Adjacent Segment Motion of Stand-Alone ALIF Versus TLIF in the Degenerative Spine: A Biomechanical Study

Alina Jacob; Daniel Haschtmann; Tamás F Fekete; Ivan Zderic; Jan Caspar; Peter Varga; Maximilian Heumann; Christian Rainer Wirtz; Nicolas Ion; R Geoff Richards; Boyko Gueorguiev; Markus Loibl

doi:10.1177/21925682251341823

. 2025 May 14;16(1):252–262. doi: 10.1177/21925682251341823

Adjacent Segment Motion of Stand-Alone ALIF Versus TLIF in the Degenerative Spine: A Biomechanical Study

Alina Jacob ^1,^2,^✉, Daniel Haschtmann ³, Tamás F Fekete ³, Ivan Zderic ¹, Jan Caspar ¹, Peter Varga ¹, Maximilian Heumann ¹, Christian Rainer Wirtz ², Nicolas Ion ⁴, R Geoff Richards ¹, Boyko Gueorguiev ¹, Markus Loibl ³

PMCID: PMC12078258 PMID: 40365962

Abstract

Study Design

Biomechanical human cadaveric study.

Objectives

Transforaminal lumbar interbody fusion (TLIF) is a well-established procedure for treating degenerative lumbar spine pathologies. However, posterior fixation has been reported to accelerate adjacent segment degeneration (ASD). Posterior fixation can be omitted in screw-anchored stand-alone anterior lumbar interbody fusion (ALIF). The present study aimed to compare the cranial adjacent segment motion of ALIF vs TLIF in specimens with reduced bone mineral density (BMD).

Methods

Sixteen fresh-frozen lumbosacral spines with reduced BMD (donors’ age 71 ± 13years, BMD 95.7 ± 34.5 mg HA/cm³) were used. Range of motion (ROM) and Neutral Zone (NZ) of the cranial adjacent segment were analyzed in flexion-extension, lateral bending, and axial rotation in native state and after TLIF or stand-alone screwed ALIF instrumentation.

Results

No significant differences between TLIF and stand-alone screwed ALIF were observed for both absolute ROM and NZ of the cranial adjacent segment in instrumented state across all tested motion directions (P ≥ .267). Decreased relative ROM of the fused segment – normalized to the corresponding segmental ROM in native state – resulted in compensatory increased relative ROM of the cranial adjacent segment after instrumentation. However, the relative adjacent segment ROM did not differ significantly between TLIF and stand-alone screwed ALIF (P ≥ .172).

Conclusions

This study found no clinically significant difference in adjacent segment motion when comparing TLIF with stand-alone screwed ALIF. Hence, both techniques appear to have a negligible impact on adjacent segment motion in poor bone quality. This suggests that neither TLIF nor stand-alone screwed ALIF increase the risk of ASD due to compensatory motion resulting from an operated adjacent segment.

Keywords: transforaminal lumbar interbody fusion, stand-alone anterior lumbar interbody fusion, adjacent segment degeneration, range of motion, neutral zone, degenerative lumbar spine

Introduction

Chronic low back pain associated with degenerative disc disease (DDD) is the leading cause of global disability. Degenerative diseases of the lumbar spine are prevalent worldwide, with DDD-related lower back pain alone affecting approximately 266 million individuals with a global incidence of 3.63%.¹ When non-operative treatments fail, lumbar fusion surgery may be indicated. Lumbar fusion increases the risk of adjacent segment disease (ASD). To achieve fusion of a segment, its motion is restricted. As a compensatory mechanism, more movement occurs in the segments above and below the fused segment,^2-4 potentially leading to ASD manifesting as DDD, olisthesis, or fracture.^5,6 Frequencies of ASD are reported to reach up to 30%.⁶ An analysis of 1751 patients in 2020 found an ASD rate of 27.8% on X-rays, with 7.6% of symptomatic ASD, and 4.6% of the cases requiring reoperation.⁷

Transforaminal lumbar interbody fusion (TLIF) is a well-established and frequently performed fusion technique, with a consistent upward trend in incidence rates.^8-10 Compared to TLIF, anterior lumbar interbody fusion (ALIF) carries a higher vascular risk, however, it is thought to be more effective at restoring lumbar and segmental lordosis, which are protective factors against ASD.^11-13 Studies comparing TLIF to screw-anchored stand-alone ALIF concerning ASD remain inconclusive.^6,14,15 Specifically, stand-alone ALIF using a cage with an integrated plate for vertebral anchoring screws – referred to as the modern-era single-level ALIF – differs from traditional ALIF as no additional posterior instrumentation is needed. Previous research has indicated that posterior fixation is associated with increased ASD,⁵ suggesting that its absence may reduce compensatory motion at the adjacent level and potentially lower the risk of ASD compared to traditional TLIF. However, there is limited biomechanical data available on adjacent segment motion for this approach.^16,17

The aim of the present study is to compare the range of motion (ROM) and neutral zone (NZ) of the cranial lumbar adjacent segment of stand-alone screwed ALIF vs an instrumented TLIF in degenerative lumbar specimens with reduced bone mineral density (BMD). The null hypothesis asserts that TLIF results in a significantly bigger increase in ROM and NZ of the cranial adjacent segment compared to stand-alone screwed ALIF.

Materials and Methods

Specimen Preparation

Sixteen fresh-frozen human cadaveric lumbar spines (seven L3-5 and nine L4-S1 segments from 7 male and 9 female donors; age 71 ± 13 years (mean ± standard deviation (SD)); trabecular BMD 95.7 ± 34.5 mg HA/cm³) were included based on the clinical definition criterion for osteoporosis using the threshold of BMD ≤ 120 mg HA/cm³. All donors gave their informed consent inherent within the donation of the anatomical gift statement during their lifetime. In addition, the institutional review boards of both the donor supplier company (ScienceCare, Phoenix, AZ, USA) and the institution where the study was conducted approved the project. For specimen selection, conventional biplanar X-rays imaging and computed tomography (CT) scans (Revolution Evo, GE Health care Chicago, IL, USA) were used. The set was screened to exclude fractures, tumors, severe scoliosis, and autofused segments. The storage temperature was -20°C. For preparation and testing the fresh-frozen specimens were thawed overnight at room temperature. Soft tissues were removed. The cranial end of L4 and the sacrum were embedded in a cylindric polymethylmethacrylate (PMMA, SCS-Beracryl, Suter Kunststoffe AG, Fraubrunnen, Switzerland) form of 45 mm height and 90 mm diameter. Screws were used to improve bone-to-PMMA anchorage. The cranial embedding was aligned parallel to the instrumented motion segment L4-5 or L5-S1. Physiological saline solution was used to prevent specimen dehydration. Stratified randomization based on sex, age, BMD, and specimen length was performed to ensure homogenous distribution of these characteristics in the 2 groups – ALIF and TLIF (Table 1).

