Tag Archive for: Cerebral palsy

Upper Limb in Cerebral Palsy

Volume 10 | Issue 1 | January-April 2024 | Page: 39-49 | Praveen Bhardwaj, Vigneswaran Varadharajan, Mukil Venthan S, S Raja Sabapathy 

DOI- https://doi.org/10.13107/ijpo.2024.v10i01.177

Submitted: 28/01/2024; Reviewed: 16/02/2024; Accepted: 11/03/2022; Published: 10/04/2024


Authors: Praveen Bhardwaj MS Ortho [1], Vigneswaran Varadharajan MS Ortho [1], Mukil Venthan S MS Ortho [1], S Raja Sabapathy MS Ortho [2]

[1] Department of Hand & Reconstructive Microsurgery Ganga Hospital, Coimbatore, Tamil Nadu, India
[2] Department of Plastic, Hand & Reconstructive Microsurgery Ganga Hospital, Coimbatore, Tamil Nadu, India

Address of Correspondence

Dr. Praveen Bhardwaj,
Consultant- Hand & Reconstructive Microsurgery Ganga Hospital, 313- Mettupalayam Road Sai Baba Colony Coimbatore, Tamil Nadu, India
E-mail: drpb23@gmail.com


Abstract

Cerebral palsy (CP) is a complex neuromuscular disorder characterized by impaired movement and coordination, often resulting in significant gait abnormalities. The spectrum of motor function impairment varies greatly among individuals with CP, influenced by muscle control issues and specific types of cerebral palsy, including spasticity and ataxia. Gait analysis, comprising both observational and instrumented techniques, is essential for assessing gait patterns and identifying abnormalities. While observational gait analysis provides qualitative insights, instrumented gait analysis offers a detailed and objective assessment through motion capture technology, allowing for comprehensive evaluation of joint angles(Kinematics) and forces(Kinetics).
Understanding gait patterns is crucial for making informed clinical decisions regarding therapeutic interventions such as surgery and orthotic management. Literature has demonstrated that gait analysis significantly improves surgical recommendations and outcomes, highlighting the importance of incorporating detailed gait data into treatment planning. However, limitations such as variability in data accuracy, the complexity of methods, and hesitancy among some orthopaedic surgeons to adopt these techniques need to be addressed. The integration of gait analysis into clinical practice represents a paradigm shift in the management of cerebral palsy, transitioning treatment from an art to a science. It enables clinicians to tailor interventions based on individual biomechanical profiles, ultimately enhancing the functional ability and quality of life for patients. Continued research and standardized practices are essential to maximize the effectiveness of gait analysis in this population, ensuring that children withe cerebral palsy receive the most appropriate and effective care.
Keywords: Gait Analysis, Cerebral Palsy, Instrumented Gait Lab


References

1. Makki D, Duodu J, Nixon M. Prevalence and pattern of upper limb involvement in cerebral palsy. J Child Orthop. 2014 May;8(3):215-9. doi: 10.1007/s11832-014-0593-0. Epub 2014 May 14. PMID: 24824566; PMCID: PMC4142879.
2. Bhardwaj P, Sabapathy SR. Assessment of the hand in cerebral palsy. Indian J Plast Surg. 2011 May;44(2):348-56. doi: 10.4103/0970-0358.85356. PMID: 22022045; PMCID: PMC3193647.
3. Van Heest AE, Bagley A, Molitor F, James MA. Tendon transfer surgery in upper-extremity cerebral palsy is more effective than botulinum toxin injections or regular, ongoing therapy. J Bone Joint Surg Am. 2015 Apr 1;97(7):529-36. doi: 10.2106/JBJS.M.01577. PMID: 25834076.
4. Libberecht K, Sabapathy SR, Bhardwaj P. The relation of patient satisfaction and functional and cosmetic outcome after correction of the wrist flexion deformity in cerebral palsy. J Hand Surg Eur Vol. 2011 Feb;36(2):141-6. doi: 10.1177/1753193410384691. Epub 2010 Oct 8. PMID: 20935023.
5. Chaudhry S, Bhardwaj P, Venkatramani H, Sabapathy SR. The Spastic Upper Extremity in Children: Multilevel Surgical Decision-making. J Am Acad Orthop Surg. 2021 May 1;29(9):e416-e426. doi: 10.5435/JAAOS-D-20-00719. PMID: 33883454.
6. Tonkin MA. The growing hand. In: Gupta A, Kay SPJ, Scheker LR, editors. The upper limb in cerebral palsy. London: Mosby; 2000. pp. 447–59.
7. Yong LY, Wong CHL, Gaston M, Lam WL. The Role of Selective Peripheral Neurectomy in the Treatment of Upper Limb Spasticity. J Hand Surg Asian Pac Vol. 2018 Jun;23(2):181-191. doi: 10.1142/S2424835518500182. PMID: 29734901.
8. Leclercq C, Mertens P. Trends and insights review. Nerve procedures in the management of upper limb spasticity. J Hand Surg Eur Vol. 2024 Jun;49(6):802-811. doi: 10.1177/17531934241238885. Epub 2024 Mar 27. PMID: 38534081.
9. De Lepeleere B, Fitoussi F. Elbow Flexor Release Combined With Selective Neurectomy of Musculocutaneous Nerve for Spastic Elbow Flexion Deformity in Children and Adolescents. J Pediatr Orthop. 2024 Sep 1;44(8):e738-e743. doi: 10.1097/BPO.0000000000002729. Epub 2024 May 21. PMID: 38770666.
10. Cambon-Binder A, Leclercq C. Anatomical study of the musculocutaneous nerve branching pattern: application for selective neurectomy in the treatment of elbow flexors spasticity. Surg Radiol Anat. 2015 May;37(4):341-8. doi: 10.1007/s00276-014-1371-x. Epub 2014 Sep 6. PMID: 25193328.
11. Zancolli E. 2nd ed. Philadelphia: Lippincott; 1979. Structural and dynamic bases of hand surgery; pp. 263–83.
12. Arnaout A, Leclercq C. Fractional Lengthening of the Forearm Flexor Muscles: Anatomic Study. J Hand Surg Am. 2022 Aug;47(8):792.e1-792.e5. doi: 10.1016/j.jhsa.2021.07.015. Epub 2021 Sep 3. PMID: 34489137.
13. Patterson JM, Wang AA, Hutchinson DT. Late deformities following the transfer of the flexor carpi ulnaris to the extensor carpi radialis brevis in children with cerebral palsy. J Hand Surg Am. 2010 Nov;35(11):1774-8. doi: 10.1016/j.jhsa.2010.07.014. PMID: 20888146.
14. Schibli S, Fridén J. Rebalancing the Spastic Wrist by Transposition of Antagonistic Muscle-Tendon Complex. Tech Hand Up Extrem Surg. 2022 Jun 1;26(2):127-130. doi: 10.1097/BTH.0000000000000371. PMID: 34711790.
15. Gschwind C, Tonkin M. Surgery for cerebral palsy: Part 1. Classification and operative procedures for pronation deformity. J Hand Surg Br. 1992 Aug;17(4):391-5. doi: 10.1016/s0266-7681(05)80260-8. PMID: 1402264.
16. Manske PR. Redirection of extensor pollicis longus in the treatment of spastic thumb-in-palm deformity. J Hand Surg Am. 1985 Jul;10(4):553-60. doi: 10.1016/s0363-5023(85)80082-4. PMID: 4020069.
17. Lawson RD, Tonkin MA. Surgical management of the thumb in cerebral palsy. Hand Clin. 2003 Nov;19(4):667-77. doi: 10.1016/s0749-0712(03)00042-8. PMID: 14596557.
18. House JH, Gwathmey FW, Fidler MO. A dynamic approach to the thumb-in palm deformity in cerebral palsy. J Bone Joint Surg Am. 1981 Feb;63(2):216-25. PMID: 7462278.
19. Carlson MG. Green’s operative hand surgery. In: Green DP, Hotchkiss RN, Pederson WC, Wolfe SW, editors. Cerebral palsy. Philadelphia: Churchill Livingstone; 2005. pp. 1197–234.
20. Carlson EJ, Carlson MG. Treatment of swan neck deformity in cerebral palsy. J Hand Surg Am. 2014 Apr;39(4):768-72. doi: 10.1016/j.jhsa.2014.01.039. Epub 2014 Mar 6. PMID: 24613587.
21. Swanson AB. Treatment of the swan-neck deformity in the cerebral palsied hand. Clin Orthop Relat Res. 1966 Sep-Oct;48:167-71. PMID: 5957466.
22. Wei DH, Terrono AL. Superficialis Sling (Flexor Digitorum Superficialis Tenodesis) for Swan Neck Reconstruction. J Hand Surg Am. 2015 Oct;40(10):2068-74. doi: 10.1016/j.jhsa.2015.07.018. Epub 2015 Aug 29. PMID: 26328902.
23. Samilson RL, Morris JM. Surgical improvement of the cerebral-palsied upper limb. Electromyographic studies and results in 128 operations. J Bone Joint Surg Am. 1964 Sep;46:1203-16. PMID: 14214354.


