Spondylolysis – Update on Diagnosis & Management David W. Kruse, M.D. Orthopaedic Specialty Ins@tute Team Physician -‐ University of California, Irvine Team Physician & Medical Task Force Member -‐ USA Gymnas@cs
DISCLOSURE Neither I, David Kruse, nor any family member(s), have any relevant financial rela
Spondylolysis -‐ Update GOALS & OBJECTIVES 1. Review of Prevalence & Anatomy 2. Review/Update controversial aspects of spondylolysis: – Diagnos@c Imaging – Bracing
3. Review goals of rehabilita@on 4. Review return to play decision-‐making
(1,2,9,13,14,19) Introduc@on
• Unilateral or Bilateral Defect – Pars Interar@cularis • Pars Interar@cularis – junc@on of pedicle, ar@cular facets, lamina • Defect at L5 in 95% of cases • Prevalence – General Popula@on: 3-‐10% – Athle@c Popula@on: 23-‐63%
• Gymnas@cs, Football, Weight Li`ing, Rowing, Volleyball
• Adolescent Athletes:
– Most common cause of back pain(13,19)
Anatomy of a Pars Defect
PARS INTERARTICULARIS LAMINA
[www.eorthopod.com]
[Neder Photos]
(1,3,9,13) Pathophysiology • Mul@factorial – +/-‐ Pre-‐exis@ng Dysplasia – Repe@@ve Microtrauma • Hyperextension, Rota@on, Hyperlordosis
• Predisposing factors: – Hyperlordosis, Thoracic kyphosis – Iliopsoas inflexibility, Thoracolumbar fascial @ghtness – Abdominal weakness – Female athlete triad
• Bony Impingement – Pars of L5 sheared by Inferior ar@cular process L4 and superior ar@cular process S1
Pathophysiology • Other predisposing factors: – Hyperlordosis – Iliopsoas inflexibility – Thoracolumbar fascial @ghtness – Abdominal weakness – Thoracic kyphosis – Female athlete triad
• Bony Impingement – Pars of L5 sheared by Inferior ar@cular process L4 and superior ar@cular process S1
Anatomy of Bony Impingement
BONY IMPINGEMENT
(12,13,14,19,20,25) Clinical Presenta@on
• Three Classic Pa@ent Types:(13,25) 1. Female, Hyperlordo@c, Hypermobile 2. Male, Hypomobile/Inflexible, Tight paraspinal 3. New to a sport, decondi@oned, poor core
Clinical Presenta@on • Examina@on: – Hyperlordosis – Hamstring inflexibility – Pain on extension (add side-‐bending to affected side -‐ Kemp Test) – Lumbosacral tenderness and muscle spasm – Stork test: low specificity(14,20), low sensi@vity(19) – Various other func@onal/provoca@ve tests(19)
Clinical Exam Sundell, Int J Sports Med, 2013(19) • Prospec@ve Case Series – Ability of clinical tests to dis@nguish between causes of back pain • Subjects: – 25 in Case group: >3 weeks LBP, 13-‐20yo, 56% Male – 13 in Control group
• Methods: – Both groups: • Clinical exam protocol • All underwent MRI L-‐spine
– Case group: CT of L4/L5
(19) Sundell, Int J Sports Med, 2013
• Clinical Exam Protocol:
– Gait padern – Inspec@on – scoliosis, lordosis, LLD, etc. – Palpa@on – Neurological examina@on – Func@onal tes@ng – Mul@ple provoca@ve tests (Stork, Percussion, Spring, Coin, Hook/Rocking tests)
• Results:
– No clinical test, alone or in combina@on, could dis@nguish between spondy and other e@ologies
Spondylolysis -‐ Imaging
Leone Skeletal Radiol 2011
Imaging Controversy • Despite spondylolysis being a well recognized and published condi@on for decades...we s@ll don’t have a consensus on imaging…due to the pros and cons for each modality, radia@on exposure in adolescent spines, and growing technology helping MRI to poten@ally become a more sensi@ve op@on.
