Foraminal height measurement techniques
Introduction
Surgical interbody fusion has been found to be an effective method of treatment for debilitating back pain (1-3). Interbody fusion has the potential advantage of removing the disc as a source of pain (4). Many methods of fusion are available to contemporary spine surgeons, of which one of the options is the anterior lumbar interbody fusion (ALIF) technique. A primary consideration of such a fusion technique is the restoration of normal anatomy, including foraminal area, disc height, lumbar lordosis and sagittal balance (5,6). Failure to restore these parameters can result in permanent loss of lordosis and sagittal balance, leading to poorer long-term outcomes (7,8).
One of the proposed advantages of ALIF is restoration of disc height and hence an indirect foraminal height restoration. While this proposed advantage is often quoted in the literature, there are few robust studies demonstrating restoration of foraminal volume. Techniques in prior studies used to quantify foraminal dimensions prior and after fusion operations include analysis from plain radiographs, computed tomography (CT) scans and magnetic resonance imaging (MRI) scans. Recent studies have attempted to standardize foraminal dimension measurements with the use of orthogonal software, accelerator-based measurements and the use of multiple images for three-dimension reconstruction of the foramen volume (4,9-16).
In the present article, a review of the literature using recommended guidelines (17,18) was performed to assess the changes in foraminal volume and dimensions with ALIF procedures.
Measurement techniques
The included study characteristics and baseline pre-operative foraminal dimensions are summarized in Table 1 and Table 2.
Table 1
| First author | Year | Country | Type of subject | Number | Intervention | Outcomes measured | Method of measurement |
|---|---|---|---|---|---|---|---|
| Stephens | 1991 | UK | Cadavers | 20 | Removal of all muscle and associated loose connective |
Foraminal shape, foraminal area | Molding technique: cotton wool with silicone rubber was used to take molds of intervetebral foramen. The cast is then used with ink to produce a “stamp” in print. This is then used to measure foraminal area and width |
| Schlegel | 1994 | USA | Embalmed human lumbosacral cadaveric spines | 10 | Resection of disc and ligamentous structures, followed by anterior distraction using 5 mm or 10 mm intradiscal spacers | Foraminal area, canal area | Foraminal space measured using direct caliperic method and via sagittal reconstruction of CT scan at midportion of pedicle on axial cut. Orthogonal software was used for quantification |
| Chen | 1995 | USA | Cadaver: 9 fresh frozen degenerative cadaver lumbar spines, stored at −20 °C until testing | 9 | Anterior interbody distraction using BAK implant | Anterior disc height, posterior disc height, pre and post op | Blunt Probe technique: probe is placed through the neuroforamen without distraction of the facet joint. It can then calculate the foraminal area. Silicon mold technique: mold created from neuroforamen, which was then injected with methylene blue. After obtaining the cast and removing excess sections, its volume and dimensions can be measured |
| Inufusa | 1995 | USA | Cadaveric spines | 19 | NA | Foraminal height, foraminal width, posterior disc height, foraminal area | Frozen cadaveric spine specimens were sliced using cryomicrotome in the sagittal plane. Sagittal CT obtained at the middle of the pedicle, then used to estimate dimentions of foramen and canal, with flexion and extension movements |
| Torun | 2006 | Turkey | Cadaveric spines | 15 | NA | Foraminal height, forminal width, diameter of nerve root | All measurements were made using an electronic digital caliper with a sensitivity degree of 0.1 mm. Measurements were performed by 3 neurosurgeons and 1 anatomist, and cross-checked |
| Hsieh | 2007 | USA | Patients who required ALIF, with minimum follow-up of |
32 | Open ALIF with instrumentation, except in the cases of patients without instability | Anterior disc height, posterior disc height, foraminal height, local Cobb angle, lumbar lordosis | Radiographs were obtained preoperatively and at follow-up. Anterior disc height was measured as distance between inferior endplate to superior endplate at anterior vertebral body line, and posterior disc height measured at vertebral body line. Foraminal height was measured as distance between inferior pedicle wall to superior pedicle wall of the level below |
| Wang | 2007 | USA | Bovine calf spine model | 16 | ALIF | Foraminal area, foraminal height, without and with dynamic loading | Preoperative and postoperative MRI was obtained. The foramen was modelled as an ellipse, and the width and height of the ellipse was calculated. For patients who also had digital images available, orthogonal software could be used to quantify the area of the shape for the foramen |