How to Cite this Article:  Bhardwaj P, Varadharajan V, Venthan SM, Sabapathy SR | Upper Limb in Cerebral Palsy | International Journal of Paediatric Orthopaedics | January-April 2024; 10(1): 39-49 . https://doi.org/10.13107/ijpo.2024.v10i01.177

(Article Text HTML)      (Full Text PDF)


Role of Gait Analysis in Management of Cerebral Palsy

Volume 10 | Issue 1 | January-April 2024 | Page: 34-38 | Chasanal Rathod

DOI- https://doi.org/10.13107/ijpo.2024.v10i01.176

Submitted: 13/01/2024; Reviewed: 05/02/2024; Accepted: 21/03/2024; Published: 10/04/2024


Authors: Chasanal Rathod MS Ortho [1,2]

[1] Department of Paediatric Orthopaedic Surgery, SRCC Children’s Hospital, Mumbai, Maharashtra, India.
[2] Xavier’s Gait Lab, Mumbai, Maharashtra, India.

Address of Correspondence

Dr. Chasanal Rathod,
Paediatric Orthopaedic Surgeon, SRCC Children’s Hospital, Mumbai, Maharashtra, India. Xavier’s Gait Lab Mumbai, Maharashtra, India.
E-mail: chasanal@gmail.com


Abstract

Cerebral palsy (CP) is a complex neuromuscular disorder characterized by impaired movement and coordination, often resulting in significant gait abnormalities. The spectrum of motor function impairment varies greatly among individuals with CP, influenced by muscle control issues and specific types of cerebral palsy, including spasticity and ataxia. Gait analysis, comprising both observational and instrumented techniques, is essential for assessing gait patterns and identifying abnormalities. While observational gait analysis provides qualitative insights, instrumented gait analysis offers a detailed and objective assessment through motion capture technology, allowing for comprehensive evaluation of joint angles(Kinematics) and forces(Kinetics).
Understanding gait patterns is crucial for making informed clinical decisions regarding therapeutic interventions such as surgery and orthotic management. Literature has demonstrated that gait analysis significantly improves surgical recommendations and outcomes, highlighting the importance of incorporating detailed gait data into treatment planning. However, limitations such as variability in data accuracy, the complexity of methods, and hesitancy among some orthopaedic surgeons to adopt these techniques need to be addressed. The integration of gait analysis into clinical practice represents a paradigm shift in the management of cerebral palsy, transitioning treatment from an art to a science. It enables clinicians to tailor interventions based on individual biomechanical profiles, ultimately enhancing the functional ability and quality of life for patients. Continued research and standardized practices are essential to maximize the effectiveness of gait analysis in this population, ensuring that children withe cerebral palsy receive the most appropriate and effective care.
Keywords: Gait Analysis, Cerebral Palsy, Instrumented Gait Lab


References

1. Bell KJ, Ounpuu S, DeLuca PA, et al. Natural progression of gait in children with cerebral palsy. J Pediatr Orthop. 2002;22:677–682
2. Gage JR, The neurological control system for normal gait. Gait Analysis in Cerebral Palsy. 1991 London MacKeith Press:37–60
3. Read HS, Hazlewood ME, Hillman SJ, Prescott RJ, Robb JE. Edinburgh visual gait score for use in cerebral palsy. J Pediatr Orthop. 2003 May-Jun;23(3):296-301. PMID: 12724590
4. Harris GF, Wertsch JJ. Procedures for gait analysis. Arch Phys Med Rehabil. 1994 Feb;75(2):216-25. PMID: 8311681.
5. Gage JR. Gait analysis. An essential tool in the treatment of cerebral palsy. Clin Orthop Relat Res. 1993 Mar;(288):126-34. PMID: 8458125.
6. Rodda J, Graham HK. Classification of gait patterns in spastic hemiplegia and spastic diplegia: a basis for a management algorithm. Eur J Neurol. 2001 Nov;8 Suppl 5:98-108. doi: 10.1046/j.1468-1331.2001.00042.x. PMID: 11851738.
7. DeLuca, Peter; Davis, Roy; Õunpuu, Sylvia; Rose, Sally; Sirkin, Robert. Alterations in Surgical Decision Making in Patients with Cerebral Palsy Based on Three-Dimensional Gait Analysis. Journal of Pediatric Orthopaedics 17(5):p 608-614, September 1997.
8. Lofterød B, Terjesen T. Results of treatment when orthopaedic surgeons follow gait-analysis recommendations in children with CP. Dev Med Child Neurol. 2008 Jul;50(7):503-9. doi: 10.1111/j.1469-8749.2008.03018.x. PMID: 18611199.
9. Rutz E, Gaston MS, Tirosh O, Brunner R. Hip flexion deformity improves without psoas-lengthening after surgical correction of fixed knee flexion deformity in spastic diplegia. Hip Int. 2012 Jul-Aug;22(4):379-86. doi: 10.5301/HIP.2012.9453. PMID: 22878968.
10. Mallet C, Simon AL, Ilharreborde B, Presedo A, Mazda K, Penneçot GF. Intramuscular psoas lengthening during single-event multi-level surgery fails to improve hip dynamics in children with spastic diplegia. Clinical and kinematic outcomes in the short- and medium-terms. Orthop Traumatol Surg Res. 2016 Jun;102(4):501-6. doi: 10.1016/j.otsr.2016.01.022. Epub 2016 Mar 31. PMID: 27050557.
11. Dreher T, Wolf SI, Maier M, Hagmann S, Vegvari D, Gantz S, Heitzmann D, Wenz W, Braatz F. Long-term results after distal rectus femoris transfer as a part of multilevel surgery for the correction of stiff-knee gait in spastic diplegic cerebral palsy. J Bone Joint Surg Am. 2012 Oct 3;94(19):e142(1-10). doi: 10.2106/JBJS.K.01300. PMID: 23032593.
12. Végvári D, Wolf SI, Heitzmann D, Klotz MC, Dreher T. Does proximal rectus femoris release influence kinematics in patients with cerebral palsy and stiff knee gait? Clin Orthop Relat Res. 2013 Oct;471(10):3293-300. doi: 10.1007/s11999-013-3086-4. Epub 2013 Jun 5. PMID: 23737262; PMCID: PMC3773150.
13. Molenaers G, Desloovere K, Fabry G, De Cock P. The effects of quantitative gait assessment and botulinum toxin a on musculoskeletal surgery in children with cerebral palsy. J Bone Joint Surg Am. 2006 Jan;88(1):161-70.
14. Cook R, Schneider I, Hazlewood E, et al. Gait analysis alters decision making in cerebral palsy. J Pediatr Orthop 2003; 23:292–295.
15. Kay R, Dennis S, Rethlefsen S, et al. The effect of preoperative gait analysis on orthopaedic decision making. Clin Orthop Relat Res 2000; 372:217–222.
16. Chang FM, Seidl AJ, Muthusamy M, et al. Effectiveness of instrumented gait analysis in children with cerebral palsy: comparison of outcomes. J Pediatr Orthop 2006; 26:612–616.
17. Kay RM, Dennis S, Rethlefsen S, Skaggs DL, Tolo VT. Impact of postoperative gait analysis on orthopaedic care. Clin Orthop Relat Res. 2000 May;(374):259-64. doi: 10.1097/00003086-200005000-00023. PMID: 10818985
18. Schutte LM, Narayanan U, Stout JL, Selber P, Gage JR, Schwartz MH et al (2000) An index for quantifying deviations from normal gait. Gait Posture 11:25–31
19. Schwartz MH, Rozumalski A (2008) The Gait Deviation Index: a new comprehensive index of gait pathology. Gait Posture 28:351–357
20. Baker R, McGinley JL, Schwartz MH et al (2009) The gait profile score and movement analysis profile. Gait Posture 30:265–269
21. Noonan K, Halliday S, Browne B, et al. Interobserver variability of gait analysis in patients with cerebral palsy. J Pediatr Orthop 2003; 23:279 – 287.
22. States RA, Krzak JJ, Salem Y, Godwin EM, Bodkin AW, McMulkin ML. Instrumented gait analysis for management of gait disorders in children with cerebral palsy: A scoping review. Gait Posture. 2021 Oct;90:1-8. doi: 10.1016/j.gaitpost.2021.07.009. Epub 2021 Aug 3. PMID: 34358847.
23. Wren TA, Gorton GE 3rd, Ounpuu S, Tucker CA. Efficacy of clinical gait analysis: A systematic review. Gait Posture. 2011 Jun;34(2):149-53. doi: 10.1016/j.gaitpost.2011.03.027. Epub 2011 Jun 8. PMID: 21646022.
24. Narayanan UG. The role of gait analysis in the orthopaedic management of ambulatory cerebral palsy. Curr Opin Pediatr. 2007 Feb;19(1):38-43. doi: 10.1097/MOP.0b013e3280118a6d. PMID: 17224660.


How to Cite this Article:  Rathod C | Role of Gait Analysis in Management of Cerebral Palsy | International Journal of Paediatric Orthopaedics | January-April 2024; 10(1): 34-38. https://doi.org/10.13107/ijpo.2024.v10i01.176

(Article Text HTML)      (Full Text PDF)


Lever Arm Disorders of the Feet in Cerebral Palsy

Volume 10 | Issue 1 | January-April 2024 | Page: 26-33 | Atul Bhaskar

DOI- https://doi.org/10.13107/ijpo.2024.v10i01.175

Submitted: 11/02/2024; Reviewed: 26/02/2024; Accepted: 13/03/2024; Published: 10/04/2024


Authors: Atul Bhaskar MS Ortho, FRCS Ortho, MCH, DNB [1,2,3]

[1] Department of Orthopaedics, Apollo Hospital, Mumbai, Maharashtra, India.
[2] Department of Orthopaedics, SRCC NH Hospital, Mumbai, Maharashtra, India.
[3] Department of Orthopaedics, Bombay Hospital Institute of Medical Sciences, Mumbai, Maharashtra, India.

