Pedicle Subtraction Osteotomy


Introduction

Lumbar pedicle subtraction osteotomy (PSO) was first described by Thomasen in 1985 for the surgical treatment of 11 patients with severe disabling kyphosis secondary to ankylosing spondylitis. In this series, Thomasen performed posterior bony wedge resection (i.e., removal of the spinous process, neural arch, and posterior part of the index vertebral body) and subsequent osteotomy closure at the L2 vertebra to achieve the desired kyphosis correction. Since then, spine surgeons have used PSOs for deformity correction in pathologies other than ankylosing spondylitis such as congenital, posttraumatic, postinfectious, neoplastic, degenerative, idiopathic, or iatrogenic deformities. In this chapter, we review PSO in the context of revision lumbar spine surgery. We highlight iatrogenic flatback syndrome as a common cause of fixed spinal deformities that may require a lumbar PSO. We provide revision spine surgery case examples that illustrate lumbar PSO correction of iatrogenic flatback deformity resulting from pseudarthrosis with a loss of sagittal correction ( Fig. 18.1 ) and from prior distraction instrumentation ( Fig. 18.2 ).

Fig. 18.1, This case illustrates revision surgery with lumbar extended pedicle subtraction osteotomy (PSO) for a patient with iatrogenic flatback deformity from pseudarthrosis and loss of sagittal correction. The patient was a 76-year-old male with multiple prior spine surgeries, most recently L3–S1 posterior instrumentation and fusion, who presented with kyphoscoliosis, intractable back and leg pain, and difficulty with ambulation. Preoperative lateral standing scoliosis films (A) and postoperative standing scoliosis films (B) are shown. Surgery involved T10 to ilium posterior instrumented arthrodesis with an L3 extended PSO and L2–L3 transforaminal lumbar interbody fusion. Vertical lines demonstrated the patient’s improved sagittal vertical axis (SVA). Lumbar lordosis is measured as the Cobb angle from the inferior end-plate of T12 to the sacral end-plate. Markings for pelvic tilt (PT) are also indicated in panels (A) and (B). Preoperative measurements were SVA +19 cm, lumbar lordosis (LL) 8 degrees, and PT 24 degrees. Postoperative measurements were SVA +11 cm, LL 48 degrees, and PT 25 degrees.

Fig. 18.2, This case illustrates revision surgery with lumbar extended pedicle subtraction osteotomy (PSO) for a patient with flatback deformity from prior distraction instrumentation. The patient was a 59-year-old female with a history of idiopathic scoliosis and Harrington rod fusion that presented with back and leg pain, difficulty standing erect, and worsening posture. Preoperative lateral standing scoliosis films (A) and postoperative lateral standing scoliosis films (B) are shown. Surgery involved T10 to ilium posterior arthrodesis with an L4 extended PSO and L4–L5 and L5–S1 transforaminal interbody fusions. Lumbar lordosis (LL) is measured from the inferior end-plate of T12 to the sacral end-plate. Markings for pelvic tilt (PT) are indicated in panels A and B. Preoperative measurements were LL 4 degrees and PT 52 degrees. Postoperative measurements were LL 56 degrees and PT 31 degrees. The patient’s global sagittal balance was improved, but C7 plumb line not shown as a result of poor visualization of cervicothoracic junction.

Regardless of the specific etiology, rigid or fixed spinal deformities can be challenging to treat surgically and a PSO may be indicated. Briefly, a lumbar PSO involves performing a three-column osteotomy with transpedicular bony wedge resections extending from the posterior elements along both pedicles and into the vertebral body. The anterior vertebral cortex is left intact so that it can act as a hinge during subsequent closure of the wedge osteotomy defect. A considerable amount of surface area is available for osseous union after wedge closure brings the bony surfaces of the anterior, middle, and posterior columns in contact. Additionally, osteotomy wedge closure can shorten the posterior column without changing the length of the anterior column, which optimizes healing potential without stretching major abdominal vessels and viscera. After closure of the posterior wedge, two nerve roots exit on each side at the vertebral level of the osteotomy through the newly formed artificial neural foramina.

