Tag Archives: Lumbar lordosis
Non-Instrumented Posterior Decompression: Correlation between Radiological parameters and functional outcomes.
Vol 11 | Issue 2 | July-December 2025 | page: 22-25 | Rahul Jaiswal, Shailesh Hadgaonkar, Ajay Kothari, Siddharth Aiyer, Pramod Bhilare, Darshan Sonawane, Ashok Shyam, Parag Sancheti
https://doi.org/10.13107/jmt.2025.v11.i02.268
Author: Rahul Jaiswal [1], Shailesh Hadgaonkar [1], Ajay Kothari [1], Siddharth Aiyer [1], Pramod Bhilare [1], Darshan Sonawane [1], Ashok Shyam [1], Parag Sancheti [1]
[1] Sancheti Institute of Orthopaedics and Rehabilitation PG College, Shivaji- nagar, Pune, Maharashtra, India.
Address of Correspondence
Dr. Rahul Jaiswal,
Sancheti Institute of Orthopaedics and Rehabilitation PG College, Shivajinagar, Pune, Maharashtra, India.
E-mail: rj199116@gmail.com
Abstract
Background: Degenerative lumbar canal stenosis causes neurogenic claudication, radicular pain and reduced walking capacity. When conservative care fails or neurological deficits progress, surgical decompression is commonly offered. This prospective study evaluated pain, disability and health-related quality of life after posterior lumbar decompression and examined changes in spinopelvic parameters.
Methods: Consecutive patients undergoing 1–4 level decompression were assessed preoperatively and at 18 months using Visual Analogue Scale for back and leg pain, Oswestry Disability Index and Short Form-36. Standing lateral radiographs including femoral heads were used to measure pelvic incidence, pelvic tilt, sacral slope and lumbar lordosis. Standardized perioperative care and structured physiotherapy were applied.
Results: Significant and sustained reductions in back and leg pain were observed with large falls in VAS and ODI, and marked gains in SF-36 domains at final follow up. Radiographically, lumbar lordosis increased modestly and PI–LL mismatch decreased on average, but these changes did not reliably predict functional improvement.
Conclusion: Posterior decompression provides meaningful, durable symptomatic and functional benefit in well selected patients with degenerative lumbar canal stenosis; modest radiographic alignment changes may occur but are not required for clinical recovery. These findings support decompression as a safe, effective option when nonoperative care fails. Periodically monitored.
Keywords: Lumbar canal stenosis, Posterior decompression, Neurogenic claudication, Oswestry Disability Index, Lumbar lordosis, PI–LL mismatch.
Introduction
Lumbar canal stenosis is a degenerative narrowing of the lumbar spinal canal and foramina that commonly presents with neurogenic claudication—leg pain, numbness or weakness precipitated by walking and relieved by sitting or flexion. Patients frequently report axial low back pain combined with limited walking distance and reduced quality of life. Nonoperative management, including activity modification, analgesics, supervised physiotherapy and selective injections, is often effective initially, but progressive or refractory symptoms and objective neurological decline are accepted indications for surgical decompression [14]. The surgical goal is to relieve neural compression, restore walking capacity and reduce pain while minimizing morbidity and preserving segmental stability. Approaches range from open laminectomy to minimally invasive unilateral laminotomy with bilateral decompression; technique selection depends on the distribution of pathology, the presence of instability and surgeon preference [15]. Outcome evaluation relies on validated patient-reported measures—Visual Analogue Scale for pain, Oswestry Disability Index for function and Short Form-36 for general health—and standardized radiographic assessment of sagittal alignment, including pelvic incidence, pelvic tilt, sacral slope and lumbar lordosis. Pelvic incidence is an anatomic constant that determines the lumbar lordosis needed for an upright balanced posture, while pelvic tilt and sacral slope are compensatory and may change with pain-avoidant posture. Restoration of pain-free posture after decompression may allow increased lordosis and decreased PI–LL mismatch in some patients, but the extent and clinical relevance of such changes remain debated. By measuring preoperative and 18-month postoperative PROMs and standing radiographs that include femoral heads for accurate pelvic parameter measurement, we sought to quantify the magnitude and durability of symptom relief and to test whether radiographic alignment changes correlate with clinically meaningful improvements. Findings aim to guide patient counselling and surgical planning. Specifically.
