Reducing the extent of facetectomy may decrease morbidity in failed back surgery syndrome

Failed back surgery syndrome (FBSS) is a frequently occurring postoperative complication [1]. Many studies have reported that biomechanical deterioration is the most crucial reason for postoperative complications such as FBSS [2‐6].

Percutaneous transforaminal endoscopic discectomy (PTED) has already been used in the treatment of lumbar disc herniation (LDH) [7, 8]. In PTED, it is necessary to perform facetectomy to expand the neuroforamen. And in patients who suffer from hypertrophy of the facet joints, extensive facetectomy is needed for the decompression of exiting nerve roots. However, such a procedure may be closely associated with postoperative complications (Fig.1).

Aetiologies related to facet joints involved in the pathogenesis of low back pain (LBP) occur in 15–37% of patients after surgery [9, 10], .and injury to the facet joint has been reported to cause a series of postoperative complications [6, 11]. Meanwhile, tears in the posterior annulus is an important trigger for discogenic LBP and LDH, which are two principal causes of FBSS [1, 12, 13]. The facet cartilage plays a key role in protecting the posterior annulus during torsion, and the capsule of the facet joint plays a similar role during flexion [14, 15]. Given that facetectomy does not directly cause injury to the articular surface and the capsule, variation in the stress distribution may result in secondary damage and increase the incidence of annulus tears [1, 12]. Furthermore, rich innervation is a typical histological feature of the facet capsule, and any increase in the mobility of the facet joint will affect the strain on the capsule and stimulate the nociceptors, thereby leading to LBP [16, 17, 18]. In addition, surgical intervention will change the force applied on the facet cartilage, leading to possible degeneration [19, 20]. Besides, the facet joint is important in the maintenance of spine stability [16, 21], and iatrogenic instability is common in patients suffering from FBSS [22, 23]. Taken together, we hypothesise that facetectomy and extensive facetectomy increase the risk of FBSS. However, this conjecture lacks the theoretical basis of biomechanics.

As a mechanical simulation research method, finite element analysis has been widely used in the investigation of postoperative biomechanical variations to infer the risk of postoperative complications [3‐5, 24]. To clarify our hypothesis and provide theoretical guidance for the PTED application, we reconstructed a lumbosacral finite element model (FEM) to determine whether varying extents of facetectomy will affect its biomechanical indexes. To the best of our knowledge, published literatures have not adequately clarified this issue.

FBSS is a significant postoperative complication with typical symptoms of persistent LBP and has been reported to be an important predictor of postoperative poor outcome [1, 22, 36]. Considering that biomechanical deterioration is the key trigger of postoperative complications [2, 4‐6], the investigation of the biomechanical conditions of FBSS is vital to reduce its risk.

Compared to traditional open discectomy, PTED may reduce the risk of FBSS. Previously studies reported that open posterior lumbar surgery will lead to the damage and atrophy of paraspinal muscles, which have been indicated as a significant cause of FBSS [36‐38]. Meanwhile, the weakness of paraspinal muscle will result in lumbar instability, a significant trigger of FBSS [1, 39]. As a minimally invasive surgical method, PTED will not damage the paraspinal muscles and the conclusion that PTED reduces the risk of FBSS seems credible [39, 40]. However, clinical studies have shown that minimally invasive surgical methods do not significantly decrease morbidity associated with postoperative complications compared to open surgery, and the damage to osteoligamentous structures during the microdiscectomy procedure can also result in biomechanical deterioration [5, 37, 41]. Thus, the conclusion that minimally invasive spine surgery could decrease the risk of FBSS may be unreliable. Given these contradictory conclusions, it is critical to pay attention on the relationship between PTED and FBSS from a biomechanical point of view.

Facetectomy is needed in PTED for accessing the intraspinal region. For patients who suffer from hypertrophy of the facet joints, larger extents of facetectomy are important for exiting nerve root decompression. However, such procedure may be closely associated with postoperative complications [6, 9, 11, 42].

To identify the effect of various extents of facetectomy on morbidity during FBSS, an issue that has not been clearly studied, a three-dimensional lumbosacral model was reconstructed and validated to assess changes in biomechanical indexes that are directly associated with FBSS, namely, maximum shear stress on the annulus in the L5 segment, von Mises stress at the facet cartilage, maximum principle capsular strain on the capsule and the total deformation of current models.

Causes of LBP that involve facet joints have been recognised as risk factors for more than half century [19, 43], and changes in the force applied on the facet surface and to capsular strain are closely associated with facet joint diseases [18, 23, 44]. In the current study, we have discovered that von Mises stress on the facet cartilage increases with larger extents of facetectomy, which may accentuate degeneration of the facet joints [45, 46], while an increase in the maximum principal strain on the capsule can result in local neuropathic pain [16, 17]. Thus, our results indicate that larger extents of facetectomy may lead to facet joint diseases and LBP, especially in the contralateral side and when the body bends in the direction of the operated side.

Notably, we show that the stress on the facet cartilage and the strain on the capsule were the highest in the L5–S1 segment, and such phenomenon may occur when biomechanical indexes is applied close to a fixed surface and specific data for this segment may be less reliable. Nonetheless, as this is a qualitative rather than a quantitative study, we believe that the results are credible.

An increase in the maximum shear stress on the annulus is an important factor that results in radical annulus tears, which may lead to discogenic LBP and LDH, two key triggers of FBSS [1, 12, 25, 26, 36]. In this study, the maximum shear stress on the annulus obviously increased during flexion and axial rotation with larger extents of facetectomy, and stress concentration can be observed at the posterior annulus (Fig. 8). In addition, the variation trends of biomechanical indexes in the annulus and the facets are same. Considering that facet cartilages and capsules will protect the posterior annulus during torsion and flexion, respectively [15], the risk of annulus tears may be increased with larger extents of facetectomy.

Facet joints are crucial for spine stabilisation, and spine instability is a common cause of FBSS [21, 22, 47, 48]. Postoperative hypermobility will accelerate disc degeneration and result in FBSS [49, 50]. The increase in the total deformation of the current models is a good indicator of lumbar instability, and we observed this phenomenon with larger extents of facetectomy under all loading conditions.

Finally, note that some patients suffer from severe postoperative LBP even if typical changes in imaging are absent [1, 51]. In such patients, we hypothesise that postoperative deterioration of biomechanical indexes leads to LBP before an organic change could be detected by imaging. Importantly, this phenomenon is further supported by the necessity to avoid, or at least reduce, biomechanical deterioration by surgical intervention. In summary, the results from this study suggest that less facetectomy is better in PTED on the premise of achieving the goal surgery, i.e. to reduce morbidity due to FBSS.

The current conclusion must be accepted on the premise of the awareness of the following limitations. LDH patients who underwent PTED present with varying grades of disc degeneration, facet degeneration and osteoporosis. In addition, this study was conducted under a single load condition rather than different load conditions. These factors influence the change in biomechanical conditions of the spine after facetectomy and can thereby affect risk in FBSS [13, 17, 25, 44]. However, these factors were not incorporated into the present study, and we expect to analyse their effects in future studies.

Less facetectomy is better in PTED for which may reduce the risk of biomechanical deterioration and consequently FBSS.