Address of Correspondence

Dr. Atul Bhaskar,
Paediatric Orthopaedic Surgeon, Department of Orthopaedics, Apollo Hospital, SRCC NH Hospital, Bombay Hospital Institute of Medical Sciences, Mumbai, Maharashtra, India.
E-mail: arb_25@yahoo.com


Abstract

The key for optimum management for progressive musculoskeletal deformities in cerebral palsy patients is understanding the causative mechanisms. The impact of muscle shortening and contracture on the long bones and joints leads to lever arm problems in the foot and ankle and the associated deformities.
Management of each deformity is considered separately although many of these can occur concurrently and the severity my vary in an individual.
Keywords: Lever, Cerebral palsy, Foot & Ankle


References

1) Theologis T. Lever arm dysfunction in cerebral palsy gait. J Child Orthop. 2013 Nov;7(5):379-82. doi: 10.1007/s11832-013-0510-y. Epub 2013 Aug 14. PMID: 24432098; PMCID: PMC3838510.
2) Dudeney, S. and Stephens, M., 1998. Foot deformities in children with cerebral palsy. Journal of Pediatric Orthopaedics, 18(6), pp.743-747
3) Min, J.J., Kwon, S.S., Sung, K.H., Lee, K.M., Chung, C.Y. and Park, M.S., 2020. Progression of planovalgus deformity in patients with cerebral palsy. BMC musculoskeletal disorders, 21(1), pp.1-8.
4) Bennet, G.C., Rang, M. and Jones, D., 1982. Varus and valgus deformities of the foot in cerebral palsy. Developmental Medicine & Child Neurology, 24(5), pp.499-503.
5) Kadhim M and Miller F. Pes planovalgus deformity in children with cerebral palsy: review article. J Pediatr Orthop B 2014; 23(5): 400–405.
6) MacInnes P, Lewis TL, Griffin C, et al. Surgical management of pes planus in children with cerebral palsy: a systematic review. PROSPERO2021 CRD42021239285, https://www.crd.york. ac.uk/prospero/display_record.php?ID=CRD42021239285 (2021, accessed 22 December 2021).
7) Lee SH, Chung CY, Park MS, Choi IH, Cho TJ. Tibial torsion in cerebral palsy: validity and reliability of measurement. Clin Orthop Relat Res. 2009 Aug;467(8):2098-104. doi: 10.1007/s11999-009-0705-1. Epub 2009 Jan 22. PMID: 19159112; PMCID: PMC2706340.
8) Andrisevic E, Westberry DE, Pugh LI, Bagley AM, Tanner S, Davids JR. Correction of Tibial Torsion in Children With Cerebral Palsy by Isolated Distal Tibia Rotation Osteotomy: A Short-term, In Vivo Anatomic Study. J Pediatr Orthop. 2016 Oct-Nov;36(7):743-8. doi: 10.1097/BPO.0000000000000525. PMID: 27603097.
9) Sung K.H., Chung C.Y., Lee K.M., Lee S.Y., Park M.S. Calcaneal lengthening for planovalgus foot deformity in patients with cerebral palsy. Clin Orthop Relat Res. 2013;471(5):1682–1690. [PMC free article] [PubMed] [Google Scholar]
10) Zeifang F, Breusch SJ and Döderlein L. Evans calcaneal lengthening procedure for spastic flexible flatfoot in 32 patients (46 feet) with a followup of 3 to 9 years. Foot Ankle Int 2006; 27(7): 500–507
11) Mosca VS. Calcaneal lengthening for valgus deformity of the hindfoot. Results in children who had severe, symptomatic flatfoot and skewfoot. J Bone Joint Surg Am 1995; 77: 500–512.
12) Andreacchio A, Orellana C, Miller F, et al. Lateral column lengthening as treatment for planovalgus foot deformity in ambulatory children with spastic cerebral palsy. J Pediatr Orthop 2000; 20: 501–505
13) Grice D.S. An extra-articular arthrodesis of the subastragalar joint for correction of paralytic flat feet in children. J Bone Joint Surg Am. 1952;34(1):927–940. [PubMed] [Google Scholar]
14) Güven M., Eren A., Akman B., Unay K., Ozkan N.K. The results of the Grice subtalar extra-articular arthrodesis for pes planovalgus deformity in patients with cerebral palsy. Acta Orthop Traumatol Turcica. 2008;42(1):31–37. Jan-Feb. [PubMed] [Google Scholar]
15) Rathjen K.E., Mubarak S.J. Calcaneal-cuboid-cuneiform osteotomy for the correction of valgus foot deformities in children. J Pediatr Orthop. 1998;18(6):775–782. [PubMed] [Google Scholar]
16) Ahmed AH, Hanna AA, Arafa AS, et al. Prospective comparison of subtalar arthroereisis with calcaneal lengthening in the management of planovalgus feet of ambulatory children with spastic cerebral palsy? Foot Ankle Spec. Epub ahead of print 3 December 2020. DOI: 10.1177/1938640020974886.
17) Suh DH, Park JH, Lee SH, et al. Lateral column lengthening versus subtalar arthroereisis for paediatric flatfeet: a systematic review. Int Orthop. 2019;43:1179-1192.
18) Turriago CA, Arbeláez MF and Becerra LC. Talonavicular joint arthrodesis for the treatment of pes planus valgus in older children and adolescents with cerebral palsy. J Child Orthop 2009; 3: 179–183
19) Elbarbary HM, Arafa AS, Said ABZ, et al. Clinical and Radiological Outcomes of Subtalar Arthroereisis for Management of Planovalgus Foot in Children With Cerebral Palsy: 3-Year Follow-up. Foot & Ankle Specialist. 2022;15(6):536-544. doi:10.1177/1938640020980911
20) Vlachou M, Demetriades D and Hager I. Subtalar arthrodesis with the combined Batchelor–Grice technique. Foot Ankle Surg 2004; 10: 79–84.
21) Dussa CU, Döderlein L, Forst R, Böhm H, Fujak A. Management of Severe Equinovalgus in Patients With Cerebral Palsy by Naviculectomy in Combination With Midfoot Arthrodesis. Foot & Ankle International. 2017;38(9):1011-1019. doi:10.1177/1071100717709577
22) Ireland, M.L. and Hoffer, M., 1985. Triple arthrodesis for children with spastic cerebral palsy. Developmental Medicine & Child Neurology, 27(5), pp.623-627. O’Connell, P.A., D’Souza, L.
23) Aiona M, Calligeros K, Pierce R. Coronal plane knee moments improve after correcting external tibial torsion in patients with cerebral palsy. Clin Orthop Relat Res. 2012 May;470(5):1327-33.
24) Stefko RM, de Swart RJ, Dodgin DA, Wyatt MP, Kaufman KR, Sutherland DH, Chambers HG. Kinematic and kinetic analysis of distal derotational osteotomy of the leg in children with cerebral palsy. J Pediatr Orthop. 1998 Jan-Feb;18(1):81-7. PMID: 9449107.
25) Cidambi EO, Farnsworth CL, Jeffords ME, Hughes JL, Parvaresh KC, Sullivan TB, Yaszay B, Edmonds EW. Distal tibial osteotomy to address internal tibial torsion: Should the fibula be cut? Clin Biomech (Bristol, Avon). 2022 Jan;91:105536. doi: 10.1016/j.clinbiomech.2021.105536. Epub 2021 Nov 20. PMID: 34920237.
26) T.L. Lewis, K. Patel, K.L. Shepherd, P. MacInnes, R. Ray, M. Kokkinakis, Hallux valgus surgery in children with cerebral palsy: A systematic review, Foot and Ankle Surgery,Volume 28, Issue 4,


How to Cite this Article:  Bhaskar A | Lever Arm Disorders of the Feet in Cerebral Palsy | International Journal of Paediatric Orthopaedics | January-April 2024; 10(1): 26-33.
https://doi.org/10.13107/ijpo.2024.v10i01.175

(Article Text HTML)      (Full Text PDF)


Crouch Gait: Evaluation and Management

Volume 10 | Issue 1 | January-April 2024 | Page: 20-25 | Hitesh Shah, Dhiren Ganjwala

DOI- https://doi.org/10.13107/ijpo.2024.v10i01.173

Submitted: 08/02/2024; Reviewed: 28/02/2024; Accepted: 17/03/2024; Published: 10/04/2024


Authors: Hitesh Shah MS Ortho [1], Dhiren Ganjwala MS Ortho [2]

[1] Department of Paediatric Orthopaedics, Kasturba Medical College, Manipal, Manipal academy of higher education, Manipal, Karnataka,
[2] Ganjwala Orthopaedic Hospital, Ahmedabad, Gujarat, India.