Table 1.

Distribution of donors’ sex, age, bone mineral density (BMD), and specimen segments in the ALIF and TLIF groups.

Variable	Total	Group
Variable	Total	ALIF	TLIF
Sex
Female	9 (56.2%)	4 (57.1%)	5 (55.6%)
Male	7 (43.8%)	3 (42.9%)	4 (44.4%)
Age (years)	71.0 ± 13.0	69.7 ± 16.9	71.3 ± 8.9
BMD (mg HA/cm³)	95.7 ± 34.5	85.2 ± 29.2	109.7 ± 38.5
Specimen segments
L3-5	7 (43.8%)	3 (42.9%)	4 (44.4%)
L4-S1	9 (56.2%)	4 (57.1%)	5 (55.6%)

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Surgical Technique

ALIF or TLIF were conducted in the in the L3-5 spines at the L4-5 level, and in the L4-S1 specimens at the lumbosacral junction, thus leaving the lumbar cranial adjacent segments L3-4 and L4-5 for analysis, respectively.

TLIF

The technique described by Jeszenszky and Harms was followed.¹⁸ First, the pedicle screws were placed to allow distraction for facilitated disc removal. Common anatomical landmarks were used to select the entry points of the screws. The mid transverse process and lateral border of the superior articular facet were used. After opening of the cortex the pedicle finder was used. Before final placement, palpation with a probe confirmed bone surrounding the screw channel in all directions. Following the determination of the screw length, titanium polyaxial pedicle screws (EXPEDIUM VERSE Spinal System, Johnson&Johnson MedTech) were inserted under radiographic control into the pedicles of the vertebrae L5 and S1. Facetectomy was performed on the left side. The posterior supraspinous and interspinous ligaments at L3-4 were incised to allow interspinous distraction. Temporary rods were used to hold distraction during discectomy. The anterior and lateral part on the right side of the annulus fibrosus were preserved to prevent migration of the cage. Endplate preparation involved careful removal of the cartilaginous layers using ring curettes. Trial implants determined the height of the selected polyether ether ketone (PEEK) TLIF spacers (T-pal Ti, Johnson&Johnson MedTech). The T-pal cage was placed in the anterior third of the disc space in the median sagittal plane. Correct placement was confirmed radiologically, before the replacement of the temporary rods with final ones. Under compression, the pedicle screw inserts were tightened using a 9 Nm torque limiter. Final biplanar X-rays verified correct screw trajectory and implant placement.

ALIF

A SynFix-LR implant (Johnson&Johnson MedTech) – a PEEK cage with an integrated titanium plate – was used for stand-alone screwed ALIF. Its four locking screws allow fixation in the upper and lower vertebra. The anterior longitudinal ligament (ALL) was resected, and the disc was partially removed. The implant height was selected to achieve press fit. Once correctly positioned, the cage was fixated by the 4 locking screws. Final X-rays in 2 planes verified correct implant placement.

Biomechanical Testing

Biomechanical testing was performed on a biaxial servo-hydraulic material testing machine (MTS 858 Mini Bionix II, MTS Systems, Eden Prairie, MN, USA) equipped with a 100 Nm/4 kN load cell (HUPPERT 6, HUPPERT GmbH, Herrenberg, Germany) according to the in vitro testing criteria for spinal implants.²¹ A previously established biomechanical test protocol^19,20 was adopted as follows: ROM and NZ of the cranial adjacent segment to the ALIF or TLIF instrumentation were assessed in flexion-extension (Flex-Ext), right and left lateral bending (LB), and right and left axial rotation (AR). The machine’s torsional actuator was used to load the specimens in 3 different setup configurations (Figure 1). A cardan joint and XY-table were used to passively neutralize artifactual shear forces and bending moments. The axial load was actively kept at a constant level of 0 N throughout the tests. This ensured unconstraint movement around the intended anatomical axis. The loading protocol consisted of 3 bidirectional ramps up to ±7.5 Nm at a rate of 4°/sec.

Figure 1. — Test setup for range of motion testing in flexion-extension (A, left), lateral bending (B, middle), and axial rotation (C, right) with XY-table (XY), cardan joint (ca), reference marker set for motion tracking (1), PMMA embedding (2), and base fixation (3).

An optical marker set was attached to each vertebra using a Kirschner wire for optical motion tracking. The marker set of L4 was aligned with its anatomical axes and planes, defining the reference coordinate system.

Data Acquisition and Evaluation

Machine data of axial load, axial displacement, torsion angle and torque were continuously acquired at 128 Hz throughout each test. In addition, the coordinates of the optical markers attached to each vertebra were continuously tracked using a stereometric optical measurement system (GOM Aramis SRX, Carl Zeiss GOM Metrology GmbH, Braunschweig, Germany) operating at a resolution of 12 megapixel and a maximum acceptance error of 0.02 mm. Based on synchronized machine and optical motion tracking data, NZ of the adjacent segment was calculated for each loading direction and instrumentation state as the range of motion where minimal resistance is provided by the implant material, reflecting a critical parameter for stability assessment. Furthermore, ROM of the adjacent segment was assessed as the peak deflection movement for each loading direction and instrumentation state separately. Further data processing included normalization of the ROM outcome measures to the native state.

