1. Forefoot Fractures Sean E. Nork, MD
2. Foot Trauma and Outcomes Turchin et al, JOT, 1999
28 patients: Polytrauma +/- foot injury
Age, gender, ISS matched
Results:
SF-36 5/8 components worse with foot injury
WOMAC All 3 components worse with foot injury These publications emphasize the importance of foot trauma as it relates to patient outcomes. After healing of all of their other complex injuries, associated foot injuries are associated with worse overall results as measured by a variety of outcomes measures. So, as tempting as it may be to minimize the attention and treatment of associated foot injuries in the multiply injured patient, don’t! While these injuries may not take priority in the initial hours or days of treatment, they should be treated aggressively and with the same attention.These publications emphasize the importance of foot trauma as it relates to patient outcomes. After healing of all of their other complex injuries, associated foot injuries are associated with worse overall results as measured by a variety of outcomes measures. So, as tempting as it may be to minimize the attention and treatment of associated foot injuries in the multiply injured patient, don’t! While these injuries may not take priority in the initial hours or days of treatment, they should be treated aggressively and with the same attention.
3. Foot Function Hindfoot: Shock absorption, propulsion, deceleration
Midfoot: Controls relationship between hindfoot and forefoot
Forefoot: Platform for standing and lever for push off The forefoot is primarily important as a platform to allow standing; and as a lever used for push off. The exact anatomical relationships between the various osseus structures determine the stability and function of the forefoot.The forefoot is primarily important as a platform to allow standing; and as a lever used for push off. The exact anatomical relationships between the various osseus structures determine the stability and function of the forefoot.
4. Forefoot Function Platform for weight bearing
Lever for propulsion This pressure diagram demonstrates the high pressures associated with the forefoot. It is not surprising that small alterations in the anatomy of this region can translate into symptomatic foot problems for the patient.This pressure diagram demonstrates the high pressures associated with the forefoot. It is not surprising that small alterations in the anatomy of this region can translate into symptomatic foot problems for the patient.
5. Anatomy First Metatarsal
Shorter & wider
Bears 1/3 body weight
Tendon attachments: (Tibialis Anterior & Peroneus Longus)
Tibialis Anterior: varus, supination, elevation
Peroneus Longus: valgus, pronation, depression
6. Anatomy: Sesamoids Medial (tibial) & Lateral (fibular)
Within FHB tendons
Articulate with 1st MT head
Weight bearing through sesamoids
7. Anatomy: Phalanges Great toe (2)
Lesser toes (3 each)
FDB attaches @ intermediate
FDL/EDL attaches @ distal
8. Biomechanics Metatarsal heads in contact with floor 60-80% of stance phase
Toes in contact with floor 75% of stance phase Once again emphasizing the importance of the forefoot with regards to stance phase. Once again emphasizing the importance of the forefoot with regards to stance phase.
9. Cross-sectional Geometry of the Human Forefoot Griffin & Richmond, Bone, 2005
Examines the relationship between external loads during walking & running and the geometrical properties of the human forefoot
Metatarsals 2-4 are the weakest in most cross-sectional geometric properties
Metatarsal 2 (and 3 to a lesser extent) experience high peak pressures; this may explain the preponderance of stress fractures in these metatarsals
10. Mechanisms of Injury: Forefoot Industrial accidents
MVA (airbags)
Indirect (twisting injuries)
Other Obviously, a variety of mechanisms are associated with forefoot injuries. Often, they are low energy injuries associated with falls or twisting injuries. However, high energy accidents associated with motor vehicle crashes, motorcycle crashes, and industrial accidents may occur. Airbags certainly protect patients and potentially decrease mortality rates. However, this may be associated with even worse foot trauma as patients survive higher and higher energy motor vehicle crashes.Obviously, a variety of mechanisms are associated with forefoot injuries. Often, they are low energy injuries associated with falls or twisting injuries. However, high energy accidents associated with motor vehicle crashes, motorcycle crashes, and industrial accidents may occur. Airbags certainly protect patients and potentially decrease mortality rates. However, this may be associated with even worse foot trauma as patients survive higher and higher energy motor vehicle crashes.
