lost in the part of the lung supplied by the injured bronchus, unaffected parts of the lungs may be able to compensate.[15]

Most TBI that results from blunt trauma occurs within the chest.[10] The most common tracheal injury is a tear near the carina or in the membranous wall of the trachea.[15] In blunt chest trauma, TBI occurs within 2.5 cm of the carina 40–80% of the time.[2] The injury is more common in the right main bronchus than the left, possibly because the former is near vertebrae, which may injure it.[2] Also, the aorta and other tissues in the mid chest that surround the left main bronchus may protect it.[22] Another possibility is that people with left main bronchus injuries are more likely to also have other deadly injuries and therefore die before reaching hospital, making them less likely to be included in studies that determine rates of injuries.[6]

Prevention Edit

Vehicle occupants who wear seat belts have a lower incidence of TBI after a motor vehicle accident.[25] However, if the strap is situated across the front of the neck (instead of the chest), this increases the risk of tracheal injury.[10] Design of medical instruments can be modified to prevent iatrogenic TBI, and medical practitioners can use techniques that reduce the risk of injury with procedures such as tracheotomy.[18]

Treatment Edit

 
An endotracheal tube may be used to bypass a disruption in the airway.

Treatment of TBI varies based on the location and severity of injury and whether the patient is stable or having trouble breathing,[2] but ensuring that the airway is patent so that the patient can breathe is always of paramount importance.[10] Ensuring an open airway and adequate ventilation may be difficult in people with TBI.[3] Intubation, one method to secure the airway, may be used to bypass a disruption in the airway in order to send air to the lungs.[3] If necessary, a tube can be placed into the uninjured bronchus, and a single lung can be ventilated.[3] If there is a penetrating injury to the neck through which air is escaping, the trachea may be intubated through the wound.[10] Multiple unsuccessful attempts at conventional (direct) laryngoscopy may threaten the airway, so alternative techniques to visualize the airway, such as fiberoptic or video laryngoscopy, may be employed to facilitate tracheal intubation.[10] If the upper trachea is injured, an incision can be made in the trachea (tracheotomy) or the cricothyroid membrane (cricothyrotomy, or cricothyroidotomy) in order to ensure an open airway.[6] However, cricothyrotomy may not be useful if the trachea is lacerated below the site of the artificial airway.[10] Tracheotomy is used sparingly because it can cause complications such as infections and narrowing of the trachea and larynx.[26] When it is impossible to establish a sufficient airway, or when complicated surgery must be performed, cardiopulmonary bypass may be used—blood is pumped out of the body, oxygenated by a machine, and pumped back in.[26] If a pneumothorax occurs, a chest tube may be inserted into the pleural cavity to remove the air.[12]

 
A left main bronchus laceration, resulting in pneumothorax. Air is evacuated from the chest cavity with a chest tube.

People with TBI are provided with supplemental oxygen and may need mechanical ventilation.[13] Employment of certain measures such as Positive end-expiratory pressure (PEEP) and ventilation at higher-than-normal pressures may be helpful in maintaining adequate oxygenation.[3] However, such measures can also increase leakage of air through a tear, and can stress the sutures in a tear that has been surgically repaired; therefore the lowest possible airway pressures that still maintain oxygenation are typically used.[3] The use of high frequency ventilation has been reported.[27] Mechanical ventilation can also cause pulmonary barotrauma when high pressure is required to ventilate the lungs.[3] Techniques such as pulmonary toilet (removal of secretions), fluid management, and treatment of pneumonia are employed to improve pulmonary compliance (the elasticity of the lungs).[26]

While TBI may be managed without surgery, surgical repair of the tear is considered standard in the treatment of most TBI.[3][28] It is required if a tear interferes with ventilation; if mediastinitis (inflammation of the tissues in the mid-chest) occurs; or if subcutaneous or mediastinal emphysema progresses rapidly;[3] or if air leak or large pneumothorax is persistent despite chest tube placement.[12] Other indications for surgery are a tear more than one third the circumference of the airway, tears with loss of tissue, and a need for positive pressure ventilation.[26] Damaged tissue around a rupture (e.g. torn or scarred tissue) may be removed in order to obtain clean edges that can be surgically repaired.[22] Debridement of damaged tissue can shorten the trachea by as much as 50%.[29] Repair of extensive tears can include sewing a flap of tissue taken from the membranes surrounding the heart or lungs (the pericardium and pleura, respectively) over the sutures to protect them.[2] When lung tissue is destroyed as a result of TBI complications, pneumonectomy or lobectomy (removal of a lung or of one lobe, respectively) may be required.[30] Pneumonectomy is avoided whenever possible due to the high rate of death associated with the procedure.[3] Surgery to repair a tear in the tracheobronchial tree can be successful even when it is performed months after the trauma, as can occur if the diagnosis of TBI is delayed.[3] When airway stenosis results after delayed diagnosis, surgery is similar to that performed after early diagnosis: the stenotic section is removed and the cut airway is repaired.[29]

Prognosis and complications Edit

 
Bronchial stenosis (arrow) two weeks after surgery for a tracheobronchial laceration[1]

Most people with TBI who die do so within minutes of the injury, due to complications such as pneumothorax and insufficient airway and to other injuries that occurred at the same time.[5] Most late deaths that occur in TBI are attributed to sepsis or multiple organ dysfunction syndrome (MODS).[2] If the condition is not recognized and treated early, serious complications are more likely to occur; for example,[30] pneumonia and bronchiectasis may occur as late complications.[3] Years can pass before the condition is recognized.[9][30] Some TBI are so small that they do not have significant clinical manifestations; they may never be noticed or diagnosed and may heal without intervention.[30]

