1. General Principles in the Assessment and Treatment of Nonunions Matthew J. Weresh, MD
Original Author: Peter Cole, MD; March 2004
New Author: Matthew J. Weresh, MD; Revised August 2006
2. Definitions Nonunion: A fracture that has not and is not going to heal
Delayed union: A fracture that requires more time than is usual and ordinary to heal
3. Previous Definitions of Nonunion Nonunion: A fracture that is a minimum of 9 months post occurrence and is not healed and has not shown radiographic progression for 3 months Orthopaedic Advisory Panel: Food & Drug Administration, 1986
4. Waiting 9 months or more is often inappropriate:
Prolonged morbidity
Inability to return to work
Narcotic dependence
Emotional impairment
5. Definition of nonunion should not limit or prevent appropriate and timely intervention
“The best treatment for nonunions is prevention”
Sir John Charnley
6. “The designation of a delayed union or nonunion is currently made when the surgeon believes the fracture has little or no potential to heal.”
Donald Wiss M.D. & William Stetson M.D.
Journal American and Orthopedic Surgery 1996
7. Classification of Nonunions Two important factors for consideration
(1) Presence or absence of infection
(2) Vascularity of fracture site
8. Classification (1) Hypertrophic
(2) Oligotrophic
(3) Avascular
Weber and Cech, 1976
9. Hypertrophic Vascularized
Callus formation present on x-ray
Elephant foot - abundant callus
Horse hoof - less abundant callus (see diagram)
10. Oligotrophic No callus on x-ray
Vascularity is present on bone scan
11. Avascular Atrophic or similar to oligotrophic on x-ray
Ischemic or cold on bone scan
13. Incidence of Nonunion Boyd et.al Connolly
No. 842(1965) No.602 (1981)
Tibia 35 % 62%
Femur 19% 23%
Humerus 17.5% 7%
Forearm 15.5% 7%
Clavicle 2% 1% *Increasing frequency of tibial nonunion over time
14. Increasing relative incidence of tibial and femoral nonunion most likely secondary to improved limb salvage techniques
15. Etiology of Nonunion: �Systemic Malnutrition
Diabetes (neurovascular)
Smoking
16. Malnutrition Adequate protein and energy is required for wound healing
Screening test:
serum albumin
total lymphocyte count
Albumin less than 3.5 and lymphocytes less than 1,500 cells/ml is significant
Seltzer et.al. JPEN 1981
17. Diabetes�(Neuropathic Fractures) Neuro arthropathy is not entirely the result of unprotected weight bearing on an insensate joint
Inability to control response to trauma can result in hyperemia, osteopenia, and osteoclastic bone resorption
18. Neuropathic Fracture Nonunions Treatment, conservative (bracing) and operative, are fought with complications
No currently accepted algorithm
Consider use of biphosphonates to decrease osteolytic response
Shelby et.al. Diab. Med. 1994
Connolly J.F. and Csencsitz T.A. CORR #348 1998
Young e.t. al. Diab. Care 1995
McCormack R.G. e.t. al. JBJS 1998
19. Smoking Decreases peripheral oxygen tension
Dampens peripheral blood flow
Well documented difficulties in wound healing in patients who smoke
Schmite, M.A. e.t. al. Corr 1999
Jensen J.A. e.t. al. Arch Surg 1991
20. Smoking vs. Fracture Healing Most information is anecdotal
No prospective randomize studies on humans
Retrospective studies show time to union
69% delay in radiographic union with smoker (2 of 44 nonunions in smokers vs. 0 of 59 nonunion in nonsmokers) increased incidence of nonunion with smokers
Schmitz, M.A. e.t.al. CORR 1999
21. Etiology of Nonunion�(Local Factors) Infection
Energy of fracture mechanism
Mechanical factors of fracture configuration
Increased motion between fracture fragments
Inadequate fixation
Wolf’s Law - lack of physiologic stresses to bone
Anatomic location
22. Infection “Of all prognostic factors in tibia fracture care, that implying the worst prognosis was infection”
Nicoll E.A. CORR 1974
23. The inflammatory response to bacteria at the site of the fracture disrupts callus, increases gap between fragments, and increases motion between fragments.
24. Energy of Fracture Mechanism Initial fracture displacement
Fracture pattern i.e:
comminution
bone loss
segmental patterns
Soft tissue disruption (vascularity and oxygen delivery)
25. Initial Fracture Displacement Delayed union and nonunion were nearly three times as frequent in tibia fractures with moderate to severe displacement as compared to fractures with slight displacement.