Address of Correspondence

Dr. Dhiren Ganjwala,
Ganjwala Orthopaedic Hospital, Ahmedabad, Gujarat, India.
E-mail: ganjwala@gmail.com


Abstract

Crouch gait, a common gait abnormality in spastic diplegia, is characterized by increased knee flexion, ankle dorsiflexion, and reduced hip extension during the stance phase. It occurs due to impairments in anti-gravity muscles and is often aggravated during adolescence due to growth spurts. The condition can result from factors such as lever arm dysfunction, joint deformities, muscle elongation, and weakness. Crouch gait significantly affects mobility, causing early fatigue, patellar tendon elongation, and potential arthritis. Prevention involves strengthening anti-gravity muscles, maintaining proper weight, and using orthoses to correct deformities. Treatment options include surgical interventions like osteotomies, tendon lengthening, and patellar tendon advancement to address deformities and restore function. Non-surgical methods include muscle-strengthening exercises and the use of appropriate orthoses. A comprehensive assessment of modifiable and non-modifiable factors is crucial for tailored management, ultimately improving gait and reducing energy expenditure during walking.
Keywords: Crouch gait, Cerebral palsy, Patella alta, Planovalgus foot, Knee fixed flexion deformity


References

1. Gage JR, editor. The treatment of gait problems in cerebral palsy. 2nd ed. London: Mac Keith Press; 2004. Treatment principles for crouch gait; p 382-97.
2. Schwartz M, Lakin G. The effect of tibial torsion on the dynamic function of the soleus during gait. Gait Posture. 2003;17:113-8.
3. Hicks J, Arnold A, Anderson F, Schwartz M, Delp S. The effect of excessive tibial torsion on the capacity of muscles to extend the hip and knee during single-limb stance. Gait Posture. 2007;26:546-52.
4. Perry J, Antonelli D, Ford W. Analysis of knee joint forces during flexed knee stance. J Bone Joint Surg Am. 1975;57:961-7.
5. Rosenthal RK, Levine DB. Fragmentation of the distal pole of the patella in spastic cerebral palsy. J Bone Joint Surg Am. 1977;59:934-9.
6. Topoleski TA, Kurtz CA, Grogan DP. Radiographic abnormalities and clinical symptoms associated with patella alta in ambulatory children with cerebral palsy. J Pediatr Orthop. 2000;20:636-9.
7. Klatt J, Stevens PM. Guided growth for fixed knee flexion deformity. J Pediatr Orthop. 2008;28:626-3
8. Gage JR, Stout JL, Novacheck TF, Matsuo K. Distal femoral extension osteotomy and patellar advancement for crouch in cerebral palsy J Bone Joint Surg Am. 2008, 90:2470-84
9. Ganjwala D, Shah H. Management of the Knee Problems in Spastic Cerebral Palsy. Indian J Orthop. 2019 Jan-Feb;53(1):53-62.
10. Das SP, Pradhan S, Ganesh S, Sahu PK, Mohanty RN, Das SK. Supracondylar femoral extension osteotomy and patellar tendon advancement in the management of persistent crouch gait in cerebral palsy. Indian J Orthop. 2012 Mar;46(2):221-8.
11. Joseph B, Reddy K, Varghese RA, Shah H, Doddabasappa SN. Management of severe crouch gait in children and adolescents with cerebral palsy. J Pediatr Orthop. 2010 Dec;30(8):832-9..
12. Ganjwala D. Multilevel orthopedic surgery for crouch gait in cerebral palsy: An evaluation using functional mobility and energy cost. Indian J Orthop. 2011 Jul;45(4):314-9.
13. Rodda JM, Graham HK, Nattrass GR, Galea MP, Correction of Severe Crouch Gait in Patients with Spastic Diplegia with Use of Multilevel Orthopaedic Surgery J Bone Joint Surg Am. 2006, 88:2653-64.
14. Mohan V, Ganjwala D, Singh K, Shah H. Evaluation of a technique of patellar tendon shortening to correct patella alta associated with severe crouch gait in cerebral palsy. J Pediatr Orthop B. 2023 Jan 1;32(1):87-93.


How to Cite this Article:  Shah H, Ganjwala D | Crouch Gait: Evaluation and Management International |  Journal of Paediatric Orthopaedics | January-April 2024; 10(1): 20-25 https://doi.org/10.13107/ijpo.2024.v10i01.174

(Article Text HTML)      (Full Text PDF)


Lever Arm dysfunction of Hips in Cerebral Palsy

Volume 10 | Issue 1 | January-April 2024 | Page: 14-19 | Jitendra Kumar Jain

DOI- https://doi.org/10.13107/ijpo.2024.v10i01.173

Submitted: 14/01/2024; Reviewed: 10/02/2024; Accepted: 06/03/2024; Published: 10/04/2024


Authors: Jitendra Kumar Jain MS Ortho [1]

[1] Trishla Foundation, Tagore Town, Prayagraj, Uttar Pradesh, India.

Address of Correspondence

Dr. Jitendra Kumar Jain,
Chairman, Trishla Foundation, Tagore Town, Prayagraj, Uttar Pradesh, India.
E-mail: jjain999@gmail.com


Abstract

In cerebral palsy, hip dysfunction is the second most common problem after equines deformity. Abnormal skeletal development of the proximal femur due to abnormal forces in cerebral palsy leads to lever arm function by reducing the length of the lever arm contributing to one of very important causes of gait abnormality. High hip anteversion, high neck shaft angle, subluxation, and dislocation are the most common lever arm dysfunctions at the hip joint. This lever arm dysfunction increases progressively with age and correspondence to GMFCS level. If not identified at a very early stage then it may progress to completely deform the femoral head & hip joint. Early identification and preventive surgery help in preventing progression in GMFCS I to III but can progress despite of preventive surgery in non-walker children FMFCS IV & V. Recurrence of the problem is also very common in non-walker children. So we need detailed information about the lever arm problem in the hip and how to deal with this problem in cerebral palsy children. In this article, we have discussed etiology, and how to identify and management protocols for different lever arm dysfunctions of the hip in cerebral palsy.
Keywords: Cerebral palsy, Lever arm dysfunction of hip, Hip subluxation, Anteversion


References

1. Peterson N, Walton R. Ambulant cerebral palsy. J. Orthop. Trauma 2016; 30 (6 ): 525-38.
2. Gage JR, Schwartz MH. Consequences of brain injury on musculoskeletal development. In; Gage JR, Schwartz MH, Koop SE, Novacheck TF (ed). The identification and treatment of gait problem in cerebral palsy. Mac Keith Press: 2nd edition; 2009. p. 107-29
3. Theologis T. Lever arm dysfunction in cerebral palsy gait-CURRENT CONCEPT REVIEW. J Child Orthop 2013; 7:379–92.
4. Robin J, Graham H K, Selber P, Dobson F, Smith K, Baker R. Proximal femoral geometry in cerebral palsy: A Population-Based Cross-Sectional Study. J Bone Joint Surg [Br] 2008; 90-B: 1372-79.
5. Ounpuu S, Solomito M, Bell K, Pierz K. Long-term outcomes of external femoral derotation osteotomy in children with cerebral palsy. Gait Posture 2017; 56: 82-8.
6. Root L. Surgical treatment for hip pain in the adult cerebral palsy patient. Dev Med Child Neurol, 2009; 51 (Suppl. 4): 84–91.
7. Goldschmidt RB. Instability of the hip in cerebral palsy. Curr. Orthop. 1998; 12: 40-50.
8. Soo B, Howard JJ, Boyd RN, Reid SM, Lanigan A, Wolfe R, Reddihough D, Graham K. Hip Displacement in Cerebral Palsy. J Bone Joint Surg (Am) 2006; 88-A: 121-9.
9. Bowena RE and Kehl DK. Radiographic outcome of soft-tissue surgery for hip subluxation in non-ambulatory children with cerebral palsy. J Pediatr Orthop 2006; 15 (2):109–12.
10. Robb JE, Hagglund G. Hip surveillance and management of the displaced hip in cerebral palsy. J Child Orthop 2013; 7:407–13.
11. Min JJ, Kwon SS, Sung KH, Lee KM, Chung CY, Park MS. Remodeling of femoral head deformity after hip reconstructive surgery in patients with cerebral palsy. J Bone Joint 2021; 103 B(1):198–203.
12. Hagglund G, Lauge-Pedersen H, Persson M. Radiographic threshold values for hip screening in cerebral palsy. J Child Orthop 2007: 1:43–7.
13. Fernandez-Palazzi F, Carpio A. Adductor Myotomy in Cerebral Palsy: Uni or Bilateral. J Child Orthop 2008; 2:225–7.
14. Shore BJ, Yu X, Desai S, Selber P, Wolfe R, Graham HK. Adductor Surgery to Prevent Hip Displacement in Children with Cerebral Palsy: The Predictive Role of the Gross Motor Function Classification System. J Bone Joint Surg (Am) 2012; 94:326-34.
15. Presedo A, Oh CW, Dabney KW, Miller F. Soft-Tissue Releases to Treat Spastic Hip Subluxation in Children with Cerebral Palsy. J Bone Joint Surg 2005; 87-A (4): 832-41.
16. Hsieh HC, Wang TM, Kuo KN, Huang SC, Wu KW. Guided Growth Improves Coxa Valga and Hip Subluxation in Children with Cerebral Palsy. Clin Orthop Relat Res (2019) 477:2568-76.
17. Davids JR. Proximal Femur Guided Growth for the Management of Hip Dysplasia in Children with Cerebral Palsy. J Pediatr Orthop B 2021; 3 (2):1-7.
18. Huh K, Rethlefsen SA, Wren TAL, Kay RM. Surgical Management of Hip Subluxation and Dislocation in Children with Cerebral Palsy: Isolated VDRO or Combined Surgery? J Pediatr Orthop 2011; 31(8): 858:63.
19. Root L, Laplaza FJ, Brourman SN, Angel DH. The severely unstable hip in cerebral palsy. Treatment with open reduction, pelvic osteotomy, and femoral osteotomy with shortening. J Bone Joint Surg (Am) 1995; 77:703-12.
20. Shore BJ, Zurakowaski D, Dufreny C, Powell D, Matheney TH, Snyder BD. Proximal femoral varus derotation osteotomy in children with cerebral palsy: The effect of age, gross motor function classification system level & surgeon volume on surgical success. J Bone Joint Surg (Am) 2015; 97:2024-31.
21. Pirpiris M, Trivett A, Baker R, Rodda J, Nattrass GR, Graham HK. Femoral derotation osteotomy in spastic diplegia proximal or distal? J Bone Joint Surg [Br] 2003;85-B:265-72.
22. Hosseinzadeh P, Baldwin K, Minaie A, Miller F. Management of Hip Disorders in Patients with Cerebral Palsy. J Bone Joint Surg 2020;8(3): e0148 •
23. Mazur JM, Danko AM, Standard SC, Loveless EA, Cummings RJ. Remodeling of the proximal femur after varus osteotomy in children with cerebral palsy. Dev Med Child Neurol 2004; 46: 412–5.
24. Davids JR. Management of Neuromuscular Hip Dysplasia in Children with Cerebral Palsy: Lessons and Challenges. J Pediatr Orthop 2018; 38 (6) Supplement 1:21-7.
25. Reidy K, Heidt C, Dierauer S, Huber H. A balanced approach for stable hips in children with cerebral palsy: a combination of moderate VDRO and pelvic osteotomy. J Child Orthop (2016); 10:281–8.
26. Mubarak SJ, Valencia FG, and Wenger DR. One-Stage Correction of the Spastic Dislocated Hip: use of pericapsular acetabuloplasty to improve coverage. J Bone Joint Surg. 1992; 74-A (9): 1347-57.
27. Canavese F, Emara K, Sembrano JN, Bialik V, Aiona MD, Sussman MD. Varus Derotation Osteotomy for the Treatment of Hip Subluxation and Dislocation in GMFCS Level III to V Patients with Unilateral Hip Involvement. Follow-up at Skeletal Maturity. J Pediatr Orthop 2010; 30 (4): 357-64.
28. Dhawale A, Karatas AF, Holmes L, Rogers KJ, Dabney KW, Miller F. Long-term outcome of reconstruction of the hip in young children with cerebral palsy. Bone Joint J 2013; 95-B: 259–65.
29. Shore BJ, Graham HK. Management of Moderate to Severe Hip Displacement in Non-ambulatory Children with Cerebral Palsy. J Bone Joint Surg 2017; 5 (12):e4.

