Critical Care/Emergency Medicine Flashcards
Page 252 - Page 329
A 42-year-old woman sustained a motor vehicle accident (MVA) 2 days ago and was brought to the Emergency Department by ambulance. She was resuscitated accordingly, and was admitted to the hospital due to fractures of ribs and her left humerus. Today, she is found to be in respiratory distress. Pulse oxymetry shows oxygen saturation of 89% on room air. She has a blood pressure of 130/85 mmHg, pulse rate of 100bpm in both arms, respiratory rate of 30 breaths per minute, and a temperature of 36.7°C. Lungs and heart are clear on auscultation. Supplemental oxygen by facial mask is started, and a chest X-ray obtained that shows whitening of the left pleural angle. Which one of the following is the most likely diagnosis?
A. Traumatic rupture of the aorta.
B. Pulmonary contusion.
C. Pneumonia.
D. Hemothorax.
E. Atelectasis.
B. Pulmonary contusion.
Except for traumatic rupture of the aorta, all the given options have respiratory distress and hypoxia as a common and early presentation. Furthermore, equal pulses of both arms make traumatic rupture of the aorta a very remote possibility.
With atelectasis (option E) and post-obstructive pneumonia (option C), fever is expected to be present. This patient is afebrile making these two less likely.
In hemothorax (option D), chest exam is not normal, and the following are present:
* Mild to moderate shortness of breath (commonly)
* Absent breath sounds on the base of the affected side
* The base of the affected lung is dull to percussion
* Faint and distant breath sounds on the apex of the affected side
With respiratory distress and hypoxia following blunt chest trauma 24 - 48 hours after the incident and a normal chest exam, pulmonary contusion would be the most likely diagnosis.
Pulmonary contusion is the bruising of lung parenchyma due to trauma. It is most commonly caused by direct blunt trauma to the chest wall, or in explosions, or a shockwave associated with penetrating trauma.
The condition may not show up immediately after the injury and becomes evident 1 or 2 days after the trauma. This necessitates close monitoring of every patient with considerable trauma to the chest wall. Hypoxia and respiratory distress are main manifestations.
Pulmonary contusion is very difficult to diagnose only based on chest exam because exam findings are almost always inconclusive.
Chest X-ray is the initial diagnostic tool; however, chest X-ray often underestimates the size of contusion and tends to lag behind the clinical picture. In pulmonary contusion, X-ray shows whitening of the affected area(s).
In one-third of the patients, radiological characteristics may take an average 6 hours to develop. The true extent of injury takes 24-48 hours to develop. When the radiologic appearance is evident in a short time after the incidence, a CT scan must be performed for assessment of associated injuries.
Pulmonary contusions usually resolve in 3 to 5 days, provided no secondary insult occurs. The main complications of pulmonary contusion are acute respiratory distress syndrome (ARDS) and pneumonia. Approximately 50% of patients with pulmonary contusion develop ARDS. This percentage increases to 80% if more than 20% of the lung is affected. Direct lung trauma, alveolar hypoxia, and blood in the alveolar space are all major activators of an inflammatory pathways resulting in acute lung injury.
Pneumonia is also a common complication of pulmonary contusion. Blood in alveolar spaces provides an excellent growth medium for bacteria. Clearance of secretions is decreased with pulmonary contusion, and this is augmented by any chest wall injury and mechanical ventilation. Good tracheal toilet and pulmonary care is essential to minimize the incidence of pneumonia in this susceptible group.
NOTE - Ruptured aorta (option A) presents with hemodynamic instability (hypotension and tachycardia) and widened mediastinum on chest X-ray.
A 24-year-old man is brought to the Emergency Department after he sustained a roadside accident. On examination, he is conscious and fully alert, has a blood pressure of 135/90 mmHg, pulse rate of 100 bpm, and respiratory rate of 22 breaths per minute. There are several tender bruises over his chest. A part of the chest wall on the right side has paradoxical respiratory movements. He is started on opiate analgesics and supplemental oxygen by face mask. A few hours later he develops drowsiness and severe dyspnea. Bedside pulse oximetry shows an oxygen saturation of 87%. Which of the following is the most appropriate management for this patient?
A. Tracheostomy
B. Intubation and ventilation.
C. Strapping the chest.
D. Tracheostomy.
E. Cricothyroidotomy.
B. Intubation and ventilation.
The clinical picture suggests flail chest. Flail chest occurs when 3 or more adjacent ribs are each fractured in 2 places, creating a floating segment comprised of several rib sections and the soft tissues between them. This unstable section of chest wall moves in the opposite direction of the uninjured, normal-functioning chest wall (paradoxical movement), and is associated with significant morbidity from pulmonary contusion. Abnormal motion can be difficult to detect and make the diagnosis difficult.
Initial management of flail chest includes oxygen and close monitoring for early signs of respiratory compromise, ideally using both pulse oximetry and clinical observation.
Pain management and pulmonary toilet is mainstay of therapy in patients whose respiration is not yet compromised. Options for pain control include patient-controlled analgesia (PCA), oral pain medications and indwelling epidural catheters.
Respiratory compromise, if develops, is a result of underlying pulmonary contusion. In alert, otherwise uncompromised patients, continuous positive airway pressure (CPAP) may spare them from the need for intubation and mechanical ventilation. However, intubation and mechanical ventilatory support is required in:
* Patients with severe injuries
* Patients with respiratory distress
* Progressively worsening respiratory functions
* Patients with respiratory suppression because of excessive narcotic pain control
NOTE - Intubation and mechanical ventilation should be followed by prophylactic chest tube insertion (often bilateral), because the ragged edges of broken ribs my lead to pneumothorax.