The traditional or classic PSO is categorized as a Schwab grade 3 osteotomy ( Table 18.1 ). A lumbar PSO allows for approximately 30 degrees of correction across the osteotomy level with a similar magnitude of corrective improvement in overall lumbar lordosis (LL); this can also result in up to 10 cm of posterior trunk translation (i.e., reduce global sagittal malalignment). Variations of the traditional PSO include the asymmetric PSO for biplanar correction (coronal as well as sagittal correction), as well as the extended PSO (Schwab grade 4 osteotomy) which allows more alignment correction by extending the wedge resection into the superior adjacent disc. Placement of an interbody cage at the osteotomy site may allow further correction when an extended PSO is performed. When performed appropriately, a lumbar PSO and its variants are powerful techniques that allow significant restoration of LL and global alignment in patients with severe fixed deformities. In addition, treatment of any potential underlying pseudarthrosis, which is often problematic during revision lumbar cases (e.g., iatrogenic flatback), can translate into improved pain and health-related quality of life (HRQL) scores in adequately aligned patients. Despite these positive outcomes, there are high complication risks associated with a PSO. Recent multicenter studies by the International Spine Study Group (ISSG) have advanced our understanding of the complication profile associated with this powerful but potentially morbid technique. After describing relevant patient indications, operative planning pearls, and the appropriate technique for a lumbar PSO, we conclude this chapter with a brief overview of these associated complications and emerging strategies to limit their occurrence.

Table 18.1
Schwab Classification of Spinal Osteotomies
Grade of Resection Brief Description of Osteotomy
Grade 1: partial facet joint resection Resection of inferior facet and joint capsule
Grade 2: complete facet joint resection Resection of inferior and superior facets of an articulation
Grade 3: pedicle and partial body resection
  • Resection of posterior elements with pedicles

  • Partial wedge resection of posterior vertebra

Grade 4: pedicle, partial body and disc resection
  • Resection of posterior elements with pedicles

  • Wider wedge resection of posterior vertebra to remove end-plate and portion of adjacent disc

Grade 5: complete vertebra and discs resection Complete resection of vertebral level and both adjacent discs
Grade 6: multiple adjacent vertebrae and discs resection Resection of several adjacent vertebral levels

Patient Selection and Operative Indications

In general, a lumbar PSO is indicated for revision spine surgery if significant correction is needed for a severe fixed spinal deformity. Patients with severe fixed spinal deformities causing positive sagittal imbalance (i.e., pitched forward with head anterior to pelvis) may present with early fatigue and disability from difficulty maintaining an erect posture and horizontal gaze. Even mildly positive sagittal imbalance can be detrimental to HRQL, and the severity of clinical symptoms increases linearly with progressive sagittal imbalance. The debilitating impact on health from adult spinal deformity can exceed the disability of more recognized chronic diseases. For example, patients with lumbar scoliosis combined with severe positive sagittal imbalance demonstrated worse HRQL scores than patients with limited use of their arms and legs. In addition to an observable “forward pitch” from positive sagittal imbalance, clinicians should be also be aware of potential compensatory mechanisms that these patients often use to partially mitigate global imbalance (e.g., knee flexion, hip extension, pelvic retroversion, increased cervical lordosis). Compensatory pelvic retroversion for sagittal spinal malalignment is measured radiographically as pelvic tilt (PT), and high values of this variable correlate with worse HRQL. Finally, patients with severe fixed deformities may also complain of intractable back pain exacerbated by ambulation or upright posture, and partly relieved with rest or recumbency.