If granulation tissue grows over the injured site, it can cause stenosis of the airway, after a week to a month.[4] The granulation tissue must be surgically excised.[26] Delayed diagnosis of a bronchial rupture increases risk of infection and lengthens hospital stay.[29] People with a narrowed airway may develop dyspnea, coughing, wheezing, respiratory tract infection, and difficulty with clearing secretions.[10] If the bronchiole is completely obstructed, atelectasis occurs: the alveoli of the lung collapse.[4] Lung tissue distal to a completely obstructed bronchiole often does not become infected. Because it is filled with mucus, this tissue remains functional.[22] When the secretions are removed, the affected portion of the lung is commonly able to function almost normally.[30] However, infection is common in lungs distal to a partially obstructed bronchiole.[22] Infected lung tissue distal to a stricture can be damaged, and wheezing and coughing may develop due to the narrowing.[15] In addition to pneumonia, the stenosis may cause bronchiectasis, in which bronchi are dilated, to develop.[22] Even after an airway with a stricture is restored to normal, the resulting loss of lung function may be permanent.[22]

Complications may also occur with treatment; for example, a granuloma can form at the suture site.[2] Also, the sutured wound can tear again, as occurs when there is excessive pressure in the airways from ventilation.[2] However, for people who do receive surgery soon after the injury to repair the lesion, outcome is usually good; the long-term outcome is good for over 90% of people who have TBI surgically repaired early in treatment.[10] Even when surgery is performed years after the injury, the outlook is good, with low rates of death and disability and good chances of preserving lung function.[30]

Epidemiology Edit

Rupture of the trachea or bronchus is the most common type of blunt injury to the airway.[22] It is difficult to determine the incidence of TBI: in as many as 30–80% of cases, death occurs before the person reaches a hospital, and these people may not be included in studies.[3] On the other hand, some TBI are so small that they do not cause significant symptoms and are therefore never noticed.[30] In addition, the injury sometimes is not associated with symptoms until complications develop later, further hindering estimation of the true incidence.[6] However, autopsy studies have revealed TBI in 2.5–3.2% of people who died after trauma.[3] Of all neck and chest traumas, including people that died immediately, TBI is estimated to occur in 0.5–2%.[30] An estimated 0.5% of polytrauma patients treated in trauma centers have TBI.[10] The incidence is estimated at 2% in blunt chest and neck trauma and 1–2% in penetrating chest trauma.[10] Laryngotracheal injuries occur in 8% of patients with penetrating injury to the neck, and TBI occurs in 2.8% of blunt chest trauma deaths.[6] In people with blunt trauma who do reach a hospital alive, reports have found incidences of 2.1% and 5.3%.[2] Another study of blunt chest trauma revealed an incidence of only 0.3%, but a mortality rate of 67% (possibly due in part to associated injuries).[6] The incidence of iatrogenic TBI (that caused by medical procedures) is rising, and the risk may be higher for women and the elderly.[31] TBI results about once every 20,000 times someone is intubated through the mouth, but when intubation is performed emergently, the incidence may be as high as 15%.[31]

The mortality rate for people who reach a hospital alive was estimated at 30% in 1966;[2] more recent estimates place this number at 9%.[22] The number of people reaching a hospital alive has increased, perhaps due to improved prehospital care or specialized treatment centers.[10] Of those who reach the hospital alive but then die, most do so within the first two hours of arrival.[9] The sooner a TBI is diagnosed, the higher the mortality rate; this is likely due to other accompanying injuries that prove fatal.[22]

Accompanying injuries often play a key role in the outcome.[10] Injuries that may accompany TBI include pulmonary contusion and laceration; and fractures of the sternum, ribs and clavicles.[2] Spinal cord injury, facial trauma, traumatic aortic rupture, injuries to the abdomen, lung, and head are present in 40–100%.[17] The most common accompanying injury is esophageal perforation or rupture (known as Boerhaave syndrome), which occurs in as many as 43% of the penetrating injuries to the neck that cause tracheal injury.[6]

History Edit

Throughout most of history, the mortality rate of TBI was thought to be 100%.[5] However, in 1871 a healed TBI was noted in a duck that had been killed by a hunter, thus demonstrating that the injury could be survived, at least in the general sense.[6] This report, made by Winslow, was the first record in the medical literature of a bronchus injury.[22] In 1873, Seuvre made one of the earliest reports of TBI in the medical literature: a 74-year-old woman whose chest was crushed by a wagon wheel was found on autopsy to have an avulsion of the right bronchus.[22] Long-term survival of the injury was unknown in humans until a report was made of a person who survived in 1927.[5][6] In 1931, a report made by Nissen described successful removal of a lung in a 12-year-old girl who had had narrowing of the bronchus due to the injury.[22] Repair of TBI was probably first attempted in 1945, when the first documented case of a successful suturing of a lacerated bronchus was made.[6] Prior to 1950, the mortality rate was 36%; it had fallen to 9% by 2001;[3][22] this improvement was likely due to improvements in treatments and surgical techniques, including those for injuries commonly associated with TBI.[3]