11. Physical Examination Gross deformity
Dislocations
Sensation
Capillary refill
Foot Compartments
12. Radiographs Foot trauma series
AP/lat/oblique
Don’t forget oblique
Sesamoid view
Tangential view (MT heads)
Contralateral foot films (comparison)
CT Scan (occasionally) The foot trauma series consists of three views for the initial evaluation of forefoot injuries. The oblique view is particularly helpful for identifying midfoot and forefoot displacements and subtle injuries. Additional views can be obtained if there is suspicion of injury in certain locations. This can include sesamoid and tangential views. Comparison views of the contralateral foot can be quite helpful. CT scans are typically not required by may be helpful in some complex injury patterns.The foot trauma series consists of three views for the initial evaluation of forefoot injuries. The oblique view is particularly helpful for identifying midfoot and forefoot displacements and subtle injuries. Additional views can be obtained if there is suspicion of injury in certain locations. This can include sesamoid and tangential views. Comparison views of the contralateral foot can be quite helpful. CT scans are typically not required by may be helpful in some complex injury patterns.
13. Treatment Principles: Foot Hindfoot: Protect subtalar, ankle and talonavicular joints
Midfoot: restore length and alignment of medial and lateral “columns”
Forefoot: Even weight distribution Some basic overall treatment principles exist for foot injuries. With respect to the forefoot, allowing for even weight distribution during stance and push off is critical. This requires an accurate restoration of the anatomy following injury.Some basic overall treatment principles exist for foot injuries. With respect to the forefoot, allowing for even weight distribution during stance and push off is critical. This requires an accurate restoration of the anatomy following injury.
14. Treatment Border Rays
First metatarsal
Fifth metatarsal
Dislocations
Multiple metatarsal shafts
Intraarticular fractures With regards to the metatarsals, the border rays tolerate displacement and shortening much less than the central three metatarsals. Particular attention much be paid to first and fifth metatarsal injuries. Central metatarsal injuries may be partially controlled due to the intermetatarsal ligaments. However, multiple metatarsal shaft fractures may require a more aggressive approach. These injuries will be specifically discussed in the slides that follow.With regards to the metatarsals, the border rays tolerate displacement and shortening much less than the central three metatarsals. Particular attention much be paid to first and fifth metatarsal injuries. Central metatarsal injuries may be partially controlled due to the intermetatarsal ligaments. However, multiple metatarsal shaft fractures may require a more aggressive approach. These injuries will be specifically discussed in the slides that follow.
15. First MT Shaft Fractures Nondisplaced
Consider conservative treatment
Immobilization with toe plate
Displaced
Most require ORIF
Strong muscle forces (TA, PL)
Deformity common
Bears 2/6 body weight For displaced first metatarsal shaft fractures, most require operative fixation. This is due to the strong muscular attachments, the amount of load that the first bears with walking, and the fact that it is a border ray. An accurate reduction (length, alignment, rotation) is necessary. If necessary, the first MTP joint may be crossed to enhance fixation for proximal fractures. This may be temporary.For displaced first metatarsal shaft fractures, most require operative fixation. This is due to the strong muscular attachments, the amount of load that the first bears with walking, and the fact that it is a border ray. An accurate reduction (length, alignment, rotation) is necessary. If necessary, the first MTP joint may be crossed to enhance fixation for proximal fractures. This may be temporary.
