Thoracic Approach to Spine Procedures

David M. Shapiro, Baron Lonner, Lily Eaker, Jonathan Gal

Abstract

The anterior approach to spine surgery is considered safe and has the potential for improving value in patient care. The unique advantages of the procedure (compared with posterior surgical instrumentation and fusion), particularly when used for correction of scoliosis, include avoiding disruption of spinal musculature for surgical exposure and reducing the number of fused vertebrae (thereby preserving postoperative spinal flexibility). In addition, there is evidence to suggest that there is a reduction in the risk of infection or need for blood transfusion in the perioperative period.

Conducting a safe and appropriate anesthetic for this type of surgical approach requires careful preoperative planning with both the surgical and neurophysiology teams. Each anesthetic plan should involve appropriate patient selection in the preoperative period, an arterial line placement (for hemodynamic monitoring and blood gases), as well as appropriate venous access, intraoperative one-lung ventilation (OLV) to optimize the surgical field, and postoperative multimodal analgesia to help maximize early physical therapy with the goal of maintaining spine mobility. Intraoperatively, communication amongst teams and an intimate knowledge of physiology and complications of intrathoracic surgery and OLV remains essential to ensuring patient safety and a satisfactory surgical result. Although relatively few surgeons in the United States perform an anterior approach to thoracic spine surgery, it is gaining widespread favor as maintaining patient safety and outcome data continue to demonstrate that the approach offers unique advantages to the posterior approach.

Keywords

thoracic; anesthesia; scoliosis; multimodal analgesia; thorascopic

Introduction

Thoracic spine surgery can be performed from anterior, posterior, or combined approaches. Selection of the appropriate surgical approach depends on the optimal surgical procedure for the patient, the complexity of intervention to be performed, the location and extent of the pathology, and the surgeon’s comfort with each technique. Thoracic spine surgery has historically been performed from a posterior approach. Recently, the anterior approach has come in and out of favor for its ability to decrease fusion levels and avoid the posterior musculature of the spine versus its higher reoperation rates and surgical complications. There has been a resurgence in the performance of anterior surgery for various pathologies, including the novel anterior vertebral body tethering (AVBT) nonfusion scoliosis correction or anterior scoliosis correction, specifically for adolescent idiopathic scoliosis (AIS). The anterior approach is predominantly used for the correction of scoliosis but is also used in the management of thoracic disc disease, vertebral fractures, malignancy (70% of spine metastases occur in the thoracic region),¹ and vertebral infections.²

U.S. Food and Drug Administration (FDA)-approved indications for AVBT include skeletally immature patients with a scoliosis angle between 30 and 65 degrees, although slight deviations from these indications is common. Patients diagnosed with AIS typically suffer from diminished health, poor quality of life, body image disturbance, and other psychosocial effects.³^,⁴ In addition, asymptomatic adolescent patients who decline early surgical intervention undergo the natural history of the disease, which may result in progressive deformity, pain, and disability. Postponing the surgical intervention in the adult often requires a greater number of levels fused and is associated with higher complication rates, longer operative times, and greater blood loss than their adolescent counterparts.⁵

To plan and perform a safe and appropriate anesthetic for anterior thoracic spine surgery, the anesthesiologist must discuss the case with the surgical and neuromonitoring teams, as well as the patient and/or guardian. The anterior approach to thoracic spine surgery has special perioperative important considerations for the anesthesiologist, including utilization of one-lung ventilation (OLV), blood conservation strategies, intraoperative neuromonitoring, and a multimodal approach to managing postoperative pain. This chapter will focus on management of scoliosis, as that is the most common indication for the anterior approach to thoracic spine surgery.

Case Presentation

The patient was a 12-year-old, 68-inch, 45-kg girl with double major idiopathic adolescent scoliosis defined as a typical double “S” shaped spinal curvature (Fig. 46.1). She did not experience pain but had progressive worsening of her spine curvatures and significant spinal deformity with expected continued worsening of the curvatures. Because of the natural history of curvatures of the size seen in this patient that will later result in back pain, as well as the potential impact on pulmonary function, surgery was recommended.

• Fig. 46.1 Radiographs of the 12-year-old female patient with double major idiopathic scoliosis treated with a right thoracic and left thoracolumbar anterior spinal tether. The scoliosis curvatures are depicted in red.

Preoperatively, the patient was seen by her pediatrician and found to be in her usual state of good health. Laboratory findings, including a basic metabolic panel, a complete blood count, and coagulation studies were all within normal limits.