Notes Edit

  1. ^ a b c Le Guen M, Beigelman C, Bouhemad B, Wenjïe Y, Marmion F, Rouby JJ (2007). "Chest computed tomography with multiplanar reformatted images for diagnosing traumatic bronchial rupture: a case report". Critical Care. 11 (5): R94. doi:10.1186/cc6109. PMC 2556736. PMID 17767714.
  2. ^ a b c d e f g h i j k l m n o p q r s t u v w x Chu CP, Chen PP (April 2002). "Tracheobronchial injury secondary to blunt chest trauma: diagnosis and management". Anaesthesia and Intensive Care. 30 (2): 145–52. doi:10.1177/0310057X0203000204. PMID 12002920.
  3. ^ a b c d e f g h i j k l m n o p q r s t u Johnson SB (2008). "Tracheobronchial injury". Seminars in Thoracic and Cardiovascular Surgery. 20 (1): 52–7. doi:10.1053/j.semtcvs.2007.09.001. PMID 18420127.
  4. ^ a b c d e f g h i j k l m Stark P (1995). "Imaging of tracheobronchial injuries". Journal of Thoracic Imaging. 10 (3): 206–19. doi:10.1097/00005382-199522000-00006. PMID 7674433. S2CID 9683995.
  5. ^ a b c d e Barmada H, Gibbons JR (July 1994). "Tracheobronchial injury in blunt and penetrating chest trauma". Chest. 106 (1): 74–8. doi:10.1378/chest.106.1.74. PMID 8020323.
  6. ^ a b c d e f g h i j k l m n o p q r s t Riley et al. (2004). pp. 544–7.
  7. ^ a b Tovar JA (February 2008). "The lung and pediatric trauma". Seminars in Pediatric Surgery. 17 (1): 53–9. doi:10.1053/j.sempedsurg.2007.10.008. PMID 18158142.
  8. ^ a b Rico FR, Cheng JD, Gestring ML, Piotrowski ES (April 2007). "Mechanical ventilation strategies in massive chest trauma". Critical Care Clinics. 23 (2): 299–315, xi. doi:10.1016/j.ccc.2006.12.007. PMID 17368173.
  9. ^ a b c Nakayama DK, Rowe MI (1988). "Intrathoracic tracheobronchial injuries in childhood". International Anesthesiology Clinics. 26 (1): 42–9. doi:10.1097/00004311-198802610-00009. PMID 3283046. S2CID 1005862.
  10. ^ a b c d e f g h i j k l m n o p q r s t u v w x y Karmy-Jones R, Wood DE (February 2007). "Traumatic injury to the trachea and bronchus". Thoracic Surgery Clinics. 17 (1): 35–46. doi:10.1016/j.thorsurg.2007.03.005. PMID 17650695.
  11. ^ a b c d Hwang JC, Hanowell LH, Grande CM (1996). "Peri-operative concerns in thoracic trauma". Baillière's Clinical Anaesthesiology. 10 (1): 123–153. doi:10.1016/S0950-3501(96)80009-2.
  12. ^ a b c Wilderman MJ, Kaiser LR (2005). "Thoracic malignancy and pathophysiology". In Atluri P, Karakousis GC, Porrett PM, Kaiser LR (eds.). The Surgical Review: An Integrated Basic and Clinical Science Study Guide. Hagerstown, MD: Lippincott Williams & Wilkins. p. 376. ISBN 0-7817-5641-3.
  13. ^ a b Paidas CN. (September 15, 2006) Thoracic Trauma. ped/3001 at eMedicine Retrieved on June 13, 2007.
  14. ^ a b c Wong EH, Knight S (May 2006). "Tracheobronchial injuries from blunt trauma". ANZ Journal of Surgery. 76 (5): 414–5. doi:10.1111/j.1445-2197.2006.03738.x. PMID 16768706. S2CID 21354960.
  15. ^ a b c d e f g Smith M, Ball V (1998). "Thoracic trauma". Cardiovascular/respiratory physiotherapy. St. Louis: Mosby. p. 217. ISBN 0-7234-2595-7. Retrieved 2008-06-12.
  16. ^ Gabor S, Renner H, Pinter H, Sankin O, Maier A, Tomaselli F, Smolle Jüttner FM (August 2001). "Indications for surgery in tracheobronchial ruptures". European Journal of Cardio-Thoracic Surgery. 20 (2): 399–404. doi:10.1016/S1010-7940(01)00798-9. PMID 11463564.
  17. ^ a b c d e f g h i j k l Euathrongchit J, Thoongsuwan N, Stern EJ (March 2006). "Nonvascular mediastinal trauma". Radiologic Clinics of North America. 44 (2): 251–8, viii. doi:10.1016/j.rcl.2005.10.001. PMID 16500207.
  18. ^ a b Trottier SJ, Hazard PB, Sakabu SA, Levine JH, Troop BR, Thompson JA, McNary R (May 1999). "Posterior tracheal wall perforation during percutaneous dilational tracheostomy: an investigation into its mechanism and prevention". Chest. 115 (5): 1383–9. doi:10.1378/chest.115.5.1383. PMID 10334157.
  19. ^ Miñambres E, González-Castro A, Burón J, Suberviola B, Ballesteros MA, Ortiz-Melón F (June 2007). "Management of postintubation tracheobronchial rupture: our experience and a review of the literature". European Journal of Emergency Medicine. 14 (3): 177–9. doi:10.1097/MEJ.0b013e3280bef8f0. PMID 17473617.
  20. ^ a b Conti M, Pougeoise M, Wurtz A, Porte H, Fourrier F, Ramon P, Marquette CH (August 2006). "Management of postintubation tracheobronchial ruptures". Chest. 130 (2): 412–8. doi:10.1378/chest.130.2.412. PMID 16899839.
  21. ^ a b c Granholm T, Farmer DL (March 2001). "The surgical airway". Respiratory Care Clinics of North America. 7 (1): 13–23. doi:10.1016/S1078-5337(05)70020-4. PMID 11584802.
  22. ^ a b c d e f g h i j k l m n o p q r s Kiser AC, O'Brien SM, Detterbeck FC (June 2001). "Blunt tracheobronchial injuries: treatment and outcomes". The Annals of Thoracic Surgery. 71 (6): 2059–65. doi:10.1016/S0003-4975(00)02453-X. PMID 11426809.
  23. ^ a b c d Wintermark M, Schnyder P, Wicky S (2001). "Blunt traumatic rupture of a mainstem bronchus: spiral CT demonstration of the "fallen lung" sign". European Radiology. 11 (3): 409–11. doi:10.1007/s003300000581. PMID 11288843. S2CID 6767450.
  24. ^ a b Scaglione M, Romano S, Pinto A, Sparano A, Scialpi M, Rotondo A (September 2006). "Acute tracheobronchial injuries: Impact of imaging on diagnosis and management implications". European Journal of Radiology. 59 (3): 336–43. doi:10.1016/j.ejrad.2006.04.026. PMID 16782296.
  25. ^ Atkins BZ, Abbate S, Fisher SR, Vaslef SN (January 2004). "Current management of laryngotracheal trauma: case report and literature review". The Journal of Trauma. 56 (1): 185–90. doi:10.1097/01.TA.0000082650.62207.92. PMID 14749588.
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  27. ^ Porro GA, Roche CD, Banderker E, van As AB (2014). "Bronchial rupture in a young child: A case report". Injury Extra. 45 (3): 25–27. doi:10.1016/j.injury.2014.01.009.
  28. ^ Mussi A, Ambrogi MC, Ribechini A, Lucchi M, Menoni F, Angeletti CA (July 2001). "Acute major airway injuries: clinical features and management". European Journal of Cardio-Thoracic Surgery. 20 (1): 46–51, discussion 51–2. doi:10.1016/S1010-7940(01)00702-3. PMID 11423273.
  29. ^ a b c Riley et al. (2004). pp. 550–51.
  30. ^ a b c d e f g h Glazer ES, Meyerson SL (2008). "Delayed presentation and treatment of tracheobronchial injuries due to blunt trauma". Journal of Surgical Education. 65 (4): 302–8. doi:10.1016/j.jsurg.2008.06.006. PMID 18707665.
  31. ^ a b Gómez-Caro Andrés A, Moradiellos Díez FJ, Ausín Herrero P, Díaz-Hellín Gude V, Larrú Cabrero E, de Miguel Porch E, Martín De Nicolás JL (June 2005). "Successful conservative management in iatrogenic tracheobronchial injury". The Annals of Thoracic Surgery. 79 (6): 1872–8. doi:10.1016/j.athoracsur.2004.10.006. PMID 15919275.