Statistical analysis was carried out using GraphPad Prism software (version 10.2.3, San Diego, CA, USA). Normality of data distribution of both the absolute and normalized data was assessed using the Shapiro-Wilk test. Descriptive data are presented as mean value ± SD or counts and percentages (%). Contingency analyses with Pearson’s Chi-Square test were used to compare the proportions of the categorical variables. Independent-Samples t-test was used to identify significant differences regarding the group characteristics ROM and NZ between the ALIF and TLIF groups. Paired-Samples t-test was used to analyse the change in adjacent segment ROM and NZ between the intact and instrumented state in each separate group. F-test was used to compare variances. Level of significance was set at P = .05.

Results

There were no significant differences in baseline characteristics between the groups (Table 1).

Cranial Adjacent Segment ROM

There were no significant differences between the adjacent segment ROM in the native state of the specimens in the ALIF vs TLIF group (P ≥ .101, Table 2, Figure 2) nor following their instrumentation (P ≥ .267). F-tests did not identify any significant differences in the variances between the groups.

Table 2.

Range of motion (ROM, nean value ± standard deviation) of the cranial adjacent segment in the native state and after ALIF and TLIF instrumentation of the caudal segment for flexion, extension, right and left lateral bending (LB), and right and left axial rotation (AR).

Variable	Native state ALIF & TLIF	Adjacent segment ROM				P-value instrumented ALIF vs TLIF
		ALIF		TLIF
		Native	Instrumented	Native	Instrumented
Flexion (°)	4.41 ± 1.97	4.90 ± 2.22	5.25 ± 2.22	3.82 ± 1.61	3.87 ± 1.56	.267
Extension (°)	−3.05 ± 1.42	−3.71 ± 1.57	−3.00 ± 1.10*	−2.54 ± 1.11	−2.98 ± 1.41	.976
Right LB (°)	3.35 ± 1.37	3.57 ± 1.50	3.71 ± 1.50	3.19 ± 1.33	3.29 ± 1.21	.405
Left LB (°)	−3.32 ± 1.34	−3.34 ± 1.54	−3.36 ± 1.64	−3.31 ± 1.25	−2.75 ± 1.20	.547
Left AR (°)	2.01 ± 0.81	2.11 ± 0.79	2.22 ± 0.82	1.93 ± 0.87	2.13 ± 0.56	.695
Right AR (°)	−2.07 ± 0.93	−2.06 ± 0.85	−2.40 ± 0.98*	−2.08 ± 1.05	−2.20 ± 0.97	.791

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Significant differences between the native and the instrumented states in each separate group are indicated by asterisks (*: P < .05).

Figure 2. — Range of motion (ROM, mean value ± standard deviation) at the cranial adjacent segment of TLIF and ALIF for flexion-extension (left) lateral bending (middle), and axial rotation (right). Comparisons between the instrumented ALIF and TLIF groups are indicated (ns: not significant).

For flexion, no significant change in ROM of the segment adjacent to the instrumentation was observed between native and instrumented state within each group (TLIF: P = .876, ALIF: P = .216). There were no significant differences between the ALIF and TLIF groups regarding the adjacent segment motion in native state (difference 0.86 ± 0.99°, P = .400) and after instrumentation (difference 1.09 ± 0.94°, P = .267). Extension motion of the adjacent segment showed no significant change after instrumentation in the TLIF group (P = .127), however, it decreased significantly after instrumentation in the ALIF group by 0.71 ± 0.70° (P = .037). For extension, there were no significant differences between the ALIF and TLIF groups regarding the adjacent segment motion in the native state (difference 1.17 ± 0.67°, P = .101) and after instrumentation (difference 0.02 ± 0.65°, P = .976).

For left LB of the adjacent segment, no significant change was indicated between native and instrumented state in both TLIF (difference 0.55 ± 1.19°; P = .202) and ALIF (difference 0.02 ± 0.63°; P = .941) groups. There were no significant differences between the ALIF and TLIF groups regarding the adjacent segment motion in native state (difference 0.04 ± 0.70°, P = .960) and after instrumentation (difference 0.61 ± 0.71°, P = .405). For right LB of the adjacent segment, no significant change was indicated between native and instrumented state in either group (TLIF: difference 0.11 ± 0.61°; P = .611; ALIF: difference 0.14 ± 0.66°; P = .586). There were no significant differences between the ALIF and TLIF groups regarding the adjacent segment motion in native state (difference 0.38 ± 0.71°, P = .600) and after instrumentation (difference 0.42 ± 0.67°, P = .547).

Right AR of the adjacent segment increased between native and instrumented state in the TLIF group by 0.12 ± 0.59° (P = .544) and significantly increased in the ALIF group by 0.34 ± 0.34° (P = .037). There were no significant differences between the ALIF and TLIF groups regarding the adjacent segment motion in native state (difference 0.02 ± 0.49°, P = .965) and after instrumentation (difference 0.20 ± 0.49°, P = .695). Left AR of the adjacent segment increased between native and instrumented state in both TLIF (difference 0.20 ± 0.68°; P = .405) and ALIF (difference 0.11 ± 0.46°; P = .544) groups without reaching statistical significance. There were no significant differences between the ALIF and TLIF groups regarding the adjacent segment motion in native state (difference 0.18 ± 0.42°, P = .671) and after instrumentation (difference 0.09 ± 0.34°, P = .791).

Relative Cranial Adjacent Segment ROM

There were no significant differences of the relative cranial adjacent segment and fused-segment ROM – being normalized to the corresponding segmental ROM in native state – between the instrumented ALIF and TLIF groups (P ≥ .172). Figure 3 shows the change in cranial adjacent segment ROM after instrumentation normalized to the corresponding native state.

Figure 3. — Relative range of motion (ROM, mean value ± standard deviation) of the fused segment (TLIF / ALIF) and the cranial adjacent segment (TLIF / ALIF Cranial Adjacent Segment) after TLIF or ALIF instrumentation, normalized to the corresponding segmental ROM in the native state for flexion-extension (Flex-Ext, left), lateral bending (LB, middle), and axial rotation (AR, right). The horizontal gridline indicates 100% native motion before lumbar interbody fusion.

