Spondylolysis and Spondylolisthesis in Athletes

• Abstract
• Introduction
• Epidemiology
• Clinical Diagnosis
• Imaging
• Classifications
• Risk Factors
• Treatment
• Complications
• Final Considerations
• Referencias

Abstract

This article is an update on spondylolysis and spondylolisthesis in athletes, from diagnosis to treatment, based on our service experience and a literature review.

Introduction

Spondylolysis is a lytic lesion in the posterior vertebral arch affecting mostly the pars interarticularis of L5; it can be unilateral or bilateral ([Fig. 1]).[1] Since spondylolysis relates to the repetition of sporting gestures, especially under flexion-extension and trunk rotation movements, it is also considered a stress fracture.[2] Therefore, spondylolysis must be the leading initial diagnostic hypothesis in athletes with low back pain.[3] Moreover, there is an unknown but relevant percentage of asymptomatic athletes with this type of injury.[4] Spondylolisthesis consists of an anterior vertebral slippage to the distal segment. In the presence of pars lysis (spondylolysis), spondylolisthesis is a type 2a injury according to the modified Wiltse etiological classification.[5] The incidence of low back pain in athletes is high, reaching 86% per the literature; in addition, its association with spondylolysis in up to 60% of the cases demonstrates the need for an exact understanding of the natural history of this condition.[6]

Epidemiology

Nearly 93% of cases of spondylolysis are associated with sports practice.[7] Its incidence in the general population is 6%. About 75% of the subjects will progress to some degree of anterior slippage, i.e., spondylolisthesis.[8] Considering each modality separately, the impact sports most practiced in developed countries have the following incidences of spondylolysis: up to 44% in hockey players,[9] of which 15.9% also have listhesis,[10] 40% in tennis players,[11] up to 40% in diving athletes,[9] 20.69% in volleyball players,[12] and up to about 50% in cricket, rugby, and American football players.[13] [14] [15] [16]

Clinical Diagnosis

Spondylolysis must be the leading diagnostic hypothesis in young athletes with low back pain until proven otherwise.[17] Any complaint lasting longer than two weeks warrants investigation. A detailed history, ruling out macrotrauma and previous injuries and including personal and family history, is essential. The most relevant information is a change in the training pattern (migration to a new sport modality, change in the amount/quality of exercise, loading increase to improve performance, etc.).[18] The next step must be a detailed physical examination. With the patient wearing swimming trunks (and preferably accompanied by someone else or a nurse), carry out the following: a) a static inspection, with an observation from all angles (front, back, and sides), to identify potential deformities (accentuated or diminished kyphosis or lordosis, scoliosis), asymmetries, and shoulder and pelvic tilts; and b) a dynamic inspection, observing gait and spine segment mobility during smooth flexion, extension, and rotation, completing the postural evaluation. Note that flexion and trunk extension can vary from +- 45 degrees;[19] also check hip movements. Proceed to palpation with the patient lying prone on a stretcher to identify any pain, muscle hypertonia, and anatomical points, including spinous processes, iliac wings, and beginning of sacroiliac joints (pain in this region indicates a positive Finger test).[20] Next, perform a neurological assessment; although spondylolysis barely affects the neurological function, this evaluation must always occur to determine the sensorimotor picture of the lower lumbar roots, namely: a) L4: medial dermatome of the leg and foot and tibialis anterior muscle; b) L5: lateral dermatome of the leg and dorsal foot and extensor hallucis longus muscle; c) S1: lateral dermatome of the foot and peroneus longus and brevis muscles - grade the motor strength in a scale from 0 (no strength) to 5 (normal strength). Also, test patellar (L4) and calcaneal (S1) tendon reflexes.[21] Special maneuvers include root irritation screening, such as the extended leg and Lasègue tests, and hip/sacroiliac maneuvers, such as the Patrick-Fabere, Gaeslen, and Finger tests. Jackson described trunk hyperextension with unipodal support as pathognomonic of spondylolysis; although contested in recent articles, this test remains the only one specific for this lesion.[22] [23]