(1,5,9) Imaging – Radiography
• A/P and Lateral – Eval DDX & Listhesis • Oblique – Observe radiolucent pars defect: – Acute: Narrow, irregular – Chronic: Smooth, Rounded
• Appreciable on Lateral view if listhesis present Leone Skeletal Radiol 2011
Imaging -‐ Radiography • U@liza@on of Oblique Images – Pro: • Poten@al for quick confirma@on of clinical suspicion • If seen – characterize chronicity
– Con: • Low sensi@vity – Miss occult and early stress lesions
• Addi@onal radia@on • Most prac@@oners likely to u@lize secondary imaging regardless
Radia@on Exposure(9)
(mSv = milisievert, measurement of radia@on dose)
• • • • •
U.S. Natural Background Exposure: 3 mSv/year Chest X-‐ray: 0.1 mSv L-‐Spine X-‐ray, 6 View: 1.5 mSv SPECT: 5 mSv CT: 10-‐20 mSv
(1,5,6,9,12,16) Imaging -‐ SPECT
• Pros: – High Sensi@vity and can localize lesion Leone Skeletal Radiol 2011 – Early diagnosis of ac@ve lesions – Differen@ate between Acute & Chronic Non-‐ Union: • Increased Signal: Osseous ac@vity/Healing Poten@al • Absence of Signal: Nonunion/Low Healing Poten@al
– Correlates with pain e@ology (improved treatment outcomes16)
Imaging -‐ SPECT • Cons: – Poor Specificity -‐ poten@al for false posi@ves • Posi@ve SPECT shown in asymptoma@c athletes • DDx for Posi@ve Bone Uptake – Infec@on, Tumor, Arthri@s
– Radia@on exposure, intravenous injec@on, increased @me for comple@on – Cannot detect chronic non-‐union – Cannot dis@nguish if incomplete fx is in healing (osteoblas@c) or developing (osteoclas@c) phase
(9) Imaging -‐ SPECT
→ Due to low specificity, a posi@ve SPECT needs to be followed up with targeted CT imaging →Because of increasingly reliable MR sequencing and the amount of radia@on exposure from combo SPECT & CT scanning, there are increasing recommenda@ons to abandon SPECT screening.
Leone Skeletal Radiol 2011
Imaging – Computed Tomography (1,2,5,6,9,14)
• Pros: Iden@fy anatomical details of a pars defect – Complete or Incomplete Pars Fracture: • Most Sensi@ve & Specific independent imaging modality
– Can help stage the chronicity of the lesion: • Wide/Sclero@c – Chronic • Narrow/Non-‐cor@cated margins -‐ Acute
– Evaluate bony healing, surgical planning – More specific than SPECT
Imaging – Computed Tomography • Cons: – Radia@on exposure – Not good at:
Leone Skeletal Radiol 2011
• Ac@ve vs. Inac@ve fracture • Early Stress Reac@on – No Cor@cal Defect
– Limited evalua@on of associated condi@ons and other differen@al diagnosis
(2,9) Imaging -‐ CT Op@ons
• Reverse-‐Angle Gantry CT: – Perpendicular to Pars Lesion(2) – Decreasing use due to advances in CT technology
• Newer Technology: – Rapid, Thin-‐Slice – Increased anatomical coverage – Higher spa@al resolu@on – Sagidal Reconstruc@ons → Results in: High resolu@on 2D reforma@ons, 3D Leone Skeletal Radiol 2011 Rendering
(9,13) Imaging -‐ SPECT + CT
• Combina@on – SPECT: highest sensi@vity for bone ac@vity – CT: highest anatomical specificity
• Neg CT + Pos SPECT: – Stress response, Pre-‐lysis – Early incomplete → Good prognosis for healing and bony union
• Pos CT + Neg SPECT: – Non-‐union chronic lesion
(1,5,9,10,11,13,14,24) Imaging -‐ MRI
• Pros: – Sensi@ve for early ac@ve lesions – Reliable for: • Early/Stress lesions • Acute complete lesions • Chronic lesions Leone Skeletal Radiol 2011 – Absence of radia@on – Visualiza@on of other spinal disorders
Imaging -‐ MRI • Cons: – Lower Sensi@vity – Mostly involving Incomplete Fractures(9,24) – Lacks ability to grade the lesion, detect bony healing – Dunn, Skeletal Radiol, 2008(11) • Compara@ve study of incomplete fxs – MRI vs. CT • MRI: Limited ability to fully depict cor@cal integrity
Imaging -‐ MRI • Highly dependent on sequencing…some of the poor sensi@vity documented in the literature poten@ally due to inadequate sequencing: – Sequencing best suited for other dx (disc) – Slice thickness inadequate – Not mul@planar – Limited edema sensi@ve sequencing