Cranial Adjacent Segment NZ

The NZ of the cranial adjacent segment level increased non-significantly between native and instrumented state in each separate group and did not show significant differences between the ALIF and TLIF groups in native state and after instrumentation for flexion-extension, lateral bending and axial rotation (Table 3, Figure 4).

Table 3.

Neutral zone (NZ, mean value ± standard deviation) of the cranial adjacent segment in the native state and after ALIF and TLIF instrumentation of the caudal segment for flexion-extension, lateral bending (LB) and axial rotation (AR).

		ALIF		TLIF
Variable	Native state ALIF & TLIF	Adjacent segment NZ				P-value instrumented ALIF vs TLIF
		Native	Instrumented	Native	Instrumented
Flexion-extension (°)	0.79 ± 0.52	0.95 ± 0.64	0.96 ± 0.59	0.66 ± 0.40	0.81 ± 0.43	.559
LB (°)	0.54 ± 0.31	0.63 ± 0.60	0.84 ± 0.87	0.62 ± 0.34	0.64 ± 0.31	.527
AR (°)	0.35 ± 0.28	0.28 ± 0.27	0.41 ± 0.27	0.41 ± 0.29	0.54 ± 0.32	.405

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Figure 4. — Neutral zone (NZ, mean value ± standard deviation) at the cranial adjacent segment of TLIF and ALIF for flexion-extension (left), lateral bending (middle), and axial rotation (right). Comparisons between the instrumented ALIF and TLIF groups are indicated (ns: not significant).

Discussion

The present study aimed to investigate differences in segmental ROM and NZ of the cranial adjacent segment of ALIF compared to TLIF. The null hypothesis was rejected, as TLIF did not result in a significantly bigger increase in ROM and NZ of the cranial adjacent segment compared to screwed stand-alone ALIF. The present data suggests that adjacent segment motion compensates for ROM restriction caused by lumbar fusion surgery. However, the absolute changes in ROM and NZ of the cranial adjacent segments after instrumentation were minimal and there were no significant differences between the TLIF and ALIF groups. Hence, both techniques appear to have a comparable impact on adjacent segment motion, suggesting that neither TLIF nor ALIF is clearly preferable in terms of reducing the risk of ASD.

Biomechanical Mechanisms

ALIF offers additional anterior column support and leaves posterior stabilizing structures intact, whereas TLIF offers more posterior support. Hence, ALIF is less effective in flexion-extension and most effective in providing stability in AR.^22-27 Most biomechanical studies focused on ROM and NZ of TLIF and stand-alone screwed ALIF in the operated segment in not severely degenerated specimens and their findings are consistent with the observations of the present work. In the current study, 2 significant changes of adjacent segment ROM from native to fused state were observed in AR and extension in the ALIF group. In right AR, ROM of the cranial adjacent segment increased significantly after instrumentation, however, the absolute change was as small as 0.3°. In extension, ROM decreased significantly after instrumentation, but the change was less than 1°, with a standard deviation equal to the observed change. Given the minimal absolute values of the changes after instrumentation and the fact that there were no significant differences between the ALIF and TLIF groups in adjacent segment ROM after instrumentation, these 2 significant changes in the ALIF group do not appear to indicate a clinically meaningful difference compared to the TLIF group. Hence, it can be concluded that, based on the present data, both techniques seem to equally predispose degenerated spines of reduced BMD for ASD, which is in agreement with prior clinical research reporting no significant differences between ALIF and TLIF outcomes and reoperation rates.^12,16,28,29

Literature Review

Previous biomechanical in vitro studies have predominantly been conducted using healthy bone with normal BMD. Volkheimer et al. conducted a systematic review to summarize the results of these previous in vitro studies focusing on the impact of spinal instrumentation on the adjacent segments with regard to the protocol and loads applied. Their review highlighted that the observed adjacent segment motion after fusion highly depends on the testing protocol and the load application. Only for dynamic implants, most studies did not find significant changes in the adjacent segment motions, independent of which test protocol was used.³⁰ It remains a subject of debate whether the assumptions underlying the different protocols reflect the postoperative situation of the patients. In this context Malakoutian et al. examined the in vivo kinematics and found that the assumption made for both the stiffness and hybrid protocols – namely that patients move exactly the same way after fusion – does not match the in vivo behavior.³¹ The motion of the whole lumbar spine tends to decrease after fusion surgery. Therefore, the gold-standard protocol considering pure bending moment flexibility seems to better reflect postoperative motion. When such protocols are used, the difference in the kinematic changes between the cranial and caudal adjacent segment could be reproduced in specimens with normal BMD.³⁰ The results of the present study are consistent with these findings and showed comparable results for degenerated spines with reduced BMD. In the current work, the gold-standard pure-bending-moment protocol was implemented following established testing criteria of spinal implants.²¹ However, no significant increase in ROM after instrumentation and no significant differences between the 2 investigated techniques were detected. Nonetheless, our team is of the opinion that a testing protocol designed to force the spine more agressively to fulfill a predetermined ROM would not reflect in vivo conditions and should not be used to provoke significant differences.

Compared to previous data using specimens with normal BMD, the present study exhibited greater data scattering.^25,30,31 This variability may be attributed to the use of degenerated specimens. Unlike the majority of previous reports, the current specimen set exhibited a lower BMD, potentially leading to reduced screw purchase and weaker fixation with less change of ROM after instrumentation. However, degenerative changes can also involve localized sclerosis with increased density which may enhance fixation in some cases.³² This duality, characterized by reduced overall BMD with regions of increased density, could have contributed to the greater variability observed in the present data.³³ Moreover, the heterogeneous nature of degenerative changes may have involved asymmetries resulting in inconsistencies and leading to differences between left and right motions.