16. First MT Base Fractures Articular injuries
Frequently require ORIF
Fixation:
Spans TMT
Doesn’t span TMT
Temporarily Spans TMT Most articular fractures at the base of the first metatarsal require operative treatment. This is due to the tendency for displacement, as well as the importance of that particular articulation. The fracture location at the base of the first metatarsal determines the location and type of fixation necessary. Plates are frequently required. Small locking plates may offer some advantage for proximal fixation. It may be necessary to span the the first TMT joint onto the medial cuneiform. This may be temporary or permanent. Most articular fractures at the base of the first metatarsal require operative treatment. This is due to the tendency for displacement, as well as the importance of that particular articulation. The fracture location at the base of the first metatarsal determines the location and type of fixation necessary. Plates are frequently required. Small locking plates may offer some advantage for proximal fixation. It may be necessary to span the the first TMT joint onto the medial cuneiform. This may be temporary or permanent.
17. 36 year old male�s/p MVC�Active Case example of a comminuted fracture at the base of the first metatarsal. Note the displacement and the instability of the first TMT joint.Case example of a comminuted fracture at the base of the first metatarsal. Note the displacement and the instability of the first TMT joint.
18. After ORIF
19. 43 year old male injured in a MVC�Observe the articular segment impaction of the base of the first.�The first MT is shortened and dorsally displaced while the plantar ligaments remain attached.
20. The patient underwent ORIF of the base of the first metatarsal with spanning of the first TMT, given the level of comminution observed. Additionally, temporary spanning external fixation was used.
21. Radiographic appearance at 3 months after removal of the external fixator and metatarsal neck k-wire fixations.
22. Non-displaced Metatarsal Fractures 2-4 Single metatarsal fractures (non-displaced)
Treatment usually nonoperative
Symptomatic: hard shoe vs AFO vs cast vs elastic bandage
Multiple metatarsal fractures (non-displaced)
Usually symptomatic treatment (as above)
May require ORIF if other associated injuries
23. Minimally Displaced Lesser Metatarsal Fractures Zenios et al, Injury 2005
Prospective and randomized (n=50)
Case vs elastic support bandage
MINIMALLY DISPLACED fractures
Higher AOFAS mid-foot scores at 3 months and less pain if treated with an elastic support bandage.
24. Displaced Metatarsal Shaft Fractures Sagittal plane displacement & angulation is most important.
Reestablish length, rotation, & declination
Dorsal deformity can produce transfer metatarsalgia
Plantar deformity can produce increased load at affected metatarsal
25. This patient sustained an open second metatarsal fracture in a crush injury. Given the soft tissue injury and continued pressure on the dorsal skin, operative fixation was elected.
27. This patient was treated with ORIF of multiple metatarsal fractures (3,4,5) through a dorsal approach. Fixation consisted of a 2.7 mm DCP on the fifth and 2.0 mm plates on the third and fourth metatarsals.
28. Medullary K-wires in Lesser MTs Exit wire distally through the proximal phalanx
Plantar wire exit may produce a hyperextension deformity of the MTP Ideally, when “pinning” a lesser metatarsal neck fracture, the K-wire should exit though the base of the proximal phalanx. This maintains the relationship between the metatarsal and the proximal phalanx. If the k-wire exits plantar to the proximal phalanx, a hyperextension deformity can be produced as demonstrated.Ideally, when “pinning” a lesser metatarsal neck fracture, the K-wire should exit though the base of the proximal phalanx. This maintains the relationship between the metatarsal and the proximal phalanx. If the k-wire exits plantar to the proximal phalanx, a hyperextension deformity can be produced as demonstrated.
29. This patient sustained multiple metatarsal neck fractures (2, 3, 4) and a dislocation of the fifth MTP joint. Note the lateral translation, lateral angulation, and the displacement on the lateral radiograph.
30. Stabilization consisted of closed reduction and percutaneous pin fixation of the multiple metatarsal fractures and closed reduction of the fifth MTP dislocation. Note the location and trajectory of the K-wires.
31. Following healing and removal of the pins, good alignment of the forefoot is demonstrated on the multiple radiographic views.