(9,13,14) Imaging -‐ MRI Sequencing
• Ideal Sequencing: 1. Edema Sensi@ve – STIR Images (T2 Fat Sat) •
Visualize bony edema: Ac@ve & Early lesions
2. Cortex (Marrow) Sensi@ve – T1 (or T2) Non Fat Sat • •
Visualize fracture Good for anatomy – Seeing cor@cal bone, high contrast between marrow and signal void of disrupted cortex
3. Mul@planar – Axial, Sagidal, Coronal Oblique 4. Thin Slice – ≤ 3mm
MRI – Complete Fracture Leone Skeletal Radiol 2011
T2 – Fat Sat: Edematous Change
T1 Sequencing: Complete Fx Cle`
MRI -‐ Incomplete Fracture
STIR Sequence: Edematous Change
T1 Sequence: Defect Inferior Cortex
Leone Skeletal Radiol 2011
CT Imaging: Incomplete Cle` Pedicle
(10) Hollenberg, Spine, 2002 • Proposed Classifica@on System: – Grade 0: Normal Pars – Grade 1: Stress Reac@on – Marrow Edema, Intact Cortex – Grade 2: Incomplete Stress Fx – Marrow Edema, Incomplete Cortex Fx – Grade 3: Acute Complete Fx – Marrow Edema, Complete Pars Fx – Grade 4: Chronic Fx – No Marrow Edema, Complete Pars Fx
• Dis@nguishes: – Stress Rxn vs. Ac@ve Fracture vs. Inac@ve Fracture
MRI – Early Acute Lesions Kobayashi, AJSM, 2013(14) • Prospec@ve study to assess the use of MRI for detec@on of early ac@ve spondy lesions • Document MRI diagnosis in those cases occult on x-‐ray • 200 athletes with LBP, Ages 10-‐18, 72% Male: – Unclear or No findings on X-‐ray • 96% No Findings, 6% Unclear Findings
– MRI performed on all 200 athletes • Sag T2, Sag STIR, Axial T1, Axial T2, Axial STIR, 4-‐5mm slices
– CT performed as follow-‐up to MRI if edema present
(14) Kobayashi, AJSM, 2013
• Results: – MRI – Noted spondy in 97 of 200 athletes (48.5%) – Follow-‐up CT – 92 of 97 posi@ve MRI cases: • Nonlysis Lesions: 43% • Early Stage: 49% • Progressive Stage: 8% • Terminal Stage: 0%
Leone Skeletal Radiol 2011
(14) Kobayashi, AJSM, 2013
• Discussion: – MRI useful in recogni@on of early ac@ve spondy – Recommend: • Use of MRI for ini@al screening a`er nega@ve x-‐ray • For posi@ve MRI -‐ Should have localized CT for staging
– No comparison to SPECT regarding sensi@vity for early ac@ve lesions – For the 51.1% with nega@ve MR: • No follow up CT → No MRI vs. CT sensi@vity comparison
Addi@onal MRI Compara@ve Studies • Campbell, et al. Skeletal Radiol, 2005(24) – Compared MRI to SPECT+CT
• Concluded Effec@ve & Reliable first-‐line imaging modality • Concluded MRI can replace SPECT • Not adequate for grading incomplete defects (3-‐4mm Slices)
• Masci, et al. BJSM, 2006(20)
– Compared MRI to SPECT only, CT only, & SPECT+CT
• MRI equal to CT in detec@on of defect (did not specify complete vs. incomplete) • MRI decreased sensi@vity compared to SPECT for stress lesion • Concluded MRI inferior to SPECT+CT for general detec@on of all types of lesions • High rate in this study of MRI false nega@ves • MRI sequencing – larger slice thickness, limited planes
(19) Sundell, Int J Sports Med, 2013 • Prospec@ve Case Series • Methods: – Case & Control groups:
• MRI L-‐spine • Sag T1, Sag T2, Cor STIR • Slice thickness not men@oned, No Axial Views
– Case group: Also received CT of L4/L5, thin-‐slice
• Results:
– 22/25 case athletes had posi@ve MRI findings – 13/25 case athletes: +MRI Ac@ve Spondy – Personal communica@on with author:
• Athletes in case group with (–)MRI for Spondy also had (–)CT
(9) MRI – Ancillary Findings
• Aid in diagnosis: – Widened sagidal diameter of spinal canal – Posterior vertebral body wedging – Lumbar Height Index • Effect of spondylolisthesis vs. predisposing factor • Present in cases of spondy without listhesis
– Reac@ve edema in pedicle adjacent to pars defect
• Direct Findings + Ancillary Findings → MRI approaches a similar Sensi@vity as CT.