This patient has developed respiratory distress despite being on analgesics and oxygen due to either respiratory suppression from analgesia or underlying pulmonary contusion. Therefore, he should be intubated and mechanically ventilated. This then should be followed by prophylactic chest tube insertion.
Stabilization of the segment with manual or object pressure restricts chest wall expansion and interferes with appropriate respiratory mechanics and is no longer used.
Other options have no role in management of flail chest and its complications.
A 34-year-old gang member sustains a penetrating chest trauma and is brought to the Emergency Department. On examination, his vital signs are stable. He has no shortness of breath. A wound is noted in the right hemithorax. Initial evaluation is consistent with an open chest wound without any air-sucking or bubbling. Auscultation reveals decreased breath sound in the right lower lung field, and percussion is associated with a dull note. Which one of the following would be the most appropriate next step in management?
A. Strap the wound with pressure.
B. Underwater-sealed chest tube.
C. Needle aspiration.
D. Intubation.
E. Thoracotomy.
B. Underwater-sealed chest tube.
The main concern in the scenario is possible hemothorax evident by decreased breath sounds and dullness on percussion. Water-sealed thoracostomy drainage is the primary mode of treatment for hemothorax.
Injuries leading to massive hemothorax include aortic rupture, myocardial rupture, and injuries to hilar structures. Other causes include injuries to the lung parenchyma and intercostal or mammary blood vessels. A volume of 30 mL is needed for hemothorax to manifest on an upright chest X-ray. In skilled hands, ultrasound can diagnose hemothorax accurately.
Although the chest wound seems open on exam, there is no sign or symptom suggestive of a sucking open chest wound potentiating tension pneumothorax for now. The main concern with open chest wounds is the fact that air tends to enter the pleural cavity through the wound, rather than into the lung through the trachea once the wound diameter exceeds 75% of the diameter of the trachea during inspiration. This will quickly lead to pneumothorax and tension pneumothorax.
NOTE - Immediate management of a sucking chest wound is with a three-side-sealed wound covering to produce a one-way valve mechanism
Option A: Wound strapping is not an option for management of hemothorax.
Option C: Immediate decompression with needle aspiration is used for urgent management of tension pneumothorax.
Option D: Intubation is not an option for management of patient with hemothorax.
Option E: Thoracotomy is the procedure of choice for surgical exploration in the following situations:
* An immediate bloody drainage of ≥20 mL/kg (approximately 1500 mL)
* Persistent bleeding (generally >3 mL/kg/hour)
* Shock despite initial treatment
A 2-year-old Aboriginal boy has ingested 2 lithium batteries 2 hours ago, and is brought to the Emergency Department. Chest and abdominal X-rays confirms the batteries to be still in the esophagus. Which one of the following would be the most appropriate management?
A. Emergency endoscopic removal of the batteries.
B. Watch for the passage for 3 days.
C. Serial chest and abdominal X-rays.
D. Urgent laparotomy.
E. Reassure the parents.
A. Emergency endoscopic removal of the batteries.
Lithium batteries can cause liquefaction necrosis as rapidly as six hours. This occurs due to production of sodium hydroxide production caused by the current of the battery. If the battery is in the esophagus, it should be endoscopically removed as soon as possible. Esophageal burns and subsequent perforation occur adjacent to the negative battery pole (anode). Injury can continue even after endoscopic removal for days to weeks due to residual alkali or weakened tissue.
A 71-year-old woman underwent a hip replacement surgery 3 days ago. Tonight, you are called to visit her because she is unwell. She is agitated, cannot sleep and is exquisitely sensitive to noise. She has a history of anxiety and depression. Physical examination is unremarkable, and the vital signs are stable. An air blood gas (ABG) analysis reveals a PaO2 of 91 mmHg (normal: 80-95 mmHg). Which one of the following diagnoses best describes this clinical picture?
A. Urinary tract infection.
B. Pulmonary embolism.
C. Paroxetine withdrawal.
D. Benzodiazepine withdrawal.
E. Transient ischemic attack.
D. Benzodiazepine withdrawal.
Agitation, sleeplessness, and more importantly exquisite sensitivity to noise suggests benzodiazepine withdrawal as the most likely explanation to this presentation. History of anxiety and depression endorse this diagnosis as well, because it is common for patients suffering from anxiety to be on benzodiazepines as a means of relief.
The benzodiazepine withdrawal syndrome is highly variable. Common symptoms include insomnia, irritability, palpitations and sensory disturbances. Abrupt discontinuation in patients on high doses, e.g. greater than diazepam 50mg daily or equivalent, may result in seizures.
Option A: Urinary tract infection (UTI) would have presented with more pronounced symptoms such as fever, frequency, urgency and/or dysuria. Without these, and considering the normal exam results, UTI seems a remote possibility.
Option B: Considering the type of the surgery and subsequent immobilization, pulmonary embolism (PE) should be doubted and investigated; however, it is unusual for a patient with PE to have stable vital signs and normal physical exam findings, and more importantly a normal arterial oxygen pressure. Additionally,sensory disturbances are not a feature seen in PE.
Option C: SSIR (e.g. paroxetine) withdrawal syndrome can cause dizziness, vertigo, headache, nausea and flu-like symptoms as well as anxiety, confusion, irritability, excessive dreaming and insomnia. Although paroxetine can be the cause as well, the presence of sensory disturbances makes benzodiazepine withdrawal more likely.
Option E: Without any focal neurological deficits in history and clinical findings, TIA is unlikely.
A 42-year-old man, who was involved in a motor vehicle accident, is being evaluated in the Emergency Department. On examination, he has stable vital signs and an oxygen saturation of 96% on room air; however, he has marked difficulty in breathing due to intractable chest wall pain, which is worse on inspiration. He only takes shallow breaths. On examination, multiple bruises and tender points are noted on his chest. A non-contrast CT scan of the chest reveals multiple bilateral rib fractures as well a small pneumothorax on the right side. Which one of the following options is the most appropriate immediate treatment to help him with breathing?