The patient and her family also met with the surgeon and extensively discussed the options for treatment. Surgical options included the standard of care posterior instrumented fusion versus the more novel AVBT procedure via a thoracic approach. It was noted that the AVBT is growth and motion sparing. The surgeon had a detailed discussion with the family regarding the risks and benefits of the AVBT procedure compared with the standard of care spinal fusion. This technique places a compressive force over the convex side of the spine (slowing down growth) to permit the concave side of the spine to relatively grow more and create a straighter spine. The goals of these procedures, as opposed to spine fusion, are to correct the spinal deformity and maintain the spine motion, particularly in the low back.

The surgeon explained that because the patient had a complex double major scoliosis, she required surgical correction of the deformity through both right-sided and left-sided incisions. The planned surgical approach on the right side consisted of a 5-cm minithoracotomy between the seventh and eighth ribs at the mid-axillary line, a second mid-axillary line portal four intercostal spaces more cephalad, and an anterior axillary line portal placed in the eighth or ninth intercostal space for introduction of the scope (Fig. 46.2). After completion of the right-sided thoracic tether from T5 through T10, the surgical team would correct the left-sided curvature. The surgical team would then perform a left-sided correction from T10 to L3 through a limited thoracotomy between the 10th and 11th ribs and a portal proximal to the thoracotomy incision in the mid-axillary line to permit access to the distal thoracic spine (Fig. 46.3).

• Fig. 46.2 Portals used for thoracic anterior vertebral body tethering with the patient in the left lateral decubitus position. Left side of image is cephalad.

• Fig. 46.3 Incisions for the thoracolumbar approach with the patient in the right lateral decubitus position.

The surgeon instructed the patient to take gabapentin 100 mg 3 times a day for 1 week before surgery.

Case Management

The patient presented for surgery in her usual state of good health. A confirmatory type and screen was drawn and 2 units of packed red blood cells were placed on hold in the blood bank. The anesthesiologist assessed the patient, discussed the anesthetic plan, including its risks, benefits, and alternatives, and answered all questions of the patient and her family. An intravenous catheter was then placed.

Before induction of anesthesia, the patient was administered three nonopioid analgesics to mitigate postoperative pain: gabapentin 300 mg by mouth (PO), acetaminophen 650 mg PO, and celecoxib 200 mg PO. She then received midazolam 4 mg for anxiolysis and anterograde amnesia and was transported to the operating room. The perioperative team assisted her into a sitting position in which a thoracic epidural was placed via a paramedian approach one to two rib spaces above the planned site of the postoperative chest tubes and above the major scoliotic curvature for ease of placement, at the T6–T7 interspace.

The patient was then positioned supine on a Jackson table with a flat-bed insert. After placement of standard American Society of Anesthesiologists monitors and preoxygenation, general anesthesia was induced with weight-appropriate dosages of lidocaine (1.5 mg/kg), propofol (2 mg/kg), fentanyl (4 mcg/kg), ketamine (0.5 mg/kg), and succinylcholine (2 mg/kg). The patient was orally intubated with a 7.5 mm single-lumen standard cuffed endotracheal tube (ETT). After successful endotracheal intubation, the tube was secured using adhesive and umbilical tape.

Total intravenous anesthesia (TIVA) was initiated for maintenance of anesthesia. This consisted of propofol (100–150 mcg/kg/min), fentanyl (1–3 mcg/kg/h), dexmedetomidine (0.2 mcg/kg/h) and a ketamine infusion (for a total of 1.5–2.5 mg/kg during the case). A phenylephrine infusion (0.05–0.5 mcg/kg/min) was needed intermittently to maintain mean arterial pressure over 85 mm Hg at critical portions of the procedure to optimize spinal cord perfusion, particularly during placement of implants and vertebral correction. A total of 8.83 mg of phenylephrine was used during the case.

A 9-Fr bronchial blocker (BB) was placed in the lumen of the right mainstem bronchus with the aid of a 4.0 mm flexible fiberoptic bronchoscope in anticipation of the right-sided procedure. A second large-bore 18-gauge intravenous (IV) line was placed for the administration of intravenous anesthetics, fluids, and potential blood products. In addition, a radial arterial line was secured for close hemodynamic monitoring and laboratory assessment of oxygenation, hematocrit, and serum electrolytes. A neuromonitoring team placed electrodes on the patient for monitoring somatosensory evoked potentials (SSEPs), transcranial motor evoked potentials (TcMEPs), and electromyography (EMG) to continually assess spinal cord integrity for the duration of the case. A bite block was placed to protect the tongue from injury during the performance of TcMEPs.