| Karahalios | 2010 | USA | Human cadaveric L3-S1 specimens | 7 | ALIF | Mean foraminal height | 3D detecting software to calculate angles of the coordinates of a specimen motion. Points representing rostral and caudal vertices of L4L5 foramina were identified and used for quantification of height and changes |
| Cho | 2012 | USA | Patients needing ALIF followed by posterior pedicle screw fixation without distraction or foraminotomy | 26 | ALIF followed by posterior pedicle screw fixation without distraction or foraminotomy | Preoperative and postoperative foraminal area | From MRI images, foramen was modeled as an ellipse. Height and width of ellipse were measured to provide dimensions |
| Kepler | 2012 | USA | Patients requiring LTIF | 29 | LTIF | Foraminal area, average disc height anterior and posterior | CT were obtained preoperatively and at follow-up. Anterior disc height was measured as distance between inferior endplate to superior endplate at anterior vertebral body line, and posterior disc height measured at vertebral body line. Foraminal height was measured as distance between inferior pedicle wall to superior pedicle wall of the level below |
| Shin | 2013 | Korea | Patients with isthmic spondylolisthesis requiring ALIF | 40 | Microscopic anterior foraminal decompression during ALIF followed by percutaneous posterior fixation | Foraminal height, foraminal width, foraminal area | CT images were obtained preoperative and postoperatively. Measurement was performed via 2D reconstruction of sagittal image at mid-portion of the foramen to obtain foraminal dimensions |
| Rao | 2015 | Australia | Patients requiring ALIF | 140 | ALIF | Foraminal area, height, width, anterior disc height, posterior disc height, local disc angle, lumbar lordosis | P-P pedicle to pedicle technique was designed to standardize the measurement of the foramen. CT scans were aligned in all three dimensions: parallel in axial plane, along midline of both pedicles, and along midline of both pedicles in the coronal plane and in sagittal plane perpendicular to the disc space. Analysis was performed using Image J |
ALIF, anterior lumbar interbody fusion; LTIF, lateral transpsoas interbody fusion; CT, computed tomography; MRI, magnetic resonance imaging.
Table 2
| First author | Number | Foraminal area (mm2) | Foraminal height (mm) | Anterior disc height (mm) | Posterior disc height (mm) | Cobb angle (deg) | Lordosis (deg) |
|---|---|---|---|---|---|---|---|
| Stephens | 20 | 101.6±24.4 | 14.85±1.85 | NR | NR | NR | NR |
| Schlegel | 10 | 166±26.7 | NR | NR | NR | NR | NR |
| Chen | 9 | NR | NR | 12.1±3.3 mm (L4-L5); 11.2±2.9 mm L5S1 | 6.3±1.5 mm (L4-L5); 5.3±1.3 mm L5S1 | NR | NR |
| Inufusa | 19 | 108.8±27.3 | 17.7±3 | NR | 5.7±2.3 | NR | NR |
| Torun | 15 | NR | 19.4±2.7 | NR | NR | NR | NR |
| Hsieh | 32 | NR | 19.7 | 10.9 | 6.4 | 7.1 | 50.4 |
| Wang | 16 | 190.8 (tapered), 168 (cylindrical) | 22 (tapered), 21.3 (cylindrical) | NR | NR | NR | NR |
| Karahalios | 7 | NR | 15.50±2.97 | NR | NR | NR | NR |
| Cho | 26 | 87.03±30.36 | NR | NR | NR | NR | NR |
| Kepler | 29 | 103±27.5 | NR | 6±3.5 | 3.9±3.9 | NR | NR |
| Shin | 40 | Osteophyte group: 94.5±16.56; disc herniation: 103.26±15.82 | Osteophyte group: 14.32±2.13; disc herniation group: 16.7±2.42 | NR | NR | NR | NR |
| Rao | 140 | 90 | 140 | 83±31 | 48±22 | 5.9±3.9 | 41.8±11.3 |
NR, not reported.
Mold-based measurements
One of the earliest studies of foraminal dimension measurements was that reported by Stephens et al. (16) in 1991. This group investigated foraminal shape and area using 20 cadaveric spine models. Following the removal of all muscle and associated loose connective tissue, the vertebral column with the major ligaments still retained was assessed quantitatively using the mold technique. Stephens et al. (16) used cotton wool doused in silicon rubber and imprinted this pliable material onto the foraminal region, allowing it to set to cast at room temperature. The cast mould was then removed from the foraminal space and sectioned to create an accurate representation of the foraminal volume. Subsequently, the cast is dabbed in ink and the faces of the cast volume are printed on paper, allowing quantification of dimensions. The foraminal height was defined as the maximal diameter of the prints, whilst the foraminal width was defined as the widest measurement perpendicular to the height. This technique was validated in this study by comparison to interpedicular heights measured on radiographs, defined as the distance between the lower margin of the upper pedicle to the upper margin of the lower pedicle. Using the mold technique, Stephens et al. reported average foraminal area of 101.6 mm2 (range 40-160 mm2) and average foraminal height of 14.9 mm (range 10-19 mm). Subgroup analysis demonstrated that the shape of the foraminal space was altered by disc degeneration, from a round to auricular shape.