References Edit

  • Riley RD, Miller PR, Meredith JW (2004). "Injury to the esophagus, trachea, and bronchus". In Moore EJ, Feliciano DV, Mattox KL (eds.). Trauma. New York: McGraw-Hill, Medical Pub. Division. pp. 544–52. ISBN 0-07-137069-2. Retrieved 2008-06-15.

External links Edit

August 26, 2023
tracheobronchial, injury, damage, tracheobronchial, tree, airway, structure, involving, trachea, bronchi, result, from, blunt, penetrating, trauma, neck, chest, inhalation, harmful, fumes, smoke, aspiration, liquids, objects, reconstruction, trachea, bronchi, . Tracheobronchial injury is damage to the tracheobronchial tree the airway structure involving the trachea and bronchi 2 It can result from blunt or penetrating trauma to the neck or chest 3 inhalation of harmful fumes or smoke or aspiration of liquids or objects 4 Tracheobronchial injuryReconstruction of the trachea and bronchi with x ray computed tomography showing disruption of the right main bronchus with abnormal lucency arrow 1 SpecialtyEmergency medicineThough rare TBI is a serious condition it may cause obstruction of the airway with resulting life threatening respiratory insufficiency 2 Other injuries accompany TBI in about half of cases 5 Of those people with TBI who die most do so before receiving emergency care either from airway obstruction exsanguination or from injuries to other vital organs Of those who do reach a hospital the mortality rate may be as high as 30 6 TBI is frequently difficult to diagnose and treat 7 Early diagnosis is important to prevent complications which include stenosis narrowing of the airway respiratory tract infection and damage to the lung tissue Diagnosis involves procedures such as bronchoscopy radiography and x ray computed tomography to visualize the tracheobronchial tree Signs and symptoms vary based on the location and severity of the injury they commonly include dyspnea difficulty breathing dysphonia a condition where the voice can be hoarse weak or excessively breathy coughing and abnormal breath sounds In the emergency setting tracheal intubation can be used to ensure that the airway remains open In severe cases surgery may be necessary to repair a TBI 3 Contents 1 Signs and symptoms 2 Causes 3 Mechanism 3 1 Anatomy 4 Diagnosis 4 1 Classification 5 Prevention 6 Treatment 7 Prognosis and complications 8 Epidemiology 9 History 10 Notes 11 References 12 External linksSigns and symptoms Edit Pneumothoraces of both lungs large arrows pneumomediastinum small arrow and subcutaneous emphysema in a patient with complete disruption of the right bronchus Air leak was continual despite suction 1 Signs and symptoms vary depending on what part of the tracheobronchial tree is injured and how severely it is damaged 6 There are no direct signs of TBI but certain signs suggest the injury and raise a clinician s suspicion that it has occurred 8 Many of the signs and symptoms are also present in injuries with similar injury mechanisms such as pneumothorax 9 Dyspnea and respiratory distress are found in 76 100 of people with TBI and coughing up blood has been found in up to 25 10 However isolated TBI does not usually cause profuse bleeding if such bleeding is observed it is likely to be due to another injury such as a ruptured large blood vessel 2 The patient may exhibit dysphonia or have diminished breath sounds and rapid breathing is common 3 Coughing may be present 11 and stridor an abnormal high pitched breath sound indicating obstruction of the upper airway can also occur 12 Damage to the airways can cause subcutaneous emphysema air trapped in the subcutaneous tissue of the skin in the abdomen chest neck and head 2 Subcutaneous emphysema present in up to 85 of people with TBI 10 is particularly indicative of the injury when it is only in the neck 13 Air is trapped in the chest cavity outside the lungs pneumothorax in about 70 of TBI 4 10 Especially strong evidence that TBI has occurred is failure of a pneumothorax to resolve even when a chest tube is placed to rid the chest cavity of the air it shows that air is continually leaking into the chest cavity from the site of the tear 11 Air can also be trapped in the mediastinum the center of the chest cavity pneumomediastinum 4 If air escapes from a penetrating injury to the neck a definite diagnosis of TBI can be made 10 Hamman s sign a sound of crackling that occurs in time with the heartbeat may also accompany TBI 14 Causes EditInjuries to the tracheobronchial tree within the chest may occur due to penetrating forces such as gunshot wounds but are more often the result of blunt trauma 6 TBI due blunt forces usually results from high energy impacts such as falls from height and motor vehicle accidents the injury is rare in low impact mechanisms 2 Injuries of the trachea cause about 1 of traffic related deaths 4 Other potential causes are falls from high places and injuries in which the chest is crushed 15 Explosions are another cause 16 Gunshot wounds are the commonest form of penetrating trauma that cause TBI 15 Less commonly knife wounds and shrapnel from motor vehicle accidents can also penetrate the airways 6 Most injuries to the trachea occur in the neck 3 because the airways within the chest are deep and therefore well protected however up to a quarter of TBI resulting from penetrating trauma occurs within the chest 10 Injury to the cervical trachea usually affects the anterior front part of the trachea 17 Certain medical procedures can also injure the airways these include tracheal intubation bronchoscopy and tracheotomy 4 The back of the trachea may be damaged during tracheotomy 18 TBI resulting from tracheal intubation insertion of a tube into the trachea is rare and the mechanism by which it occurs is unclear 19 However one likely mechanism involves an endotracheal tube catching in a fold of membrane and tearing it as it is advanced downward through the airway 20 When an endotracheal tube tears the trachea it typically does so at the posterior back membranous wall 17 Unlike TBI that results from blunt trauma most iatrogenic injuries to the airway involve longitudinal tears to the back of the trachea or tears on the side that pull the membranous part of the trachea away from the cartilage 20 Excessive pressure from the cuff of an endotracheal tube can reduce blood supply to the tissues of the trachea leading to ischemia and potentially causing it to become ulcerated infected and later narrowed 4 The mucosal lining of the