Aims and objectives
This prospective study aimed to evaluate the clinical effectiveness of posterior lumbar decompression in patients with degenerative lumbar canal stenosis and to relate clinical recovery to radiographic spinopelvic measures. Primary objectives were to quantify pain reduction using the Visual Analogue Scale for back and leg pain and to measure improvement in disability using the Oswestry Disability Index and health-related quality of life using the Short Form-36. Secondary objectives included calculating pelvic incidence, pelvic tilt, sacral slope and lumbar lordosis on standardized standing lateral radiographs before and after surgery and exploring correlations between radiographic change, including PI–LL mismatch, and patient-reported outcomes. The intent was to determine whether radiographic restoration of sagittal relationships parallels meaningful clinical recovery after decompression. We also sought to record perioperative complications, level-wise decompression details and the need for further intervention, to inform patient selection and counselling for decompression without routine fusion across enrolled patients to 18 months.
Materials and methods
This single-centre prospective study enrolled consecutive patients between October 2019 and December 2021 who met predefined inclusion criteria: age 40 years or older, symptomatic degenerative lumbar canal stenosis and planned posterior decompression at one to four levels. Exclusion criteria included grade ≥2 spondylolisthesis, prior lumbar fusion, infection, tumor, traumatic stenosis and inability to complete outcome scoring. Institutional ethical clearance and informed consent were obtained. Baseline assessment comprised a structured history, neurological examination and patient-reported outcome measures—Visual Analogue Scale for back and leg pain, Oswestry Disability Index and Short Form-36. Imaging included standing anteroposterior and lateral lumbar radiographs that included the femoral heads for accurate pelvic parameter measurement and MRI to localise levels of neural compression. Spinopelvic angles were measured using standard geometric definitions (PI = PT + SS; lumbar lordosis by Cobb angle from L1 to S1). Surgical procedures—open laminectomy, laminotomy or unilateral over-the-top bilateral decompression—were selected according to pathology and surgeon judgement with the aim of adequate neural decompression while preserving posterior supporting structures when feasible [16,17]. Perioperative care consisted of routine antibiotic prophylaxis, thromboprophylaxis where indicated, early ambulation and a structured physiotherapy pathway. Complications were recorded prospectively. Follow-up assessments, including PROMs and repeat standing radiographs, were performed at 18 months. Level-wise decompression, operative time, estimated blood loss and perioperative complications were documented. Missing data were handled and sensitivity analyses evaluated their effect on primary outcomes. Statistical comparisons used paired tests for preoperative and postoperative measures and Spearman correlation to explore relationships between radiographic change and patient-reported outcomes.
Review of literature
Lumbar canal stenosis is a common degenerative spinal disorder whose prevalence rises with age and that represents a frequent cause of chronic low back pain and walking limitation in older adults [1]. Pathology commonly reflects a combination of intervertebral disc height loss, facet joint arthropathy, osteophyte formation and ligamentum flavum hypertrophy that together narrow the central canal, lateral recesses and foramina producing neurogenic claudication and radicular symptoms [2, 3]. Historical descriptions linked nerve compression to leg symptoms and surgical pioneers developed decompressive operations aimed at relieving neural compromise while attempting to preserve spinal stability [4]. Contemporary surgical options range from wide open laminectomy to targeted laminotomy, unilateral over-the-top decompression and minimally invasive fenestration, with muscle-sparing approaches advocated to reduce soft-tissue trauma and accelerate recovery [5, 6]. Randomized and cohort studies generally show significant and durable symptom relief after decompression, though perioperative morbidity and recovery profiles vary by technique and patient factors. Less invasive techniques tend to reduce blood loss and hospital stay while producing comparable short-term patient-reported outcome measure gains. Systematic reviews emphasise that decompression reliably lessens pain and disability, but controversies persist about when to add fusion—particularly in the presence of low-grade spondylolisthesis [7].