Chen et al. (10) also employed a variant of the silicon mold technique. Silicon rubber was used to fill the neuroforaminal space and allowed to set, creating an exact mold of this volume. In contrast to Stephens et al., Chen et al. injected their silicon mold with methylene blue, a dye which provided visual markers of the lateral and medial borders of the foraminal space. Subsequently, the mold was taken out and trimmed down to the precise borders defined by the methylene blue dye. From the mold, the foraminal height and width could be measured. To determine the foraminal volume, the authors used the mathematical relationship between density, volume and mass of silicon, where the density was defined as 1.05 g/cm3. In tandem with another measurement technique, Chen et al. demonstrated that following anterior interbody distraction using a BAK cage implant, there was a 28.5% increase in foraminal area at the L4-L5 level and 26.4% increase in foraminal area at the L5-S1 level. Foraminal volume was also increased by 22.9% (L4-L5) and 21.5% (L5-S1) following a simulated ALIF procedure on a cadaveric spine model.
Caliper-based measurement
Another technique used in early foraminal volume quantification studies involves the use of calipers directly on the foraminal space. Schlegel et al. (9) reported a 37.2% increase in foraminal area using caliperic method and sagittal CT scans (at middle of the pedicle) after distracting the disc space. Besides the mold technique, Chen et al. utilized the Blunt Probe technique, where probes of different sizes were placed into the neuroforamen without distraction. Essentially a variant of the caliper approach, the Blunt Probe technique used finely graded circular blunt probes, of which the largest diameter probe that was able to pass through the neuroforamen without forced distraction was recorded and used to determine the neuroforaminal area.
More recently, Torun et al. (19) used an electronic digital caliper with sensitivity of 0.1 mm. Measurements were performed by three neurosurgeons and crossed checked with measurements performed by an experienced anatomist. From their quantification, Torun et al. reported mean foraminal height of 19.4 mm from 15 cadaveric spine models.
Wang et al. (11) employed a similar method called a Cement Mold technique which used a 3-D Gel Instant Molding Compound. However the mold created, according to the shape of the neuroforamen, was pressed on to recording paper to create a digital imprint and therefore may have been subject to deformations. Digital imaging software was employed to calculate foraminal height and cross-sectional area. They found ALIF with tapered and cylindrical cages improved foraminal area by 17% and foraminal height by 9%.
Radiographic methods
Hsieh et al. (4), who compared the difference between ALIF and transforaminal lumbar interbody fusion (TLIF), reported an 18.5% increase in foraminal height following an ALIF. Plain radiographs were taken preoperative and postoperative in order to measure the disc parameters and foraminal dimensions. Anterior disc height was defined as the distance between the inferior to superior endplate at the anterior vertebral body line. The posterior disc height was measured similarly at the vertebral body line. Similarly to prior studies, the foraminal height was measured as the distance between the inferior pedicle wall to superior pedicle wall of the level below. Although ALIF was superior to TLIF in restoring foraminal height, disc height and local disc angle, there was no difference in clinical outcome at 2 years.
CT based measurements
Schlegel et al. (9), in conjunction with their direct caliperic technique, also used sagittal reconstruction of CT scans at the midportion of the pedicle on axial cut. Orthogonal software was utilized for accurate computer-based measurements of the foraminal area and canal area in 10 embalmed human lumbosacral cadaveric spines. Schlegel simulated ALIF interventions by resecting disc and ligamentous structures, followed by anterior distraction using 5 mm or 10 mm intradiscal spacers. Significant increases in foraminal area were noted (40%) following anterior distraction.
Inufusa et al. (12) used 19 frozen cadaveric spine specimens, which were then sliced using cryomicrotome in the sagittal plane in order to study the dimensions of the neuroforamen. The actual dimensions were measured using a sagittal CT scan at the level of the middle of the pedicle. The goal of the study was to look at changes in foraminal and canal dimensions with flexion and extension. At rest, the foraminal area was reported to be 108.8 mm2 and foraminal height was reported as 17.7 mm, consistent with values reported in prior cadaveric studies.