The patient was positioned in the left lateral decubitus position and an axillary roll was placed to relieve pressure on the neurovascular plexus of the dependent arm. All pressure points on the upper and lower extremities were well-padded. Care was taken to ensure that there was no excessive pressure on the eyes and ears. A final positioning check was performed before surgical preparation and draping.

Dexamethasone 10 mg IV was administered for antiinflammatory and antiemetic effects. Cefazolin and gentamicin were dosed by weight for antimicrobial prophylaxis.

A preincisional bronchoscopy was performed to ensure proper placement of the BB in the right mainstem bronchus. Subsequently, the cuff on the BB was inflated, initiating OLV, and the lumen of the BB was placed on gentle suction to facilitate lung deflation to optimize surgical exposure. To improve oxygenation during the early stages of OLV, the patient was placed on an fraction of inspired oxygen (FiO2) of 100% for 15 to 30 minutes and then maintained on an FiO2 of 80% to 100% for the duration of the procedure with a target oxygen saturation (SpO2) over 94%.

Vertebral body screws were placed and connected with a tethering cable to correct the scoliosis. Next, the incision was closed and a chest tube was placed in the seventh intercostal space. The BB was then deflated to reinitiate two-lung ventilation. Next, the patient was returned to the supine position and the placement of the BB in the left mainstem bronchus was facilitated by the use of fiberotic bronchoscopy. The patient was placed in the right lateral decubitus position for left-sided scoliosis correction. Once completed, a chest tube was inserted in the 10th intercostal space on the left side.

Approximately 1 hour prior to the conclusion of the procedure, the dexmedetomidine, fentanyl, and ketamine infusions were discontinued. After closure of the diaphragm and chest wall, the propofol infusion was slowly titrated down to allow for timely anesthesia emergence and extubation. At the end of the surgery, the patient was returned to the supine position and extubated. Total operative time was 300 minutes and estimated blood loss was 500 mL. In the operating room, a neurologic examination was performed by the surgical team to assess spinal cord and nerve root integrity. Subsequently, the patient was transferred to the pediatric intensive care unit (PICU) for postoperative care and observation. Note that a pediatric stepdown unit may also be appropriate depending on the institution.

Once in the PICU, the patient-controlled epidural analgesia (PCEA) infusion of hydromorphone (5 mcg/mL) at a rate of 20 mcg/h with three demand doses of 10 mcg available per hour was initiated. In addition to PCEA, the postoperative pain regimen consisted of acetaminophen (15 mg/kg IV every 6 hours; maximum 1 g/dose), ketorolac (0.5 mg/kg IV every 6 hours for 3 days) and gabapentin (100 mg PO three times daily). The acute pain service assessed the patient’s pain regimen each morning and further tailored it as appropriate. Hydromorphone (0.3–0.6 mg IV q2h) for pain and diazepam (2–4 mg IV q8h) for spinal muscle spasms were administered as needed. The chest tubes were removed on postoperative day 3, after which the epidural infusion was stopped, and the catheter was removed. Once the patient’s pain was well controlled on oral medications and she was able to ambulate, she was discharged home from the hospital.

The postoperative, postdischarge analgesic regimen consisted of several medications. The patient was prescribed a 10-day supply of oxycodone 5 mg PO every 4 hours (plus additional tablets for breakthrough pain as needed), diazepam 2 mg PO every 8 hours as needed for muscle spasms, ibuprofen 400 mg PO three times daily, acetaminophen 15 mg/kg PO every 6 hours, and gabapentin 100 mg PO three times daily. The patient was instructed to take polyethylene glycol 17 g PO twice a day and docusate 100 mg PO three times daily to mitigate the side effect of constipation. As an aside, note that if the patient does not tolerate oxycodone because of nausea or it does not provide adequate analgesia, the surgical team can provide an equivalent dosage of oral morphine or hydromorphone.

Risks, Benefits, and Alternatives

Preoperative Management for Postoperative Pain

Pain management for this procedure begins before the patient’s arrival on the day of surgery. There is evidence that administration of preoperative oral nonopioid medications, including gabapentin,^6–10 pregabalin,¹¹^,¹² celecoxib,⁷^,¹⁰^,¹¹ and acetaminophen¹³ improve postoperative pain scores and reduce the incidence of chronic incisional pain and postoperative opioid consumption, thereby decreasing opioid-related side effects, such as nausea, constipation, and sedation. Reducing these side effects may help improve patient satisfaction and maximize postoperative early ambulation and physical rehabilitation in patients undergoing spine surgery. Although there is a paucity of data regarding the efficacy of these agents when used specifically for anterior spine surgery, given their wide therapeutic index and minimal side effects, the benefits outweigh the risks.