Biomechanical models and clinical series highlight spinopelvic morphology as an important aspect of adult spinal mechanics. Pelvic incidence is a fixed anatomical parameter that influences the magnitude of lumbar lordosis required for balanced posture, while pelvic tilt and sacral slope reflect compensatory pelvic rotation [8]. Observational reports indicate that pain-driven flexed posture may partially reverse after decompression, allowing modest increases in lumbar lordosis and reductions in PI–LL mismatch when preoperative flexion is dynamic rather than structural [9,10]. Other studies caution that degenerative loss of lordosis due to disc collapse and chronic muscular atrophy may be less amenable to change without instrumented realignment, emphasising the need to distinguish reversible pain-adaptive postures from fixed deformity when planning surgery [11]. Outcome assessment has moved toward validated patient-reported outcome measures—Visual Analogue Scale, Oswestry Disability Index and Short Form-36—which capture pain, function and general health and facilitate comparison across series [12]. Finally, reported complications of decompression are well described and include dural tear, infection and rare progression to instability; most series report low rates manageable with standard techniques and targeted rehabilitation [13].
Results
One hundred and forty consecutive patients were included (86 males, 54 females) with a mean age of 57.7 years (range 28–81) and mean BMI 26.4 kg/m². Distribution of decompressed levels was single level 43.6%, two levels 33.6%, three levels 18.6% and four levels 4.3%. Mean symptom duration was 17.9 months, and 70.4% of patients reported claudication within 100 metres of walking. Comorbidities included hypertension and diabetes in a substantial subset.
Functional outcomes improved markedly. Median preoperative VAS was 7 for back pain and 9 for leg pain; median VAS fell to 4 immediately postoperatively and to 1 at 18 months for both domains. Mean ODI decreased from 58.1 preoperatively to 36.5 early after surgery and to 20.9 at final follow up. SF-36 domain scores rose across physical function, pain and general health, with the overall median SF-36 rising from 42.1 to 78.1 (p < 0.001).
Radiographic analysis available for 112 patients showed a modest increase in lumbar lordosis (median 44.31° pre-op to 48.06° at 18 months) and a reduction in PI–LL mismatch (median 1.81° to –0.07°, p = 0.008). Complications included six intraoperative dural tears and one spondylodiscitis requiring reoperation; most complications were managed without long-term adverse effect. No deaths.
Discussion
This prospective cohort demonstrates that posterior decompression reliably reduces leg and back pain and improves function in patients with degenerative lumbar canal stenosis. Most patients had marked early benefits that were sustained at 18 months, reflected in large falls in VAS and ODI and gains in SF-36 [5, 7, and 18]. On imaging we found modest but consistent increases in lumbar lordosis and reductions in PI–LL mismatch at the group level. This pattern likely reflects reversal of a pain-avoidant, flexed posture rather than true structural realignment, since many patients assume a guarded stance to lessen neural tension. Relief of neural compression removes nociceptive drivers and allows functional gains even in the absence of large radiographic shifts [9, 11].
Several reports of non-instrumented decompression describe clinical benefit with only modest alignment change, underscoring that sagittal parameters are one piece of a multifactorial outcome picture [4, 6]. We included patients treated with varied decompression techniques, including chimney sublaminar approaches described by Lin and colleagues, which can achieve neural release while conserving posterior elements [19]. Complications were uncommon; dural tears were repaired intraoperatively and one deep infection required reoperation, but most adverse events were managed without lasting functional loss. These results highlight the importance of meticulous technique, prompt recognition and treatment of complications, and a structured rehabilitation pathway to consolidate gains [13, 20].
Limitations temper the strength of our conclusions. This single-centre series used heterogeneous operative approaches and experienced some loss to follow up, which may introduce selection effects and limit generalizability. Only a subset had complete radiographic datasets, reducing power for subgroup analyses and making it difficult to define which baseline spinopelvic profiles predict radiographic or clinical trajectories. Future studies stratifying PI, spondylolisthesis and preoperative lordosis will better guide fusion decisions [8, 20].
Conclusion
Posterior lumbar decompression in patients with degenerative lumbar canal stenosis produces substantial and sustained reductions in back and leg pain and meaningful improvements in disability and overall health-related quality of life. Modest group-level increases in lumbar lordosis and reductions in PI–LL mismatch may occur after surgery, but these radiographic shifts did not reliably predict the extent of symptomatic recovery in this cohort. Therefore, while spinopelvic assessment offers valuable anatomical context for surgical planning, restoration of sagittal parameters should not be viewed as a prerequisite for clinical benefit following neural decompression. Emphasis should remain on careful patient selection, meticulous decompressive technique, standardised perioperative care and structured rehabilitation to optimize outcomes. Longer-term and subgroup analyses are needed to determine whether particular patients derive additional advantage from alignment restoration or fusion procedures. Shared decision-making that explains expected symptomatic improvement and the uncertain role of radiographic change will aid personalized care planning over time.