The pathogenesis of ASD remains unknown. Even though the present study did not identify major differences in adjacent segment ROM between the groups, there may still be some existing differences in the biomechanics of ALIF vs TLIF relevant for ASD. These findings could lead to rethinking of the ASD risk mitigation by prioritizing preoperative management, such as BMD modification, rather than only focusing on procedural modifications. Prior work indicated that segments adjacent to the fusion experience increased stresses and higher disc pressure,^34,35 clinically manifesting as accelerated DDD or instability.^36-38 Previous biomechanical studies using finite element analysis observed variations in the stress distribution between ALIF and TLIF.^39,40 In this context, ALIF demonstrated advantages in stress distribution over TLIF, attributed to its larger footprint.⁴¹ Some clinical studies suggest that posterior fixation favors ASD due to increased motion of the adjacent segment,^5,42 whereas other investigations on adjacent segment motion found that ALIF cages had a greater impact on the motion compared to TLIF cages. Such deviations from the results of the present study could be explained by the use of different implants – the majority of previous studies used conventional (not stand-alone) ALIF cages or expandable TLIF cages.^23,34

Increased ROM of the adjacent segment alone after instrumentation may not be the primary cause of ASD. Multiple risk factors for ASD have been identified. Patient-based risk factors include severe preoperative existing adjacent segment DDD, high body mass index (BMI), advanced age, reduced BMD, and surgery-related risk factors considering the length of the construct and its sagittal alignment.^43-45 Data suggests that in long term patients benefit strongly from properly restored sagittal profile.^46,47 Mechanical complications are closely linked to the spinal shape and sagittal parameters can greatly assist surgeons.⁴⁸ Both lordosis distribution and inflection point are directly related to patient outcomes and reoperation rates, however, they are not used for surgery planning of short-segment stabilization in all centers.⁴⁶

To prevent ASD, semi-rigid fixation techniques have been developed. Designed for long constructs, these techniques aim to reduce stress on the adjacent segments by creating a gradual transition zone at the proximal end of a fusion construct. There are 2 main approaches: pretensioning of the cranial level of the construct and reinforcement of the motion segment adjacent to the construct. An example for the pretensioning approach is the tether pedicle screw system that smoothens the transition at the upper instrumented vertebra. Reinforcement methods include sublaminar tape, pretensioned suture loops, transverse hooks, and lamina hooks. A biomechanical study on sublaminar band tensioning at the cranial adjacent segment observed that the ROM increase at this segment (L2-3) after fusion (L3-S1) could be reduced without increase at the level above (L1-2).^49,50 Semi-rigid fixation techniques may not be optimal for short-segment stabilization due to insufficient stability, loss of alignment, and potential higher stresses on screws. Increase micromotion could accelerate loosening and insufficient rigidity can potentially lead to delayed fusion. Overall, semi-rigid fixation techniques are considered as a possible alternative for selected long-segment constructs, where flexibility can help distribute loading across multiple levels and avoid stress concentrations to minimize adjacent segment degeneration. In short segment-constructs, however, these benefits are outweighed by the need for stability and rigidity.^51,52

Limitations

This study has some limitations. First, the small sample size limits statistical power. Second, sample heterogeneity limits comparability. Like all transitional zones, the lumbosacral junction has a distinct anatomy making it less comparable to lumbar motion segments.⁵³ To address this heterogeneity, we reported relative ROM of the operated L4-5 and L5-S1 segments which was normalized to the corresponding native state. The present study focused on cranial L4-5 or L3-4 adjacent segment motions, which are comparable, rather than on the motions of the fused segments as examined in previous studies.⁵⁴ Third, isolated directions of motion without physiological influences of muscle forces of soft tissue were investigated.⁵⁵ Hence, the results cannot be directly applied to the complex dynamic movements in vivo. However, we used a standardized validated quasi-static loading protocol.⁵⁶ Fourth, the present human cadaveric study followed established testing standards without simulation of muscle forces, body weight, and abdominal pressure.^21,56 These factors may have a compensatory effect for minor instabilities or, conversely, higher forces may act on the spine in vivo and accelerate instability.^55,57 The results of the current in vitro study cannot be directly transferred to the complex movement patterns of the human spine in vivo and only primary stability was assessed.

To our knowledge, the presented study is the first to investigate the adjacent motion of stand-alone ALIF vs TLIF in human spines of reduced BMD. As this is an ex vivo biomechanical work, these findings cannot immediately reframe surgeons’ risk assessment, however, they offer new insights and serve as a valuable foundation for future clinical research. When interpreted within its limitations, the findings of this study may help understand in which cases ASD may occur and how optimal outcome of lumbar spinal fusion surgery can be achieved.

Outlook

To investigate causality, biomechanical predictors of ASD need to be identified for stand-alone ALIF and TLIF. The interplay between patient-specific factors (eg, sagittal alignment, BMI) and surgical technique needs to be investigated in clinical studies. A setup with simulation of muscle forces and moments would make the results more transferable.

Conclusion

Acknowledgments

The authors are not compensated and there are no other institutional subsidies, corporate affiliations, or funding sources supporting this work unless clearly documented and disclosed. This investigation was performed with the assistance of the AO Foundation.

Footnotes

The author(s) declared no potential conflicts of interest with respect to the research, authorship, and/or publication of this article.

Funding: The author(s) received no financial support for the research, authorship, and/or publication of this article.

Ethical Statement

Ethical Approval

This study was approved by the institutional internal review board based on the approval of the specimen delivery by Science Care Ethics Committee. All donors gave their informed consent inherent within the donation of the anatomical gift statement during their lifetime. Statement for the ethical use of human cadaveric tissues: the authors declare that every effort was made to follow all local and international ethical guidelines and laws that pertain to the use of human cadaveric donors in biomechanical research.