 


How to Cite this Article:  Jain J | Lever Arm dysfunction of Hips in Cerebral Palsy | International Journal of Paediatric Orthopaedics | January-April 2024; 10(1): 14-19 .  https://doi.org/10.13107/ijpo.2024.v10i01.173

(Article Text HTML)      (Full Text PDF)


Understanding the Biomechanics of Lever Arm Disorders in Cerebral Palsy

Volume 10 | Issue 1 | January-April 2024 | Page: 09-13 | Jayanth Sampath, Taral Nagda

DOI- https://doi.org/10.13107/ijpo.2024.v10i01.172

Submitted: 01/02/2024; Reviewed: 14/02/2024; Accepted: 18/03/2024; Published: 10/04/2024


Authors: Jayanth Sampath MS Ortho [1], Taral Nagda MS Ortho [2]

[1] Department of Paediatric Orthopaedics, Rainbow Children’s Hospital, Bangalore, Karnataka, India.

[2] Department of Paediatric Orthopaedics, SRCC NH Children’s Hospital, Mumbai, Maharashtra, India

Address of Correspondence

Dr. Jayanth S. Sampath,
Rainbow Children’s Hospital, Bangalore, Karnataka, India.
E-mail: jayanthdoc@gmail.com


Abstract

Levers in the human body play an important role in facilitating efficient movement. Muscle forces act around the axis of movement of adjacent joints. The normal moment of a joint (M) is the product of the muscle force (F) and the length of lever arm (d). The primary neurological insult in cerebral palsy (CP) causes shortening of muscles, joint contractures, and torsional abnormalities in bones. The resulting ineffective lever arm leads to a failure to produce an appropriate torque and subsequent gait abnormalities. Therefore, the effects of lever arm dysfunction should be considered when gait improvement surgery is being offered to children with CP. This review will explain the role of levers in normal human biomechanics and the significance of lever arm dysfunction in the management of CP.
Keywords: Biomechanics, Lever arm, Disorder, Cerebral palsy


References

1. Gage JR, editor. The treatment of gait problems in cerebral palsy. 2nd ed. London: Mac Keith Press; 2004. Treatment principles for crouch gait; p 382-97.
2. Theologis T. Lever arm dysfunction in cerebral palsy gait. J Child Orthop. 2013;7(5):379-382.
3. Kalkman BM, Bar-On L, Cenni F, et al. Achilles tendon moment arm length is smaller in children with cerebral palsy than in typically developing children. J Biomech. 2017;56:48-54.
4. Õunpuu S, Solomito M, Bell K, Pierz K. Long-term outcomes of external femoral derotation osteotomies in children with cerebral palsy. Gait Posture. 2017;56(March 2016):82-88..
5. Kim HY, Cha YH, Chun YS, Shin HS. Correlation of the torsion values measured by rotational profile, kinematics, and CT study in CP patients. Gait Posture. 2017;57:241-245.
6. Saglam Y, Ekin Akalan N, Temelli Y, Kuchimov S. Femoral derotation osteotomy with multi-level soft tissue procedures in children with cerebral palsy: Does it improve gait quality? J Child Orthop. 2016;10(1):41-48.
7. Kadhim M, Miller F. Crouch gait changes after planovalgus foot deformity correction in ambulatory children with cerebral palsy. Gait Posture. 2014;39(2):793-798.
8. Kadhim M, Holmes L, Miller F. Long-term Outcome of Planovalgus Foot Surgical Correction in Children with Cerebral Palsy. J Foot Ankle Surg. 2013;52(6):697-703.
9. Kim HT, Jang JH, Ahn JM, Lee JS, Kang DJ. Early results of one-stage correction for hip instability in cerebral palsy. Clin Orthop Surg. 2012;4(2):139-148.
10. Ganjwala D. Multilevel orthopedic surgery for crouch gait in cerebral palsy: An evaluation using functional mobility and energy cost. Indian J Orthop. 2011;45(4):314..
11. Foroohar A, McCarthy JJ, Yucha D, Clarke S, Brey J. Head-shaft angle measurement in children with cerebral palsy. J Pediatr Orthop. 2009;29(3):248-250.
12. Rethlefsen SA. Causes of Intoeing Gait in Children with Cerebral Palsy. J Bone Jt Surg. 2006;88(10):2175..
13. Čobeljić G, Djorić I, Bajin Z, Despot B. Femoral derotation osteotomy in cerebral palsy: Precise determination by tables. Clin Orthop Relat Res. 2006;(452):216-224.
14. Kadhim M, Holmes L, Church C, Henley J, Miller F. Pes planovalgus deformity surgical correction in ambulatory children with cerebral palsy. J Child Orthop. 2012;6(3):217-227.
15. Aiona M, Calligeros K, Pierce R. Coronal plane knee moments improve after correcting external tibial torsion in patients with cerebral palsy. Clin Orthop Relat Res. 2012;470(5):1327-1333.
16. Davids JR, Gibson TW, Pugh LI, Hardin JW. Proximal femoral geometry before and after varus rotational osteotomy in children with cerebral palsy and neuromuscular hip dysplasia. J Pediatr Orthop. 2013;33(2):182-189.
17. Rodda JM, Sciences H. Severe Crouch Gait in the Sagittal Gait Patterns of Spastic Diplegic Cerebral Palsy : the Impact of Single Event Multilevel Surgery. 2005;(November).
18. Inan M, Altinta?? F, Duru I. The evaluation and management of rotational deformity in cerebral palsy. Acta Orthop Traumatol Turc. 2009;43(2):106-112.
19. Heimkes B, Stotz S, Heid T. Pathogenesis and prevention of spastic hip dislocation. Z Orthop Ihre Grenzgeb. 1992;130(5):413-418.
20. Pirpiris M, Trivett A, Baker R, Rodda J, Nattrass GR, Graham HK. Femoral derotation osteotomy in spastic diplegia. J Bone Jt Surg. 2003;85(2):265-272.


How to Cite this Article:  Sampath J, Nagda T | Understanding the Biomechanics of Lever Arm Disorders in Cerebral Palsy | International Journal of Paediatric Orthopaedics | January-April 2024; 10(1): 09-13 . https://doi.org/10.13107/ijpo.2024.v10i01.172

(Article Text HTML)      (Full Text PDF)


Indian Hip Surveillance Guidelines for Children with Cerebral Palsy

Volume 10 | Issue 1 | January-April 2024 | Page: 02-08 | Ashok N Johari, Dhiren Ganjwala, Alaric Aroojis

DOI- https://doi.org/10.13107/ijpo.2024.v10i01.171

Submitted: 12/01/2024; Reviewed: 09/02/2024; Accepted: 18/02/2024; Published: 10/04/2024


Authors: Ashok N Johari MS Ortho [1], Dhiren Ganjwala MS Ortho [2], Alaric Aroojis MS Ortho [3]

[1] Department of Paediatric Orthopaedic & Spine Surgery, Children’s Orthopaedic Centre, Mumbai, Maharashtra, India.
[2] Department of Paediatric Orthopaedic Surgery, Ganjwala Orthopaedic Hospital, Ahmedabad, Gujarat, India.
[3] Department of Paediatric Orthopaedics, Bai Jerbai Wadia Hospital for Children, Mumbai, Maharashtra, India.