References
1. Ferguson SA, Merryweather A, Thiese MS, Hegmann KT, Lu ML, Kapellusch JM, et al. Prevalence of low back pain, seeking medical care, and lost time due to low back pain among manual material handling workers in the United States. BMC Musculoskelet Disord. 2019; 20(1):1–8.
2. Magras I, Athanasiou A, Magra V. Lumbar spinal stenosis. Spine Surg A Case-Based Approach. 2019; 77–80.
3. Botwin KP, Gruber RD. Lumbar spinal stenosis: Anatomy and pathogenesis. Phys Med Rehabil Clin N Am. 2003; 14(1):1–15.
4. Divi SN, Goyal DKC, Bowles DR, Mujica VE, Guzek R, Kaye ID, et al. How do spinopelvic parameters influence patient-reported outcome measurements after lumbar decompression? Spine J. 2020; 20(10):1610–7.
5. Hatakka J, Pernaa K, Rantakokko J, Laaksonen I, Saltychev M. Effect of lumbar laminectomy on spinal sagittal alignment: a systematic review. Eur Spine J. 2021; 30(9):2413–26.
6. Shin EK, Kim CH, Chung CK, Choi Y, Yim D, Jung W, et al. Sagittal imbalance in patients with lumbar spinal stenosis and outcomes after simple decompression surgery. Spine J. 2017; 17(2):175–82.
7. Haro H, Maekawa S, Hamada Y. Prospective analysis of clinical evaluation and self-assessment by patients after decompression surgery for degenerative lumbar canal stenosis. Spine J. 2008; 8(2):380–4.
8. Ghobrial GM, Al-Saiegh F, Heller J. Spinopelvic Balance. Oper Tech Spine Surg. 2018; 2(8):281–7.
9. Anna I, Gemma V-C, David C, Augusto C, Enric C, Ana Garcia DF, et al. Lumbar lordosis in patients undergoing non-instrumented spinal stenosis. Int J Spine Res. 2021; 3:004–10.
10. Liang C, Sun J, Cui X, Jiang Z, Zhang W, Li T. Spinal sagittal imbalance in patients with lumbar disc herniation: Its spinopelvic characteristics, strength changes of the spinal musculature and natural history after lumbar discectomy. BMC Musculoskelet Disord. 2016; 17(1):1–8.
11. Jeon CH, Lee HD, Lee YS, Seo HS, Chung NS. Change in Sagittal Profiles after Decompressive Laminectomy in Patients with Lumbar Spinal Canal Stenosis: A 2-Year Preliminary Report. Spine. 2015; 40(5):E279–85.
12. Kirkaldy-Willis C. The three-joint complex and degeneration. (Referenced in thesis). 1961/1978.
13. Ashley P. Of Neurosurgery. 1986; 3–36.
14. Genevay S, Atlas SJ. Lumbar Spinal Stenosis. Best Pract Res Clin Rheumatol. 2010; 24(2):253–65.
15. Postacchini F. Management of lumbar spinal stenosis. J Bone Joint Surg Br. 1996; 78(1):154–64.
16. Shenouda EF, Gill SS, Laing R, Johnston R. Laminal fenestration for the treatment of lumbar nerve root foraminal stenosis. Br J Neurosurg. 2002; 16(5):494–6.
17. Sengupta DK, Herkowitz HN. Lumbar spinal stenosis: Treatment strategies and indications for surgery. Orthop Clin North Am. 2003; 34(2):281–95.
18. Watanabe K, Hosoya T, Shiraishi T, Matsumoto M, Chiba K, Toyama Y. Lumbar spinous process-splitting laminectomy for lumbar canal stenosis. J Neurosurg Spine. 2005; 3(5):405–8.
19. Lin SM, Tseng SH, Yang JC, Tu CC. Chimney sublaminar decompression for degenerative lumbar spinal stenosis. J Neurosurg Spine. 2006; 4(5):359–64.
20. Benz RJ, Garfin SR. Current techniques of decompression of the lumbar spine. Clin Orthop Relat Res. 2001; 384:75–81.
| How to Cite this Article: Jaiswal R, Hadgaonkar S, Kothari A, Aiyer S, Bhilare P, Sonawane D, Shyam A, Sancheti P. Non-Instrumented Posterior Decompression: Correlation between Radiological parameters and functional outcomes. Journal of Medical Thesis. 2025 July-December; 11(2):22-25. |
Institute Where Research was Conducted: Department of Orthopaedics, Sancheti Institute of Orthopaedics and Rehabilitation, Shivajinagar, Pune, Maharashtra, India.