ORCID iDs

Alina Jacob https://orcid.org/0000-0001-7241-741X

Daniel Haschtmann https://orcid.org/0000-0003-0437-8521

Tamás F. Fekete https://orcid.org/0000-0001-5231-5600

Ivan Zderic https://orcid.org/0000-0003-0484-887X

Peter Varga https://orcid.org/0000-0003-2738-6436

Maximilian Heumann https://orcid.org/0000-0001-9298-1923

Christian Rainer Wirtz https://orcid.org/0000-0001-8358-1813

Nicolas Ion https://orcid.org/0009-0008-2143-1797

R. Geoff Richards https://orcid.org/0000-0002-7778-2480

Boyko Gueorguiev https://orcid.org/0000-0001-9795-115X

Markus Loibl https://orcid.org/0000-0001-7631-0476

Data Availability Statement

Data and materials are available on reasonable request.*

References

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9.Reisener M-J, Pumberger M, Shue J, Girardi FP, Hughes AP. Trends in lumbar spinal fusion-a literature review. J Spine Surg. 2020;6:752-761. [DOI] [PMC free article] [PubMed] [Google Scholar]
10.Grotle M, Småstuen MC, Fjeld O, et al. Lumbar spine surgery across 15 years: trends, complications and reoperations in a longitudinal observational study from Norway. BMJ Open. 2019;9:e028743. [DOI] [PMC free article] [PubMed] [Google Scholar]
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12.Ahlquist S, Park HY, Gatto J, Shamie AN, Park DY. Does approach matter? A comparative radiographic analysis of spinopelvic parameters in single-level lumbar fusion. Spine J. 2018;18:1999-2008. [DOI] [PubMed] [Google Scholar]
13.O'Connor B, Drolet CE, Leveque J-CA, et al. The impact of interbody approach and lumbar level on segmental, adjacent, and sagittal alignment in degenerative lumbar pathology: a radiographic analysis six months following surgery. Spine J. 2022;22:1318-1324. [DOI] [PubMed] [Google Scholar]
14.Bains RR, Royse KE, Fennessy J, et al. Are there differences in the reoperation rates for operative adjacent-segment disease between ALIF+PS, PLIF+PS, TLIF+PS, and LLIF+PS? An analysis of a cohort of 5291 patients. J Neurosurg Spine. 2024;40:733-740. [DOI] [PubMed] [Google Scholar]
15.Tao X, Matur AV, Khalid S, et al. TLIF is associated with lower rates of adjacent segment disease and complications compared to ALIF: a matched-cohort analysis. Spine. 2023;48:1335-1341. [DOI] [PubMed] [Google Scholar]
16.Giang G, Mobbs R, Phan S, Tran TM, Phan K. Evaluating outcomes of stand-alone anterior lumbar interbody fusion: a systematic review. World Neurosurg. 2017;104:259-271. [DOI] [PubMed] [Google Scholar]
17.Farber SH, Dugan RK, White MD, et al. A comparison of modern-era anterior lumbar interbody fusion and minimally invasive transforaminal lumbar interbody fusion at the lumbosacral junction. J Neurosurg Spine. 2023;39:785-792. [DOI] [PubMed] [Google Scholar]
18.Harms JG, Jeszenszky D. Not available. Oper Orthop Traumatol. 1998;10:90-102. [DOI] [PubMed] [Google Scholar]
19.Heumann M, Benneker LM, Constant C, et al. Decreasing implant load indicates spinal fusion when measured continuously. J Biomech. 2024;163:111929. [DOI] [PubMed] [Google Scholar]
20.Windolf M, Heumann M, Varjas V, et al. Continuous rod load monitoring to assess spinal fusion status-pilot in vivo data in sheep. Medicina (Kaunas, Lithuania). 2022;58:899. [DOI] [PMC free article] [PubMed] [Google Scholar]
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24.Ploumis A, Wu C, Fischer G, et al. Biomechanical comparison of anterior lumbar interbody fusion and transforaminal lumbar interbody fusion. J Spinal Disord Tech. 2008;21:120-125. [DOI] [PubMed] [Google Scholar]
25.Niemeyer TK, Koriller M, Claes L, Kettler A, Werner K, Wilke HJ. In vitro study of biomechanical behavior of anterior and transforaminal lumbar interbody instrumentation techniques. Neurosurgery. 2006;59:1271-1276. [DOI] [PubMed] [Google Scholar]
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Associated Data

This section collects any data citations, data availability statements, or supplementary materials included in this article.

Data Availability Statement

Data and materials are available on reasonable request.*

[bibr1-21925682251341823] 1.Ravindra VM, Senglaub SS, Rattani A, et al. Degenerative lumbar spine disease: estimating global incidence and worldwide volume. Glob Spine J. 2018;8:784-794. [DOI] [PMC free article] [PubMed] [Google Scholar]

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[bibr8-21925682251341823] 8.Meng B, Bunch J, Burton D, Wang J. Lumbar interbody fusion: recent advances in surgical techniques and bone healing strategies. Eur Spine J. 2021;30:22-33. [DOI] [PubMed] [Google Scholar]

[bibr9-21925682251341823] 9.Reisener M-J, Pumberger M, Shue J, Girardi FP, Hughes AP. Trends in lumbar spinal fusion-a literature review. J Spine Surg. 2020;6:752-761. [DOI] [PMC free article] [PubMed] [Google Scholar]

[bibr10-21925682251341823] 10.Grotle M, Småstuen MC, Fjeld O, et al. Lumbar spine surgery across 15 years: trends, complications and reoperations in a longitudinal observational study from Norway. BMJ Open. 2019;9:e028743. [DOI] [PMC free article] [PubMed] [Google Scholar]

[bibr11-21925682251341823] 11.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;7:379-386. [DOI] [PubMed] [Google Scholar]

[bibr12-21925682251341823] 12.Ahlquist S, Park HY, Gatto J, Shamie AN, Park DY. Does approach matter? A comparative radiographic analysis of spinopelvic parameters in single-level lumbar fusion. Spine J. 2018;18:1999-2008. [DOI] [PubMed] [Google Scholar]

[bibr13-21925682251341823] 13.O'Connor B, Drolet CE, Leveque J-CA, et al. The impact of interbody approach and lumbar level on segmental, adjacent, and sagittal alignment in degenerative lumbar pathology: a radiographic analysis six months following surgery. Spine J. 2022;22:1318-1324. [DOI] [PubMed] [Google Scholar]

[bibr14-21925682251341823] 14.Bains RR, Royse KE, Fennessy J, et al. Are there differences in the reoperation rates for operative adjacent-segment disease between ALIF+PS, PLIF+PS, TLIF+PS, and LLIF+PS? An analysis of a cohort of 5291 patients. J Neurosurg Spine. 2024;40:733-740. [DOI] [PubMed] [Google Scholar]