Imaging

Radiography reveals a radiolucent lesion in the pars interarticularis at the level investigated in collimated lateral and oblique views (the so-called “Scotty dog” sign) with a 97% accuracy for chronic spondylolysis (post-edema with an established fracture) ([Figs. 1c] and [1d]).[24] Healing lesions present the typical sclerosis of bone callus in the anteroposterior view.[25] Lateral radiographs under maximal extension and flexion may indicate instabilities resulting from the increased slippage in the anterior direction (spondylolisthesis) greater than 4 mm or a tilt higher than 10 degrees between adjacent plateaus.[26]

Computed tomography (CT) is still the best test to study complete or incomplete lesions with bone continuity for precise anatomical visualization. As such, CT is often requested for the preoperative planning of cases refractory to conservative treatment ([Fig. 1a]). The reverse gantry angle technique ([Fig. 1b]) provides a faithful image of the lesion and differentiates it from the joint facet (double facet sign).[27] CT reveals small, sclerotic, and hypertrophic reactions related to lesion evolution and differential diagnoses, such as osteoid osteoma. However, CT may be most valuable for postoperative consolidation follow-up.[28]

The great advantage of magnetic resonance imaging (MRI) over CT is lesion detection at an early stage, i.e., identifying a medullary edema with no bone continuity loss in the pars. In the past, MRI accuracy was deemed insufficient for a safe spondylolysis diagnosis; this belief has been discredited due to the evolution of image acquisition techniques culminating in a specific classification.[29] Another obvious advantage of MRI is that it does not require radiation, unlike CT, avoiding its potentially undesirable effects. MRI is also the most effective way to point out foraminal stenoses, discopathies, and radicular anatomical changes; it may even detect neural tumors ([Fig. 4a]).[30]

Although not part of our routine, bone scintigraphy can differentiate acute from chronic lesions,[31] like MRI.

On the other hand, single-photon emission computed tomography-computed tomography (SPECT-CT) is more accurate than other tests[32] both for diagnosis and for anatomical location as it allows the differentiation of chronic (“cold”) and acute (“hot”) lesions. Due to SPECT-CT's high cost and radiation issues, we use it only when MRI does not clarify the diagnostic hypothesis ([Fig. 2a]).

Classifications

MRI is the base for the most accepted spondylolysis classification. In this classification, MRI findings generate the following five groups: type 0 (no alterations), type 1 (edema with no cortical rupture), type 2 (bone irregularity demonstrating incomplete pars lesion), type 3 (acute lesion), and type 4 (chronic lesion).[29]

At first treated as a local alteration, spondylolysis with spondylolisthesis was next evaluated with pelvic balance, then the entire spine, and finally, as a global alteration. This assessment allows the observation of compensatory knee flexion even in milder cases.[33]

The traditional classifications for spondylolisthesis include the modified Wiltse classification, which is etiological. Type II refers to spondylolytic listhesis, and it consists of subtypes A (pars lysis, the most frequent spondylolytic listhesis in athletes), B (elongated pars), and C (traumatic injury). Meyerding[34] described another classification system based on the percentage of slippage (no slippage; up to 25% slippage; 25 to 50% slippage; 50 to 75% slippage; 75 to 100% slippage; and spondyloptosis, i.e., total slippage).

The Spinal Deformity Study Group (SDSG) classification for spondylolisthesis in L5-S1 (the most commonly affected level) considers the sacropelvic orientation.

Lateral radiographs evaluate the overall sagittal balance using the three following parameters: slippage degree, pelvic tilt, and spinopelvic alignment. These radiographs identify six injury types with progressive severity; the first three are low-grade lesions, the most common in athletes. This classification guides the surgical approach according to the need to restore the sagittal parameters.[35] In addition, an algorithm differentiates spondylolysis from acute nonspecific low back pain. The authors described the difficulty of finding lesion-specific clinical signs and their differentiation from nonspecific low back pain in imaging tests, such as radiography, which also does not have acceptable diagnostic accuracy. Therefore, diagnosis requires more complex, expensive tests, like CT and MRI.