University Affiliation: MUHS, Nashik, Maharashtra, India.
Year of Acceptance of Thesis: 2022
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The Spinopelvic Alignment Hypothesis: Does Optimal PI–LL and PT Restoration Drive Better Patient-Reported Outcomes after Laminectomy?
Vol 11 | Issue 2 | July-December 2025 | page: 3-6 | Rahul Jaiswal, Shailesh Hadgaonkar, Ajay Kothari, Siddharth Aiyer, Pramod Bhilare, Darshan Sonawane, Ashok Shyam, Parag Sancheti
https://doi.org/10.13107/jmt.2025.v11.i02.258
Author: Rahul Jaiswal [1], Shailesh Hadgaonkar [1], Ajay Kothari [1], Siddharth Aiyer [1], Pramod Bhilare [1], Darshan Sonawane [1], Ashok Shyam [1], Parag Sancheti [1]
[1] Sancheti Institute of Orthopaedics and Rehabilitation PG College, Shivaji- nagar, Pune, Maharashtra, India.
Address of Correspondence
Dr. Rahul Jaiswal,
Sancheti Institute of Orthopaedics and Rehabilitation PG College, Shivajinagar, Pune, Maharashtra, India.
E-mail: rj199116@gmail.com
Abstract
Background: Lumbar canal stenosis commonly causes leg pain, numbness and reduced walking distance in middle-aged and older adults. Degenerative loss of disc height, enlargement of facet joints and thickening of the ligamentum flavum narrow the spinal canal, compressing nerve roots and producing neurogenic claudication and disability. Conservative care—physiotherapy, medications and epidural injections—helps many patients, yet persistent symptomatic stenosis often requires surgical decompression to relieve nerve compression and restore walking tolerance and independence.
Hypothesis: The study proposes that decompression alone, applied to patients with degenerative lumbar canal stenosis and Grade I spondylolisthesis without clear instability, will yield meaningful and sustained reductions in leg and back pain and substantial improvement in daily function and overall health. It further proposes that measurable restoration of lumbar lordosis and pelvic alignment will be modest for most patients, and that symptomatic recovery will depend chiefly on relief of neural compression and reversal of pain-driven antalgic posture rather than on large radiographic corrections.
Clinical importance: If these expectations are met, a decompression-first strategy supports a less invasive pathway for most patients who lack objective instability, avoiding the additional morbidity of fusion while delivering reliable symptom relief. Emphasis on validated patient-reported outcomes—pain scores, the Oswestry Disability Index and general health measures—keeps decision-making focused on what matters to patients: reduced pain, improved mobility and better quality of life. Counseling should set realistic expectations about likely functional gains and the limited degree of radiographic change to be expected after decompression alone.
Future research: Randomized, multicentre trials comparing decompression alone with decompression plus fusion in patients who have borderline sagittal parameters are needed to define radiographic thresholds that justify fusion. Longer follow-up and objective measures—quantitative assessment of paraspinal muscle quality and gait analysis—will help predict who benefits most from fusion versus decompression alone. This study reports prospective medium-term outcomes using validated measures and standardized standing radiographs to examine the link between symptom relief and sagittal alignment. Findings aim to guide practical surgical decisions for everyday spine care. Durable outcomes.