Address of Correspondence

Dr. Alaric Aroojis
Hon. Consultant, Paediatric Orthopaedics, Bai Jerbai Wadia Hospital for Children, Mumbai, Maharashtra, India.
E-mail: aaroojis@gmail.com


Guidelines

Preamble:
Hip displacement is the second most common musculoskeletal impairment in children with cerebral palsy (CP). More than one-third of the children are affected by this problem. Hip displacement in children with CP is often asymptomatic until the hip is partially or fully dislocated, resulting in pain, gait disturbances, impaired sitting balance, difficulty in perineal care and pressure sores. The incidence of hip displacement is much higher in non-ambulatory children.

It is now well-known that hip surveillance programmes can effectively detect hip displacement early, leading to earlier proactive management with better outcomes. National and provincial hip surveillance programmes have been developed and adopted in various regions of the world, with evidence supporting the role of surveillance in preventing dislocations and avoiding the need for salvage surgery.

To offer similar benefits to Indian children with CP, a guidelines development project on National Hip Surveillance Program for Cerebral Palsy was initiated in May 2020. Based on the outcome of the one-year guidelines’ development project, this guidelines document was prepared from an Indian practice perspective.

About development of this Indian guideline:
Professional organisations whose members are involved in the care of children with CP were involved in the formation of this guideline. A National Expert Committee was constituted with representatives of these organisations. Advice was sought from international experts on this topic who acted as the Advisory Committee.

In phase 1: The Expert Committee reviewed more than 80 published research articles related to various aspects of hip displacement in CP. Key points from these articles were listed. National guidelines from other countries/regions were also reviewed, discussed and referred.

In phase 2: All important questions related to hip surveillance were listed. These questions were circulated to all the members of the expert committee. The Delphi process was used to develop consensus on these practical questions. When more than 80% of group members agreed to a particular viewpoint, it was considered as a consensus. With two rounds of the Delphi process, the committee reached a consensus on every single question. Consensus statements were listed.

In phase 3: The guideline was drafted based on these consensus statements. The main document was written keeping the from a healthcare professional’s perspective. A simple version of this guideline was also prepared to spread awareness about this important message to the caregivers / family / healthcare aid workers.

NATIONAL GUIDELINES COMMITTEE

STEERING COMMITTEE
Dr. Ashok N. Johari
Paediatric Orthopaedic & Spine Surgeon, Children’s Orthopaedic Centre, Mumbai, India

Dr. Dhiren Ganjwala
Consultant Paediatric Orthopaedic Surgeon, Ganjwala Orthopaedic Hospital, Ahmedabad, India

Dr. Alaric Aroojis
Hon. Consultant, Paediatric Orthopaedics, Bai Jerbai Wadia Hospital for Children, Mumbai, India

ADVISORY BOARD
Dr. Kishore Mulpuri
Paediatric Orthopaedic Surgeon, BC Children’s Hospital, Vancouver, Canada

Stacey Miller
Lead Physiotherapist, BC Children’s Hospital, Vancouver, Canada

Dr. Abhay Khot
Paediatric Orthopaedic Surgeon, Royal Children’s Hospital, Melbourne, Australia

Dr. Mohan Belthur
Attending Paediatric Orthopaedic Surgeon, Phoenix Children’s Hospital, Phoenix, Arizona, USA

COMMITTEE MEMBERS
Dr. Sakti Prasad Das
Director, SV NIRTAR, Orissa, India

Dr. Anand Varma
Dept. of Physical Medicine & Rehabilitation, Karnataka Institute of Medical Sciences, Hubballi, India

Asha Chitnis
Consultant Paediatric Therapist, Vedanta Programs, Mumbai, India

Madhavi Kelapure
Paediatric Physiotherapist, Deenanath Mangeshkar Hospital, Pune, India

Trupti Nikharge
Occupational Therapist, B.Y.L.Nair Hospital, Mumbai, India

Dr. Meenakshi Murthy Girish
Professor & Head, Paediatrics, AIIMS, Nagpur, India

Dr. Leena Srivastava
Head, Child Development and Guidance Centre, Bharati Vidyapeeth Medical College and Hospital, Pune, India

Dr. Anaita Udwadia-Hegde
Consultant Paediatric Neurologist, Jaslok Hospital and Research Centre, Mumbai, India.

Dr. Surekha Rajadhyaksha
Professor and Chief of Paediatric Neurology and Epilepsy, Bharati Vidyapeeth Hospital, Pune, India

Dr. Mahesh Kamate
Professor of Paediatric Neurology, KAHER’s JN Medical College, Belagavi, India

Dr. Sandeep Patwardhan
Professor of Orthopaedics, Paediatric orthopaedics, Sancheti Institute for Orthopaedics and Rehabilitation, Pune, India

Dr. T.S. Gopakumar
Professor of Orthopaedics, MES Medical College, Perinthalmanna, Malappuram, India

Dr. P N Gupta
Professor, Department of Orthopaedics, Govt. Medical College Hospital, Chandigarh, India

Dr. Jayanth Sampath
Consultant Paediatric Orthopaedic Surgeon, Rainbow Children’s Hospital, Bangalore, India

Dr. Binu Kurian
Consultant Paediatric Orthopaedic Surgeon, St. John’s Medical College Hospital, Bangalore, India

Dr. Abhay Gahukamble
Assistant Professor, Dept of Orthopaedic Surgery at Christian Medical College and Hospital, Vellore, India

Dr. Sanjay Wadhwa
Professor, Dept. of PMR, AIIMS, New Delhi, India

Punita V. Solanki
Occupational Therapist, Mumbai, India

Dr. Rekha MittalAdditional Director (Paediatric Neurology), Madhukar Rainbow Children’s Hospital, New Delhi, India

Aijaaz Ashai
Director & HOD, Adams Wylie Physio Rehab Center, Mumbai, India


This guideline is for the medical professionals who are involved in the care of children with cerebral palsy (CP).

Children with cerebral palsy are at increased risk for hip displacement. Hip displacement may occur gradually and may not be painful initially. However, many dislocated hips become painful eventually and lead to reduced function and impaired quality of life. [1]

What is hip surveillance?
Hip surveillance is a process of actively monitoring the child for early identification of hip displacement. It is carried out by clinical and radiographic examinations at regular intervals, so that silent hip impairments are identified. When hip impairments are identified early, they can be managed by less aggressive surgical interventions, thus leading to better structural and functional outcomes. Hip surveillance has been found to be effective in several large population-based studies. [2]

Who should be surveilled?
All children and youth diagnosed with CP and those children not yet diagnosed with CP but for whom there is a clinical suspicion of having CP should be enrolled for surveillance. Besides the spastic variety, dystonic, athetoid, ataxic and hypotonic types of CP are included in hip surveillance.

By whom should the child be surveilled?
All trained clinicians working with children with CP can carry out hip surveillance. These include paediatricians, developmental paediatricians, paediatric neurologists, physical therapists, occupational therapists, physical medicine & rehabilitation experts, orthopaedic surgeons, and paediatric orthopaedic surgeons.

How the child should be surveilled?
Each visit for surveillance consists of two components: a clinical examination and a radiographic examination.

The clinical examination includes determining / re-confirming the Gross Motor Function Classification System (GMFCS) level. Inquiring about hip pain that may be present when moving the hip, changing positions, when looking after personal care.

The passive range of abduction is measured for each hip with maximum possible extension at the hips and knees (Figure 1). Attention is given to the presence of pain while moving the hip. Gait observation should identify cases having Winters, Gage & Hicks (WGH) type 4 gait pattern. They form a subset that deserves special attention.

The examiner also looks for pelvic asymmetry and scoliosis (Figure 2).

The radiographic examination consists of taking an antero-posterior (AP) pelvis radiograph in a supine position with standardized positioning. The pelvis is squared whilst positioning. The hips are kept in neutral abduction/adduction (Figure 3). The patellae should face upwards. For children having flexion deformity at the hips, both lower limbs are flexed at the hips till lumbar lordosis is obliterated. This prevents anterior tilting of the pelvis (Figure 4 & 5).

Migration percentage (MP) is measured on an anteroposterior radiograph. [3] It measures the percentage of the ossified femoral head that lies outside the ossified acetabular roof. To measure the MP, a horizontal line is drawn through each triradiate cartilage (solid horizontal line) and a vertical line is drawn perpendicular to it at the lateral margin of the ossified acetabulum (solid vertical line). Two lines are drawn parallel to this solid vertical line at the medial and lateral border of the ossified femoral head (dotted lines). The distance between these two dotted lines is the width of the ossified femoral head (B). The width of the femoral head which is lateral to the solid vertical line (A) is divided by the width of the ossified femoral head (B). Migration percentage = A/B x 100 (Figure 6).


Migration percentage (MP) is measured for each hip separately.