For select patients with rigid deformities at locations where previous anterior spinal surgery was performed, a PSO remains an attractive treatment option if a high magnitude of correction is needed. Many studies have assessed lumbar PSOs with focus on sagittal plane correction, and have suggested the following potential indications: fixed deformities with sharp or angular kyphosis and sagittal vertical axis (SVA) greater than 8 cm, high spinopelvic mismatch requiring more than 30 degrees restoration of LL but insufficient anterior curve flexibility for effective multilevel posterior column osteotomies (PCO; Schwab grade 2), and severe deformities of high enough magnitude which exceed the corrective capacity of multilevel PCOs. Potential PSO patients may have a history of prior fusion surgery, degenerative or inflammatory disease resulting in spontaneous fusion with sharp angular kyphosis, ankylosing spondylitis with thoracolumbar kyphosis, posttraumatic vertebral fractures, and/or progressive untreated idiopathic scoliosis. Because this review series focuses on revision lumbar spine surgery, we highlight iatrogenic flatback syndrome as a common cause of fixed deformity that may warrant a lumbar PSO. Significant contributing factors to iatrogenic flatback deformity have been identified and include distraction instrumentation in the lower lumbar spine or sacrum (e.g., Harrington distraction instrumentation), pseudarthrosis resulting in loss of sagittal correction, improper patient positioning causing reduced LL during transpedicular instrumentation, and segmental distraction for “foraminal enlargement” or during interbody device or graft placement. We provide revision case examples illustrating PSO correction of iatrogenic flatback deformity (see Figs. 18.1 and 18.2 ). Of note, in addition to being indicated for patients with fixed positive sagittal malalignments, a PSO may also be indicated for patients with a pelvic incidence (PI) to LL mismatch who remain globally sagittally aligned. In a study from Smith et al. and the ISSG, this form of compensated flatback syndrome was shown to be a significant source of pain and disability and demonstrated similar HRQL improvement after surgical correction compared with deformity correction surgery on patients with positive sagittal malalignment.

The magnitude of correction necessary for achieving optimal outcomes varies with each deformity patient, and factors such as preoperative health status, medical comorbidities, and baseline global or regional alignment are important surgical considerations. Surgeons should also consider preoperative segmental curve flexibility and the compensatory ability of postoperative adjacent unfused segments. Curve flexibility can influence surgical planning when considering the approach (anterior, posterior, lateral), number of spinal levels to fuse, and the type of corrective osteotomy. Deformities with more than approximately 30% correction on dynamic radiographs are generally considered more flexible and less likely to require a three-column osteotomy such as a PSO. Curves with less than 30% correction on dynamic imaging, however, may generally be considered fixed or rigid and are more likely to require a three-column osteotomy.

Operative Planning

There are many factors to consider when planning a PSO for revision lumbar spine surgery. First, the amount of necessary correction should be considered. This includes both focal correction at the osteotomy wedge and the ensuing regional and global alignment changes that it can produce. A subset of patients with fixed sagittal deformity may have positive sagittal imbalance indicated by increased SVA (horizontal offset from the center of the C7 vertebral plumb line to the posterior-superior border of the S1 vertebra on standing 36-inch long-cassette radiograph). Although definitive ranges for normal versus pathological SVA are debated, the Scoliosis Research Society and Schwab et al. classified SVA as follows: normal SVA (<4 cm), moderately increased SVA (4–9.5 cm), and severe positive SVA (>9.5 cm). Studies have demonstrated positive SVA and progressive sagittal imbalance correlate with worse pain and disability. Therefore restoration of more normal sagittal balance is critically important in reconstructive spinal surgery. Like SVA, T1-spinopelvic inclination (T1-SPI, the angle between the vertical plumb line and the line drawn from the vertebral body center of T1 and the center of the femoral heads) is another global spinopelvic parameter that refers to truncal inclination, but has been relatively underused despite having strong correlation to HRQL outcome measures.

In addition to SVA and T1-SPI, other studies have emphasized the importance of pelvic parameters, including PI and PT, in the assessment of sagittal spinal alignment. Abnormal pelvic retroversion (increased PT) may help mitigate positive sagittal malalignment, but can adversely affect ambulation and increase energy utilization, which may negatively impact HRQL. Based on LL and these spinopelvic parameters, Schwab et al. provided evidence to suggest potential threshold values for predicting severe disability (Oswestry Disability Index [ODI] >40) that could help guide clinical assessments for therapeutic decision-making. Determined threshold values for severe disability included: SVA more than 4.7 cm, PT more than 22 degrees, and PI-LL mismatch greater than 11 degrees. Therefore, when planning a PSO for revision lumbar spine surgery, achieving more harmony among spinopelvic parameters with low SVA and PT is a critical goal. Reasonable postoperative target alignment includes the following: SVA greater than 5 cm, PT greater than 25 degrees, and LL proportional to the PI (e.g., PI-LL mismatch <10 degrees). However, it is important to recognize that these realignment target values should be adjusted for age, with older patients having less stringent alignment targets.

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