Risk Factors

The following intrinsic variables are associated with a greater risk of spondylolysis: male gender, occult spina bifida,[36] [37] increased lordosis and pelvic tilt,[38] hamstring muscles shortening, and an imbalance of the anterior and posterior muscles that stabilize the trunk.[39] We also understand that the amount and quality of exercise are extrinsic determinant factors for this type of injury.[2] [40]

Treatment

Most cases respond well to conservative treatment, which consists of relative rest and rehabilitation with physical therapy.[41] We do not recommend braces in our routine for two reasons. First, braces result in disuse atrophy of the trunk-stabilizing paravertebral muscles; second, they do not respect the immobilization principle, i.e., blocking the range of motion in a proximal and a distal joint, since these orthoses do not act on the hips.[17] The plaster cast of Risser-Cotrel[42] provides hip blocking, but it is in total disuse due to the discomfort to the patient. Surgical treatment is reserved for cases with no improvement after at least six months of conservative treatment. Some authors recommended infiltration in the pars defect area to confirm the pain origin.[43] The first surgical procedure proposed for this type of lesion was non-instrumented in situ arthrodesis with a posterolateral graft.[44] Subsequently, scientific evidence indicated that the associated instrumentation significantly increased the fusion success rate, which was even higher with the inclusion of the three columns, i.e., 360-degree arthrodesis, either by a posterior route alone or combined with an anterior approach. We believe arthrodesis is not the optimal treatment due to medium-term loss of range of motion and adjacent degeneration, which are even more likely in athletes.[45] Here CA, are two techniques for direct pars repair with no arthrodesis and placing an autologous graft in the defect area ([Fig. 3]).[46] [47] [48] [49] [50] This is our technique of choice in most cases, especially when the disc at the involved level presents no degeneration, a common finding in young athletes with a recent injury. This procedure has very satisfactory outcomes, with around 90% of the patients returning to the pre-injury sporting. Using intraoperative CT and neuronavigation allows a percutaneous approach; we believe that simplifying the procedure will change the protocol, shortening the time of conservative treatment and increasing surgical fixation indications ([Fig. 2]).[17]

Moreover, it is possible to use an endoscopic technique for curettage and graft placement in the pars gap for percutaneous fixation, increasing the lesion consolidation rate and making the procedure minimally invasive. For cases of spondylolisthesis higher than grade I (more than 25% of slippage), advanced disc disease, or significant associated instability, we consider 360-degree arthrodesis with the placement of a spacer via the anterior approach (ALIF). Alternatively, we contemplate the posterior endoscopic approach using the Endoscopic Spinal Stabilization technique with EndoLIF® ([Fig. 4]) complemented with percutaneous screws via the posterior approach. However, fusion has disadvantages, as already mentioned. Another option is a temporary reduction with pedicle screws with no arthrodesis (no posterolateral graft placement or facet opening), followed by synthesis material removal ([Fig. 5]). The advantage of this technique is the lack of arthrodesis, but there is a risk of synthesis material breakage during consolidation of the pars interarticular failure.

Complications

There are reports of immediate postoperative complications, including local infection, pain in the bone graft donor region, and synthesis material breakage, but at an extremely low rate (p = 0.011).[51]

Final Considerations

All low back pain cases for more than two weeks in young athletes must be considered a stress fracture until proven otherwise. Lumbar spondylolysis in athletes results from local overload during the repetitive effort of high-performance training. In young subjects, it may also occur with anterior slippage and spondylolytic spondylolisthesis. The prognosis is associated with early diagnosis and termination of impact activities. Lesion identification through imaging tests is paramount, and MRI seems to be the test of choice after negative radiographs. Doubtful cases may benefit from scintigraphy and SPECT-CT, when available. CT is reserved for chronic cases refractory to conservative treatment during surgical planning or follow-up to confirm consolidation. Conservative treatment is enough in the absolute majority of cases. However, surgical indications may be more frequent in professional athletes due to the long time away from sports.

Conflito de Interesses

Os autores não têm conflito de interesses a declarar.