A. Intubation.
B. Morphine.
C. Chest strapping.
D. Needle aspiration of the pneumothorax.
E. Underwater-sealed chest drain.
B. Morphine.
Pain control has a fundamental role to play in the management of rib fractures to decrease chest wall splinting and alveolar collapse. Patients with pain due to rib fractures, such as this, try to minimize their chest wall motion by shallow breathing and avoiding coughing efforts. Adequate pain management improves tolerance for deep breathing and coughing that will result in enhanced lung volume and clearance of secretions. These will reduce the risk of lung collapse and pneumonia.
A number of inpatient strategies have been proposed to optimize pain control in patients with rib fractures, including:
- Regional anesthesia - Regional anesthesia techniques available for the management of multiple rib fractures include continuous epidural infusion, paravertebral block, intrapleural infusion, and intercostal nerve block.
- Intravenous narcotics - Intravenous narcotics e.g. morphine can provide rapid adequate pain control. Intravenous route is preferred over subcutaneous or intramuscular injections because of the rapid and predictable onset of action. Although there is no evidence to support use intravenous nonsteroidal anti-inflammatory drugs (e.g. ketorolac) for pain control in rib fracture, they can be used to supplement and reduce narcotic use. However, these agents are avoided in patients who have a significant bleeding risk (e.g. hemothorax, solid organ injury) and those with renal insufficiency or hypovolemia. Patient-controlled analgesia (PCA) is advocated for patients with rib fractures because of a more timely access to pain medication by the patients and a reduced risk for excessive sedation.
- The size of the pneumothorax and O2 saturation in this patient, make pain caused by fractured ribs the only respiratory problem for now, and adequate pain control is the first priority forcomfortable and painless breathing. This can be achieved by measures described above. Of the options only morphine can be used for pain control.
Option A: Intubation would be the most appropriate option for patients with fail chest with contraindications or inadequate response to less invasive measures such as CPAP or BiPAP.
Option C: Chest strapping by decreasing chest wall movements can be somewhat useful but it decreases adequate ventilation which is in disagreement with the management objectives. It is not an appropriate treatment.
Option D: Needle aspiration is the most appropriate next step in patients with tension pneumothorax for immediate relief. This then is followed by chest tubes and continues underwater-sealed drainage.
Option E: Water-sealed chest drain must be inserted for treatment of the pneumothorax; however, the pneumothorax is small and has not compromised oxygenation yet. It is not a priority at this stage.
A 35-year-old man is brought to the Emergency Department after he sustained a car crash. On examination, he has a blood pressure of 80/50 mmHg, heart rate of 110 bpm, and respiratory rate of 19 breaths per minute. He is pale and diaphoretic. Bedside pulse oxymetry shows an oxygen saturation of 95% on room air. Which one of the following is the most appropriate next step in management?
A. Supplemental oxygen.
B. Chest X-ray (CXR).
C. CT scan.
D. Intravenous colloid fluids.
E. Blood transfusion.
A. Supplemental oxygen.
In all trauma patients (like other patients) the ABC (airway, breathing, and circulation) protocol should be followed in a sequential manner. There is no comment regarding airway compromise. He also does not appear to have any respiratory distress. In addition, the normal oxygen saturation of 95% (94-100%) excludes respiratory compromise - at least for now.
The patient, however, is in pre-shock state evident by a systolic blood pressure of less than 90 mmHg. Reflexive tachycardia is
confirmatory. Although tension pneumothorax and cardiac tamponade can cause shock in the absence of hemorrhage, there are no clues to such conditions in the scenario. These make hemorrhagic shock the most likely cause of hypotension and tachycardia.
In all trauma patients in hemorrhagic shock, oxygen supplementation is beneficial and should be considered as the very next best step in management even if oxygen saturation is within the normal limits but not maximum. Maximizing the blood oxygen pressure compensates, to some extent, the decreased tissue oxygenation due to diminished perfusion caused by hypovolemia.
Option B and C: CXR and other imaging modalities such as CT scan should be withheld until the patient is hemodynamically stable.
Option D: Replenishing the lost volume is the most essential step after adequate oxygenation is ensured. Classically, isotonic solutions such as normal saline or ringer is used. Preference of colloids over isotonic fluids is still a place of significant debate.
Option E: Blood transfusion is considered when initial fluid resuscitation using 2 liters of intravenous fluid fails to restore and maintain adequate perfusion.
A 27-year-old woman is rushed to the Emergency Department by paramedics after she sustained a motor vehicle accident. Upon arrival, she is unconscious, has a blood pressure of 80/60 mmHg, pulse of 120 bpm, and respiratory rate of 22 breaths per minute. Stridor is noted on phsical examination. The patient has an oxygen saturation of 88% on room air. Supplemental oxygen is provided immediately, intravenous fluids are started, and a portable cervical X-ray obtained that reveals a fractured and dislocated cervical vertebra. Which one of the following is the most appropriate step in management of her airway?
A. Cricothyroidotomy.
B. Tracheostomy.
C. Intubation.
D. CPAP.
E. Increasing the oxygen flow.
C. Intubation.
This patient has concomitant compromised airway and a critical spinal injury at C2 level. Unconsciousness and stridor together mean that this patient should have an airway secured. This could be achieved by endotracheal intubation as the most effective and convenient method. However, intubation could be associated with immediate respiratory paralysis if the cervical lesion is above the C3 level or delayed phrenic nerve paralysis from ascending edema of the spinal cord in lower cervical lesions.
