Physical Address
304 North Cardinal St.
Dorchester Center, MA 02124
With approximately 15,000 deaths per year, trauma is the leading cause of death in children over 1 year of age in the United States. Anesthesiologists and anesthetists in nearly every type of hospital setting will eventually be exposed to the multiply injured child. In this chapter, we review in detail the anesthetic considerations for trauma and burn management in the pediatric population.
The most common causes of traumatic injury in children are based on age. In infants, the most common cause is child abuse. In toddlers, it is falls from heights, and in school-aged children motor vehicle and bicycle accidents.
Severe traumatic brain injury (TBI) is the most common cause of death in injured children. An acceleration or deceleration injury can result in a cerebral contusion, which may be located on the same side as the impact, on the opposite side of the impact (contra-coup injury), or both. Blunt or penetrating trauma may cause an intracranial hemorrhage. A tear of the middle meningeal artery produces an epidural hematoma, and trauma that causes rupture of bridging veins results in a subdural hematoma. Any of these aforementioned injuries may produce a condition known as diffuse axonal injury (DAI), which is associated with permanent disability. Children are more susceptible to TBI because of less central nervous system (CNS) myelination, thinner and more compliant cranial bones, and a larger head-to-body ratio than adults.
Contusions and intracranial bleeds are diagnosed by computed tomography (CT). Patients with DAI and abnormal neurologic exams may initially have a normal CT scan. Cerebral edema may be evident on a subsequent scan.
TBI should be suspected in children with head trauma despite an absence of neurologic abnormalities. Indicators of occult TBI include loss of consciousness any time after the event, and multiple episodes of emesis. Sedated children with multiple injuries should be considered to have TBI because of their inability to perform a reliable neurologic exam.
TBI resulting from child abuse is the leading cause of death in children under 1 year of age. This diagnosis should be considered when the child’s injuries are out of proportion to the history or the child’s developmental level. Common presenting signs include irritability, emesis, decreased level of consciousness, seizures, and coma. There may be multiple injuries at different stages of healing. Injuries may be severe and include subdural hematoma, subarachnoid hemorrhage, skull fracture or DAI with or without cerebral edema. Although state law varies, all physicians must report suspected child abuse to the proper authorities (i.e., social services, child protective services, police, etc.). Careful documentation of the history, physical examination and intraoperative findings is helpful if legal testimony is required at a later date.
While this category includes chocking, Sudden Infant Death Syndrome (SIDS) is the leading cause of death in children from 1 month to 1 year of age. According to the Centers for Disease Control and Prevention (CDC), 26% of SIDS deaths are caused by accidental suffocation or strangulation in bed (ASSB). In 1994 a national “Safe to Sleep Campaign” was launched to combat this epidemic. Since the initiation of “Safe to Sleep,” SIDS deaths have decreased by 50% in the United States. Over half of all infants that present with SIDS will require escalation of care and most will proceed to have significant neurologic injury from hypoxia.
The incidence of spinal cord injury (SCI) in pediatric trauma is estimated to be 1%, which is lower than the adult population because of greater flexibility of the pediatric cervical spine. Any child with an unknown mechanism of injury, multisystem trauma, brain injury, or a known injury above the clavicle should be suspected to also have SCI. Approximately 50% of children with SCI have concomitant TBI. Conversely, the presence of TBI substantially increases the risk for SCI.
SCI in children is diagnosed and managed in a similar manner to adults. Radiographs of the cervical spine should include anteroposterior and lateral views that include the cervicothoracic junction (“swimmer’s view”), and views of the odontoid process of C2. However, the cervical spine cannot be “cleared” by radiographic examination without a normal neurologic exam. Therefore children with normal cervical spine radiographs should be kept immobilized until thoroughly examined because spinal cord instability and neurologic deficits may occur without a fracture. A neurologic deficit without a fracture is called SCIWORA (spinal cord injury without radiologic abnormalities). The term was coined in the pre-MRI era. We now know that most of these children will have demonstrable abnormalities on magnetic resonance imaging (MRI). SCIWORA can occur in the cervical or thoracic spinal cord, mainly in children less than 8 years of age. In about one-quarter of children with SCIWORA, the onset of the neurologic deficit is delayed. These children will initially have minor sensory or motor deficits that progress over time. The majority of SCIWORA injuries are caused by severe flexion or extension injuries of the neck that cause ligamentous stretching or disruption without bony injury. Continued immobilization and cervical spine precautions are necessary because of the possibility of evolving injury.