[bibr15-21925682251341823] 15.Tao X, Matur AV, Khalid S, et al. TLIF is associated with lower rates of adjacent segment disease and complications compared to ALIF: a matched-cohort analysis. Spine. 2023;48:1335-1341. [DOI] [PubMed] [Google Scholar]

[bibr16-21925682251341823] 16.Giang G, Mobbs R, Phan S, Tran TM, Phan K. Evaluating outcomes of stand-alone anterior lumbar interbody fusion: a systematic review. World Neurosurg. 2017;104:259-271. [DOI] [PubMed] [Google Scholar]

[bibr17-21925682251341823] 17.Farber SH, Dugan RK, White MD, et al. A comparison of modern-era anterior lumbar interbody fusion and minimally invasive transforaminal lumbar interbody fusion at the lumbosacral junction. J Neurosurg Spine. 2023;39:785-792. [DOI] [PubMed] [Google Scholar]

[bibr18-21925682251341823] 18.Harms JG, Jeszenszky D. Not available. Oper Orthop Traumatol. 1998;10:90-102. [DOI] [PubMed] [Google Scholar]

[bibr19-21925682251341823] 19.Heumann M, Benneker LM, Constant C, et al. Decreasing implant load indicates spinal fusion when measured continuously. J Biomech. 2024;163:111929. [DOI] [PubMed] [Google Scholar]

[bibr20-21925682251341823] 20.Windolf M, Heumann M, Varjas V, et al. Continuous rod load monitoring to assess spinal fusion status-pilot in vivo data in sheep. Medicina (Kaunas, Lithuania). 2022;58:899. [DOI] [PMC free article] [PubMed] [Google Scholar]

[bibr21-21925682251341823] 21.Wilke HJ, Wenger K, Claes L. Testing criteria for spinal implants: recommendations for the standardization of in vitro stability testing of spinal implants. Eur Spine J. 1998;7:148-154. [DOI] [PMC free article] [PubMed] [Google Scholar]

[bibr22-21925682251341823] 22.Schleicher P, Gerlach R, Schär B, et al. Biomechanical comparison of two different concepts for stand alone anterior lumbar interbody fusion. Eur Spine J. 2008;17:1757-1765. [DOI] [PMC free article] [PubMed] [Google Scholar]

[bibr23-21925682251341823] 23.Bakhaidar M, Harinathan B, Devaraj KB, DeGroot A, Yoganandan N, Shabani S. Comparative biomechanical analysis of anterior lumbar interbody fusion and bilateral expandable transforaminal lumbar interbody fusion cages: a finite element analysis study. Int J Spine Surg. 2024;18:441-447. [DOI] [PMC free article] [PubMed] [Google Scholar]

[bibr24-21925682251341823] 24.Ploumis A, Wu C, Fischer G, et al. Biomechanical comparison of anterior lumbar interbody fusion and transforaminal lumbar interbody fusion. J Spinal Disord Tech. 2008;21:120-125. [DOI] [PubMed] [Google Scholar]

[bibr25-21925682251341823] 25.Niemeyer TK, Koriller M, Claes L, Kettler A, Werner K, Wilke HJ. In vitro study of biomechanical behavior of anterior and transforaminal lumbar interbody instrumentation techniques. Neurosurgery. 2006;59:1271-1276. [DOI] [PubMed] [Google Scholar]

[bibr26-21925682251341823] 26.Jacob A, Heumann M, Zderic I, et al. Cyclic testing of standalone ALIF versus TLIF in lumbosacral spines of low bone mineral density: an ex vivo biomechanical study. Eur Spine J. 2024;33:3443-3451. [DOI] [PubMed] [Google Scholar]

[bibr27-21925682251341823] 27.Harris BM, Hilibrand AS, Savas PE, et al. Transforaminal lumbar interbody fusion: the effect of various instrumentation techniques on the flexibility of the lumbar spine. Spine. 2004;29:E65-E70. [DOI] [PubMed] [Google Scholar]

[bibr28-21925682251341823] 28.Alhaug OK, Dolatowski FC, Thyrhaug AM, Mjønes S, Dos Reis JABPR, Austevoll I. Long-term comparison of anterior (ALIF) versus transforaminal (TLIF) lumbar interbody fusion: a propensity score-matched register-based study. Eur Spine J. 2024;33:1109-1119. [DOI] [PubMed] [Google Scholar]

[bibr29-21925682251341823] 29.Phan K, Thayaparan GK, Mobbs RJ. Anterior lumbar interbody fusion versus transforaminal lumbar interbody fusion--systematic review and meta-analysis. Br J Neurosurg. 2015;29:705-711. [DOI] [PubMed] [Google Scholar]

[bibr30-21925682251341823] 30.Volkheimer D, Malakoutian M, Oxland TR, Wilke HJ. Limitations of current in vitro test protocols for investigation of instrumented adjacent segment biomechanics: critical analysis of the literature. Eur Spine J. 2015;24:1882-1892. [DOI] [PubMed] [Google Scholar]

[bibr31-21925682251341823] 31.Malakoutian M, Volkheimer D, Street J, Dvorak MF, Wilke HJ, Oxland TR. Do in vivo kinematic studies provide insight into adjacent segment degeneration? A qualitative systematic literature review. Eur Spine J. 2015;24:1865-1881. [DOI] [PubMed] [Google Scholar]

[bibr32-21925682251341823] 32.Schömig F, Becker L, Schönnagel L, et al. Avoiding spinal implant failures in osteoporotic patients: a narrative review. Glob Spine J. 2023;13:52S-58S. [DOI] [PMC free article] [PubMed] [Google Scholar]

[bibr33-21925682251341823] 33.Aziz MSR, Nicayenzi B, Crookshank MC, Bougherara H, Schemitsch EH, Zdero R. Biomechanical measurements of cortical screw purchase in five types of human and artificial humeri. J Mech Behav Biomed Mater. 2014;30:159-167. [DOI] [PubMed] [Google Scholar]