Keywords: Lumbar canal stenosis, Decompression, Lumbar lordosis, Spinopelvic parameters, Oswestry Disability Index, Neurogenic claudication
Background
Lumbar canal stenosis is a common degenerative condition of the lower spine that produces leg pain, numbness and progressive difficulty with walking. Over time, loss of disc height, enlargement of the facet joints, osteophyte formation and thickening of the ligamentum flavum narrow the spinal canal and compress nerve roots. Patients typically report leg symptoms that worsen with standing and walking and ease with sitting or forward flexion; back pain often coexists but the dominant complaint is usually reduced walking tolerance and functional decline. [1–4]
Initial care is conservative: physiotherapy, analgesics, activity modification and epidural injections can relieve symptoms for many patients. When symptoms persist or progressive neurological deficit develops despite nonoperative care, surgery is considered. The surgical aim is straightforward — remove the compressive elements to free the nerves, reduce pain, and restore walking ability and day-to-day function. Traditional open laminectomy achieves reliable decompression but may injure paraspinal muscles or destabilize the posterior elements in some patients. Over the years, muscle-sparing laminotomies and other less invasive decompressive techniques have been developed to lower soft-tissue trauma while preserving the neural benefit. [5–9]
Beyond nerve decompression, modern practice considers spinal balance. Spinopelvic parameters — pelvic incidence, pelvic tilt, sacral slope and lumbar lordosis — describe how the spine and pelvis align in the sagittal plane and influence load distribution and long-term mechanical pain. In degenerative disease, patients commonly adopt a flexed, antalgic posture; relief of pain may permit a more erect stance and a measurable increase in lumbar lordosis. However, true structural correction depends on reversing degenerative disc collapse, facet arthropathy and muscle degeneration — changes that often cannot be corrected solely by decompression. Reported effects of decompression on sagittal metrics therefore vary: some series show modest improvement in lordosis, whereas others find little change. [10–13]
This uncertainty has important clinical consequences. For patients with clear instability or marked deformity, fusion with realignment may be necessary. For the majority with symptomatic stenosis and at most low-grade spondylolisthesis, the question is whether decompression alone will deliver the functional recovery they need without the added morbidity of fusion. Large cohort studies and randomized trials have demonstrated that decompression reliably reduces leg pain and improves disability and quality of life for many such patients, though a subset will later require fusion for mechanical symptoms or progression. [14, 15, 21]
Measuring both patient-reported outcomes (pain scores, Oswestry Disability Index, general health measures such as SF-36) and standing spinopelvic radiographs before and after surgery provides practical information. It shows whether symptom relief aligns with measurable changes in sagittal balance, and it helps surgeons decide when radiographic findings should push them toward fusion rather than decompression alone. The present work reports a prospective series that tracked validated clinical scores and standardized standing radiographs in patients undergoing lumbar decompression, with the aim of clarifying the relationship between symptomatic recovery and radiographic alignment. [16–20]
Hypothesis
Two linked hypotheses guided the study.
First, in patients with degenerative lumbar canal stenosis — including those with Grade I spondylolisthesis but without clear mechanical instability — decompression alone will produce substantial and sustained reductions in leg and back pain, plus meaningful improvement in disability and overall health. Relief of direct neural compression reduces ongoing nociception and venous congestion of the nerve roots, allowing functional recovery and improved walking tolerance. Previous prospective studies support the expectation that decompression yields clinically important gains on VAS, ODI and general health measures. [7, 14, 15]
Second, measurable restoration of sagittal alignment after decompression will be modest for most patients and will not be essential for clinical recovery. Pain-driven forward-flexed posture and posterior pelvic tilt commonly accompany stenosis; when pain subsides, a degree of postural correction may occur, producing small increases in lumbar lordosis. Yet long-standing structural degeneration — disc height loss, facet arthropathy and fatty change of the paraspinal musculature — limits large or durable radiographic correction without reconstructive measures. Several reports document inconsistent changes in pelvic parameters after decompression, suggesting that functional recovery often occurs even in the absence of major alignment change. [10–13, 16–18]
To test these hypotheses, the study enrolled consecutive, eligible patients who met predefined inclusion criteria (symptomatic degenerative lumbar canal stenosis, age threshold, instability up to Grade I) and excluded those with higher-grade slips, prior fusion, infection or tumour. Each patient underwent decompression appropriate to the pathology (laminotomy, laminectomy or muscle-preserving techniques). Outcome assessment combined validated PROMs — VAS for back and leg pain, ODI for disability, and SF-36 for health-related quality of life — with standardized standing lateral radiographs that included the femoral heads to permit accurate measurement of pelvic incidence, pelvic tilt, sacral slope and lumbar lordosis. [20–22]
