Talar Neck Fracture

Talar neck fractures are rare but high-morbidity injuries (<1% of all fractures) resulting from high-energy trauma, with significant risk of avascular necrosis (AVN) and posttraumatic arthritis due to the talus's tenuous, predominantly extraosseous blood supply and 57% articular cartilage coverage.[1-2] The modified Hawkins-Canale classification guides treatment and predicts osteonecrosis risk.[3]

1. History

Mechanism: Forced dorsiflexion (historically "aviator's astragalus"), high-energy axial loading, or pronation-dorsiflexion[4-5]
Most common causes: motor vehicle accidents (46%), falls from height (43%), motorcycle crashes, and sports injuries[6]
Key HPI: Exact mechanism (axial load vs. twisting), height of fall, speed of MVC, position of foot at impact
Immediate inability to bear weight, severe hindfoot/ankle pain, rapid swelling
Ask about associated injuries — polytrauma is common given the high-energy mechanism[4]
Prior ankle injuries, baseline ambulatory status

2. Alarm Features

Open fracture (30% of talar neck fractures) — emergent surgical indication[7-8]
Fracture-dislocation with tenting of skin — risk of skin necrosis if not urgently reduced[1]
Neurovascular compromise — assess dorsalis pedis, posterior tibial pulses, and sensation (tibial/peroneal nerve distributions)
Compartment syndrome of the foot
Associated polytrauma (spine, pelvis, contralateral calcaneus — "Don Juan" pattern)
Gross deformity with medial or posterior prominence of the talar body (Hawkins III/IV)

3. Medications

Acute pain management: IV opioids, ketorolac (if no contraindications), regional nerve block (popliteal/saphenous)
Procedural sedation for closed reduction of dislocations
DVT prophylaxis — prolonged non-weight-bearing expected
Avoid: NSAIDs long-term in the perioperative period if concern for bone healing (controversial but commonly avoided)
Smoking cessation counseling — smoking associated with Hawkins sign inaccuracy and impaired microvascular revascularization[9]

4. Diet

Not a primary driver of management
Adequate calcium and vitamin D intake during prolonged non-weight-bearing recovery
Optimize nutrition for bone healing, especially in polytrauma patients

5. Review of Systems

MSK: Pain in ipsilateral foot, ankle, knee, hip, spine (associated injuries in polytrauma)
Vascular: Numbness, tingling, coolness of foot (neurovascular compromise)
Skin: Open wounds, skin tenting, blistering (soft tissue envelope compromise)
Constitutional: Symptoms suggesting polytrauma (head injury, chest/abdominal pain)
Psych: Mechanism-related (e.g., suicidal ideation if fall from height)

6. Collateral History and Family History

Witnesses to mechanism (fall height, MVC speed, ejection)
Baseline functional status and ambulatory ability
Family history is generally not contributory
Social context: Occupation (manual labor, military), smoking status, alcohol use, recreational drug use — all affect healing and outcomes
Diabetes status — associated with higher AVN risk[10]

7. Risk Factors

Young active males (mean age ~32–37 years, 86% male)[6-7]
Motor vehicle accidents (especially motorcyclists) and falls from height[6]
High-energy mechanisms
Open fractures and comminuted fractures — independently associated with higher AVN and worse outcomes[8]
Smoking — impairs microvascular revascularization[9]
Diabetes mellitus[10]

8. Differential Diagnosis

Talar body fracture — fracture line posterior to the lateral process; different classification (Sneppen)[3]
Subtalar dislocation without fracture — pure ligamentous injury
Calcaneal fracture — axial load mechanism overlap; assess Böhler's angle
Lateral process fracture ("snowboarder's fracture") — frequently missed on radiographs[3]
Ankle fracture-dislocation (malleolar fractures)
Midfoot (Lisfranc) injury — if mechanism involves forefoot loading
Osteochondral lesion of the talar dome — more subtle, often missed acutely
Navicular fracture — adjacent bone, similar mechanism

9. Past Medical History

Prior ankle/foot injuries or surgeries
Peripheral vascular disease (compromises already tenuous talar blood supply)
Diabetes, smoking, chronic steroid use — all impair healing
Osteoporosis — may affect fixation strategy
Previous contralateral lower extremity injuries

10. Physical Exam

Vital signs: Assess for hemodynamic instability in polytrauma
Inspection: Gross deformity, swelling, ecchymosis, open wounds, skin tenting (especially medially/posteriorly), fracture blisters
Palpation: Tenderness over talar neck (anterior ankle, sinus tarsi), medial malleolus, lateral malleolus, calcaneus, midfoot
Neurovascular exam: Dorsalis pedis and posterior tibial pulses, capillary refill, sensation in tibial, superficial/deep peroneal distributions
Range of motion: Typically unable to perform due to pain; do not force
Compartment assessment: Palpate foot compartments for tenseness
Associated injuries: Examine entire ipsilateral extremity, spine, pelvis