32. Stress Fractures of Metatarsals 2 - 4 Identify Cause
First ray hypermobility
Short first ray
Tight gastrocnemius
Long metatarsal
Treatment
Treat cause if identifiable
If overuse, activity restriction
Reserve ORIF for displaced fractures
33. Metatarsal Neck Fractures Usually displace plantarly
May require reduction and fixation:
Closed reduction and pinning
Open reduction and pinning
ORIF (dorsal plate)
36. Metatarsal Head Fractures Unusual
Articular injuries
May require ORIF
(especially if first MT) This is an unusual injury. In the example shown, the patient sustained an injury due to a circular saw cut of the distal aspect of the first metatarsal. Following reduction and healing, the avascular changes of the articular segment are obvious. However, collapse did not occur.This is an unusual injury. In the example shown, the patient sustained an injury due to a circular saw cut of the distal aspect of the first metatarsal. Following reduction and healing, the avascular changes of the articular segment are obvious. However, collapse did not occur.
37. Fifth Metatarsal Fractures Mid diaphyseal fractures
Stress fractures (proximal diaphysis)
Jones fractures (metadiaphyseal jxn)
Tuberosity fractures
38. Proximal Fifth Metatarsal Fractures�Dameron, TB, JAAOS, 1995 Zone 1 cancellous tuberosity
insertion of PB & plantar fascia
involves metatarsocuboid joint
Zone 2 distal to tuberosity
extends to 4/5 articulation
Zone 3 distal to proximal ligaments
usually stress fractures
extends to diaphysis for 1.5 cm
39. Proximal Fifth Metatarsal Fractures�Dameron, TB, JAAOS, 1995 Relative Frequency
Zone 1 93%
Zone 2 4%
Zone 3 3%
40. Fifth Metatarsal Blood Supply Smith, J et al, F&A, 1992
Cadaver Arterial Injection Study (n = 10)
Nutrient artery with intramedullary branches (retrograde flow to proximal fifth metatarsal)
Multiple metaphyseal arteries
Conclusions: Fracture distal to the tuberosity disrupts the nutrient arterial supply and creates relative avascularity
41. Fifth Metatarsal Blood Supply
42. Zone 1 Fractures: Tuberosity Etiology
Avulsion from lateral plantar aponeurosis
(Richli & Rosenthal, AJR, 1984)
Treatment
Symptomatic
Hard shoe
Healing usually uneventful
(Dameron, T, JBJS, 1975)
43. Zone 1 Fractures: Tuberosity�Weiner, et al, F & A Int, 1997 60 patients
Randomized to short leg cast vs soft dressing only
Weight bearing in hard shoe in all
Healing in 44(average) - 65(all) days
Soft dressing only: shorter recuperation (33 vs 46 days) and similar foot score (92 vs 86)
Conclusions: Faster return to function without compromising radiographic union or clinical outcome in patients treated without casting.
44. Zone 1 Fractures: Tuberosity�Egol et al, F & A Int, 2007 50 fractures in 49 patients
Prospective outcomes study of fifth metatarsal base avulsion fractures
Protocol: hard shoe, weight bearing as tolerated
Average of 22 days lost from work
86% to pre-injury status at 6 months (only 20% at 3 months)
Conclusions: Fifth metatarsal base fractures associated with loss of work productivity. Return is expected but takes significant time, with recovery of 6 months or longer in some patients
45. Zone 2 Fractures: Metadiaphyseal
46. Zone 2 Fractures: Metadiaphyseal Treatment Controversial
Union frequently a concern
Early weight bearing associated with increased nonunion (Torg, Ortho, 1990; Zogby, AJSM, 1987)
47. Zone 2 Fractures: Metadiaphyseal Operative Treatment
Medullary Screw Stabilization
(Delee, 1983; Kavanaugh, 1978; Dameron, 1975)
Bone Graft Stabilization
(Dameron, 1975; Hens, 1990; Torg, 1984)
48. Zone 2 Fractures: Metadiaphyseal Operative Treatment
Medullary Screw Stabilization
Bone Graft Stabilization
49. Zone 2 Fractures: Metadiaphyseal Operative Treatment
Biomechanical Comparison of Screws
(Sides et al, Foot & Ankle Int, 2006)
Compared 6.5 mm cancellous screw and variable pitch, tapered screw
CONCLUSIONS: Headless, tapered, variable pitch compression screws of the size tested are not entirely comparable to 6.5-mm lag screws in this application. They are effective in resisting bending but do not offer equivalent resistance to thread pull-out.