trachea may also be injured by inhalation of hot gases or harmful fumes such as chlorine gas 17 This can lead to edema swelling necrosis death of the tissue scar formation and ultimately stenosis 17 However TBI due to inhalation foreign body aspiration and medical procedures is uncommon 17 Mechanism EditThe structures in the tracheobronchial tree are well protected so it normally takes a large amount of force to injure them 6 In blunt trauma TBI is usually the result of violent compression of the chest 5 10 Rapid hyperextension of the neck usually resulting from vehicle crashes can also injure the trachea and trauma to the neck can crush the trachea against the vertebrae 10 A crush injury of the larynx or cervical trachea can occur in head on collisions when the neck is hyperextended and strikes the steering wheel or dashboard this has been called a dashboard injury 10 The larynx and cervical trachea may also be injured in front on collisions by the seat belt 10 Although the mechanism is not well understood TBI due to blunt trauma is widely thought to be caused by any combination of three possible mechanisms an increase in pressure within the airways shearing and pulling apart 11 The first type of injury sometimes called an explosive rupture may occur when the chest is violently compressed for example when a driver strikes the steering wheel in a vehicle accident 4 or when the chest is crushed 21 The pressure in the airways especially the larger airways the trachea and bronchi quickly rises as a result of the compression 22 because the glottis reflexively closes off the airways 2 When this pressure exceeds the elasticity of the tissues they burst thus the membranous part of the trachea is more commonly affected by this mechanism of injury than cartilaginous portions 22 The second mechanism may occur when the chest is suddenly decelerated as occurs in vehicle accidents producing a shearing force 22 The lungs are mobile in the chest cavity but their movement is more restricted near the hilum 22 Areas near the cricoid cartilage and carina are fixed to the thyroid cartilage and the pericardium respectively thus if the airways move they can tear at these points of fixation 2 The third mechanism occurs when the chest is compressed from front to back causing it to widen from side to side 10 The lungs adhere to the chest wall because of the negative pressure between them and the pleural membranes lining the inside of the chest cavity thus when the chest widens they are pulled apart 10 This creates tension at the carina the airway tears if this tensile force exceeds its elasticity 10 This mechanism may be the cause of injury when the chest is crushed 22 Most TBI are probably due to a combination of these three mechanisms 6 When airways are damaged air can escape from them and be trapped in the surrounding tissues in the neck subcutaneous emphysema and mediastinum pneumomediastinum if it builds up to high enough pressures there it can compress the airways 2 Massive air leaks from a ruptured airway can also compromise the circulation by preventing blood from returning to the heart from the head and lower body this causes a potentially deadly reduction in the amount of blood the heart is able to pump out 7 Blood and other fluids can build up in the airways and the injury can interfere with the patency of the airway and interfere with its continuity 2 However even if the trachea is completely transected the tissues surrounding it may hold it together enough for adequate air exchange to occur at least at first 4 Anatomy Edit Diagram of the larynx trachea and bronchiThe trachea and bronchi form the tracheobronchial tree The trachea is situated between the lower end of the larynx and the center of the chest where it splits into the two bronchi at a ridge called the carina The trachea is stabilized and kept open by rings made of cartilage that surround the front and sides of the structure these rings are not closed and do not surround the back which is made of membrane 21 The bronchi split into smaller branches and then to bronchioles that supply air to the alveoli the tiny air filled sacs in the lungs responsible for absorbing oxygen An arbitrary division can be made between the intrathoracic and cervical trachea at the thoracic inlet an opening at the top of the thoracic cavity 17 Anatomical structures that surround and protect the tracheobronchial tree include the lungs the esophagus large blood vessels the rib cage the thoracic spine and the sternum 17 Children have softer tracheas and a more elastic tracheobronchial trees than adults this elasticity which helps protect the structures from injury when they are compressed may contribute to the lower incidence of TBI in children 21 Diagnosis Edit A patient with traumatic complete disruption of the right bronchus Computed tomography scan following emergency chest tube drainage Axial 1 25 mm thick sections with a lung window a Persistent bilateral pneumothorax pneumomediastinum and extensive subcutaneous emphysema b Multiple lucencies around the right bronchial tree curved arrow precluding the correct recognition of the bronchial rupture c The Macklin effect around the right lower pulmonary vein white arrow d Coronal view demonstrating multiple areas of alveolar consolidation in the right upper and lower lobes intraparenchymal lucencies resulting from lung lacerations are visible on the right side thick arrows Rapid diagnosis and treatment are important in the care of TBI 6 if the injury is not diagnosed shortly after the injury the risk of complications is higher 11 Bronchoscopy is the most effective method to diagnose locate and determine the severity of TBI 6 10 and it is usually the only method that allows a definitive diagnosis 23 Diagnosis with a flexible bronchoscope which allows the injury to be visualized directly is the fastest and most reliable technique 8 In people with TBI bronchoscopy may reveal that the airway is torn or that the airways are blocked by blood or that a bronchus has collapsed obscuring more distal lower bronchi from view 3 Chest x ray is the initial imaging technique used to diagnose TBI 17 The film may not have any signs in an otherwise asymptomatic patient 15 Indications of TBI seen on radiographs include deformity in the trachea or a defect in the tracheal wall 17 Radiography may also show cervical emphysema air in the tissues of the neck 2 X rays may also show accompanying injuries and signs such as fractures