Fractures of the Forearm

• 1.
  

  Perform a block of the brachial plexus via the axillary route, see Chapter 5, page 164 for drugs and doses. Ultrasonography improves the success with brachial plexus blocks.

  
  
• 2.
  

  Intravenous blocks are not satisfactory for reduction of fractures. It is more difficult to apply an optimally tight cast to an exsanguinated limb.

Fractures of the Femur

• 1.
  

  A block of the femoral nerve with lidocaine or bupivacaine is easy to perform and relieves pain and muscle spasm as the traction apparatus is being applied.

  
  
• 2.
  

  A catheter may be introduced to the femoral sheath and a continuous femoral nerve block maintained with 0.5% bupivacaine (see continuous femoral block Chapter 5, page 166 ).

General Anesthesia

Every child with a recent fracture must be considered to have a full stomach and a rapid-sequence induction should be performed. Vomiting more frequently occurs during emergence from anesthesia; therefore, the child should be fully awake and in a lateral position before extubation.

Postoperative

• 1.
  

  Pain may be quite severe after routine orthopedic surgery, and should be controlled by either systemic analgesic drugs or regional analgesia or a combination of these:

  
  
  
  
  • a.
    

    Regimens combining acetaminophen and a nonsteroidal antiinflammatory drug (NSAID) are more effective than either drug alone. Acetaminophen (40 mg/kg PR or 15 mg/kg PO) with ketoprofen (2 mg/kg IV) augmented by titrated doses of opioids as required is a suitable basic regimen. Pain should be assessed using standard objective measures (see Chapter 7 ).

    
    
  • b.
    

    Patient-controlled analgesia (PCA) may be appropriate for many children (see Chapter 7 ).

    
    
  • c.
    

    Regional analgesia provided by neuraxial or peripheral nerve block. When possible the latter should be chosen as this is less likely to cause complications. In children, it is customary to perform blocks and insert catheters under general anesthesia. Peripheral nerve blocks and catheter placement should be guided by ultrasonography when possible.

    
    
  • d.
    

    Peripheral nerve blocks may be initiated in the operating room and continued through the PACU to the ward or even to home using a disposable elastomeric infusion pump. The decision to continue this at home will depend upon the home circumstances and the attitude and abilities of the parents. A postoperative infusion of ropivacaine 0.2% at a rate of 0.1 ml/kg/hr has been suggested for continuous peripheral nerve block.

  
  

Surgical Procedures

• 1.
  

  Posterior spinal fusion may be performed using contoured metal rods to stabilize the spine postoperatively until bony fusion occurs. In some children with a flexible spine, the deformity is corrected solely by a posterior fusion. Adjustable rods may be placed in some young children to permit adjustments during growth.

  
  
• 2.
  

  In some, an anterior thoracoabdominal approach may be used to remove the intervertebral discs or a hemivertebra to correct a lateral curve. This may be an open procedure or an endoscopic procedure.

  
  
• 3.
  

  In others, the two procedures are combined: an anterior release followed by a posterior fusion. In this case, surgery is often prolonged, and associated with significant blood loss: a challenge for the anesthesiologist. Anterior release procedures may be carried out endoscopically, in which case the special considerations for endoscopic surgery apply (see Chapter 13, page 339 ).

Special Anesthesia Problems

• 1.
  

  Anesthesia management must take into account the following:

  
  
  
  
  • a.
    

    The severity and cause of the curvature. The more severe the curve, the more pulmonary function is impaired, and greater the likelihood of postoperative pulmonary failure.

    
    

    If the scoliosis is secondary to neuromuscular disease:

    
    
    
    
    • i.
      

      Pulmonary function impairment caused by the mechanical effects of the spinal curvature may be compounded by involvement of respiratory muscles in the disease process. Postoperative respiratory insufficiency is more likely.

      
      
    • ii.
      

      Increased bleeding may be expected. This may be a result of altered vascular responses and platelet adhesion associated with myopathies (e.g., Duchenne muscular dystrophy).

      
      
    • iii.
      