[bibr34-21925682251341823] 34.Ebrahimkhani M, Arjmand N, Shirazi-Adl A. Adjacent segments biomechanics following lumbar fusion surgery: a musculoskeletal finite element model study. Eur Spine J. 2022;31:1630-1639. [DOI] [PubMed] [Google Scholar]

[bibr35-21925682251341823] 35.Cheh G, Bridwell KH, Lenke LG, et al. Adjacent segment disease followinglumbar/thoracolumbar fusion with pedicle screw instrumentation: a minimum 5-year follow-up. Spine. 2007;32:2253-2257. [DOI] [PubMed] [Google Scholar]

[bibr36-21925682251341823] 36.Sim HB, Murovic JA, Cho BY, Lim TJ, Park J. Biomechanical comparison of single-level posterior versus transforaminal lumbar interbody fusions with bilateral pedicle screw fixation: segmental stability and the effects on adjacent motion segments. J Neurosurg Spine. 2010;12:700-708. [DOI] [PubMed] [Google Scholar]

[bibr37-21925682251341823] 37.Early years postgraduate surgical training programmes in the UK are failing to meet national quality standards: an analysis from the ASiT/BOTA Lost Tribe prospective cohort study of 2,569 surgical trainees. Int J Surg. 2018;52:376-382. [DOI] [PubMed] [Google Scholar]

[bibr38-21925682251341823] 38.Wang S-K, Wang P, Li X-Y, Kong C, Niu JY, Lu SB. Incidence and risk factors for early and late reoperation following lumbar fusion surgery. J Orthop Surg Res. 2022;17:385. [DOI] [PMC free article] [PubMed] [Google Scholar]

[bibr39-21925682251341823] 39.Guo T-M, Lu J, Xing Y-L, et al. A 3-dimensional finite element analysis of adjacent segment disk degeneration induced by transforaminal lumbar interbody fusion after pedicle screw fixation. World Neurosurg. 2018;124:e51-e57. [DOI] [PubMed] [Google Scholar]

[bibr40-21925682251341823] 40.Lu X, Li D, Wang H, et al. Biomechanical effects of interbody cage height on adjacent segments in patients with lumbar degeneration: a 3D finite element study. J Orthop Surg Res. 2022;17:325. [DOI] [PMC free article] [PubMed] [Google Scholar]

[bibr41-21925682251341823] 41.Faizan A, Kiapour A, Kiapour AM, Goel VK. Biomechanical analysis of various footprints of transforaminal lumbar interbody fusion devices. J Spinal Disord Tech. 2014;27:E118-E127. [DOI] [PubMed] [Google Scholar]

[bibr42-21925682251341823] 42.Demir Ö, Öksüz E, Deniz FE, Demir O. Assessing the effects of lumbar posterior stabilization and fusion to vertebral bone density in stabilized and adjacent segments by using Hounsfield unit. J Spine Surg. 2017;3:548-553. [DOI] [PMC free article] [PubMed] [Google Scholar]

[bibr43-21925682251341823] 43.Anandjiwala J, Seo J-Y, Ha K-Y, Oh IS, Shin DC. Adjacent segment degeneration after instrumented posterolateral lumbar fusion: a prospective cohort study with a minimum five-year follow-up. Eur Spine J. 2011;20:1951-1960. [DOI] [PMC free article] [PubMed] [Google Scholar]

[bibr44-21925682251341823] 44.Kim H-J, Kang K-T, Chun H-J, Lee CK, Chang BS, Yeom JS. The influence of intrinsic disc degeneration of the adjacent segments on its stress distribution after one-level lumbar fusion. Eur Spine J. 2015;24:827-837. [DOI] [PubMed] [Google Scholar]

[bibr45-21925682251341823] 45.Wang T, Ding W. Risk factors for adjacent segment degeneration after posterior lumbar fusion surgery in treatment for degenerative lumbar disorders: a meta-analysis. J Orthop Surg Res. 2020;15:582. [DOI] [PMC free article] [PubMed] [Google Scholar]

[bibr46-21925682251341823] 46.Wang X, Xu J, Zhu Y, et al. Biomechanical analysis of a newly developed shape memory alloy hook in a transforaminal lumbar interbody fusion (TLIF) in vitro model. PLoS One. 2014;9:e114326. [DOI] [PMC free article] [PubMed] [Google Scholar]

[bibr47-21925682251341823] 47.Radovanovic I, Urquhart JC, Ganapathy V, et al. Influence of postoperative sagittal balance and spinopelvic parameters on the outcome of patients surgically treated for degenerative lumbar spondylolisthesis. J Neurosurg Spine. 2017;26:448-453. [DOI] [PubMed] [Google Scholar]

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PERMALINK

Adjacent Segment Motion of Stand-Alone ALIF Versus TLIF in the Degenerative Spine: A Biomechanical Study

Alina Jacob, MD

Daniel Haschtmann, MD

Tamás F Fekete, MD, PhD

Ivan Zderic, PhD

Jan Caspar

Peter Varga, PhD

Maximilian Heumann, MSc

Christian Rainer Wirtz, MD Prof

Nicolas Ion, MD

R Geoff Richards, PhD Prof

Boyko Gueorguiev, PhD Prof

Markus Loibl, MD Prof

Abstract

Study Design

Objectives

Methods

Results

Conclusions

Introduction

Materials and Methods

Specimen Preparation

Table 1.

Surgical Technique

TLIF

ALIF

Biomechanical Testing

Figure 1.

Data Acquisition and Evaluation

Results

Cranial Adjacent Segment ROM

Table 2.

Figure 2.

Relative Cranial Adjacent Segment ROM

Figure 3.

Cranial Adjacent Segment NZ

Table 3.

Figure 4.

Discussion

Biomechanical Mechanisms

Literature Review

Limitations

Outlook

Conclusion

Acknowledgments

Footnotes

Ethical Statement

Ethical Approval

ORCID iDs

Data Availability Statement

References

Associated Data

Data Availability Statement

ACTIONS

PERMALINK

RESOURCES

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