Follow-up extended to the medium term and compared baseline and postoperative PROMs and radiographic metrics. The core analytic questions were: how large are the clinical gains after decompression, do spinopelvic parameters change meaningfully, and are radiographic changes correlated with improvements in pain and function? The practical intent was to determine whether decompression-first remains the sound initial strategy for most patients without objective instability, reserving fusion for those with evidence of structural deformity or persistent mechanical symptoms. [21–25]
Discussion
The study observed consistent and clinically meaningful improvement in symptoms and function after lumbar decompression. Patients reported substantial drops in leg and back pain and marked reduction in disability scores; general health measures improved in parallel, reflecting greater mobility and daily independence. These clinical gains mirror those found in prior prospective cohorts and randomized studies that established decompression as the primary surgical treatment for symptomatic stenosis when instability is absent. [7, 14, 23]
On radiographs, changes in lumbar lordosis and pelvic parameters were generally modest. Some patients regained a measure of lordosis as pain relieved and antalgic posture resolved, but the cohort did not show large, uniform corrections of sagittal alignment. Importantly, the magnitude of radiographic change did not consistently predict the degree of functional recovery: many patients with little or no radiographic change experienced large symptomatic benefit, and conversely, radiographic improvement did not guarantee superior clinical outcomes. This dissociation underscores that relief of neural compression — not radiographic perfection — chiefly drives early to medium-term recovery after decompression. [10–12, 16–18]
Several considerations explain why radiographs and symptoms diverge. Decompression directly treats the proximate cause of neurogenic claudication, allowing nerve roots to recover function; this process improves pain and walking even when underlying degenerative deformity remains. Structural features such as disc collapse, facet joint arthropathy and paraspinal muscle atrophy restrict the scope for radiographic correction unless reconstructive procedures are performed. Measurement variability, heterogeneity in the number of levels decompressed, and patient factors (obesity, sarcopenia, and hip or knee compensation) further blur any simple relationship between angle changes and patient function. [11, 21, 22]
Clinically, the findings support a pragmatic approach. For patients whose principal problem is neurologic — leg pain and neurogenic claudication — and who lack clear dynamic instability or marked sagittal deformity, decompression alone is an appropriate initial strategy. It reduces operative morbidity compared with fusion while delivering predictable symptomatic relief. For patients whose predominant complaint is mechanical back pain linked to fixed sagittal imbalance, or those with high pelvic incidence–lumbar lordosis mismatch, fusion and alignment-restoring surgery should be considered to address the structural driver of pain and to prevent late progression. Thus, selection should integrate symptoms, objective instability assessment, radiographic measures and the patient’s functional goals. [23–25]
Limitations include single-centre design, potential selection bias, variability of surgical technique and medium-term rather than long-term follow-up. Radiographic measurement error and absence of quantitative paraspinal muscle assessment are additional constraints. Nonetheless, the results add to the body of evidence demonstrating that decompression alone provides meaningful symptom relief for the majority of appropriately selected patients and that substantial radiographic correction is not a necessary precondition for clinical benefit.
Clinical importance
Decompression without fusion reliably reduces leg pain, improves walking capacity and enhances quality of life in patients with degenerative lumbar canal stenosis and Grade I or absent spondylolisthesis when objective instability is not present. Prioritizing symptom-driven indications and validated patient-reported outcomes keeps decision-making focused on what matters to patients: less pain and better function. Fusion remains important for those with fixed deformity, progressive slip or predominant mechanical back pain, but for many patients a decompression-first pathway minimizes surgical risk while achieving the desired clinical goals. [21–24]
Future direction
Randomized, multicentre trials comparing decompression alone with decompression plus fusion in patients with borderline sagittal parameters are needed to define thresholds that justify adding fusion. Longer follow-up with objective measures — quantitative MRI of paraspinal muscles, gait analysis and standardized PROMs — will improve the ability to predict who will regain upright posture after decompression and who will progress to mechanical failure, enabling more precise, individualized surgical planning. [23–25]
References
1. Ferguson SA, Merryweather A, Thiese MS, Hegmann KT, Lu ML, Kapellusch JM, et al. Prevalence of low back pain, seeking medical care, and lost time due to low back pain among manual material handling workers in the United States. BMC Musculoskelet Disord. 2019; 20(1):1–8.
2. Magras I, Athanasiou A, Magra V. Lumbar spinal stenosis. Spine Surg A Case-Based Approach. 2019; 77–80.
3. Botwin KP, Gruber RD. Lumbar spinal stenosis: Anatomy and pathogenesis. Phys Med Rehabil Clin N Am. 2003; 14(1):1–15.
4. Divi SN, Goyal DKC, Bowles DR, Mujica VE, Guzek R, Kaye ID, et al. How do spinopelvic parameters influence patient-reported outcome measurements after lumbar decompression? Spine J. 2020; 20(10):1610–7.