26. Fracture Pattern Fracture patterns in higher energy injuries (i.e.: comminution, bone loss, or segmental patterns) have a higher degree of soft tissue and bone ischemia
27. Soft Tissue Disruption 1. Introgenic
2. Traumatic
28. Traumatic Soft Tissue Disruption Incidence of nonunion is increased with open fractures
More severe open fracture (i.e. Gustillo III B vs Grade I) have higher incidence of nonunion
Gustilo et.al.Jol 1984
Widenfalk et.al.Injury 1979
Edwards et.al. Ortho Trans 1979
Velazco et.al. TBJS 1983
29. Introgenic Excessive soft tissue dissection and periosteal stripping at time of previous fixation
30. Tscherne Soft Tissue Classification Not all high energy fractures are open fractures. This classification emphasizes the importance of viability of the soft tissue envelope at the zone of injury.
Fractures with Soft Tissue Injuries
Springer Verlag 1984
31. Soft Tissue Classification Grade 0: Soft tissue damage is absent or negligible
Grade I: Superficial abrasion or contusion caused by fragment pressure from within
Grade II: Deep, contaminated abrasion associated with localized skin or muscle contusion from direct trauma
Grade III: Skin extensively contused or crushed, muscle damage may be severe. Subcutaneous avulsion, possible artery injury, compartment syndrome
32. Revascularization of ischemic bone fragments in fractures is derived from the soft tissue. If the soft tissue (skin, muscle, adipose) is ischemic, it must first recover prior to revascularizing the bone.��� E.A. Holden, JBJS 1972
33. Mechanical Factors Excessive motion at fracture secondary to poor fixation, failed fixation, or inadequate immobilization
Lack of physiologic mechanical stimulation to fracture area (i.e. nonweight bearing, fracture fixed in distraction, adynamic environment with external fixation)
34. Anatomic Location of Fractures Some areas of skeleton are at risk for nonunion due to anatomic vascular considerations i.e.:
Proximal 5th metatarsal, femoral neck, carpal scaphoid
35. Diagnosis of Nonunion- History Nature of original injury (high or low energy)
Previous open wounds of injury site
Pain present at fracture site
Symptoms of infection i.e.
Antalgic gait or decrease use secondary to pain
History of any drainage or wound healing difficulties
36. Examination Alignment
Deformity
Soft tissue integrity
Erythema, warm, drainage
Vascularity of limb
Pulses, transcutaneous oximetry
Stability at fracture site
Pain assessed during this portion of examination
37. X-rays AP, lateral, and oblique (45degree internal and 45 degree external)
In majority of cases, this is all that is required to confirm nonunion
Examination under fluoroscopy to check for motion can occasionally be helpful also
38. Tomography Linear tomograms
Helpful if metallic hardware present
Helps to identify persistent fracture line in:
Hyptrophic nonunions in which x-rays are not diagnostic and pain persists at fracture site
Computed tomography and MRI are replacing linear tomography if no hardware present
39. Subclinical Undetected Infection The main diagnostic dilemma in evaluation of nonunions
40. Radionuclide Scanning Technetium - 99 diphosphonate
Detects repairable process in bone ( not specific)
Gallium - 67 citrate
Accumulate at site of inflammation (not specific)
Sequential technetium or gallium scintigraphy
Only 50-60% accuracy in subclinical ostoemyelitis
Esterhai et.al. J Ortho Res. 1985
Smith MA et.al. JBJS Br 1987
41. Indium III - Labeled Leukocyte Scan Good with acute osteomyelitis, but less effective in diagnosing chronic or subacute bone infections
Sensitivity 83-86%, specificity 84-86%
Technique is superior to technetium and gallium to identify infection
Nepola JV e.t. al. JBJS 1993
Merkel KD e.t. al. JBJS 1985
42. MRI Abnormal marrow with increased signal on T2 and low signal on T1
Can identify and follow sinus tacts and sequestrum
Mason study- diagnostic sensitivity of 100%, specificity 63%, accuracy 93%
Berquist TH et.al. Magn Res Img
Modic MT et.al. Rad. Clin Nur Am 1986
Mason MD et.al. Rad. 1989
43. Tissue Biopsy Antibiotic discontinued for 72 hours prior to biopsy
Multiple representative biopsy specimens should be obtained
Cultures sent for gram stain, aerobic, anerobic, fungal, and acid fast studies
Open biopsy techniques can be inconclusive due to problem of detecting bacteria protected by an external glycocalyx
Gristina AG el.al
Inst Con Lect 1990
44. Treatment Nonoperative
Operative
45. Nonoperative Ultrasound
Electric stimulator
Bone marrow injection