Synopsis of Imaging Debate • Posi@ves and Nega@ves for all • Important to know the limita@ons of your imaging op@ons • Important to know the imaging techniques and sequences u@lized by your imaging centers -‐ MRI
(9,13) Synopsis of Imaging Debate
• Reasons for SPECT/CT: – Confidence in the combina@on of: • Sensi@vity (SPECT) and specificity (CT)
– MRI nega@ve & athlete not responding to current plan of care – MRI contraindicated – Ideal MRI sequencing not available
• Follow-‐up CT: Grading necessary, assess bony healing
Synopsis of Imaging Debate • MRI as first-‐line?: – Visualize stress reac@ons, Acute and Chronic lesions – No radia@on in pediatric popula@on – Rule out other pathology – Know capabili@es of your imaging center
• MRI’s downside: Lower sensi@vity for incomplete fractures, can’t assess bony healing or grade of the lesion
Poten@al Imaging Protocol • Clinical Exam + Lumbar X-‐ray (AP & Lat) • Ini@al screen with MRI: – Sensi@ve for early ac@ve lesions – Iden@fy ac@ve vs. inac@ve lesions – Localize pathology – Rule out other differen@al diagnosis – Minimize Radia@on
• Localized CT -‐ for posi@ve Spondy on MRI: – Staging of lesion – Baseline for follow up imaging – bony healing
Spondylolysis -‐ Management
Conserva@ve Management • Overall:
– Rest from sport – stop repe@@ve extension/rota@on – Achieve pain-‐free status • Rest period with or without bracing
– Rehabilita@on – Return to Play transi@on
• Debate:
– Ini@al length of @me restricted from sport – Bracing: • Decision to u@lize bracing • Type of brace
– Time course for full return to sport
Spondylolysis -‐ Bracing(1,5,6,7,8,9,12,17,18) • Types of Braces:
– Thoraco-‐lumbar-‐sacral orthosis (TLSO) – an@lordo@c – Lumbo-‐sacral orthosis (LSO) – Corset/So` Brace
• Controversy:
– Lack of controlled studies – ques@on efficacy – Similar outcomes despite type of brace • Maintain lordosis vs. An@lordo@c • So` corset vs. Hard Shell Ortho@c
– Bony healing with and without bracing – Is it the immobiliza@on or the forced compliance with ac@vity restric@on?
Spondylolysis -‐ Bracing(1,5,6,7,8,9,12,17,18) • Controversy: – Lack of controlled studies – ques@on efficacy – Similar outcomes despite type of brace • Maintain lordosis vs. An@lordo@c • So` corset vs. Hard Shell Ortho@c
– Bony healing with and without bracing – Is it the immobiliza@on or the forced compliance with ac@vity restric@on?