and subcutaneous emphysema 2 If subcutaneous emphysema occurs and the hyoid bone appears in an X ray to be sitting unusually high in the throat it may be an indication that the trachea has been severed 4 TBI is also suspected if an endotracheal tube appears in an X ray to be out of place or if its cuff appears to be more full than normal or to protrude through a tear in the airway 17 If a bronchus is torn all the way around the lung may collapse outward toward the chest wall rather than inward as it usually does in pneumothorax because it loses the attachment to the bronchus which normally holds it toward the center 6 In a person lying face up the lung collapses toward the diaphragm and the back 23 This sign described in 1969 is called fallen lung sign and is pathognomonic of TBI that is it is diagnostic for TBI because it does not occur in other conditions however it occurs only rarely 6 In as many as one in five cases people with blunt trauma and TBI have no signs of the injury on chest X ray 23 CT scanning detects over 90 of TBI resulting from blunt trauma 3 but neither X ray nor CT are a replacement for bronchoscopy 6 At least 30 of TBI are not discovered at first 4 this number may be as high as 50 24 In about 10 of cases TBI has no specific signs either clinically or on chest radiography and its detection may be further complicated by concurrent injuries since TBI tends to occur after high energy accidents 2 Weeks or months may go by before the injury is diagnosed even though the injury is better known than it was in the past 22 Classification Edit Lesions can be transverse occurring between the rings of the trachea longitudinal or spiral They may occur along the membranous part of the trachea the main bronchi or both 2 In 8 of ruptures lesions are complex occurring in more than one location with more than one type of lesion or on both of the main bronchi and the trachea 2 Transverse tears are more common than longitudinal or complex ones 17 The laceration may completely transect the airway or it may go only partway around Partial tears that do not go all the way around the circumference of the airway do not allow a lacerated airway to become completely detached tears that encircle the whole airway can allow separation to occur 23 Lacerations may also be classified as complete or incomplete 4 In an incomplete lesion a layer of tissue surrounding the bronchus remains intact and can keep the air in the airway preventing it from leaking into the areas surrounding the airways 14 Incomplete lacerations may require closer scrutiny to detect 24 and may not be diagnosed right away 14 Bronchial injuries are divided into those that are accompanied by a disruption of the pleura and those that are not in the former air can leak from the hole in the airway and a pneumothorax can form 15 The latter type is associated with more minor signs pneumothorax is small if it occurs at all and although function is lost in the part of the lung supplied by the injured bronchus unaffected parts of the lungs may be able to compensate 15 Most TBI that results from blunt trauma occurs within the chest 10 The most common tracheal injury is a tear near the carina or in the membranous wall of the trachea 15 In blunt chest trauma TBI occurs within 2 5 cm of the carina 40 80 of the time 2 The injury is more common in the right main bronchus than the left possibly because the former is near vertebrae which may injure it 2 Also the aorta and other tissues in the mid chest that surround the left main bronchus may protect it 22 Another possibility is that people with left main bronchus injuries are more likely to also have other deadly injuries and therefore die before reaching hospital making them less likely to be included in studies that determine rates of injuries 6 Prevention EditVehicle occupants who wear seat belts have a lower incidence of TBI after a motor vehicle accident 25 However if the strap is situated across the front of the neck instead of the chest this increases the risk of tracheal injury 10 Design of medical instruments can be modified to prevent iatrogenic TBI and medical practitioners can use techniques that reduce the risk of injury with procedures such as tracheotomy 18 Treatment Edit An endotracheal tube may be used to bypass a disruption in the airway Treatment of TBI varies based on the location and severity of injury and whether the patient is stable or having trouble breathing 2 but ensuring that the airway is patent so that the patient can breathe is always of paramount importance 10 Ensuring an open airway and adequate ventilation may be difficult in people with TBI 3 Intubation one method to secure the airway may be used to bypass a disruption in the airway in order to send air to the lungs 3 If necessary a tube can be placed into the uninjured bronchus and a single lung can be ventilated 3 If there is a penetrating injury to the neck through which air is escaping the trachea may be intubated through the wound 10 Multiple unsuccessful attempts at conventional direct laryngoscopy may threaten the airway so alternative techniques to visualize the airway such as fiberoptic or video laryngoscopy may be employed to facilitate tracheal intubation 10 If the upper trachea is injured an incision can be made in the trachea tracheotomy or the cricothyroid membrane cricothyrotomy or cricothyroidotomy in order to ensure an open airway 6 However cricothyrotomy may not be useful if the trachea is lacerated below the site of the artificial airway 10 Tracheotomy is used sparingly because it can cause complications such as infections and narrowing of the trachea and larynx 26 When it is impossible to establish a sufficient airway or when complicated surgery must be performed cardiopulmonary bypass may be used blood is pumped out of the body oxygenated by a machine and pumped back in 26 If a pneumothorax occurs a chest tube may be inserted into the pleural cavity to remove the air 12 A left main bronchus laceration resulting in pneumothorax Air is evacuated from the chest cavity with a chest tube People with TBI are provided with supplemental oxygen and may need mechanical ventilation 13 Employment of certain measures such as Positive end expiratory pressure PEEP and ventilation at higher than normal pressures may be helpful in maintaining adequate oxygenation 3 However such measures can also increase leakage of air through a tear and can stress the sutures in a tear that has been