According to Advanced Trauma Life Support (ATLS®) guidelines, orotracheal intubation is the preferred method of airway management for patients with traumatic cardiopulmonary arrest, even with evidence of spinal injury. Orotracheal intubation using rapid sequence intubation protocol is recommended for patients who are breathing but unconscious and in need for airway control or ventilatory support. In-line spinal stabilization should be maintained throughout the procedure to minimize the spinal columns movement and reduce the risk of causing or exacerbating a spinal cord injury.
Option A: Cricothyroidotomy is indicated when an airway is required immediately in a patient who is not a candidate for orotracheal or nasotracheal intubation. Severe facial trauma is the most common indication. It is absolutely contraindicated in children younger than 12 years due to the risk of consequent tracheal stenosis. Relative contraindications include:
* Airway obstruction distal enough to the cricoid membrane that a cricothyroidotomy would not provide a secure airway with which to ventilate the patient
* Presence of a SHORT neck, which includes Surgery (history or prior neck surgery), Hematoma, Obesity, Radiation (evidence of radiation therapy), or Trauma/burns, making it difficult to locate the patient’s anatomical landmarks or producing an increased risk of further complications
* Tumor, infection, or abscess at the site of incision Lack of operator experience with the procedure
Option B: Tracheostomy should be performed in the operating room and is indicated for patients who are planned for prolonged mechanical ventilation.
- Tracheostomy may be considered in the following situations:
- Congenital anomaly (e.g., laryngeal hypoplasia, vascular web)
- Upper airway foreign body that cannot be dislodged with Heimlich and basic cardiac life support maneuvers
- Supraglottic or glottic pathologic condition (e.g., infection, neoplasm, bilateral vocal cord paralysis)
- Neck trauma that results in severe injury to the thyroid or cricoid cartilages, hyoid bone, or great vessels
- Subcutaneous emphysema
- Facial fractures that may lead to upper airway obstruction (e.g., comminuted fractures of the mid face and mandible)
- Upper airway edema from trauma, burns, infection, or anaphylaxis
- Prophylaxis (as in preparation for extensive head and neck procedures and the convalescent period)
- Severe sleep apnea not amendable to continuous positive airway pressure devices or other less invasive surgery
- Tracheostomy may also be performed to provide a long-term route for mechanical ventilation in cases of respiratory failure or to provide pulmonary toilet in the following cases:
- Inadequate cough due to chronic pain or weakness Aspiration and the inability to handle secretions
Option D: CPAP cannot provide a secure airway and is not an appropriate option in this patient.
Option E: Increasing the oxygen flow while the airway is compromised is futile.
A 23-year-old man is brought to the emergency department by ambulance paramedics after he sustained a stab wound in the chest in a street fight. On examination, he has a knife stuck in the left hemithorax. The patient is awake, oriented and cooperative. His blood pressure is 110/65mmHg, heart rate 100 bpm and respiratory rate 18 breaths per minute. There are no raised neck or forehead veins. Which one of the following is the most appropriate next step in management?
A. Remove the knife int he emergencey department and place deep sutures.
B. Remove the knife in the emergency department after you obtained a chest X-ray (CXR).
C. Transfer the patient to the operating room (OR), remove the knife in the OR and insert chest tube.
D. Insert chest tube in the emergency department and then remove the knife.
E. Perform a needle thoracocentesis for immediate decompression and then transfer the patient to the OR.
C. Transfer the patient to the operating room (OR), remove the knife in the OR and insert chest tube.
As a rule, all impaled foreign bodies should be secured in place and not removed until the patient is in the operating room (OR). The rationale behind this approach is that the object could have damaged major blood vessels, which are temporarily blocked by the object. If the object is removed, the pressure over the vessels is released, and life-threatening, potentially uncontrollable hemorrhage could ensue.
Such patients should be taken to the OR for removal of the impaled object in a controlled environment where potential bleeding after removal can be promptly controlled. A chest tube should be left in place for successful drainage of blood leak or air in the pleural space. As many as 80% of patients with penetrating chest trauma have hemothorax, pneumothorax, or both.
Any options suggesting removal of the knife in any place other than the OR is incorrect.
Immediate needle aspiration is the most appropriate next step in patients with tension pneumothorax which is not the case here. Tension pneumothorax presents with hypotension and difficulty breathing as well as other findings such as diminished air entry into the affected side, tracheal deviation away from the site of the injury, and diminished breath sounds and hyper-resonance of the affected hemithorax.
A 27-year-old man is brought to the Emergency Department after he sustained a stab wound to the left side of his upper chest. On examination, blood pressure is 120/90 mmHg, heart rate 110, and respiratory rate 19 breaths per minute. Bedside pulse oxymetry shows an oxygen saturation of 91% on room air. On inspection, the trachea is deviated to the left and breathing appears labored. Auscultation reveals decreased air entry into the left lung. The left side of the chest is dull to percussion. Which one of the following is the most appropriate next step in management?
A. Give him supplemental oxygen.
B. Insert chest tube in the left hemithorax.
C. Thoracocentesis.
D. Intravenous fluids.
E. Take him the operating room (OR) immediately.
A. Give him supplemental oxygen.
This patient has labored breathing and decreased oxygen saturation (normal 94%-100%) in the setting of penetrating chest trauma. Air entry is also diminished on the injured side. These can be caused by either hemothorax or pneumothorax. With dullness over the affected lung, hemothorax is the diagnosis, as in pneumothorax the presence of air in the pleural space gives rise to hyper-resonance on percussion on the affected side.
Regardless of the etiology, however, this patient is in obvious respiratory compromise evident by decreased lung air entry, elevated respiratory rate, and decreased oxygen saturation (< 94%) in the range of mild hypoxia; therefore, the first action must be application of supplemental oxygen according to the ABC protocol (airway, breathing , and circulation). This then should be followed by immediate chest tube insertion for evacuation of the air/blood form the pleural cavity as the definite treatment.