5. Hatakka J, Pernaa K, Rantakokko J, Laaksonen I, Saltychev M. Effect of lumbar laminectomy on spinal sagittal alignment: a systematic review. Eur Spine J. 2021; 30(9):2413–26.
6. Shin EK, Kim CH, Chung CK, Choi Y, Yim D, Jung W, et al. Sagittal imbalance in patients with lumbar spinal stenosis and outcomes after simple decompression surgery. Spine J. 2017; 17(2):175–82.
7. Haro H, Maekawa S, Hamada Y. Prospective analysis of clinical evaluation and self-assessment by patients after decompression surgery for degenerative lumbar canal stenosis. Spine J. 2008; 8(2):380–4.
8. Ghobrial GM, Al-Saiegh F, Heller J. Spinopelvic Balance. Oper Tech Spine Surg. 2018; 2(8):281–7.
9. Anna I, Gemma V-C, David C, Augusto C, Enric C, Ana Garcia DF, et al. Lumbar lordosis in patients undergoing non-instrumented spinal stenosis. Int J Spine Res. 2021; 3:004–10.
10. Liang C, Sun J, Cui X, Jiang Z, Zhang W, Li T. Spinal sagittal imbalance in patients with lumbar disc herniation: Its spinopelvic characteristics, strength changes of the spinal musculature and natural history after lumbar discectomy. BMC Musculoskelet Disord. 2016; 17(1):1–8.
11. Jeon CH, Lee HD, Lee YS, Seo HS, Chung NS. Change in Sagittal Profiles after Decompressive Laminectomy in Patients with Lumbar Spinal Canal Stenosis: A 2-Year Preliminary Report. Spine. 2015; 40(5):E279–85.
12. Kirkaldy-Willis WH. The three-joint complex and the pathogenesis of backache. J Bone Joint Surg Br. 1982; 64-B: 178–86.
13. Ashley P. Historical perspectives in spinal surgery. J Neurosurg. 1985; 62:394–8.
14. Genevay S, Atlas SJ. Lumbar Spinal Stenosis. Best Pract Res Clin Rheumatol. 2010; 24(2):253–65.
15. Postacchini F. Management of lumbar spinal stenosis. J Bone Joint Surg Br. 1996; 78(1):154–64.
16. Shenouda EF, Gill SS, Laing R, Johnston R. Laminal fenestration for the treatment of lumbar nerve root foraminal stenosis. Br J Neurosurg. 2002; 16(5):494–6.
17. Sengupta DK, Herkowitz HN. Lumbar spinal stenosis: Treatment strategies and indications for surgery. Orthop Clin North Am. 2003; 34(2):281–95.
18. Watanabe K, Hosoya T, Shiraishi T, Matsumoto M, Chiba K, Toyama Y. Lumbar spinous process-splitting laminectomy for lumbar canal stenosis. J Neurosurg Spine. 2005; 3(5):405–8.
19. Lin SM, Tseng SH, Yang JC, Tu CC. Chimney sublaminar decompression for degenerative lumbar spinal stenosis. J Neurosurg Spine. 2006; 4(5):359–64.
20. Benz RJ, Garfin SR. Current techniques of decompression of the lumbar spine. Clin Orthop Relat Res. 2001; 384:75–81.
21. Elder BD, Witham TF. Low Back Pain and Spondylosis. Semin Neurol. 2016; 36(5):456–61.
22. Ills A W, Olivieri S. Aging and musculoskeletal function. Aging Ment Health. 1998; 2:344–8.
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| How to Cite this Article: Jaiswal R, Hadgaonkar S, Kothari A, Aiyer S, Bhilare P, Sonawane D, Shyam A, Sancheti P. The Spinopelvic Alignment Hypothesis: Does Optimal PI–LL and PT Restoration Drive Better Patient-Reported Outcomes after Laminectomy?. Journal of Medical Thesis. 2025 July-December; 11(2):3-6. |
Institute Where Research was Conducted: Department of Orthopaedics, Sancheti Institute of Orthopaedics and Rehabilitation, Shivajinagar, Pune, Maharashtra, India.
University Affiliation: MUHS, Nashik, Maharashtra, India.
Year of Acceptance of Thesis: 2022
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