High Yield Overview

SYNDESMOTIC INSTABILITY - HIGH ANKLE SPRAIN

AITFL + PITFL + IOL + ITL | External Rotation Mechanism | Subtle on Plain Films | Fix if Unstable

1-11%Of all ankle sprains

4Ligament structures (AITFL, PITFL, IOL, ITL)

6mmClear space threshold for instability

8-12Weeks return to sport vs 2-4 for lateral sprain

WEST POINT CLASSIFICATION

Latent

PatternStable with stress, no diastasis

TreatmentConservative

Subluxation

PatternUnstable with stress, reduces

TreatmentConsider fixation

Dislocation

PatternFrank diastasis, does not reduce

TreatmentOperative fixation

Critical Must-Knows

External rotation is the primary mechanism - AITFL tears first, then IOL, then PITFL
Clear space greater than 6mm on mortise view indicates instability
Tibiofibular overlap less than 6mm (AP) or less than 1mm (mortise) suggests diastasis
Clinical tests: squeeze test, external rotation stress test, Cotton test (fibular translation)
Surgical fixation: position ankle in dorsiflexion and neutral rotation to avoid malreduction
Screw vs suture button: both effective, suture button allows physiologic motion

Examiner's Pearls

"
High ankle sprain = syndesmotic injury requiring 2-3x longer recovery than lateral sprain
"
Always rule out syndesmotic injury in ankle fractures - Maisonneuve pattern has proximal fibula fracture
"
Squeeze test compresses tibia/fibula at mid-calf - reproduces pain at syndesmosis
"
External rotation stress view shows diastasis - compare to contralateral side

Clinical Imaging

Imaging Gallery

2-panel AP and lateral ankle X-ray showing syndesmotic diastasisCredit: Unknown via Open-i (NIH) (CC-BY 4.0)

TightRope suture button device components photographCredit: Unknown via Open-i (NIH) (CC-BY 4.0)

Critical Syndesmotic Instability Exam Points

Mechanism: External Rotation

External rotation of the foot on a planted ankle is the key mechanism. This sequentially disrupts AITFL (first), interosseous ligament (second), and PITFL (last). Internal rotation injuries are rare and produce different patterns.

Radiographic Clear Space

Clear space greater than 6mm on mortise view is the most reliable plain film sign of diastasis. Also check tibiofibular overlap: less than 6mm on AP or less than 1mm on mortise is abnormal. Need stress views if equivocal.

Squeeze Test Gold Standard

Squeeze test (compressing tibia and fibula at mid-calf) has the highest sensitivity for syndesmotic injury. Pain at the ankle (not at the squeeze site) indicates syndesmotic disruption. External rotation stress test is also highly specific.

Dorsiflexion During Fixation

Position the ankle in dorsiflexion during syndesmotic fixation. The talus is wider anteriorly - dorsiflexion locks the talus in the mortise and prevents over-compression. Check reduction on intraoperative fluoroscopy before fixation.

Quick Decision Guide - Syndesmotic Injury Management

Injury Pattern	Stability	Treatment	Key Points
Isolated sprain, no diastasis	Stable on stress views	Conservative: boot 2-4 weeks, progressive weight bearing	Return to sport 6-8 weeks (longer than lateral sprain)
Subluxation on stress	Latent instability	Consider fixation if athletic demands high, otherwise trial conservative	MRI can confirm extent of ligament injury
Frank diastasis on static films	Unstable (West Point dislocation)	Operative fixation mandatory	1-2 screws or suture button construct
Ankle fracture with syndesmotic injury	Unstable if disrupted	Fix fracture, then assess syndesmosis with Cotton test intraoperatively	Fix if more than 2mm fibular translation or diastasis on stress

Mnemonic

PITFALL - Syndesmotic Ligament Anatomy

PITFL (Posterior inferior TibiوFibular Ligament)

Strongest component, last to tear

Interosseous ligament (IOL)

Distal extension of interosseous membrane

Transverse tibiofibular ligament

Deep part of PITFL, labrum-like function

AITFL (Anterior inferior TibiوFibular Ligament)

First to tear, most clinically important

Anatomic reduction essential

Even 1mm malreduction causes arthritis

Lateral malleolus position

Must restore length, rotation, and apposition

Long recovery time

8-12 weeks vs 2-4 for lateral sprain

Memory Hook:PITFALL reminds you of the ligaments (PITFL, IOL, AITFL) and the pitfalls of missing or undertreating syndesmotic injury