surgically repaired therefore the lowest possible airway pressures that still maintain oxygenation are typically used 3 The use of high frequency ventilation has been reported 27 Mechanical ventilation can also cause pulmonary barotrauma when high pressure is required to ventilate the lungs 3 Techniques such as pulmonary toilet removal of secretions fluid management and treatment of pneumonia are employed to improve pulmonary compliance the elasticity of the lungs 26 While TBI may be managed without surgery surgical repair of the tear is considered standard in the treatment of most TBI 3 28 It is required if a tear interferes with ventilation if mediastinitis inflammation of the tissues in the mid chest occurs or if subcutaneous or mediastinal emphysema progresses rapidly 3 or if air leak or large pneumothorax is persistent despite chest tube placement 12 Other indications for surgery are a tear more than one third the circumference of the airway tears with loss of tissue and a need for positive pressure ventilation 26 Damaged tissue around a rupture e g torn or scarred tissue may be removed in order to obtain clean edges that can be surgically repaired 22 Debridement of damaged tissue can shorten the trachea by as much as 50 29 Repair of extensive tears can include sewing a flap of tissue taken from the membranes surrounding the heart or lungs the pericardium and pleura respectively over the sutures to protect them 2 When lung tissue is destroyed as a result of TBI complications pneumonectomy or lobectomy removal of a lung or of one lobe respectively may be required 30 Pneumonectomy is avoided whenever possible due to the high rate of death associated with the procedure 3 Surgery to repair a tear in the tracheobronchial tree can be successful even when it is performed months after the trauma as can occur if the diagnosis of TBI is delayed 3 When airway stenosis results after delayed diagnosis surgery is similar to that performed after early diagnosis the stenotic section is removed and the cut airway is repaired 29 Prognosis and complications Edit Bronchial stenosis arrow two weeks after surgery for a tracheobronchial laceration 1 Most people with TBI who die do so within minutes of the injury due to complications such as pneumothorax and insufficient airway and to other injuries that occurred at the same time 5 Most late deaths that occur in TBI are attributed to sepsis or multiple organ dysfunction syndrome MODS 2 If the condition is not recognized and treated early serious complications are more likely to occur for example 30 pneumonia and bronchiectasis may occur as late complications 3 Years can pass before the condition is recognized 9 30 Some TBI are so small that they do not have significant clinical manifestations they may never be noticed or diagnosed and may heal without intervention 30 If granulation tissue grows over the injured site it can cause stenosis of the airway after a week to a month 4 The granulation tissue must be surgically excised 26 Delayed diagnosis of a bronchial rupture increases risk of infection and lengthens hospital stay 29 People with a narrowed airway may develop dyspnea coughing wheezing respiratory tract infection and difficulty with clearing secretions 10 If the bronchiole is completely obstructed atelectasis occurs the alveoli of the lung collapse 4 Lung tissue distal to a completely obstructed bronchiole often does not become infected Because it is filled with mucus this tissue remains functional 22 When the secretions are removed the affected portion of the lung is commonly able to function almost normally 30 However infection is common in lungs distal to a partially obstructed bronchiole 22 Infected lung tissue distal to a stricture can be damaged and wheezing and coughing may develop due to the narrowing 15 In addition to pneumonia the stenosis may cause bronchiectasis in which bronchi are dilated to develop 22 Even after an airway with a stricture is restored to normal the resulting loss of lung function may be permanent 22 Complications may also occur with treatment for example a granuloma can form at the suture site 2 Also the sutured wound can tear again as occurs when there is excessive pressure in the airways from ventilation 2 However for people who do receive surgery soon after the injury to repair the lesion outcome is usually good the long term outcome is good for over 90 of people who have TBI surgically repaired early in treatment 10 Even when surgery is performed years after the injury the outlook is good with low rates of death and disability and good chances of preserving lung function 30 Epidemiology EditRupture of the trachea or bronchus is the most common type of blunt injury to the airway 22 It is difficult to determine the incidence of TBI in as many as 30 80 of cases death occurs before the person reaches a hospital and these people may not be included in studies 3 On the other hand some TBI are so small that they do not cause significant symptoms and are therefore never noticed 30 In addition the injury sometimes is not associated with symptoms until complications develop later further hindering estimation of the true incidence 6 However autopsy studies have revealed TBI in 2 5 3 2 of people who died after trauma 3 Of all neck and chest traumas including people that died immediately TBI is estimated to occur in 0 5 2 30 An estimated 0 5 of polytrauma patients treated in trauma centers have TBI 10 The incidence is estimated at 2 in blunt chest and neck trauma and 1 2 in penetrating chest trauma 10 Laryngotracheal injuries occur in 8 of patients with penetrating injury to the neck and TBI occurs in 2 8 of blunt chest trauma deaths 6 In people with blunt trauma who do reach a hospital alive reports have found incidences of 2 1 and 5 3 2 Another study of blunt chest trauma revealed an incidence of only 0 3 but a mortality rate of 67 possibly due in part to associated injuries 6 The incidence of iatrogenic TBI that caused by medical procedures is rising and the risk may be higher for women and the elderly 31 TBI results about once every 20 000 times someone is intubated through the mouth but when intubation is performed emergently the incidence may be as high as 15 31 The mortality rate for people who reach a hospital alive was estimated at 30 in 1966 2 more recent estimates place this number at 9 22 The number of people reaching a hospital alive has increased perhaps due to improved prehospital care or