Option B: Chest tube must be inserted for management of hemothorax after supplemental oxygen is given.
Option C: Needle thoracocentesis would be indicated for emergent decompression if there was tension pneumothorax. In tension pneumothorax, the excess air in the pleural space leads to increased pressure within the affected hemithorax resulting in compression of the mediastinum away from the site of the injury. The heart then twists around its superior-inferior axis and kinks veins and decrease venous blood return to the heart. This leads to hypotension and shock. As mentioned earlier, the mediastinal structures and trachea are pushed away from the site of the injury, unlike this patient whose trachea is shifted towards the side of the injury.
Option D: Intravenous fluids are not indicated for now as the patient has normal blood pressure and heart rate.
Option E: Pneumothorax or hemothorax alone can be treated in the Emergency Department with chest tube, and is not an indication for transferring the patient to the OR per se.
A 32-year-old man presents to the Emergency Department with a knife impaled in his back under the right scapula. On examination, he has blood pressure of 85/50 mmHg, heart rate of 110 bpm and respiratory rate of 22 breaths per minute. There is adequate air entry into both lungs, but the breathing is labored and the patient can say one sentence at a time. Pulse oxymetry shows an O2 saturation of 91% on room air.
After starting him on supplemental oxygen by face mask and intravenous fluids, which one of the following will be the next best step in management?
A. Urgent CT scan of the chest.
B. Intubation.
C. Cross match.
D. Removal of the knife under general anesthesia.
E. Chest tube.
C. Cross match.
Low blood pressure and tachycardia in this patient indicate internal hemorrhage. Although tension pneumothorax and cardiac tamponade can cause similar picture, there is no clue to such conditions in the scenario. Tension pneumothorax is associated with shifted trachea away from the site of the injury, hyper-resonance, and/or decreased chest wall movements on the affected side. Cardiac tamponade results in decreased diastolic flow to the heart, pulsus paradoxus, hypotension, and tachycardia. Both tension pneumothorax and cardiac tamponade can lead to raised neck and forehead veins; however, veins might be flat due to concomitant hemorrhage and hypovolemia.
This patient has another problem as well – the impaled knife. As a rule, any impaled foreign body should be secured in place and not removed until the patient is in the operating room (OR). The rationale to this approach is that the object could have damaged major blood vessels, which are temporarily sealed by the object. If the object is removed, the pressure over the vessels is released and life-threatening and potentially uncontrollable hemorrhage could occur. This would be a grave condition in this patient which is already hemorrhaging.
In this patient blood should be drawn for typing, cross matching, and reservation after initial resuscitation with oxygen and fluid. Blood should be available in the OR in case the repair is prolonged, and bleeding cannot be stop immediately.
Option A: In this patient, measures such as initial resuscitation, blood typing and cross match, and immediate transfer to the OR should not be delayed for imaging studies such as CXR or CT scan.
Option B: Intubation of this patient should be considered in the OR if general anesthesia is planned. The knife is then removed, and any possible damage repaired.
Option D: This patient must be transferred to the OR for removal of the impaled object in a controlled environment and under general anesthesia. However, blood group typing and cross matching should be performed before that.
Option E: A chest tube will be secured in the OR after the knife is removed and damages repaired because approximately 80% of patients with penetrating chest injuries have hemothorax, pneumothorax, or both.
A 32-year-old man is brought to the Emergency Department by ambulance after he sustained a house fire. On examination, the patient is conscious but in severe distress due to pain. He has voice hoarseness, burns around the neck, and burned nose hair. Which one of the following is the next best step in management?
A. Intubation.
B. Oxygen by face mask.
C. Intravenous morphine for analgesia.
D. Debridment of the burns and application of topical antibiotics.
E. Intravenous fluids.
B. Oxygen by face mask.
In victims of a close environment burns, smoke and heat inhalation is associated with significant risk of airway obstruction. Any patient with sooth in the mouth or nose or burns in the face or mouth or around the neck should be monitored very carefully for airway compromise due to edema. Burn victims should be intubated before edema results in complete airway obstruction.
This patient has hoarseness that indicates airway involvement, and intubation should be considered. In meanwhile he should receive supplemental oxygen as the most important next step in management while arrangements for intubation are undertaken.
All other options are considered as parts of management, but none takes precedent over oxygenation and intubation.
A 19-year-old man is brought to the Emergency Department after he sustained a stab wound to the right side of his chest. The knife is still in. On examination, his vital signs are within normal range and there is no respiratory distress; however, air entry to the right lung is diminished. A chest X-ray (CXR) reveals a 25% pneumothorax on the right side. Which one of the following is the most appropriate next step in management?
A. Admit and observe.
B. Perform serial chest X-rays.
C. Removal of the knife in the operating room under general anesthesia and chest tube insertion.
D. Removal of the knife in the operating room under general anesthesia.
E. Thoracotomy.
C. Removal of the knife in the operating room under general anesthesia and chest tube insertion.
As a rule, any impaled foreign body should be secured in place and not removed until the patient is in the operating room (OR). The rationale behind this approach is that the object could have damaged major blood vessels, which are temporarily tamponaded by the object. If the object is removed, the pressure over the vessels is released, and life-threatening, potentially uncontrollable hemorrhage could occur.
Treatment of this patient’s pneumothorax should be undertaken in the operating room by inserting a chest tube and water-sealed chest drainage after the knife is removed and any damage is repaired.
Option A: Admission and observation is incorrect because not only this patient requires emergency removal of the impaled knife in the OR, his traumatic pneumothorax should be treated with chest tube.
Option B: Admission and observation with serial chest X-rays is considered in selected patients with occult asymptomatic pneumothoraces. A 25% symptomatic pneumothorax needs definite treatment with chest tube insertion.