50. Recent Review:�Zwitser and Breederveld, Injury, 2009 Fracture of the fifth metatarsal: Diagnosis and Treatment
Tuberosity fractures:
Non-displaced treated non-operatively
If displaced >2mm or with >30% of the cubometatarsal joint, operative treatment
Shaft fractures:
Non-displaced treated non-operatively
If displaced >3 or 4mm or >10 degrees angulation, consider operative treatment
51. Recent Review:�Zwitser and Breederveld, Injury, 2009 Fracture of the fifth metatarsal: Diagnosis and Treatment
“Jones Fractures”
Torg classification based on radiographic appearance and healing potential
Type I: narrow fracture line and no intramedullary sclerosis
Type II: widening of the fracture line with evidence of intramedullary sclerosis
Type III: complete obliteration of the medullary canal with sclerotic bone
52. Recent Review:�Zwitser and Breederveld, Injury, 2009 Fracture of the fifth metatarsal: Diagnosis and Treatment
“Jones Fractures”
Torg classification based on radiographic appearance and healing potential
Type I: non-operative treatment
Type II: treatment dependent on activity level (op vs non-op)
Type III: operative treatment indicated
53. Comminuted fracture of the base of the fifth metatarsal
55. MTP Joint Injuries Sprains
“Turf Toe”: hyperextension with injury to thee plantar plate
Hyperflexion sprains
Dislocations
56. First MTP Dislocations�Jahss, F&A, 1980 Type I: Hallux dislocation without disrupting sesamoid
Irreducible closed!
MT incarcerated by conjoined tendons and intact sesamoid
Open reduction required (dorsal, plantar, or medial approach)
Type II: Disruption of intersesamoid ligament (type A)
Transverse fracture of one of the sesamoids (type B)
Usually stable after reduction
Treatment usually conservative and symptomatic (hard shoe for 4-6 weeks)
57. Lesser MTP Dislocations Uncommon
Dorsal vs Lateral
Usually stable post reduction
Rarely require open reduction
If unstable post reduction, consider k-wire fixation
58. Fractures of the Great Toe Proximal Phalanx Fractures
ORIF for transverse & displaced (?)
ORIF intraarticular fractures (?)
Interphalangeal Joint Fractures
Nonoperative treatment usually
Distal Phalanx Fractures
Taping usually adequate
Hard shoe
59. Sesamoid Injuries Sesamoiditis
Acute fractures
Stress fractures in dancers and runners
60. Fractures of the LesserToes Correct alignment & rotation
Attempt taping to adjacent toe
May require open reduction and pinning if adequate reduction not obtained
61. Newer Implants Locking plates
May be useful in patients with osteoporosis or comminuted fractures that require spanning fixation from the metatarsals to the midfoot.
Not needed in routine fractures of the foot.
62. This patient sustained a complex constellation of injuries to the midfoot and the metatarsals. Additionally, there are associated fractures of the cuboid. This has resulted in lateral translation of the forefoot.
63. Stabilization consisted of fixation of all components of the injury including the cuboid fracture, the multiple LisFranc joint dislocations, and fixation of the third metatarsal base fracture. Because of the comminution at the base of the third metatarsal, a locking implant was used.
64. This patient was referred after temporary stabilization of a comminuted first metatarsal base fracture
65. Because of the significant intraarticular involvement of the base of the first, fixation consisted of a direct reduction of the articular surface combined with spanning of the first TMT joint. A locking plate was used to ensure maintenance of length of the medial column given the limited fixation possibilities in the medial cuneiform
66. The Crushed Foot Soft Tissue Evaluation
Assess whether salvageable
sensate, perfused, adequate plantar tissue
Wash open wounds
Reposition bone deformity that threatens the skin
Reduce dislocations
Release compartments as needed This is an example of a crushed foot that could not be salvaged. Treatment consisted of primary amputation.This is an example of a crushed foot that could not be salvaged. Treatment consisted of primary amputation.