specialized treatment centers 10 Of those who reach the hospital alive but then die most do so within the first two hours of arrival 9 The sooner a TBI is diagnosed the higher the mortality rate this is likely due to other accompanying injuries that prove fatal 22 Accompanying injuries often play a key role in the outcome 10 Injuries that may accompany TBI include pulmonary contusion and laceration and fractures of the sternum ribs and clavicles 2 Spinal cord injury facial trauma traumatic aortic rupture injuries to the abdomen lung and head are present in 40 100 17 The most common accompanying injury is esophageal perforation or rupture known as Boerhaave syndrome which occurs in as many as 43 of the penetrating injuries to the neck that cause tracheal injury 6 History EditThroughout most of history the mortality rate of TBI was thought to be 100 5 However in 1871 a healed TBI was noted in a duck that had been killed by a hunter thus demonstrating that the injury could be survived at least in the general sense 6 This report made by Winslow was the first record in the medical literature of a bronchus injury 22 In 1873 Seuvre made one of the earliest reports of TBI in the medical literature a 74 year old woman whose chest was crushed by a wagon wheel was found on autopsy to have an avulsion of the right bronchus 22 Long term survival of the injury was unknown in humans until a report was made of a person who survived in 1927 5 6 In 1931 a report made by Nissen described successful removal of a lung in a 12 year old girl who had had narrowing of the bronchus due to the injury 22 Repair of TBI was probably first attempted in 1945 when the first documented case of a successful suturing of a lacerated bronchus was made 6 Prior to 1950 the mortality rate was 36 it had fallen to 9 by 2001 3 22 this improvement was likely due to improvements in treatments and surgical techniques including those for injuries commonly associated with TBI 3 Notes Edit a b c Le Guen M Beigelman C Bouhemad B Wenjie Y Marmion F Rouby JJ 2007 Chest computed tomography with multiplanar reformatted images for diagnosing traumatic bronchial rupture a case report Critical Care 11 5 R94 doi 10 1186 cc6109 PMC 2556736 PMID 17767714 a b c d e f g h i j k l m n o p q r s t u v w x Chu CP Chen PP April 2002 Tracheobronchial injury secondary to blunt chest trauma diagnosis and management Anaesthesia and Intensive Care 30 2 145 52 doi 10 1177 0310057X0203000204 PMID 12002920 a b c d e f g h i j k l m n o p q r s t u Johnson SB 2008 Tracheobronchial injury Seminars in Thoracic and Cardiovascular Surgery 20 1 52 7 doi 10 1053 j semtcvs 2007 09 001 PMID 18420127 a b c d e f g h i j k l m Stark P 1995 Imaging of tracheobronchial injuries Journal of Thoracic Imaging 10 3 206 19 doi 10 1097 00005382 199522000 00006 PMID 7674433 S2CID 9683995 a b c d e Barmada H Gibbons JR July 1994 Tracheobronchial injury in blunt and penetrating chest trauma Chest 106 1 74 8 doi 10 1378 chest 106 1 74 PMID 8020323 a b c d e f g h i j k l m n o p q r s t Riley et al 2004 pp 544 7 a b Tovar JA February 2008 The lung and pediatric trauma Seminars in Pediatric Surgery 17 1 53 9 doi 10 1053 j sempedsurg 2007 10 008 PMID 18158142 a b Rico FR Cheng JD Gestring ML Piotrowski ES April 2007 Mechanical ventilation strategies in massive chest trauma Critical Care Clinics 23 2 299 315 xi doi 10 1016 j ccc 2006 12 007 PMID 17368173 a b c Nakayama DK Rowe MI 1988 Intrathoracic tracheobronchial injuries in childhood International Anesthesiology Clinics 26 1 42 9 doi 10 1097 00004311 198802610 00009 PMID 3283046 S2CID 1005862 a b c d e f g h i j k l m n o p q r s t u v w x y Karmy Jones R Wood DE February 2007 Traumatic injury to the trachea and bronchus Thoracic Surgery Clinics 17 1 35 46 doi 10 1016 j thorsurg 2007 03 005 PMID 17650695 a b c d Hwang JC Hanowell LH Grande CM 1996 Peri operative concerns in thoracic trauma Bailliere s Clinical Anaesthesiology 10 1 123 153 doi 10 1016 S0950 3501 96 80009 2 a b c Wilderman MJ Kaiser LR 2005 Thoracic malignancy and pathophysiology In Atluri P Karakousis GC Porrett PM Kaiser LR eds The Surgical Review An Integrated Basic and Clinical Science Study Guide Hagerstown MD Lippincott Williams amp Wilkins p 376 ISBN 0 7817 5641 3 a b Paidas CN September 15 2006 Thoracic Trauma ped 3001 at eMedicine Retrieved on June 13 2007 a b c Wong EH Knight S May 2006 Tracheobronchial injuries from blunt trauma ANZ Journal of Surgery 76 5 414 5 doi 10 1111 j 1445 2197 2006 03738 x PMID 16768706 S2CID 21354960 a b c d e f g Smith M Ball V 1998 Thoracic trauma Cardiovascular respiratory physiotherapy St Louis Mosby p 217 ISBN 0 7234 2595 7 Retrieved 2008 06 12 Gabor S Renner H Pinter H Sankin O Maier A Tomaselli F Smolle Juttner FM August 2001 Indications for surgery in tracheobronchial ruptures European Journal of Cardio Thoracic Surgery 20 2 399 404 doi 10 1016 S1010 7940 01 00798 9 PMID 11463564 a b c d e f g h i j k l Euathrongchit J Thoongsuwan N Stern EJ March 2006 Nonvascular mediastinal trauma Radiologic Clinics of North America 44 2 251 8 viii doi 10 1016 j rcl 2005 10 001 PMID 16500207 a b Trottier SJ Hazard PB Sakabu SA Levine JH Troop BR Thompson JA McNary R May 1999 Posterior tracheal wall perforation during percutaneous dilational tracheostomy an investigation into its mechanism and prevention Chest 115 5 1383 9 doi 10 1378 chest 115 5 1383 PMID 10334157 Minambres E Gonzalez Castro A Buron J Suberviola B Ballesteros MA Ortiz Melon F June 2007 Management of postintubation tracheobronchial 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tracheobronchial injuries due to blunt trauma Journal of Surgical Education 65 4 302 8 doi 10 1016 j jsurg 2008 06 006 PMID 18707665 a b Gomez Caro Andres A Moradiellos Diez FJ Ausin Herrero P Diaz Hellin Gude V Larru Cabrero E de Miguel Porch E Martin De Nicolas JL June 2005 Successful conservative management in iatrogenic tracheobronchial injury The Annals of Thoracic Surgery 79 6 1872 8 doi 10 1016 j athoracsur 2004 10 006 PMID 15919275 References EditRiley RD Miller PR Meredith JW 2004 Injury to the esophagus trachea and bronchus In Moore EJ Feliciano DV Mattox KL eds Trauma New York McGraw Hill Medical Pub Division pp 544 52 ISBN 0 07 137069 2 Retrieved 2008 06 15 External links Edit Retrieved from https en wikipedia org w index php title Tracheobronchial injury amp oldid 1170012932, wikipedia, wiki, book, books, library,

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