Option D: Knife removal should be followed by chest tube insertion for drainage of blood and post-op pleural secretions even in the absence of pneumothorax.
Option E: Thoracotomy may be indicated for acute or chronic conditions.
Acute indications include the following:
* Cardiac tamponade
* Acute hemodynamic deterioration/cardiac arrest in the trauma center
* Penetrating truncal trauma (resuscitative thoracotomy)
* Vascular injury at the thoracic outlet
* Loss of chest wall substance (traumatic thoracotomy)
* Massive air leak
* Endoscopic or radiographic evidence of significant tracheal or bronchial injury
* Endoscopic or radiographic evidence of esophageal injury
* Radiographic evidence of great vessel injury
* Mediastinal passage of a penetrating object
* Significant missile embolism to the heart or pulmonary artery
* Transcardiac placement of an inferior vena caval shunt for hepatic vascular wounds
Chronic indications for thoracotomy include the following:
* Non-evacuated clotted hemothorax
* Chronic traumatic diaphragmatic hernia
* Traumatic cardiac septal or valvular lesion
* Chronic traumatic thoracic aortic pseudoaneurysm
* Non-closing thoracic duct fistula
* Chronic (or neglected) post-traumatic empyema
* Infected intrapulmonary hematoma (e.g. traumatic lung abscess)
* Missed tracheal or bronchial injury
* Tracheoesophageal fistula
* Innominate artery/tracheal fistula
* Traumatic arterial/venous fistula
A 36-year-old man is rushed into the Emergency Department by paramedics after he sustained a head-on collision as an unrestrained driver. He has a hard collar and his head is fixed to a spine board. On a quick review, he is conscious and fully oriented, but in distress as he is not able to feel his arms and legs. There is no visible site of active bleeding or limb deformity. Chest is clear to auscultation, neck veins are not raised, and abdominal exam is inconclusive. His blood pressure is 90/40 mmHg, heart rate 50 bpm and respiratory rate 18 breath per minute. His oxygen saturation is 88% on room air. Sphincter tone is decreased and there is no sensation or deep tendon reflexes below the neck. He is immediately placed on supplemental oxygen via face mask. Which one of the following would be the most appropriate next step in management?
A. Placement in Trendelenburg position.
B. Intravenous colloid fluids.
C. Blood transfusion.
D. Adrenaline.
E. Atropine.
A. Placement in Trendelenburg position.
The scenario suggests neurogenic shock. The most common cause of shock in a trauma patient is hypovolemic shock even in the presence of obvious spinal injury. In comparison, neurogenic shock is much less common and when the condition exists it can mask the presentation of hypovolemic shock; therefore, it is imperative that hemorrhage, as the most likely cause of decreased blood pressure is excluded. Neurogenic shock is always a diagnosis of exclusion.
In this patient, no site of active bleeding is noted. There is also no limb deformity to point towards long bone (or pelvic) fractures as the source of bleeding and decreased blood pressure. Abdominal exam is unremarkable as well.
Tension pneumothorax and cardiac tamponade are other conditions that can lead to decreased blood pressure by impeding venous return to the heart. For these to exist, chest should be involved. There are no comments as to chest involvement in the scenario; moreover, breathing is normal, and no abnormalities are found on auscultation.
Although the possible sources of occult bleeding should be thoroughly investigated, with no clues pointing towards other causes of hypotension, especially hemorrhage and obstruction, the next possible cause to consider in this patient must be neurogenic shock.
Neurogenic shock is classically characterized by hypotension, bradycardia, and peripheral vasodilatation. Neurogenic shock is due to loss of sympathetic vascular tone and happens only after a significant proportion of the sympathetic nervous system has been damaged – as can occur with lesions above the 6th thoracic vertebra. In a quadriplegic patient, blood pressure normally ranges between 80/40mmHg to 100/60 mmHg and pulse rate is down to 50 bpm.
The first measure to consider in patients with neurogenic shock is close attention to airway, breathing and circulation (ABC). Hypoperfusion to an injured spine can be associated with poor outcomes. Oxygenation should be monitored carefully, and oxygen be given. It is recommended that patients with traumatic spinal injury receive 15L/m oxygen via a non-rebreathing mask.
Hypotension and bradycardia are common features of neurogenic shock. According to guidelines by Neurosurgical Society of Australia, the first measure to consider is placement of the patient in Trendelenburg position. In neurogenic shock, the main mechanism of hypotension is pooling of blood in the peripheral venules and small vein; therefore, such maneuver can correct hypotension by increased venous return to the heart.
This patient has hypoxia evident by an oxygen saturation of 88% (normal ≥95%); therefore, supplemental oxygen should begin. In patients with neurogenic shock, systolic blood pressure should be maintained above 90 mmHg. Placement of the patient in Trendelenburg position (if there are no contraindication e.g., head trauma) should be considered next.
Option B: Isotonic fluids (not colloids) should come next after oxygenation and placement in Trendelenburg position. Careful monitoring for volume overload is a ‘must’.
Option C: Blood transfusion is considered in hemorrhagic patients if there is minimal response to adequate fluid resuscitation using crystalloids (e.g. normal saline). Patients with neurogenic shock as their sole underlying cause of their hypotension do not require blood transfusion.
Option D: Vasopressors or inotropes such as dopamine, nor-adrenaline (norepinephrine) or phenylephrine are considered for patients with hypotension resistant to position or adequate volume resuscitation. Urinary output can be an appropriate guide (urinary output of < 0.5cc/kg/hour). Adrenaline is not used for such a purpose.