      Cardiomyopathy may occur in adolescents with Duchenne muscular dystrophy.

      
      
    • iv.
      

      Selection of suitable drugs may be limited (i.e., avoid succinylcholine and inhalational anesthetics to prevent rhabdomyolysis if a myopathy is present. Titrate doses of nondepolarizing relaxants if required.

    
    
    
    
  • b.
    

    The degree of respiratory and cardiovascular impairment:

    
    
    
    
    • i.
      

      Surgery may be expected to stabilize the cardiorespiratory effects of the disease but may not improve these.

      
      
    • ii.
      

      A further impairment of pulmonary function must be anticipated in the early postoperative phase and may require respiratory support.

    
    
    
    
  • c.
    

    The type of corrective procedure proposed.

    
    
    
    
    • i.
      

      Posterior fusion only

      
      
    • ii.
      

      Anterior and posterior fusion combined

    
    

  
  
  
  
• 2.
  

  Preoperative assessment must include the following:

  
  
  
  
  • a.
    

    Detailed history and examination for an indication of abilities, stamina, and the presence of any other significant medical conditions.

    
    
  • b.
    

    Routine hematology studies, biochemistry, and cross matching for transfusion.

    
    
  • c.
    

    Pulmonary function studies, including blood gas analysis. (These studies may not be possible in very young children due to lack of cooperation.)

    
    
  • d.
    

    Echocardiogram to assess myocardial function for all children (particularly adolescents) with very severe curves or associated myopathy.

  
  
  
  
• 3.
  

  Be alert for signs of significant respiratory impairment (i.e., tachypnea at rest, severely reduced vital capacity, abnormal blood gas values, inability to cough effectively). Postoperatively, hypoventilation, secretion retention, and atelectasis are likely in response to pain, analgesic drugs, and immobilization that will further compound existing problems.

  
  
• 4.
  

  Severe impairment of respiratory function is not a contraindication to surgery, provided that resources are available for postoperative intensive respiratory care (including controlled ventilation, if necessary). Fixation of the spinal deformity is essential to prevent further deterioration of respiratory function (but usually does not result in significant improvement).

  
  
• 5.
  

  Children with a vital capacity less than 40% of normal may develop major respiratory complications postoperatively and likely require postoperative ventilation.

Special Anesthesia Problems

• 1.
  

  Because the child will be in the prone position, extra care should be taken to secure the tracheal tube and prevent it from becoming dislodged. If preoperative correction of the spinal curvature has been achieved with an exoskeletal apparatus, intubation will probably be difficult; fixation of the head and neck may render adequate direct laryngoscopy impossible, making a fiberoptic technique necessary.

  
  
• 2.
  

  Discuss with the family and the child the need for invasive lines, postoperative ventilation (if likely), the need for ICU, and the potential for an intraoperative wake-up test.

  
  
• 3.
  

  Blood loss may be severe (in excess of 50% of the estimated blood volume [EBV]). Most bleeding originates from the vertebral veins, which become engorged if there is any pressure on the anterior abdomen. Blood loss is also related to the extent of the surgery (length of spine to be fused) and to the surgeon’s speed and expertise. Those with scoliosis secondary to a recognized neuromuscular disorder usually have a larger blood loss than those with idiopathic scoliosis. Alternatives to homologous transfusion should be considered:

  
  
  
  
  • i.
    

    Autologous blood programs are very suitable for preoperative collections in these children.

    
    
  • ii.
    

    Intraoperative acute normovolemic hemodilution may be used cautiously.

    
    

    (These procedures may be optimized by giving oral ferrous sulfate daily beginning 4 weeks before surgery and then administering twice-weekly intramuscular injections of erythropoietin commencing 2 weeks before surgery. The hematocrit (Hct) should not be allowed to exceed 55% preoperatively).

  
  
  
  
  • iii.
    

    The cell saver may be used to salvage erythrocytes from suctioned blood. However, transfusion of large volumes of washed cells may lead to coagulopathy because of dilution of coagulation factors. Fresh-frozen plasma should also be administered if blood loss exceeds one blood volume.