How frequently should the child be surveilled?
Surveillance should preferably start by the of 2 years for children for whom the diagnosis of CP is made, or even at an earlier age when the diagnosis of CP is suspected. Surveillance frequency depends mainly on the GMFCS level, age of the child, and the age at which hip surveillance is started.
For the sake of easy understanding, the CP population is divided into 3 groups.
• GMFCS level I & II
• GMFCS level III
• GMFCS level IV & V

Children with GMFCS level I & II function should have a clinical and radiographic examination at 2, 6, and 10 years. In addition, they should have clinical examination at age 4 years and 8 years. Children with a Group IV hemiplegic gait pattern should have a clinical exam and x-ray every 2 years after the age 10 years till skeletal maturity.

Children with GMFCS level III function require clinical and radiographical examination every year till the age of 8 years. After 8 years, hip surveillance is carried out every 2 years till skeletal maturity if MP remains less than 30% and MP is stable (stability defined as <10% change in MP over a 12-month period). If a child enters hip surveillance after the age of 8 years, the child should have yearly radiograph for first 2 years and thereafter the frequency is reduced to once in 2 years..

Children with GMFCS level IV and V function should have a clinical and radiographic examinations every 6 months for the first two years. If the MP is less than 30% and MP is stable (stability defined as <10% change in MP over a 12-month period), clinical exams and imaging may be reduced to annual visit. Children at GMFCS level IV and V should have a clinical and radiographic examination every year till skeletal maturity. If a child enters hip surveillance after the age of 4 years, the child should have a radiograph every 6 months for the first 2 years and thereafter the frequency is reduced to annual x-rays.

If in doubt about the GMFCS level, consider the child to have a more severe GMFCS level and accordingly follow guidelines for that GMFCS level.

For quick visual reference please see the figure 7.

Time of discharge from hip surveillance

Children at GMFCS levels I & II are discharged at 10 years if the MP is stable and less than 30%. An exception is a child with Winter & Gage hemiplegic type 4 gait, who should be followed up till skeletal maturity.

Children at GMFCS levels III, IV & V are discharged when they attain skeletal maturity, have MP < 30%, and when pelvic obliquity and scoliosis are not progressive on clinical examinations. Closure of the triradiate cartilage on the AP pelvis x-ray is used to indicate skeletal maturity (Figure 8).

Exception: Child having MP > 30% or progressive pelvic obliquity or scoliosis requires continued surveillance.

What should be the further line of action after hip surveillance?
A child is referred to paediatric orthopaedic surgeons, if
• MP value is 30% or more
• If MP is less than 30% but a child has hip abduction less than 30 degrees
• If MP is less than 30% but a child has hip pain during a clinical exam
• If MP is less than 30% but child / family reports pain at hip during activities
All other children continue to undergo hip surveillance till they are discharged from the surveillance program.

Additional information:
Gross Motor Function Classification System (GMFCS)
The GMFCS is a validated classification system used to describe the gross motor function of children with CP. [4] The expanded and revised version of the GMFCS which is available online is used as a reference. It can be downloaded free of charge from the website https://www.canchild.ca/system/tenon/assets/attachments/000/000/058/original/GMFCS-ER_English.pdf

The GMFCS classifies the children and young adults into five levels on the basis of their self-initiated movement with particular emphasis on sitting, walking, and wheeled mobility. The GMFCS has five levels for describing differences in severity of motor abilities. Distinctions between levels are based on functional limitations, the need for hand-held mobility devices or wheeled mobility. For different age groups, separate descriptions are provided. Generally, it takes only a few minutes to assign a GMFCS level.
The GMFCS is relatively stable but in small children it is likely to change. [5] So, it is important that during each visit, GMFCS level is reconfirmed or re-evaluated.

GMFCS levels I & II suggest a child who is ambulatory without handheld mobility aid. Figure 9 & 10 represent typical GMFCS I & II children in the age group of 6 to 12 years.

GMFCS level III suggests a child who is ambulatory with handheld mobility aid. Figure 11 represents typical GMFCS III children in the age group of 6 to 12 years.

GMFCS level IV represents a child who is a marginal ambulator. For walking, they need the help of a caretaker and the mobility aid (Figure 12). Child at GMFCS level V is considered non-ambulatory (Figure 13).

Winters, Gage and Hicks (WGH) type 4 gait
Winters, Gage and Hicks described four types of gait pattern in hemiplegic children with CP. [6] This classification was based on the sagittal plane kinematics of the ankle, knee, hip and pelvis. The Australian CP group added frontal and transverse planes kinematics to this classification. Child with type 4 gait walks with hip flexed, adducted and internally rotated, knee flexed and ankle in equinus. (Figure 14) Type 4 child can be distinguished easily by gait observation. One does not need computerised gait analysis for identifying this gait pattern.

Key points
• Hip Surveillance detects hip displacement early and reduces the need for major surgeries.
• Hip surveillance can be carried out by all medical and allied healthcare professionals involved in the care of children with CP.
• Children with all motor types of CP require hip surveillance.
• Surveillance frequency mainly depends on the GMFCS level and the age of the child.
• Migration percentage is used to quantify the severity of hip displacement on standardised AP pelvis radiographs.
• A child is referred to a paediatric orthopaedic / orthopaedic surgeon if MP value is 30% or more, hip abduction is less than 30 degrees, or if hip pain is reported during clinical examination or while performing certain activities.


References

1. Ramstad K, Terjesen T: Hip pain is more frequent in severe hip displacement: A population-based study of 77 children with cerebral palsy. J Pediatr Orthop B 2016;25: 217-221.
2. Hagglund G, Alriksson-Schmidt A, Lauge-Pedersen H, Robdy-Bousquet E, Wagner P, Westbom L: Prevention of dislocation of the hip in children with cerebral palsy: 20 year results of a population-based prevention programme. Bone Joint J 2014;96-B:1546-1552.
3. Reimers, J. The stability of the hip in children. A radiological study of the results of muscle surgery in cerebral palsy. Acta Orthop Scand 1980; 184: S1-100.
4. Wood E, Rosenbaum P. The gross motor function classification system for cerebral palsy: a study of reliability and stability over time. Dev Med Child Neurol 2000; 42: 292– 96.
5. Palisano RJ, Cameron D, Rosenbaum PL, Walter SD, Russell D. Stability of the gross motor function classification system. Dev Med Child Neurol 2006; 48: 424– 28.
6. Winters T, Gage J, Hicks R. Gait patterns in spastic hemiplegia in children and young adults. J Bone Joint Surg Am 1987; 69(3): 437-441.


How to Cite this Article:  Johari AN, Ganjwala D, Aroojis A | Indian Hip Surveillance Guidelines for Children with Cerebral Palsy | International Journal of Paediatric Orthopaedics | January-April 2024; 10(1): 02-08 . https://doi.org/10.13107/ijpo.2024.v10i01.171

(Article Text HTML)      (Full Text PDF)


Split Transfer of Tibialis Posterior for Dynamic Equinovarus Deformity in Children with Cerebral Palsy

Volume 9 | Issue 2 | May-August 2023 | Page: 06-09 | Ravi Chandra Vattipalli, Manoranjan Bandela

DOI- https://doi.org/10.13107/ijpo.2023.v09.i02.164

Submitted: 14/12/2022; Reviewed: 12/02/2023; Accepted: 15/05/2023; Published: 10/08/2023


Authors: Ravi Chandra Vattipalli DNB Ortho, Manoranjan Bandela MS Ortho 

[1] Department of Orthopaedics, Apollo Hospitals, Visakhapatnam, Andhra Pradesh, India.

Address of Correspondence

Dr. Ravichandra Vattipalli,
Consultant Orthopaedic Surgeon, Apollo Hospitals, Visakhapatnam, Andhra Pradesh, India.
E-mail: vatravi@hotmail.com


Abstract

Children with cerebral palsy often have foot deformities, equinovarus being one of the most common deformities. Several procedures have been advocated, centered around rerouting the tibialis posterior tendon. Whole transfer of the tendon is associated with poor results. The current study aims to establish the efficacy of split tendon transfer of the posterior tibial tendon rerouted through the interosseous membrane and anchored to the lateral cuneiform. Surgical results were analyzed using an indigenously developed score, considering the cultural need for bare foot walking.
Keywords- Split tendon transfer of tibialis posterior, Equinovarus deformity, Cerebral palsy