Option E: Atropine is reserved for patients with bradycardia of < 50bpm. As mentioned earlier, it is quite common for patients with neurogenic shock to have bradycardia down to 50bpm. Atropine is only indicated if there is severe bradycardia (< 40 bpm), or when there is significant hemodynamic instability caused by it. Atropine should also be considered in patients who are undergoing maneuvers that can induce bradycardia by vagal stimulation e.g., nasopharyngeal suction or intubation.
A 56-year-old man undergoes hip surgery. In the following 24 hours, he only passes 200 ml of urine. During the surgery he was given 1.5 liters of normal saline and 2 units of packed red cells. Which one of the following investigations is more likely to find the cause of the oliguria?
A. Administration of 1 liter of normal saline in 1 hour and monitoring the response.
B. CT scan of the abdomen and the pelvis.
C. Retrograde pyelogram.
D. DSMA scan.
E. Urine analysis.
A. Administration of 1 liter of normal saline in 1 hour and monitoring the response.
Oliguria, defined as a urine output less than 30 ml/hour (0.5ml/kg/hour) is a common problem in post-operative period. This can be a consequence of fluid and blood loss resulting in increased release of aldosterone and antidiuretic hormone (ADH) by the adrenal cortex and posterior pituitary, respectively, in the first 24 hours after the surgery. Oliguria should be temporary and not last more than 24 hours. A urinary output of less than 500 ml within the first 24 hours warrants prompt investigations.
Before the oliguria is attributed to diminished urine output, it is important to ensure that the patient is not in urinary retention. A full, tender bladder is often a typical presentation of urinary retention. If in doubt, a catheter should be passed to check the urine volume in the bladder. Ultrasound can be used as an alternative.
Oliguria is caused by either of the following:
- Poor renal perfusion (pre-renal failure e.g., hypovolemia or pump failure)
- Renal failure (e.g., acute tubular necrosis)
- Renal tract obstruction (post-renal failure)
Most cases of post-operative oliguria are secondary to hypovolemia. This should always be considered first until proven otherwise. This holds true about this patient as well. More so because he had developed hypovolemia during the surgery requiring resuscitation with fluid and blood.
In such circumstance, the next best step would be fluid challenge. One liter of normal saline is administered, and urine output monitored closely. An increase in urine output in response to fluid administration is both therapeutic and diagnostic for oliguria due to hypovolemia.
With renal failure as the underlying cause, oliguria will not respond to fluid challenge. If that is the case, investigation should include urine and plasma osmolality and electrolytes as well as an ultrasound for assessment of urinary tract obstruction as a possible cause of renal failure.
Option B: CT scan is not useful for diagnosis of renal failure. If imaging is required, ultrasonography is the preferred option.
Option C: Retrograde pyelogram requires contrast media. If renal failure is a concern, any option suggesting contrast imaging is incorrect. Contrast media is nephrotoxic and a hazard in patients with suspected renal failure.
Option D: DSMA scan has no role in workup for oliguria or renal failure.
Option E: Urinalysis for urine specific gravity is a part of routine investigation in patients with suspected renal failure and is indicated if the patient does not respond to fluid resuscitation. Other tests are urine and serum osmolality and urea, creatinine, electrolytes.
A 30-year-old woman is brought into the Emergency Department after falling from a horse while riding. She has a hard collar on and her head is taped to a hard spine board. She is fully conscious and oriented but unable to move any of her limbs. She answers the question in a normal voice. On a quick review, no visible active bleeding is noted. Chest is clear to auscultation and abdominal exam is inconclusive. No limb deformity is noted either. She has a blood pressure of 85/40 mmHg, heart rate of 50 bpm, and oxygen saturation of 90% on room air. Which one of the following is the most appropriate next step in management?
A. Atropine.
B. Adrenaline.
C. Oxygen.
D. Trendelenburg position.
E. Intravenous colloid fluids.
C. Oxygen.
In all trauma patients, initial survey and management starts with the ABC protocol (airway, breathing, and circulation).
This patient is fully conscious and oriented and answers the questions in a normal voice; therefore, her airway is not compromised, and no further airway management is indicated - at least for now.
Breathing comes next. An oxygen saturation of 90% on room air indicates mild hypoxia and requires supplemental oxygen as the most important next step in management. Additionally, hypoxia in the face of cord injury can adversely affect neurologic outcome. Arterial oxygenation should be monitored and supplemented as needed.
No site of active bleeding or any other clues to hemorrhage as the cause hypotension is present in this patient. Although, thorough investigation is required to exclude overt or occult hemorrhage as the most common cause of shock in trauma patients, given the clinical findings on the quick review, neurogenic rather than hemorrhagic shock is more likely.
Patients with neurogenic shock often have bradycardia down to 50bpm and a blood pressure ranging from 80/40 mmHg to 100/60 mmHg.
Option A: Patients with neurogenic shock have bradycardia of down to 50 bpm. No specific therapy is required unless there is significant hemodynamic instability or severe bradycardia (< 40 bpm).
Option B: Inotrope medications such as dopamine, norepinephrine, or phenylephrine maybe indicated in patients with resistant hypotension.
Option D and E: This patient may be initially placed in Trendelenburg position (head down) to relocate the pooled blood in the peripheral venules and small veins to the heart. This results in an increase in cardiac output and blood pressure. Longer term management includes judicious administration of crystalloids (not colloids) such as Hartman’s solution or normal saline to maintain a blood pressure of 90-100 mmHg. This is critical as hypoperfusion of the injured spine is associated with neurological sequelae and poor outcomes. These, however, do not take precedence over oxygen supplementation as the most appropriate next step in this patient.
A 48-year-old man with history of heavy smoking and alcohol drinking had a laparotomy with oversewing of a perforated duodenal ulcer. 24 hours after the operation, he is confused and disorientated. Which one of the following is the most appropriate initial investigation?