46. Ultrasound Ultrasound fracture stimulation devices have shown ability to increase callus response in fresh fractures (shortens time for visible callus on x-ray)
Prospective randomized trial in nonunion population has not been done
Use in nonunions remains theoretical Goodship & Kenwright JBJS 1985
47. Electric Stimulation Piezoelectric nature of bone - stress generated electric potentials exist in bone and are related to callus formation Fukada & Yasuda,J Phys Soc Jpn 1957 Busse H CAL e.t. al. Science 1962
Electromagnetic fields influence vascularization of fibrocartilage, cell proliferation & matrix production Monograph Series,AAOS
48. Three Modalities of Electric bone Growth Stimulators 1. Direct current - percutaneous or implanted electrodes
2. Electromagnetic stimulation - uses time varying magnetic fields (noninvasive)
3. Capacitive coupling - uses electrodes placed on skin (noninvasive)
49. Two Attempts at Well Controlled Double Blind (placebo) Studies on Nonunion Healing with Electric Stimulation 1. Pulsed electromagnetic fields
Tibial delayed unions 16-32 weeks from injury
45% united in active device group
14% united in placebo group (P < 0.02) Sharrard JBJS e.t. al 1990
2. Capacitive coupling
6 of 10 with active device healed
0 of 11 with placebo device healed (P < 0.004) Scott G and King JBJS 1994
50. Contraindication to Electric Stimulation Synovial pseudoarthrosis
Electric stimulation does not address associated problems of angulation, malrotation and shortening
51. Unanswered Questions When is electric stimulation indicated
Which fracture types are indicated
What are the efficacy rates
What time after injury is best for application Ryaby JT Corr 1998
52. Bone Marrow Injection Percutaneous bone marrow injected to level of fracture
9 of 10 delayed tibia fractures united
80% of 100 tibial fracture patients united when in conjunction with adequate fixation
*Nonradomized and anecdotal studies
Connolly J., CORR. 1995
53. Surgical Treatment Fibular osteotomy
Bone graft
Plate osteosynthesis
Intramedullary nailing
External fixation
54. Fibular Osteotomy Fibula can distract or unweight physiologic forces seen in the tibia Teitz, C.C. e.t.al.JBJS 1980
Often used as adjunctive procedure to assist with deformity correction and surgical stabilization of tibia
Dynamizes tibial to augment healing environment
55. Bone Grafting Osteoinductive - contain proteins or chemotactic factors that attract vascular ingrowth and healing
i.e.. demineralized bone matrix & BMP’s
Osteoconductive - contains a scaffolding for which new bone growth can occur
i.e. allograft bone, calcium hydroxyappatite
56. Bone Grafting Used to stimulate biologic response of healing in nonunions (usually atrophic nonunions)
Also used to fill defects in fracture zone
i.e. up to 6 cm intercalary defects of long bones)
Bosse, MJ e.t.al. JBJS 1989
57. rhBMP-2 44% reduction in need for secondary intervention in the treatment of acute open tibial fractures
Gorender,S e.t.al. JBJS 2002
58. rhBMP-2 Reduces incidence of nonunion in high risk fractures
Believed to reduce the need for autologous bone grafting
Theoretically makes sense in the operative treatment of nonunions
59. Plate Osteosynthesis Corrects malalignment
Restores function & stabilizes fracture fragments directly
Compresses fragments in some circumstances to augment healing
Allows patients to mobilize surrounding joints and dynamize fracture environment
Requires adequate skin and soft tissue coverage
Often used with adjunctive bone graft
60. Locking Plate Technology Will give better fixation in pathologic bone
Most likely will prevent early failure
Occasionally seen with traditional compression plating techniques
61. Intramedullary Nailing Mechanically stabilizes long bone nonunions as a load sharing implant
Corrects malalignment
Reaming is initially detrimental to intramedullary blood supply, but it does recover and is believed to stimulate biologic healing at fracture
Allow patient to mobilize surrounding joints and dynamize fracture environment
62. Intramedullary Nailing Can be performed without direct exposure or dissection of the fracture soft tissue envelope
Nonapplicable in articular fractures
63. External Fixation Correct malalignment
Used primarily in management of infected nonunions
Allows for repeated debridements, soft tissue reconstructive procedures, and adjunctive bone-grafting
Small wire ring fixators can also allow for bone transport into large intercalary defects
Ring fixators can also generate large compressive forces at fracture to allow mobilization of joints and improve fracture healing environment