  
  
  
  
• 4.
  

  Spinal cord function is usually monitored during surgery: the use of somatosensory evoked potentials (SSEPs) has been augmented by the addition of motor evoked potentials (MEPs), stimulating the cord above the level of the surgery and recording the electromyogram from the limb.

  
  

  Anesthetic techniques that permit the monitoring of evoked potentials limit inhalational agents to 0.5 MAC, although large doses of opioids may be given. Nitrous oxide decreases the amplitude of evoked potentials and is usually avoided. Propofol/opioid infusions are the mainstay for these anesthetics. Benzodiazepines may be used to induce amnesia. During the testing of MEPs, better results are obtained with minimal neuromuscular blockade (i.e., 2 to 4 twitches on a train of four); specifically, most electrophysiologists permit an intermediate-acting relaxant for tracheal intubation and then no further relaxant during surgery whereas others permit an infusion to maintain a limited degree of neuromuscular blockade. Because of the difficulty in assessing depth of anesthesia during TIVA, a depth of anesthesia monitor is often used.

  
  

  Despite the use of multimodal neurophysiologic monitoring, a wake-up test may still be required (i.e., a surgical misadventure or failure of the monitoring system). Fortunately, the anesthesia technique that provides for neurophysiologic monitoring also allows for a rapid wake-up test should this be required.

  
  

  Every child should be awake at the end of the operation, so that both sensory and motor function can be tested immediately. Any defects should be reported to the surgeon promptly.

  
  
• 5.
  

  Pulmonary function may be severely impaired. The anesthesiologist must check that the present state is optimal and exclude any superimposed acute respiratory disease.

  
  
• 6.
  

  Postoperative pain is considerable; intrathecal opioids administered intraoperatively have been effective for postoperative analgesia and may also facilitate intraoperative BP control and reduce blood loss. Otherwise epidural analgesia or PCA should be planned and these options discussed with the child and family.

  
  
• 7.
  

  Visual loss occurs rarely after spine surgery.

  
  
  
  
  • a.
    

    The most common ocular injury is a corneal abrasion. Far less common is visual loss because of posterior ischemic optic neuropathy (PION) (occurring three times more frequently than anterior AION) or central retinal artery occlusion (CRAO) may rarely occur after spine surgery—especially when performed in the prone position.

    
    
  • b.
    

    Age: occurs rarely in pediatric patients (<18 years).

    
    
  • c.
    

    Factors associated with visual loss because of ION include preoperative anemia, prolonged surgery, intraoperative hypotension, low hematocrit, and major blood loss. CRAO results from direct facial-orbital compression.

    
    
  • d.
    

    A possible but unproven factor in the genesis of postspinal visual loss is excessive crystalloid fluid administration intraoperatively. This is known to increase intraocular pressure (IOP) and periorbital edema.

    
    
  • e.
    

    NB. Visual loss recovers in 44% of those with ION but in 0% of those with CRAO.

    
    

    Procedures that reduce the risk of intraoperative visual loss:

  
  
  
  
• 1.
  

  Assess the child carefully and encourage staged procedures if the proposed operation may be excessively long (>6 hours) or associated with large blood losses (>45% estimated blood volume).

  
  
• 2.
  

  Position carefully:

  
  
  
  
  • a.
    

    Avoid pressure on the eyes—check frequently during surgery and document this in the anesthesia record.

    
    
  • b.
    

    Position the head in a neutral forward position (no neck flexion, extension, or rotation) so that it is level with or above the heart.

  
  
  
  
• 3.
  

  Monitor the hematocrit frequently and avoid markedly reduced levels intraoperatively.

  
  
• 4.
  

  Monitor central venous pressure and administer balanced crystalloid and colloid solutions to maintain an adequate blood volume.

  
  
• 5.
  

  Induced hypotension is an accepted practice for spine surgery but avoid excessively reduced levels from baseline (i.e., within 20% to 25% of baseline mean arterial pressure or a minimum systolic pressure of 80 to 90 mm Hg).

Check the child’s vision immediately upon awakening and seek consultation if there are any defects.