11. Lab Studies

Routine trauma labs: CBC, BMP, coagulation studies, type and screen (if surgical candidate)
Lactate if concern for polytrauma/shock
Pre-operative: HbA1c if diabetic, albumin/prealbumin if nutritional concern
No specific labs diagnose talar fracture
ESR/CRP if concern for open fracture with contamination or delayed presentation

12. Imaging

First-line: AP, lateral, and mortise radiographs of the ankle; AP and lateral of the foot[3][11]
Canale view (15° pronation, 75° cephalad beam angle) improves talar neck visualization
Plain radiographs have only ~77% sensitivity for talar neck fractures and poor sensitivity for displacement/comminution[12]
Gold standard: CT scan — essential for all suspected talar neck fractures to assess displacement, comminution, intra-articular extension, associated injuries, and classification[1][3][11]
CT is the imaging modality of choice for preoperative planning[1]
MRI: Not needed acutely; useful at 6–12 weeks for AVN assessment if Hawkins sign is absent[11][13]
When imaging is unnecessary: Imaging is always indicated when talar fracture is suspected

13. Special Tests

Modified Hawkins-Canale Classification (determined on CT):[3][7][14] Export Type Description AVN Rate References I Nondisplaced fracture, no subluxation ~10%[1-2]
II Displaced fracture + subtalar subluxation/dislocation ~27%[1-2]
IIA Subluxation only (no full dislocation) ~0%[3]
IIB Full subtalar dislocation ~25%[3]
III Displaced + subtalar AND tibiotalar dislocation ~53%[1-2]
IV Type III + talonavicular dislocation ~48%[1-2]
Hawkins sign: Subchondral lucency in the talar dome on AP radiograph at 6–8 weeks post-injury — indicates preserved vascularity and low risk of AVN. Sensitivity ~100%, specificity ~58%. A positive Hawkins sign may be unreliable in smokers.[9][13][16]
Talar neck fractures with proximal body extension (TNPE): Associated with significantly higher AVN (49% vs 19%), collapse, and nonunion compared to isolated neck fractures[10]

14. ECG

Not routinely indicated for isolated talar fracture
Obtain if polytrauma, procedural sedation planned, or significant comorbidities

15. Assessment

Talar neck fractures are orthopedic emergencies when associated with dislocation or open injury. The talus has no muscular attachments and a predominantly extraosseous blood supply, making it uniquely vulnerable to AVN.[2-3] Key prognostic factors:
Degree of initial displacement/dislocation is the strongest predictor of AVN — not timing of definitive fixation[7-8]
Overall AVN rate: ~25–31%; posttraumatic arthritis rate: ~43–79% depending on follow-up duration[14][17]
Even when AVN develops, 44% revascularize without talar dome collapse, and 90% demonstrate <25% collapse[7][18]
Functional outcomes worsen with increasing Hawkins grade, comminution, and open fractures[8][19]

16. Treatment Plan

Initial stabilization (ED)

Splint in neutral position (posterior splint with stirrup)
Urgent closed reduction of any associated dislocation — procedural sedation, longitudinal traction with plantarflexion, then manipulation[1][8]
Open fractures: IV antibiotics (cefazolin ± gentamicin per Gustilo-Anderson grade), tetanus update, urgent irrigation and debridement[4]
Elevate extremity, ice, strict non-weight-bearing

Definitive management

Hawkins Type I (nondisplaced): Short leg cast or boot, non-weight-bearing 6–8 weeks; some advocate percutaneous screw fixation[1][19]
Hawkins Type II–IV (displaced): ORIF is the standard of care[1-2][19]
Urgent reduction of dislocations to protect soft tissue envelope and neurovascular structures[1]
Delayed definitive ORIF (after soft tissue swelling subsides, typically 7–14 days) is safe and does not increase AVN risk[7-8][20]
Dual anterior incision approach (anteromedial + anterolateral) with plate and screw fixation is the modern preferred technique[1-2][21]
Anatomic reduction is the single most important surgical goal — nonanatomic reduction is associated with higher rates of secondary reconstructive surgery[18]
Postoperative: Non-weight-bearing for 8–12 weeks; serial radiographs to monitor for Hawkins sign at 6–8 weeks[9][13]

17. Disposition

Admit: All displaced fractures (Hawkins II–IV), fracture-dislocations, open fractures, polytrauma, neurovascular compromise, irreducible dislocations[1][4]
Observation/short stay: Nondisplaced (Hawkins I) fractures may be splinted and discharged with urgent orthopedic follow-up within 1 week if reliable patient
Orthopedic consultation: Required for all talar neck fractures from the ED — emergent for open fractures, dislocations, and neurovascular compromise[19]
Transfer: To a level I/II trauma center if orthopedic foot/ankle expertise is unavailable

18. Follow Up / Return Precautions

Follow-up: Orthopedic surgery within 5–7 days for nondisplaced fractures; sooner if any displacement
Serial radiographs at 6–8 weeks to assess for Hawkins sign[9][13]
If Hawkins sign absent at 8 weeks → obtain MRI to evaluate for AVN[13]
Long-term follow-up for ≥2 years — posttraumatic arthritis rate increases to 81% with >2 years of follow-up[14]

Return precautions (counsel patient)

Increasing pain, numbness, tingling, or color change in the foot → return immediately (compartment syndrome, vascular compromise)
Wound drainage, fever, redness → infection
Inability to maintain non-weight-bearing status
Expected recovery: Prolonged — most patients require 3–6 months minimum before any weight-bearing; functional outcomes are often imperfect, and patients should be counseled about high complication rates[8][17]

References

1. Current Concepts in Talar Neck Fracture Management. — Whitaker C, Turvey B, Illical EM. Current Reviews in Musculoskeletal Medicine. 2018.