Kepler et al. (15), when measuring foraminal volume change in lateral transpsoas interbody fusion (LTIF) cases, used CT scans to measure the foraminal area but no standardized technique was used. CT images were obtained preoperatively and postoperative at follow-up. Similar to prior radiographic and CT based measurement studies, the anterior disc height was defined as the distance between the inferior and superior endplates at the anterior vertebral body line, whilst posterior disc height was measured at the vertebral body line. From CT scans of 29 patients, there was a 35% increase in foraminal area at the L4-L5 level. Significant increases in anterior disc height (65%) and posterior disc height (61.5%) were also noted.
Similarly, Shin et al. (6) used CT images obtained preoperative and postoperatively to calculate the foraminal height, width and area. Two-dimensional reconstructions of the sagittal image were performed at the mid-portion of the foramen, before and after ALIF and percutaneous posterior fixation. In their study, patients were subgrouped into indications, osteophyte induced and disc herniation. In the osteophyte group, there was a 41.8% increase in foraminal area and 36.4% increase in foraminal height to 19.5 mm. In the disc herniation group, foraminal area increased by 38% to 142.7 mm2, whilst foraminal height increased 25% to 20.87 mm.
MRI based quantification
Cho et al. (14) used MRI scans to measure the foraminal area preoperatively and postoperatively with ALIF surgery. Sagittal images from printed films or on the Vitrea (imaging software) were utilized. The foraminal space was modelled as an ellipse shaped, and the height and width of the foraminal space was then deduced using known mathematical formulations for the short and long diameters of ellipses. Foraminal dimensions were determined preoperatively and postoperatively following an ALIF procedure with posterior pedicle screw fixation performed on 26 patients. Cho et al. reported a significant increase in foraminal area to 124.7 mm2 (43.3%).
For a select group of patients in the study by Wang et al who had digital images, orthogonal software was utilized to determine the area of the foramen shape, without need to model this as an ellipse. However, similar results were reported by both techniques.
Accelerometer based measurements
Another method included that employed by Karahalios et al. (13), which used 3D motion detecting software to calculate angles of the coordinates of specimen motion in describing the spine’s angular motion. The points representing the rostral and caudal vertices of the left and right L4/5 foramina were then identified with the help of a digitizing probes and rigid-body methods, and were used in quantifying foraminal height and changes. The goal of this study was to look at stability provided by interspinous clamp compared to ALIF. A 4.9% increase in foraminal height was reported in cadavers with ALIF only, compared with 11.6% in cadavers undergoing ALIF with plates, and 7.7% increase using ALIF with bilateral screws.
Pedicle-to-pedicle quantification
Recently, the first clinical study to quantify foraminal dimensions using a standardized approach with three-dimensional CT scans before and after ALIF in 140 patients was published. Rao et al. (20) analysed CT scans in maximum intensity projection format. A new pedicle to pedicle (P-P technique) technique was designed to standardize the measurement of foramen, which involved aligning the CT scans in 3 dimensions; parallel in axial plane, along the midline of both the pedicles in the coronal plane and in the sagittal plane perpendicular to the disc space. The snapshot of the foramen so obtained was measured using Image J. From this, foraminal area, height and width could be quantified. This technique was also used to measure anterior and posterior disc height, as well as lumbar lordosis and local angle. From scans of 140 patients with 184 levels, the authors reported increased foraminal area (67%), foraminal height (21%) and width (38%). There were also significant improvements in anterior disc height (90%), posterior disc height (77%), and lumbar lordosis (6%). High intra- and inter-class reliability was demonstrated.
Overall, all studies regardless of technique demonstrated significant increases in foraminal area and foraminal height following fusion procedures (Table 3). The increase in foraminal area ranged from 15.6% to 67%, whilst the increase in foraminal height ranged from 4.9% to 36.4%. The variation in percentage of increase is like to due to various factors including: (I) the differences in anatomy between humans and cadaveric models; (II) ALIF or anterior procedure performed, and whether plates or posterior screw fixation was performed or not; (III) different shape and size cages used, e.g., tapered vs. cylindrical; and (IV) the inherent differences among measurement techniques employed.