References

1. Sees JP, Miller F (2013) Overview of foot deformity management in children with cerebral palsy. J Child Orthop 7(5):373–377.
2. Michlitsch MG, Rethlefsen SA, Kay RM (2006) The contributions of anterior and posterior tibialis dysfunction to varus foot deformity in patients with cerebral palsy. J Bone Joint Surg 88(8):1764–1768.
3. Banks, H.H.: The foot and ankle in cerebral palsy. In Orthopaedic Aspects of Cerebral Palsy. Samilson, R.L. (ed.), Philadelphia, J.B. Lippincott, 1975, pp. 212-215.
4. Kling, T.F., Jr., Kaufer, H., and Hensinger, R.N.: Split posterior tibial tendon transfers in children with cerebral spastic paralysis and equinovarus deformity. J. Bone Joint Surg., 67A:186-194, 1985.
5. Baker, L . D., and HILL, L . M .: Foot Alignment in the Cerebral Palsy Patient. J. Bone and Joint Surg. , 46•A: 1- 15, Jan. 1964.
6. Bisla R . S.; Louis. H . J.: and Albano P: Transfer of Tibial is Posterior Tendon in Cerebral Palsy. J. Bone and Joint Surg. , 5&A: 497-500, June 197 h.
7. Br ccx, E. E.: Orthopaedic Management of Cerebral Palsy. Philadelphia, W. B. Saunders, 1979.
8. GRITZK», T. L.; Six ti ELi, L . T.; and DU Ncx N , W . R.: Posterior Tibial Tendon Transfer through the I nterosseous Membrane to Correct Equinovarus deformity in Cerebral Palsy. An Initial Experience. Clin. Orthop. , 89: 201-206, 1972.
9. K xuren, H ERBERT: Split Tendon Transfers. Orthop. Trans. . 1: 191 . 1977.
10. R uox, R., and FROST, H . M .: Cerebral Palsy: Spastic Varus and Forefoot Adductus, Treated by I ntramuscular Posterior Tibial Tendon Lengthening. Clin. Orthop. . 79: 61 70, 1971 .
11. SCHt4 EiDes, MonaoE, and Be LOW, Koas EL : Deformity of the Foot following Anterior Transfer of the Posterior Tibial Tendon and Lengthening of the Achilles Tendon for Spastic Equinovarus. Clin. Orthop. , 125: 113- 118, 1977.
12. TrnmEn, J. W., and CooeER, R . R .: A nterior Transfer of the Tibialis Posterior through the I nterosseous Membrane. Clin. Orthop. , 83: 241-244, 1972.
13. Wx ter ss, M . B.; Jones, J. B .; R ¥ DER, C. T.; and Bnow s, T. H .: Transplantation of the Posterior Tibial Tendon. J. Bone and Joint Surg. ,36-A: 1181- 1189, Dec. 1954.
14. W tLLix sis. P. F.: Restoration of Muscle Balance of the Foot by Transfer of the Tibialis Posterior. J. Bone and Joint Surg. , 58-Bf 21: 217-219, 1976.
15. Vlachou M, Dimitriadis D (2010) Split tendon trasnsfer for the correction of the spastic varus deformity: a case series study. J Foot Ankle Res 3:28.
16. Kaufer H (1977) Split tendon tranfers. Orthop Trans 1:191.
17. Green NE, Griffin PP, Shiavi R (1983) Split posterior tibial tendon in spastic cerebral palsy. J Bone Joint Surg 65(6):748–75.
18. Kling TF, Kaufer H, Hensinger RN (1985) Split posterior tibial tendon transfers in children with cerebral spastic paralysis and equinovarus deformity. J Bone Joint Surg 67(2):186–194.
19. Aleksić, M., Baščarevic, Z., Stevanović, V. et al. Modified split tendon transfer of posterior tibialis muscle in the treatment of spastic equinovarus foot deformity: long-term results and comparison with the standard procedure. International Orthopedics (SICOT) 44, 155–160 (2020).
20. GREE s, N.: Strength of the A nterior Tibial Muscle in Spastic Hemiplegic Cerebral Palsy. In press
21. Lagast, J., Mylle, J., and Fabry, G.: Posterior tibial tendon transfer in spastic equinovarus. Arch. Orthop. Traum. Surg.,108:100-103,1989.
22. Schneider, M., and Balon, K.: Deformity of the foot following anterior transfer of the posterior tibial tendon and lengthening of the achilles tendon for spastic equinovarus. Clin. Orthop., 125:113-118, 1977.
23. Turner, J.W., and Cooper, R.R.: Anterior transfer of the tibialis posterior through the interosseous membrane. Clin. Orthop.,83:241-245, 1972.
24. Williams, P.F.: Restoration of muscle balance of the foot by transfer of the tibialis posterior. J. Bone Joint Surg., 58B:217219,1976.
25. Mulier T, Moens P, Molenaers G et al (1995) Split posterior tibial tendon transfer through the interosseous membrane in spastic equinovarus deformity. Foot Ankle Int 16(12):754–759.
26. Saji MJ, Upadhyay SS, Hsu LC et al (1993) Split tibialis posterior transfer for equinovarus deformity of cerebral palsy. Long-term results of a new surgical procedure. J Bone Joint Surg (Br) 75(3): 498–501.


How to Cite this Article:  Vattipalli R, Bandela M | Split Transfer of Tibialis Posterior for Dynamic Equinovarus Deformity in Children with Cerebral Palsy | International Journal of Paediatric Orthopaedics | May-August 2023; 9(2): 06-09 | https://doi.org/10.13107/ijpo.2023.v09.i02.164

(Article Text HTML)      (Full Text PDF)


A Review of Decision Making in Foot Problems in Cerebral Palsy

Volume 8 | Issue 3 | September-December 2022 | Page: 02-05| Rohan Parwani

DOI- https://doi.org/10.13107/ijpo.2022.v08i03.142


Authors: Rohan Parwani [1]

[1] Department of Orthopaedics, Shri M P Shah Medical College, Jamnagar, Gujarat, India.

Address of Correspondence

Dr. Rohan Parwani
Assistant Professor, Department of Orthopaedics, Shri M. P Shah Medical College, Jamnagar, Gujarat, India.
E-mail: arthorohan@gmail.com


Abstract

Ambulatory children with cerebral palsy suffer from a range of problems. There are issues with stance, stability, posture, and endurance. The foot plays a significant role in the pathogenesis and treatment of these problems, especially in the lower limb. Our review article tries to highlight the foot problems and their solutions. The most common deformity in a child with cerebral palsy is the hindfoot equinus. This fixed deformity leads to poor balance in stance and reduced power generated during the push-off phase. Proper identification of the gait pattern and the role of the foot in deranging the gait can help decide ways to enhance the walk of a cerebral palsy child. Physiotherapy and stretching are vital to improving muscle physiology and growth. The weak muscles need to be supplemented with splints. There is also a significant role in the judicious use of surgery in cerebral palsy. Deciding which surgery to employ is critical and often contributes to the success or a disastrous failure. Our article highlights various facets of decision-making and ways to arrive at a proper decision.
Keywords- Cerebral palsy, Foot, Equinus, Gait


References

1. Mathewson MA, Lieber RL. Pathophysiology of muscle contractures in cerebral palsy. Phys Med Rehabil Clin N Am. 2015;26(1):57-67.
2. Abd El Aziz HG, Khatib AHE, Hamada HA. Does the Type of Toeing Affect Balance in Children With Diplegic Cerebral Palsy? An Observational Cross-sectional Study. J Chiropr Med. 2019;18(3):229-235.
3. Sees JP, Miller F. Overview of foot deformity management in children with cerebral palsy. J Child Orthop. 2013;7(5):373-377.
4. Kadhim M, Holmes L Jr, Church C, Henley J, Miller F. Pes planovalgus deformity surgical correction in ambulatory children with cerebral palsy. J Child Orthop. 2012;6(3):217-227.
5. Brunner R, Rutz E. Biomechanics and muscle function during gait. J Child Orthop. 2013;7(5):367-371.
6. Atbaşı Z, Erdem Y, Kose O, Demiralp B, Ilkbahar S, Tekin HO. Relationship Between Hallux Valgus and Pes Planus: Real or Fiction? J Foot Ankle Surg. 2020 May-Jun;59(3):513-517.
7. DOBSON, F. (2010), Assessing selective motor control in children with cerebral palsy. Developmental Medicine & Child Neurology, 52: 409-410.
8. Davids JR, Holland WC, Sutherland DH. Significance of the confusion test in cerebral palsy. J Pediatr Orthop. 1993 Nov-Dec;13(6):717-21.
9. Maas, Josina & Dallmeijer, Annet & Huijing, Peter & Brunstrom-Hernandez, Janice & Kampen, Petra & Jaspers, Richard & Becher, Jules. (2012). Splint: The efficacy of orthotic management in rest to prevent equinus in children with cerebral palsy, a randomised controlled trial. BMC pediatrics. 12. 38. 10.1186/1471-2431-12-38.
10. Ganjwala D, Shah H. Management of the Knee Problems in Spastic Cerebral Palsy. Indian J Orthop. 2019;53(1):53-62.
11. Givon U. Beyin felcinde kas zayifliği [Muscle weakness in cerebral palsy]. Acta Orthop Traumatol Turc. 2009 Mar-Apr;43(2):87-93.
12. Chambers MA, Moylan JS, Smith JD, Goodyear LJ, Reid MB. Stretch-stimulated glucose uptake in skeletal muscle is mediated by reactive oxygen species and p38 MAP-kinase. J Physiol. 2009;587(Pt 13):3363-3373.
13. Graham, H.K.. (2001), Botulinum toxin type A management of spasticity in the context of orthopaedic surgery for children with spastic cerebral palsy. European Journal of Neurology, 8: 30-39.
14. Kadhim M, Miller F. Crouch gait changes after planovalgus foot deformity correction in ambulatory children with cerebral palsy. Gait Posture. 2014 Feb;39(2):793-8.
15. Sung KH, Chung CY, Lee KM, Lee SY, Park MS. Calcaneal lengthening for planovalgus foot deformity in patients with cerebral palsy. Clin Orthop Relat Res. 2013;471(5):1682-1690.
16. Bishay S, Morshed GM, Tarraf Y, Pasha N (2016) Double Column Foot Osteotomy to Correct Flexible Valgus Foot Deformity in Children with Spastic Cerebral Palsy. Clin Res Foot Ankle 4:198.


How to Cite this Article: Parwani R | A Review of Decision Making in Foot Problems in Cerebral Palsy | International Journal of Paediatric Orthopaedics | May-August 2022; 8(2): 02-05.
https://doi.org/10.13107/ijpo.2022.v08.i03.142

(Article Text HTML)      (Full Text PDF)