67. This patient’s multiple and complex fractures of the midfoot (and calcaneus; and pilon) were sequentiallly fixed. Because of the significant comminution of the fourth metatarsal, a locking plate was used.
68. Recommended Readings Cavanaugh, PR, et al. Pressure Distribution Patterns under Symptom-free Feet during barefoot standing. Foot Ankle, 7:262-276, 1987
Dameron, TB, Fractures of the Proximal Fifth Metatarsal: Selecting the Best Treatment Option. J Acad Orthop Surg, 3(2): 110-114, 1995.
Holmes, James. AAOS Monograph “The Traumatized Foot”, pages 55-75, 2002.
Lawrence, SJ, and Botte, MJ. Foot Fellow’s Review: Jones’ Fractures and Related Fractures of the Proximal Fifth Metatarsal. Foot & Ankle, 14(6), 358-365, 1987.
Smith, JW, et al. The Intraosseus Blood Supply of the Fifth Metatarsal: Implications for Proximal Fracture Healing. Foot & Ankle, 13(3), 143-152, 1992
69. Recommended Readings Adelaar, RS: Complications of forefoot and midfoot fractures. Clin Orthop Relat Res, (391): 26-32, 2001.
Armagan, OE, and Shereff, MJ: Injuries to the toes and metatarsals. Orthop Clin North Am, 32(1): 1-10, 2001.
Griffin, NL, and Richmond, BG: Cross-sectional geometry of the human forefoot. Bone, 37(2): 253-60, 2005.
Mittlmeier, T, and Haar, P: Sesamoid and toe fractures. Injury, 35 Suppl 2: SB87-97, 2004.
Zenios, M; Kim, WY; Sampath, J et al.: Functional treatment of acute metatarsal fractures: a prospective randomised comparison of management in a cast versus elasticated support bandage. Injury, 36(7): 832-5, 2005.
70. Recent Literature 1. Blundell, C. M.; Nicholson, P.; and Blackney, M. W.: Percutaneous screw fixation for fractures of the sesamoid bones of the hallux. J Bone Joint Surg Br, 84(8): 1138-41, 2002.
2. Dalal, R., and Mahajan, R. H.: Single transverse, dorsal incision for lesser metatarsophalangeal exposure. Foot Ankle Int, 30(3): 226-8, 2009.
3. Den Hartog, B. D.: Fracture of the proximal fifth metatarsal. J Am Acad Orthop Surg, 17(7): 458-64, 2009.
4. Egol, K.; Walsh, M.; Rosenblatt, K.; Capla, E.; and Koval, K. J.: Avulsion fractures of the fifth metatarsal base: a prospective outcome study. Foot Ankle Int, 28(5): 581-3, 2007.
5. Leumann, A.; Pagenstert, G.; Fuhr, P.; Hintermann, B.; and Valderrabano, V.: Intramedullary screw fixation in proximal fifth-metatarsal fractures in sports: clinical and biomechanical analysis. Arch Orthop Trauma Surg, 128(12): 1425-30, 2008.
6. Raikin, S. M.; Slenker, N.; and Ratigan, B.: The association of a varus hindfoot and fracture of the fifth metatarsal metaphyseal-diaphyseal junction: the Jones fracture. Am J Sports Med, 36(7): 1367-72, 2008.
7. Sides, S. D.; Fetter, N. L.; Glisson, R.; and Nunley, J. A.: Bending stiffness and pull-out strength of tapered, variable pitch screws, and 6.5-mm cancellous screws in acute Jones fractures. Foot Ankle Int, 27(10): 821-5, 2006.
8. Zwitser, E. W., and Breederveld, R. S.: Fractures of the fifth metatarsal; diagnosis and treatment. Injury, 2009.
72. Questions?