The majority of thoracic trauma in children consists of blunt injuries caused by motor vehicle accidents. Adults struck by cars typically experience pelvic or lower extremity fractures because of the level of the bumper of a car. For most school age and younger children, the level of the bumper corresponds to the thorax or head. Therefore children are more likely to suffer thoracic injuries and TBI when struck by a car. Thoracic injuries are the second leading cause of death despite accounting for less than 5% of pediatric trauma. Pulmonary contusion is the most common type of thoracic injury; rib fractures are less common than in adults. Because of the relatively high compliance of the chest wall of young children (noncalcified rib cage) severe intrathoracic injuries can occur without obvious external injuries or rib fractures. As in adults, pneumothorax, hemothorax, and lung laceration are important sequelae of penetrating thoracic trauma.
Blunt abdominal trauma is primarily associated with injuries to the spleen and liver, but renal, pancreatic, and hollow viscous injuries can also occur. When a child restrained by a lap belt presents with abdominal or flank ecchymosis (lap belt sign), there is likely an abdominal injury or a horizontal fracture of a lumbar vertebral body (Chance fracture). Management of solid organ injury is largely expectant unless the child demonstrates hypotension unresponsive to resuscitative measures. Penetrating abdominal injuries usually result in intestinal injury and require surgical intervention. Extremity injuries with or without underlying vascular tears are common in children, as are complex lacerations and growth plate injuries. Simple scalp lacerations may be the cause of a significant amount of blood loss.
Attention to the quantity and quality of the urine output is important. Head trauma is associated with development of diabetes insipidus or SIADH. Direct muscle injury may result in rhabdomyolysis, which may cause myoglobinuria and lead to renal damage.
The initial management period (the “golden hour”) after an injury is focused on cardiorespiratory resuscitation and transport to an appropriate facility. As with adult trauma, there is controversy concerning the most appropriate care facility for pediatric trauma victims; outcome studies that provide a definitive answer are lacking. Pediatric trauma patients treated in adult hospitals had higher in-hospital mortality , and longer lengths of stay.
Management during this period is guided by the principles of advanced trauma life support (ATLS). The initial approach involves primary and secondary surveys, followed by definitive care of all injuries. The primary survey consists of optimizing oxygenation and ventilation, recognizing potentially life-threatening injuries and stabilizing the cervical spine. All life-threatening conditions are identified and managed simultaneously. Once the primary survey is completed, a thorough head-to-toe examination (secondary survey) is performed to identify all injuries.
The most critical aspect of successful management of pediatric trauma is adequate oxygenation and ventilation. The lucid and hemodynamically stable child can be managed conservatively; oxygen can be delivered by facemask as required. In the child with depressed consciousness, chin-lift and jaw-thrust maneuvers may be required to maintain upper airway patency while simultaneously stabilizing the child’s neck in the neutral position. Additional interventions may include oropharyngeal suctioning, insertion of an oral airway, and if the child is unstable, positive pressure ventilation using bag-mask ventilation or insertion of a laryngeal mask. Bag-mask ventilation can be effective and, in some children, may be an alternative to endotracheal intubation in the prehospital setting (depending on the training and experience of the prehospital provider). Indications for tracheal intubation in injured children include the following:
Decreasing level of consciousness (Glasgow Coma Scale <8; Table 37.1 )
GLASGOW COMA SCALE | INFANT COMA SCALE | ||
---|---|---|---|
RESPONSE | SCORE | RESPONSE | SCORE |
Eye Opening | Eye Opening | ||
Spontaneous | 4 | Spontaneous | 4 |
To Speech | 3 | To Speech | 3 |
To pain | 2 | To pain | 2 |
None | 1 | None | 1 |
Best motor response | Best motor response | ||
Obeys verbalcommand | 6 | Normal spontaneousmovements | 6 |
Localizes pain | 5 | Withdraws to touch | 5 |
Withdraws in response to pain | 4 | Withdraws to pain | 4 |
Abnormal flexion | 3 | Abnormal flexion | 3 |
Extension posturing | 2 | Extension posturing | 2 |
None | 1 | None | 1 |
Best verbal response | Best verbal response | ||
Oriented and converses | 5 | Coos, babbles, interacts | 5 |
Confused | 4 | Irritable | 4 |
Inappropriate words | 4 | Cries to pain | 4 |
Incomprehensible Sounds | 3 | Moans to pain | 3 |
None | 1 | None | 1 |
Marked respiratory failure secondary to chest trauma or other causes
Hemodynamic instability despite initial fluid resuscitation
Difficult bag-mask ventilation or the anticipated need for prolonged assisted ventilation, and to facilitate hyperventilation during management of increased intracranial pressure
Loss of protective airway reflexes
Endotracheal intubation may be difficult or in some cases impossible in conscious or semiconscious children. Unless consciousness is severely depressed, endotracheal intubation is accomplished by induction of general anesthesia using a modified rapid sequence technique with application of cricoid pressure and hyperventilation with 100% oxygen.