Spondylolysis -‐ Bracing • Historical Perspec@ve: – Steiner/Micheli, 1985(7): documented success with bracing protocol • 6 months, 23 hrs/day • 6 months wean from brace
– Jackson/Wiltse, 1981(18): documented success with ac@vity restric@on only, no bracing
Referenced Bracing Strategy(13,22,23) d’Hemecourt, Orthopaedics, 2000(23) Micheli , Clin Sports Med, 2006(22)
• Ini@al:
– Removed from sport, Boston brace 23hrs/day – Begin physical therapy
• 4 to 6 weeks:
– If pain-‐free & progressing well in PT • Return to sport in brace
• 4 months:
– If bony healing or pain-‐free nonunion: wean brace – If pain and no healing: consider bone s@m
• 9-‐12 months:
– If persistent pain and nonunion: surgical fixa@on
(5,7,8,9) Addi@onal Brace Parameters
• If acute, (+)SPECT/MRI & (-‐)CT: – 3-‐6 months – Rest from aggrava@ng ac@vity – Adempt bony healing – Most recommend brace for acute lesions: mul@ple proposed strategies
• Chronic Lesions: – Rest un@l pain-‐free, no brace, then start other conserva@ve measures – Brace if can’t become pain-‐free
Bracing Literature Update
Sairyo K, J Neurosurg Spine, 2012(15) • Examine which spondylolysis lesions will go on to bone healing with bracing and how long it takes – 63 pars defects, 37 pa@ents, Ages 8-‐18 – Followed for bony healing with bracing – CT & MRI performed: • Early, Progressive High Signal (MR edema), Progressive Low Signal (no MR edema), Terminal
– Brace: molded plas@c TLSO – Repeat CT at 3mo and 6mo
Sairyo K, J Neurosurg Spine, 2012(15) • Results:
– Early – 94%, 3.2 mo – Progressive/High Signal – 64%, 5.4 mo – Progressive/Low Signal – 27%, 5.7mo – Terminal – 0%
• Supports early (CT stage) and ac@ve (MR edema) lesions have best prognosis for bone healing • Limita@ons:
– No non-‐braced control group – Study looking at bone healing, not pain relief or return to sport
(5,12,13) Spondylolysis Rehabilita@on
• General Principles: – Start early – In conjunc@on with pain reducing stage – Progress through generalized range of mo@on and spine stabiliza@on – Kine@c chain assessment & resistance training – Sport-‐specific retraining
Rehabilita@on of the Gymnast (Courtesy of Dr. Larry Nassar -‐ USAG Medical Director)
• Phase 1: Ini@ate at @me of Dx – Neutral Spine -‐ Correct Imbalances/Core Stability • Phase 2: Starts when pain-‐free – Start into extension, strengthening in extension • Phase 3: Once tolera@ng extension in PT – Start sport-‐specific extension work in the gym • Phase 4: Final progression – Gymnas@cs-‐specific progression, finish correc@on of baseline imbalances/mechanical deficiencies
Rehabilita@on of the Gymnast • Common deficiencies in the gymnast: – Shoulder & Thoracic mobility restric@ons – Lower Crossed Syndrome: • Hip flexor/quad/IT band/erector spinae flexibility • Gluteus medius and core strength
– Dyskine@c posterior chain firing paderns • Hamstring, Gluteus, Erector spinae
Kruse, CSMR, 2009
Rehabilita@on of the Gymnast (Courtesy of Dr. Larry Nassar -‐ USAG Medical Director)
Natural Progression Spondylolisthesis(1,4,5,13) • Bilateral Pars Defect
– 70% associated listhesis – Cases of low-‐grade slippage have 5% risk of progression
• Fortunately low documented risk of progression in athletes • Highest Risk for Progression – >50% slippage at diagnosis – Skeletally immature or <16yo – Significant decreased risk with increased age
• Follow-‐Up – Skeletally Immature – Lateral Radiographs Q6-‐12mo
(21) Return To Play
• Successful comple@on of a comprehensive physical therapy program • Can accomplish full and pain-‐free range of mo@on • Return of sport-‐specific strength and aerobic fitness • Able to perform sport-‐specific skills without pain
References 1. Foreman P, et al. L5 spondylolysis/spondylolisthesis: a comprehensive review with an anatomic focus. Childs Nerv Syst. 2013;29:209-‐16. 2. Harvey CJ, et. The radiological inves@ga@on of lumbar spondylolysis. Clin Radiol. 1998;53:723-‐28. 3. Standaert CJ, Herring SA. Spondylolysis: a cri@cal review. Br J Sports Med. 2000;34:415-‐22. 4. Muschik M, et al. Compe@@ve sports and the progression of spondylolisthesis. J Pediatr Orthop. 1996;16:364-‐9. 5. Kruse D, Lemmen B. Spine Injuries in the Sport of Gymnas@cs. Curr Sports Med Rep. 2009;8:20-‐28. 6. Standaert CJ, Herring SA. Expert opinion and controversies in sports and musculoskeletal medicine: the diagnosis and treatment of spondylolysis in adolescent athletes. Arch Phys Med Rehabil. 2007;88:537-‐40.