2. Talus Fractures: Evaluation and Treatment. — Lee C, Brodke D, Perdue PW, Patel T. The Journal of the American Academy of Orthopaedic Surgeons. 2020.

3. Talar Fractures and Dislocations: A Radiologist's Guide to Timely Diagnosis and Classification. — Melenevsky Y, Mackey RA, Abrahams RB, Thomson NB. Radiographics : A Review Publication of the Radiological Society of North America, Inc. 2015.

4. Talar Neck and Body Fractures. — Rammelt S, Zwipp H. Injury. 2009.

5. Injuries of the Talus and Its Joints. — Kleiger B. Clinical Orthopaedics and Related Research. 1976.

6. Different Patterns and Characteristics of Talar Injuries at Two Main Orthopedic Trauma Centers in Shiraz, South of Iran. — Vosoughi AR, Fereidooni R, Shirzadi S, Zomorodian SA, Hoveidaei AH. BMC Musculoskeletal Disorders. 2021.

7. A New Look at the Hawkins Classification for Talar Neck Fractures: Which Features of Injury and Treatment Are Predictive of Osteonecrosis?. — Vallier HA, Reichard SG, Boyd AJ, Moore TA. The Journal of Bone and Joint Surgery. American Volume. 2014.

8. Talar Neck Fractures: Results and Outcomes. — Vallier HA, Nork SE, Barei DP, Benirschke SK, Sangeorzan BJ. The Journal of Bone and Joint Surgery. American Volume. 2004.

9. The Hawkins Sign of the Talus: The Impact of Patient Factors on Prediction Accuracy. — Griffin JT, Landy DC, Mechas CA, et al. The Journal of Bone and Joint Surgery. American Volume. 2024.

10. Association of Talar Neck Fractures With Body Extension and Risk of Avascular Necrosis. — Mechas CA, Aneja A, Nazal MR, et al. Foot & Ankle International. 2023.

11. ACR Appropriateness Criteria® Acute Trauma to the Ankle. — Smith SE, Chang EY, Ha AS, et al. Journal of the American College of Radiology : JACR. 2020.

12. Diagnostic Accuracy of Plain Radiographs Compared to CT Scans in Classifying Talus Injuries. — Fereidooni R, Moein SA, Ayatizadeh SH, et al. BMC Musculoskeletal Disorders. 2025.

13. The Prognostic Value of the Hawkins Sign and Diagnostic Value of MRI After Talar Neck Fractures. — Chen H, Liu W, Deng L, Song W. Foot & Ankle International. 2014.

14. Outcomes of Talar Neck Fractures: A Systematic Review and Meta-Analysis. — Dodd A, Lefaivre KA. Journal of Orthopaedic Trauma. 2015.

15. Complications of Talar Neck Fractures by Hawkins Classification: A Systematic Review. — Jordan RK, Bafna KR, Liu J, Ebraheim NA. The Journal of Foot and Ankle Surgery : Official Publication of the American College of Foot and Ankle Surgeons. 2017.

16. Prognostic Reliability of the Hawkins Sign in Fractures of the Talus. — Tezval M, Dumont C, Stürmer KM. Journal of Orthopaedic Trauma. 2007.

17. Conservative and Surgical Treatment of Talar Fractures: A Systematic Review and Meta-Analysis on Clinical Outcomes and Complications. — Saravi B, Lang G, Ruff R, et al. International Journal of Environmental Research and Public Health. 2021.

18. Rethinking Avascular Necrosis After Displaced Talus Fractures and Dislocations. — Frazer A, Ndoja S, Grad V, et al. Journal of Orthopaedic Trauma. 2026.

19. Surgical Treatment of Talus Fractures. — Shakked RJ, Tejwani NC. The Orthopedic Clinics of North America. 2013.

20. Long-Term Radiographic and Clinical-Functional Outcomes of Isolated, Displaced, Closed Talar Neck and Body Fractures Treated by ORIF: The Timing of Surgical Management. — Biz C, Golin N, De Cicco M, et al. BMC Musculoskeletal Disorders. 2019.

21. Surgical Management of Displaced Talus Neck Fractures: Single vs Double Approach, Screw Fixation Alone vs Screw and Plating Fixation-Systematic Review and Meta-Analysis. — Giordano V, Liberal BR, Rivas D, et al. Injury. 2021.