Work developed at the Department of Orthopedics and Traumatology, Faculty of Medical Sciences of Santa Casa de São Paulo, São Paulo, SP, Brazil.

• Referencias

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Publikationsverlauf

Eingereicht: 23. April 2023

Angenommen: 29. Mai 2023

Artikel online veröffentlicht:
21. März 2024

© 2024. The Author(s). This is an open access article published by Thieme under the terms of the Creative Commons Attribution 4.0 International License, permitting copying and reproduction so long as the original work is given appropriate credit (https://creativecommons.org/licenses/by/4.0/)

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• Referencias

• 1 Berger RG, Doyle SM. Spondylolysis 2019 update. Curr Opin Pediatr 2019; 31 (01) 61-68
  CrossrefPubMedGoogle Scholar
• 2 Chung CC, Shimer AL. Lumbosacral Spondylolysis and Spondylolisthesis. Clin Sports Med 2021; 40 (03) 471-490
  CrossrefPubMedGoogle Scholar
• 3 Wiltse LL, Widell Jr EH, Jackson DW. Fatigue fracture: the basic lesion is inthmic spondylolisthesis. J Bone Joint Surg Am 1975; 57 (01) 17-22
  CrossrefPubMedGoogle Scholar
• 4 Gagnet P, Kern K, Andrews K, Elgafy H, Ebraheim N. Spondylolysis and spondylolisthesis: A review of the literature. J Orthop 2018; 15 (02) 404-407
  CrossrefPubMedGoogle Scholar
• 5 Wiltse LL, Newman PH, Macnab I. Classification of spondylolisis and spondylolisthesis. Clin Orthop Relat Res 1976; (117) 23-29
  PubMedGoogle Scholar
• 6 De Lima MV, Duarte Júnior A, Jorge PB, Bryk FF, Meves R, Avanzi O. Frequency of spondylolysis and chronic low back pain in young soccer players. Coluna/Columna 2014; 13 (02) 120-123
  CrossrefGoogle Scholar
• 7 Sakai T, Goda Y, Tezuka F. et al. Characteristics of lumbar spondylolysis in elementary school age children. Eur Spine J 2016; 25 (02) 602-606
  CrossrefPubMedGoogle Scholar
• 8 Fredrickson BE, Baker D, McHolick WJ, Yuan HA, Lubicky JP. The natural history of spondylolysis and spondylolisthesis. J Bone Joint Surg Am 1984; 66 (05) 699-707
  CrossrefPubMedGoogle Scholar
• 9 Rossi F, Dragoni S. The prevalence of spondylolysis and spondylolisthesis in symptomatic elite athletes: radiographic findings. Radiography 2001; 7 (01) 37-42
  CrossrefGoogle Scholar
• 10 Sakai T, Sairyo K, Suzue N, Kosaka H, Yasui N. Incidence and etiology of lumbar spondylolysis: review of the literature. J Orthop Sci 2010; 15 (03) 281-288
  CrossrefPubMedGoogle Scholar
• 11 McAnany S, Patterson D, Hecht AC. Spine injuries in tennis players. In: Colvin AC, Gladstone JN. eds. The young tennis player: Injury prevention and treatment. Cham: Springer International Publishing;; 2016: 121-134
  Google Scholar
• 12 Külling FA, Florianz H, Reepschläger B, Gasser J, Jost B, Lajtai G. High prevalence of disc degeneration and spondylolysis in the lumbar spine of professional beach volleyball players. Orthop J Sports Med 2014; 2 (04) 2325967114528862
  CrossrefPubMedGoogle Scholar
• 13 Crewe H, Elliott B, Couanis G, Campbell A, Alderson J. The lumbar spine of the young cricket fast bowler: an MRI study. J Sci Med Sport 2012; 15 (03) 190-194
  CrossrefPubMedGoogle Scholar
• 14 Engstrom CM, Walker DG. Pars interarticularis stress lesions in the lumbar spine of cricket fast bowlers. Med Sci Sports Exerc 2007; 39 (01) 28-33
  CrossrefPubMedGoogle Scholar