There are no universal recommendations regarding the most appropriate approach to maintain cervical spine stabilization during tracheal intubation. As in adults, manual in-line stabilization by a trained assistant is used most often, with care taken to keep the cervical spine in the neutral position during direct laryngoscopy, or fiberoptic-guided tracheal intubation. Flexible fiberoptic bronchoscopy is an option in pediatric trauma patients but pediatric-sized bronchoscopes are not available in all facilities and often have poor optical resolution and limited suctioning capabilities. Tracheal intubation with video-laryngoscopy can be used to minimize cervical spine movement. Nasotracheal intubation may be easier using fiberoptic bronchoscopy but is contraindicated in patients with basilar skull fractures. Characteristics of a basilar skull fracture include periorbital (raccoon’s eyes) and mastoid (Battle’s sign) ecchymosis, and cerebrospinal spinal (CSF) drainage from the nose or ear canals.
Additional precautions during airway manipulation are warranted for the pediatric trauma patient with possible head or neck injury. These include avoidance of the Trendelenburg position, and keeping the neck in the neutral position at all times to avoid jugular kinking. In infants less than 6 months of age, the head and cervical spine should be immobilized using a spine board with tape across the infant’s forehead, and blankets or towels around the neck. In older infants and children, the head should be immobilized in the manner described above or by using a small rigid cervical collar. Children older than about 8 years of age require a medium-sized cervical collar. In infants with a prominent occiput, a roll placed under the shoulders provides neutral alignment of the spine and avoids excessive flexion that often occurs in the supine position. These maneuvers will help prevent further cervical spine injury. A rigid collar will effectively prevent cervical spine distraction. A soft collar will permit a five to seven mm distraction of the cervical spine during laryngoscopy; hence it is not routinely recommended.
Primary cardiac arrest is unusual in pediatric trauma unless the child has suffered direct cardiothoracic trauma. Commotio cordis is the term given to the development of ventricular fibrillation after a sudden, intense, nonpenetrating impact on the chest wall over the anatomic location of the left ventricle. Animal studies demonstrate that the timing of this impact in relation to the cardiac cycle (between the QRS complex and the T wave) is crucial for development of this fatal complication.
Pediatric trauma commonly causes shock, which is usually classified as hypovolemic, cardiogenic, neurogenic, or septic. The traumatized, hypovolemic child presents unique physiologic patterns, in that children tend to compensate for blood loss and may retain normal vital signs until 30% to 40% of their blood volume has been lost. In other words, blood pressure may remain normal during clinically significant anemia and hypovolemia. The systolic and diastolic blood pressures may be maintained by vasoconstriction and the pulse pressure may be narrow, rather than wide, as observed during general anesthesia and neurogenic shock (owing to loss of arterial and venous peripheral tone). Hypotension and decreased urine output are more ominous signs of hypovolemic shock; however, they may not occur in children until more than 30% blood volume has been lost. Bradycardia in this setting is life-threatening, as heart rate is a major component of cardiac output in small children.
TBI can be associated with hypotension. The hypertensive component of Cushing’s triad may not be present and cerebral perfusion pressure (CPP; mean arterial pressure minus ICP or CVP, whichever is higher) may not be maintained. The minimum CPP necessary to meet metabolic demands in infants and children has not been established and is largely extrapolated from adults. In children under 6 years of age, cerebral blood flow averages 106 mL per 100 g of brain tissue, and cerebral metabolic rate averages 5.2 mL/min per 100 g of brain tissue. This is in contrast to 58 mL and 3.3 mL per 100 g of brain, respectively, in the adult, and indicates greater cerebral blood flow and metabolic requirements in children. As cerebral autoregulation can also be impaired in children with TBI, systemic blood pressure should be maintained above normal in the absence of ICP monitoring. In injured children, an increased ICP (>20 mm Hg) and decreased CPP (<50 mm Hg) are associated with a poor outcome. Additional risk factors in brain-injured children include Pa o 2 <60 mm Hg, Pa co 2 <25 mmHg or >45 mm Hg, and a systolic blood pressure <90 mm Hg.
