PRINCIPLES OF EXTERNAL FIXATION

1. PRINCIPLES OF EXTERNAL FIXATION 27/06/2006 Dr. Rami Eid

2. Frame components • Pins. • Clamps and Rings. • Connecting rods.

3. Pins

4. Clamps and Rings

5. Frame Design • One plane. • Two planes. • Ilizarov. • Hybrid.

6. One plane frame • Resisting sagittal bending. • Decrease compression.

7. Biplanar frame • Increase frontal bending stiffness. • Increase resistance to torsion.

8. Multiplanar frame • Obstructs soft tissue access. • More stability and early weight bearing. • Bone defect reconstruction.

9. Hybrid frame • Rigid fixation of periarticular fractures with less complexity than a ring fixator.

10. Factors affecting the stability of external fixation

11. To Be Safe and Effective : • Avoid injuries to the vital limb anatomy. • Provide access for wound debridement and other procedures. • Meet the mechanical demands of the patient and the injury.

12. Complications • Loosening and chronic pain. • Pin site infection. • Deformity, delayed union, nonunion. • Nerves and vessels injuries, joint pyarthrosis. • Soft tissues contracture.

13. Professor De Bastiani started it all in the 1970’s …. in Verona, Italy

14. He did not like Plates and Screws for treating fractures • More soft tissue damage • Disturbed fracture site • Damaged periosteum • Significant deep infection • Second operation to remove • Risk of refracture

15. And he didn’t like available External Fixation Frames • Difficult to assemble • Multilateral types heavy and cumbersome • Too rigid for good callus • Second operation to remove

16. What fractures need to heal ? • Initial stability (but not complete rigidity) - to reduce pain - to keep the pieces in the right place - to help bridging callus to start growing • Additional movement later on - to help callus to mature and become hard

17. Orthofix • Rapidly applied • Monolateral • Lightweight • Stable • Minimally invasive • Half-pins • Reduction facility • Converted from RIGID to DYNAMIC

18. Orthofix

19. The Orthofix (10.000) The special features of this fixator: • The conical screws and their design • The ball-jointed clamps • The telescopic body

20. Screw Characteristics • Non-transfixing (half-pins) • Conical thread • Self-tapping • Capable of minimal flexion on weightbearing

21. Screw Characteristics

22. Callus starts to form even before Dynamization begins

23. CYCLIC MICROMOVEMENT • The fracture gap opens and closes sequentially.

24. The Ball-Jointed Clamps • Either straight clamps or T-clamps • 360° of rotation and 36° of angulation in any plane to assist fracture reduction

25. The Ball-Jointed Clamps

26. The Telescopic Body • Central body locking nut can be loosened to convert fixator to the DYNAMIC mode

27. The Telescopic Body

28. DYNAMIZATION Stable fractures: 2 – 4 weeks Unstable fractures: 5 – 8 weeks

29. DYNAMIZATION

30. If Dynamization starts too late • Prolonged healing times • Non-union • Screw loosening

31. Patient Benefits • Short operation and anaesthetic time • Lightweight device • Early mobilization • Early weightbearing • Early hospital discharge (unless polytrauma) • Joint function preserved • Out-patient removal (no second operation)

33. MoKazem.com • هذه المحاضرة هي من سلسلة محاضرات تم إعدادها و تقديمها من قبل الأطباء المقيمين في شعبة الجراحة العظمية في مشفى دمشق, تحت إشراف د. بشار ميرعلي. • الموقع غير مسؤول عن الأخطاء الواردة في هذه المحاضرة. • This lecture is one of a series of lectures were prepared and presented by residents in the department of orthopedics in Damascus hospital, under the supervision of Dr. Bashar Mirali. • This site is not responsible of any mistake may exist in this lecture. Dr. Muayad Kadhim د. مؤيد كاظم