• 15 Semon RL, Spengler D. Significance of lumbar spondylolysis in college football players. Spine 1981; 6 (02) 172-174
  CrossrefPubMedGoogle Scholar
• 16 Iwamoto J, Abe H, Tsukimura Y, Wakano K. Relationship between radiographic abnormalities of lumbar spine and incidence of low back pain in high school rugby players: a prospective study. Scand J Med Sci Sports 2005; 15 (03) 163-168
  CrossrefPubMedGoogle Scholar
• 17 Watkins RG. Lumbar spondylolysis and spondylolisthesis in athletes. Semin Spine Surg 2010; 22 (04) 210-217
  CrossrefGoogle Scholar
• 18 Kaeding CC, Miller T. The comprehensive description of stress fractures: a new classification system. J Bone Joint Surg Am 2013; 95 (13) 1214-1220
  CrossrefPubMedGoogle Scholar
• 19 Hebert SK, Barros Filho TEP, Xavier R, Pardini Júnior AG. Ortopedia e traumatologia: Principios e Prática. Porto Alegre:: Artmed; 2016
  Google Scholar
• 20 Murakami E, Aizawa T, Noguchi K, Kanno H, Okuno H, Uozumi H. Diagram specific to sacroiliac joint pain site indicated by one-finger test. J Orthop Sci 2008; 13 (06) 492-497
  CrossrefPubMedGoogle Scholar
• 21 Stanley H. Exame clinico musculoesqueletico. São Paulo: Manole; 2016
  Google Scholar
• 22 Jackson DW, Wiltse LL, Dingeman RD, Hayes M. Stress reactions involving the pars interarticularis in young athletes. Am J Sports Med 1981; 9 (05) 304-312
  CrossrefPubMedGoogle Scholar
• 23 Masci L, Pike J, Malara F, Phillips B, Bennell K, Brukner P. Use of the one-legged hyperextension test and magnetic resonance imaging in the diagnosis of active spondylolysis. Br J Sports Med 2006; 40 (11) 940-946 , discussion 946
  CrossrefPubMedGoogle Scholar
• 24 Amato M, Totty WG, Gilula LA. Spondylolysis of the lumbar spine: demonstration of defects and laminal fragmentation. Radiology 1984; 153 (03) 627-629
  CrossrefPubMedGoogle Scholar
• 25 Araki T, Harata S, Nakano K, Satoh T. Reactive sclerosis of the pedicle associated with contralateral spondylolysis. Spine 1992; 17 (11) 1424-1426
  CrossrefPubMedGoogle Scholar
• 26 Boden SD, Wiesel SW. Lumbosacral segmental motion in normal individuals. Have we been measuring instability properly?. Spine 1990; 15 (06) 571-576 [published correction appears in Spine 1991;16(7):855]
  CrossrefPubMedGoogle Scholar
• 27 Hession PR, Butt WP. Imaging of spondylolysis and spondylolisthesis. Eur Radiol 1996; 6 (03) 284-290
  CrossrefPubMedGoogle Scholar
• 28 Campbell RS, Grainger AJ, Hide IG, Papastefanou S, Greenough CG. Juvenile spondylolysis: a comparative analysis of CT, SPECT and MRI. Skeletal Radiol 2005; 34 (02) 63-73
  CrossrefPubMedGoogle Scholar
• 29 Hollenberg GM, Beattie PF, Meyers SP, Weinberg EP, Adams MJ. Stress reactions of the lumbar pars interarticularis: the development of a new MRI classification system. Spine 2002; 27 (02) 181-186
  CrossrefPubMedGoogle Scholar
• 30 Major NM, Helms CA, Richardson WJ. MR imaging of fibrocartilaginous masses arising on the margins of spondylolysis defects. AJR Am J Roentgenol 1999; 173 (03) 673-676
  CrossrefPubMedGoogle Scholar
• 31 Papanicolaou N, Wilkinson RH, Emans JB, Treves S, Micheli LJ. Bone scintigraphy and radiography in young athletes with low back pain. AJR Am J Roentgenol 1985; 145 (05) 1039-1044
  CrossrefPubMedGoogle Scholar
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