A. Blood alcohol level.
B. Arterial blood gases (ABG).
C. Serum electrolytes.
D. Chest X-ray.
E. Liver function tests.
B. Arterial blood gases (ABG).
Post-operative confusion/disorientation is one of the serious post-operative complications. The most common cause of post-operative confusion is hypoxia that must be excluded or confirmed by an arterial blood gas (ABG) analysis as the most appropriate initial step in management.
Hypoxia is most likely due to hypoventilation as a result of sedative drugs and post-operative analgesics; however, other etiologies such as electrolyte disturbances, atelectasis, and sepsis with gram negative organisms should always been considered and excluded. Sepsis with gram negative organism can lead to acute respiratory distress syndrome (ARDS) and shock in a short time. Drugs or alcohol withdrawal is another cause to consider.
Option A: Delirium tremens (DT) or alcohol withdrawal can also be associated with post-operative delirium and confusion. However, the diagnosis is clinical and bases on the history of alcohol consumption. Blood alcohol level do not help with the diagnosis.
Option C: Electrolyte derangements (particularly hypo- and hypernatremia) are other common cause of post-op confusion. An electrolyte panel is an important part of investigation in patients with post-operative confusion after hypoxia is excluded.
Option D: Chest X-ray is indicated in patients with post-operative confusion after the cause is confirmed to be hypoxia by ABG. Pulmonary atelectasis or pneumonia may be evident on chest X-ray.
Option E: Without the history of liver disease, confusion is unlikely to have been caused by liver disease. Liver function tests are not among routine investigations in patients with post-operative confusion.
A 40-year-old woman underwent cholecystectomy. On the first post-operative day, she develops fever and shortness of breath. After chest physiotherapy which one of the following is the next best step in management?
A. Continuation of chest physiotherapy.
B. Commencement of antibiotics.
C. Postural drainage.
D. Supplemental oxygen.
E. Bronchoscopy.
D. Supplemental oxygen.
The clinical findings of shortness of breath and fever in the early post-operative period (within 24 hours) are suggestive of atelectasis. Management of post-operative atelectasis starts with chest physiotherapy, followed by supplementation of oxygen to achieve an oxygen saturation of above 90%.
Option A: Continuation of chest physiotherapy is an appropriate step in management of atelectasis; however, after initial physiotherapy, supplemental oxygen should be given to maintain adequate oxygen saturation.
Option B: Antibiotics are not indicated in treatment of atelectasis unless chest infection follows.
Option C: Postural drainage helps with clearing of the secretions. The patient is asked to rest on the non-affected side to let the secretions drain by gravity. This is an important step in management of patients with atelectasis after initial physiotherapy and oxygen supplementation.
Option E: Bronchoscopy would be indicated if continuous chest physiotherapy fails. Routine use of bronchoscopy for removing secretions is not recommended.
In the first 24 hours after elective cholecystectomy, a 50-year-old woman develops a fever of 38.2°C and pulse rate of 110 bpm. The respiratory rate is 22 breaths per minute. She is smoker and had no pre-operative problems except the biliary pain. Which one of the following can explain this presentation?
A. Wound infection.
B. Pulmonary embolism.
C. Pulmonary atelectasis.
D. Bile leakage.
E. Pneumonia.
C. Pulmonary atelectasis.
Based on the history and clinical findings, pulmonary atelectasis is the most likely cause of this presentation. Pulmonary atelectasis is a quite common cause of post-operative fever in the first 24 hours of surgery, particularly in smokers.
Postoperative atelectasis is usually caused by decreased compliance of lung tissue, impaired regional ventilation, retained airway secretions, and/or postoperative pain that interferes with spontaneous deep breathing and coughing. Operations in the upper abdomen are most prone to development of atelectasis.
Option A: Wound infection presents more delay around 7th day post operation. Clinical signs of infection such as erythema, local tenderness, and/or purulent secretions are often found on clinical examination.
Option B: Pulmonary embolism typically occurs around 5th day post-operation, and presents with pleuritic chest pain, tachycardia, and tachypnea. The patient may or may not be febrile. It is less likely that a patient develops pulmonary embolism within the first day of surgery.
Option D: Leakage of bile presents with general malaise, abdominal pain, low-grade fever, and mildly elevated liver function tests. Shortness of breath and tachycardia are not common features.
Option E: Pneumonia often complicates atelectasis at around 3rd day post-op. It is early for development of pneumonia.
Eighteen hours after an uneventful cholecystectomy on a 45-year-old woman, she develops a fever and a cough. A chest X-ray (CXR) is obtained that is shown in the following photograph. Which one of the following is the next best step in management?
A. Chest physiotherapy.
B. Oral antibiotics.
C. Intravenous antibiotics.
D. Intravenous steroids.
E. Morphine.
A. Chest physiotherapy.
Of significance on the CXR, is the loss of the right heart border shadow, indicating collection in the right middle lobe. The onset of symptoms within the first 24 hours post-operatively, in addition to the CXR findings is consistent with the diagnosis of atelectasis. Atelectasis is common in abdominal and trans-thoracic procedures. Mucus retention in airways leads to post-obstructive collapse of the distal airways, particularly in the lower parts of the lung. Pneumonia can complicate atelectasis.
Post-operative atelectasis is managed as follows:
- Removal of impacted secretion by percussion and encouraging the patient to actively cough.
- Passive postural drainage.
The most important step in management is chest physiotherapy, followed by oxygen supplementation. If the above measures failed, a catheter can be passed through, guided by bronchoscope, for more vigorous removal of the secretions.
Option B and C: Antibiotics are not indicated unless fever persists more than 48 hours, suggesting superimposed pulmonary infection (pneumonia).
Option D: Steroids have no role in management of atelectasis.
Option E: Morphine is not indicated for management of atelectasis. Furthermore, morphine can decrease respiratory drive and worsens the atelectasis.