Table 3
| First author | Intervention | Δ Foraminal area (%) | Δ Foraminal height (%) | Δ Anterior disc height (%) | Δ Posterior disc height (%) |
|---|---|---|---|---|---|
| Schlegel | ALIF | 25.8% | NR | NR | NR |
| Chen | ALIF | 28.5% (L4-L5), 26.4% (L5-S1) | NR | 35.2% (L4-L5), 24.8% (L5-S1) | 37.1% (L4-L5), 45.1% (L5-S1) |
| Hsieh | ALIF | NR | 18.5% | 65.1% | 34.4% |
| Wang | ALIF | 17.7% (tapered), 15.6% (cylindrical) | 12.3% (tapered), 8.5% (cylindrical) | NR | NR |
| Karahalios | ALIF | NR | 4.9% (standalone), 17.0% (plates), 7.7% (bilateral screws) | NR | NR |
| Cho | ALIF | 43.3% | NR | NR | NR |
| Kepler | ALIF | 35.0% | NR | 65% | 61.5% |
| Shin | ALIF | 42.1% (osteophyte), 38.1% (disc herniation) | 36.4% (osteophyte), 25.0% (disc herniation) | NR | NR |
| Rao | ALIF | 67% | 21% | 90% | 77% |
ALIF, anterior lumbar interbody fusion; NR, not reported.
Progress in measurement techniques
As per the literature presented, there are very few studies which have measured lumbar foramen areas or heights. Most of the studies have been performed in spine cadaveric models (9,10,12,13,16,19), and of the few clinical studies available, a standardized technique of measuring the foramen values was not employed. Clinical studies have shown significant improvement in foraminal measurements after ALIF (6,15). None of the clinical studies have looked at the effect of restoration of disc height parameters on foraminal area restoration. But this has been elegantly demonstrated in a cadaveric study by Schlegel et al. (9), which showed that a 10 mm distraction of disc can result in 40% foramen area improvement.
Initial studies used relatively crude techniques of direct caliper, probes or creation of molds to estimate the foraminal space dimensions. Whilst advocates of this approach argue that the use of a penetrating caliper or probe may stimulate the functional relationship between nerve and foramen, ultimately, measurements are not recorded using a digitized approach and the instruments themselves have poor sensitivity. Recent studies have used advanced versions of these tools, including electronic calipers, in an attempt to obtain more accurate quantification of foraminal height and width.
Following this, studies started to use clinical images, in the form of radiographs, CT and MRI scans. The use of radiographs has proved to be inadequate, given that this approach does not account for the change in orientation of the foramen dependent on the depth of the radiograph. More specifically, the foramen changes orientation from almost horizontal to anterocaudal, moving from upper lumbar to the lumbosacral junction. Compared to radiographs, CT offers better definition and images of soft tissue and bone of the foramen. There are several limitations with this technique. Firstly, many CT images are obtained on supine patients, which may underestimate the foraminal area compared to standing patients undertaking radiographs. Secondly, the majority of studies employing CT imaging for foraminal measurements have done so using single orientations. Despite the study by Shin et al. measuring all foraminal dimensions, this investigation only created a two-dimensional reconstruction. The more recent study by Rao et al. (20) addressed the issue of non-standardized quantification from CT images by using images obtained by three dimensions (Pedicle-to-pedicle technique), which were then aligned to reconstruct the foraminal space.
MRI can also be used for determining foraminal measurements. MRI can provide a more detailed and accurate foraminal shape compared to CT images. Potential limitations may include the fact that artefacts will show up more compared to CT, especially following instrumentation. Similarly to CT, the use of MRI images of single orientations is not standardized, which may increase the heterogeneity of reported measurements (21).
Advances in technology have led to one study (13) using an accelerometer-based technique for analysis of the foraminal dimensions. This technology would be particularly useful in measuring real-time changes in foraminal dimensions, such as during flexion and extension movements, and changes in angulation.
Conclusions
In summary, various measurement techniques have been used in the literature for quantification of foraminal dimensions. Consistent results have demonstrated significant increases in foraminal area and height following anterior lumbar interbody distraction, providing evidence that ALIF can indirectly increase foraminal height. Future studies should use standardized measurement approaches such as the Pedicle-to-Pedicle technique with CT or MRI images to determine changes in foraminal dimensions.
Acknowledgements
None.
Footnote
Conflicts of Interest: The authors have no conflicts of interest to declare.