References 7. Steiner ME, Micheli LJ. Treatment of symptoma@c spondylolysis and spondylolisthesis with the modified Boston brace. Spine. 1985;10:937-‐40. 8. Standaert CJ. New Strategies in the management of low back injuries in gymnasts. Curr Sports Med Rep. 2002;1:293-‐300. 9. Leone A, et al. Lumbar spondylolysis: a review. Skeletal Radiol. 2011;40:683-‐700. 10. Hollenberg GM, et al. Stress reac@ons of the lumbar pars interar@cularis: the development of a new MRI classifica@on system. Spine. 2002;27:181-‐6. 11. Dunn AJ, et al. Radiological findings and healing paderns of incomplete stress fractures of the pars interar@cularis. Skeletal Radiol. 2008;37:443-‐50. 12. Kim HJ, Green DW. Spondylolysis in the adolescent athlete. Curr Opin Pediatr. 2011;23:68-‐72.
References 13. McCleary MD, Congeni JA. Current concepts in the diagnosis and treatment of spondylolysis in young athletes. Curr Sports Med Rep. 2007;6:62-‐66. 14. Kobayashi A, et al. Diagnosis of Radiographically Occult Lumbar Spondylolysis in Young Athletes by Magne@c Resonance Imaging. Am J Sports Med. 2013;41:169-‐76. 15. Sairyo K, et al. Conserva@ve treatment for pediatric lumbar spondylolysis to achieve bone healing using a hard brace: what type and how long? J Neurosurg Spine. 2012;16:610-‐14. 16. Raby N, Mathews S. Symptoma@c spondylolysis: correla@on of ct and spect with clinical outcome. Clin Radiology. 1993;48:97-‐99. 17. Steiner M, Micheli L. Treatment of symptoma@c spondylolysis and spondylolisthesis with modified Boston brace. Spine. 1985;10:937-‐43. 18. Jackson D, Wiltse L. Stress reac@on involving the pars interar@cularis in young athletes. Am J Sport Med. 1981;9:304-‐112.
References 19. Sundell C-‐G, et al. Clinical Examina@on, Spondylolysis and Adolescent Athletes. Int J Sports Med. 2013;34:263-‐67. 20. Masci L, et al. Use of the one-‐legged hyperextension test and magne@c resonance imaging in the diagnosis of ac@ve spondylolysis. Br J Sports Med. 2006;40:940-‐46. 21. Eddy D, Congeni J, Loud K. A Review of Spine Injuries and Return to Play. Clin J Sport Med. 2005;15:453-‐58. 22. Micheli L, Cur@s C. Stress fractures in the spine and sacrum. Clin Sports Med. 2006;25:75-‐88. 23. d’Hemecourt P, et al. Spondylolysis: returning the athlete to sports par@cipa@on with brace treatment. Orthopaedics. 2002;25:653-‐57. 24. Campbell R, et al. Juvenile spondylolysis: a compara@ve analysis of CT, SPECT and MRI. Skeletal Radiol. 2005;34:63-‐73. 25. Congeni J. Evalua@ng spondylolysis in adolescent athletes. J Musculoskel Med. 2000;17:123-‐29.
Contact Informa@on • David W. Kruse, M.D. • Orthopaedic Specialty Ins@tute – Orange, CA – 714.937.4898
•
[email protected]