Vascular access is an important and often challenging component of pediatric trauma management. A 22-gauge or larger peripheral IV catheter will suffice for induction of general anesthesia but may not be adequate for resuscitation of the child with major trauma. In the latter scenario, at least two large-bore IV catheters are recommended. Saphenous veins are larger than the peripheral veins of distal extremities and thus are commonly used to secure vascular access, either percutaneously or by surgical exposure. In an emergent situation, if peripheral access is unobtainable after three rapid attempts or duration greater than 90 seconds in young children, intraosseous (IO) access should be inserted using any large-bore needle, EZ IO or bone marrow needle. Any nontraumatized long bone may be used. The preferred site is the anteromedial surface of the proximal tibia, 2 cm below and 1 to 2 cm medial to the tibial tuberosity on the flat part of the bone. Other possible sites of insertion include the distal femur 3 cm above the lateral condyle in the midline, and the medial surface of the distal tibia 1 to 2 cm above the medial malleolus. The insertion technique entails the advancement of a large-bore needle until the periosteum of the bone is contacted. With a twisting, boring motion the needle is advanced until it is felt to penetrate into the marrow cavity by a loss of resistance. Negative aspiration of marrow does not preclude use of the intraosseous line provided that infused fluids do not extravasate into the subcutaneous tissues. If marrow is obtained, it may be sent for routine lab investigation and type-and-crossmatch. Any type of crystalloid or colloid solution may be infused into the marrow, and higher than normal infusion pressures may be required. This route of access is temporary until more definitive access can be secured.
It is important to recognize the risk for hyperkalemia in significant blood transfusion in pediatric trauma patients. Because of smaller caliber intravenous catheters, the risk for hemolysis from shearing forces is greater. This can lead to increase in the release of intracellular potassium as the cell membrane is compromised. The age of the O negative blood used must also be considered as both length of storage and irradiation can cause leaking of the intracellular potassium in to the supernatant. In infants and toddlers this potassium load from rapid infusion can quickly cause cardiac compromise and even asystole.
Central venous catheters are acceptable routes of venous access in children. The femoral vein is preferred in children with head or neck injuries; however, it is contraindicated in abdominal trauma with suspected inferior vena cava injury.
In the immediate post injury phase, aggressive fluid resuscitation is critical, as hypoperfusion and hypoxia can induce anaerobic cellular metabolism resulting in the formation of inflammatory mediators that can have significant systemic effects. There are no evidence-based data to unequivocally support either crystalloid or colloid as preferred resuscitative fluid in pediatric trauma. Initial fluid resuscitation in children consists of warmed isotonic crystalloids solution (e.g., Lactated Ringer’s) as a bolus of 20 mL/kg. If there is no physiologic response or there is evidence of persistent volume loss, a second bolus should be administered. The goal of initial crystalloid resuscitation is to rapidly achieve normal age-appropriate hemodynamic values and to restore adequate tissue perfusion. Children with evidence of hemorrhagic shock who fail to respond to initial crystalloid resuscitation efforts should receive a red blood cell transfusion (at least 10 mL/kg) and undergo immediate surgical evaluation for possible operative interventions. Hypotonic dextrose-containing crystalloid solutions should be avoided and hydroxyethyl starch administration is discouraged because it may exacerbate a coexisting coagulopathy when administered in amounts greater than 20 mL/kg. Hypertonic saline lowers intracranial pressure and improves cerebral blood flow in patients with TBI, but further study is ongoing to determine its role in pediatric trauma resuscitation.
In infants, the Glasgow Coma Scale (GCS) has a modified verbal component to allow a developmentally appropriate evaluation. The trend in GCS is more important than the absolute number. Pupillary examination is also an important component of the neurologic assessment. For example, pinpoint pupils indicate pontine herniation and dilated pupils suggest uncal herniation.
In the final phase of the primary survey, the entire body must be examined while avoiding hypothermia. Normothermia is maintained by increasing the room temperature, and using overhead warming lights and forced warm-air blankets.
Become a Clinical Tree membership for Full access and enjoy Unlimited articles
If you are a member. Log in here