References
- Fritzell P, Hägg O, Wessberg P, et al. 2001 Volvo Award Winner in Clinical Studies: Lumbar fusion versus nonsurgical treatment for chronic low back pain: a multicenter randomized controlled trial from the Swedish Lumbar Spine Study Group. Spine (Phila Pa 1976) 2001;26:2521-32; discussion 2532-4. [PubMed]
- An H, Boden SD, Kang J, et al. Summary statement: emerging techniques for treatment of degenerative lumbar disc disease. Spine (Phila Pa 1976) 2003;28:S24-5. [PubMed]
- Booth KC, Bridwell KH, Eisenberg BA, et al. Minimum 5-year results of degenerative spondylolisthesis treated with decompression and instrumented posterior fusion. Spine (Phila Pa 1976) 1999;24:1721-7. [PubMed]
- Hsieh PC, Koski TR, O'Shaughnessy BA, et al. Anterior lumbar interbody fusion in comparison with transforaminal lumbar interbody fusion: implications for the restoration of foraminal height, local disc angle, lumbar lordosis, and sagittal balance. J Neurosurg Spine 2007;7:379-86. [PubMed]
- Mobbs RJ, Loganathan A, Yeung V, et al. Indications for anterior lumbar interbody fusion. Orthop Surg 2013;5:153-63. [PubMed]
- Shin SH, Choi WG, Hwang BW, et al. Microscopic anterior foraminal decompression combined with anterior lumbar interbody fusion. Spine J 2013;13:1190-9. [PubMed]
- Vernon-Roberts B, Pirie CJ. Degenerative changes in the intervertebral discs of the lumbar spine and their sequelae. Rheumatol Rehabil 1977;16:13-21. [PubMed]
- Sohn HM, You JW, Lee JY. The relationship between disc degeneration and morphologic changes in the intervertebral foramen of the cervical spine: a cadaveric MRI and CT study. J Korean Med Sci 2004;19:101-6. [PubMed]
- Schlegel JD, Champine J, Taylor MS, et al. The role of distraction in improving the space available in the lumbar stenotic canal and foramen. Spine (Phila Pa 1976) 1994;19:2041-7. [PubMed]
- Chen D, Fay LA, Lok J, et al. Increasing neuroforaminal volume by anterior interbody distraction in degenerative lumbar spine. Spine (Phila Pa 1976) 1995;20:74-9. [PubMed]
- Wang M, Dalal S, Bagaria VB, et al. Changes in the lumbar foramen following anterior interbody fusion with tapered or cylindrical cages. Spine J 2007;7:563-9. [PubMed]
- Inufusa A, An HS, Lim TH, et al. Anatomic changes of the spinal canal and intervertebral foramen associated with flexion-extension movement. Spine (Phila Pa 1976) 1996;21:2412-20. [PubMed]
- Karahalios DG, Kaibara T, Porter RW, et al. Biomechanics of a lumbar interspinous anchor with anterior lumbar interbody fusion. J Neurosurg Spine 2010;12:372-80. [PubMed]
- Cho W, Sokolowski MJ, Mehbod AA, et al. MRI measurement of neuroforaminal dimension at the index and supradjacent levels after anterior lumbar interbody fusion: a prospective study. Clin Orthop Surg 2013;5:49-54. [PubMed]
- Kepler CK, Sharma AK, Huang RC, et al. Indirect foraminal decompression after lateral transpsoas interbody fusion. J Neurosurg Spine 2012;16:329-33. [PubMed]
- Stephens MM, Evans JH, O'Brien JP. Lumbar intervertebral foramens. An in vitro study of their shape in relation to intervertebral disc pathology. Spine (Phila Pa 1976) 1991;16:525-9. [PubMed]
- Moher D, Liberati A, Tetzlaff J, et al. Preferred reporting items for systematic reviews and meta-analyses: the PRISMA statement. PLoS Med 2009;6:e1000097. [PubMed]
- Phan K, Tian DH, Cao C, et al. Systematic review and meta-analysis: techniques and a guide for the academic surgeon. Ann Cardiothorac Surg 2015;4:112-22. [PubMed]
- Torun F, Dolgun H, Tuna H, et al. Morphometric analysis of the roots and neural foramina of the lumbar vertebrae. Surg Neurol 2006;66:148-51; discussion 151. [PubMed]
- Rao PJ, Maharaj MM, Phan K, et al. Indirect foraminal decompression after anterior lumbar interbody fusion: a prospective radiographic study using a new pedicle-to-pedicle technique. Spine J 2015;15:817-24. [PubMed]
- Phan K, Mobbs RJ. Systematic reviews and meta-analyses in spine surgery, neurosurgery and orthopedics: guidelines for the surgeon scientist. Journal of Spine Surgery 2015;1:19-27.