Thus patients are placed on a preemptive pain regimen of gabapentin (100 mg orally, taken three times daily) 1 week before the day of surgery. On the day of surgery, the patient is given an oral multimodal nonopioid medication regimen of gabapentin 300 mg, acetaminophen 15 mg/kg, and celecoxib 200 mg. For patients over 70 kg, dosages increase to gabapentin 600 mg, acetaminophen 1000 mg, and celecoxib 400 mg.

Epidural Placement and Management

The epidural catheter is typically placed before the induction of general anesthesia. This offers the advantage of patient feedback during placement and immediate postprocedure neurologic assessment. In addition, placement is generally easier with the patient in a sitting position, whereas placement in the lateral decubitus position with the patient under general anesthesia is not recommended and is rarely performed. In cases where a young patient is unable to tolerate the awake procedure even after the administration of mild to moderate sedation, it may be reasonable to perform the procedure after the induction of general anesthesia, so long as the perceived benefits outweigh the risks. There may be an increased risk of inadvertent dural puncture or injury during placement. Proper patient positioning and epidural placement may be more challenging under general anesthesia in the lateral decubitus position, particularly in patients with a significant scoliotic curvature. Therefore in some cases it may be optimal to place the epidural catheter after the procedure and before extubation, when the spine scoliosis anatomy is corrected and straightened.

The operative side (if unilateral) and vertebral levels, targeted for correction, should dictate the approach to placement and location of the thoracic epidural for postoperative analgesia. If placing a thoracic epidural using a paramedian approach, it is prudent to perform the procedure on the ipsilateral side as the surgical exposure so as to mitigate the consequences of a pneumothorax, a rare complication of placement,¹⁴ and to place the catheter above the site of the planned chest tubes for maximal postoperative analgesic benefit.

Postoperative epidural infusion of hydromorphone provides analgesia for the thoracotomy incisions and chest tubes that remain in place. An epidural combination of hydromorphone and a local anesthetic, such as bupivacaine, provides superior analgesia and minimizes systemic side effects of either medication by allowing for a reduced dosage of both. However, especially in spine surgery, local anesthetics may cause numbness and weakness that can confound the results of a neurologic examination and make it difficult to diagnose potential surgical complications. For this reason, an opioid-only epidural infusion is recommended.

Endotracheal Tube Choice

ETT choice and size depends on patient size, extent and laterality of surgical procedure, provider comfort and preference, as well as a careful weighing of the advantages and disadvantages of each type of tube (Table 46.1). With the exception of the youngest and smallest patients undergoing surgical correction, most patients can accommodate a 7.5-mm standard cuffed ETT, through which a 9-Fr BB may be placed on the operative side to allow for OLV.¹⁵ Should intubation prove difficult with this size ETT, a 7.0-mm ETT, although tighter fitting with the BB and fiberoptic bronchoscope (for proper placement and visualization), is sufficient. There are rare occasions in which a double-lumen tube (DLT) is favored over a BB. These include: (1) patients who are appropriate size to accommodate a DLT (≥35 Fr), (2) those whose scoliosis curve apex is mid-thoracic (T8‒T9), and (3) patients with a severe Cobb angle, the latter two making manipulation of the BB more challenging.¹⁵ There are also 32 Fr and 28 Fr DLT that can be used for adolescents. However, they are infrequently used because they would not accommodate the standard 4.0-mm fiberoptic bronchoscope.

Table 46.1

Endotracheal Tube Choice
Lung Isolation Technique	Advantages	Disadvantages
Bronchial blockers (BB)	1. Easier placement in children and known difficult airways 2. Ability to ventilate through standard ETT during placement 3. Size selection rarely an issue 4. Capability of selectively isolating lung lobes (if warranted) 5. Capacity to safely provide postoperative two lung ventilation after BB removal	1. Increased time necessary for placement and alternating side of OLV 2. Higher incidence of BB dislodgement during patient positioning and surgical manipulation 3. Requires presence of fiberoptic bronchoscope for duration of case 4. Difficulty isolating right upper lobe because of early takeoff from right mainstem bronchus 5. Inability to provide CPAP or perform bronchoscopy on isolated lung
Double-lumen tube	1. Faster initial placement 2. Reduced risk of dislodgement, repositioning less frequent 3. CPAP easily administered to isolated lung 4. Ability to perform bronchoscopy on isolated lung 5. Alternating side of lung isolation is easy	1. Not optimal for postoperative mechanical ventilation 2. Increased incidence of laryngeal and/or bronchial trauma and hoarseness ¹⁶ 3. Size selection more challenging 4. Difficult placement in patients with challenging airways