Mnemonic

EXTERNAL - Mechanism and Clinical Assessment

External rotation

Primary mechanism of injury

X-ray: clear space and overlap

Clear space greater than 6mm, overlap less than 6mm (AP) or less than 1mm (mortise)

Tests: squeeze, external rotation, Cotton

Clinical examination maneuvers

Examine proximal fibula

Maisonneuve fracture pattern

Reduction checked on fluoro

Intraoperative assessment before fixation

Neutral rotation during fixation

Ankle in dorsiflexion and neutral rotation

Anterior tibiofibular ligament first

Sequential failure pattern

Longer recovery than lateral

High ankle sprain takes 8-12 weeks

Memory Hook:EXTERNAL reminds you of the external rotation mechanism and the key assessment and treatment principles

Mnemonic

SCREW vs BUTTON Decision

Screw: rigid fixation

3.5mm or 4.5mm cortical screw, 3-4 cortices

Cotton test intraop

Assess fibular translation to confirm instability

Remove screw at 8-12 weeks (if not bioabsorbable)

Prevents screw breakage

Early motion with button

Suture button allows physiologic motion

Weight bearing delayed with screw

Protected until screw removal or union

Memory Hook:SCREW highlights the traditional screw fixation approach and the need for removal

Mnemonic

6-1-2 Rule for Radiographic Assessment

6mm clear space

Greater than 6mm on mortise = diastasis

1mm mortise overlap

Less than 1mm tibiofibular overlap on mortise = abnormal

2mm fibular translation

Greater than 2mm on Cotton test = unstable

Memory Hook:Remember the critical measurements: 6-1-2 for clear space, overlap, and translation

Overview and Epidemiology

Syndesmotic instability, commonly called a high ankle sprain, refers to disruption of the ligamentous structures that bind the distal tibia and fibula together, allowing abnormal motion and widening (diastasis) of the ankle mortise.

Incidence and context:

Accounts for 1-11% of all ankle sprains in the general population
Much higher incidence in contact sports (American football, rugby, ice hockey)
Present in 23% of operatively treated ankle fractures
Associated with Maisonneuve fractures (proximal fibula fracture with syndesmotic disruption)

Clinical significance:

Prolonged recovery: 8-12 weeks to return to sport vs 2-4 weeks for lateral ankle sprain
High missed diagnosis rate: up to 20% initially missed on clinical examination
Post-traumatic arthritis: even 1mm of malreduction increases contact pressures by 40%
Chronic pain and instability if undertreated

Why 'High' Ankle Sprain?

The term "high ankle sprain" distinguishes syndesmotic injuries from the much more common lateral ankle sprain (ATFL/CFL). The syndesmotic ligaments are located above the ankle joint proper, between the tibia and fibula, rather than connecting the talus to the fibula (as in lateral sprains).

Mechanism of injury:

External rotation of the foot relative to the leg (most common)
Foot planted, body rotates over it
Common in cutting sports, tackles, or getting foot caught in a hole
Less commonly: hyperdorsiflexion or eversion

The syndesmotic ligament complex:

AITFL (Anterior Inferior Tibiofibular Ligament) - tears first
IOL (Interosseous Ligament) - distal extension of interosseous membrane
PITFL (Posterior Inferior Tibiofibular Ligament) - strongest, tears last
ITL (Inferior Transverse Ligament) - deep portion of PITFL

Pathophysiology

Injury mechanism and sequential failure:

Syndesmotic injuries occur through a predictable biomechanical sequence when external rotation force is applied to the foot while the leg is fixed:

Stage 1: AITFL disruption

External rotation force first tensions the AITFL
AITFL is relatively weaker than PITFL
Partial or complete tear occurs depending on force magnitude
Allows initial widening of anterior syndesmosis

Stage 2: Interosseous ligament failure

Continued external rotation propagates injury proximally
Interosseous ligament tears from distal to proximal
May extend several centimeters up the interosseous membrane
Creates potential space for fibular displacement

Stage 3: PITFL disruption

PITFL is the strongest component (42% of stability)
Last to fail in complete syndesmotic disruption
May avulse with posterior malleolus fracture (Volkmann fragment)
Complete disruption allows frank diastasis

Biomechanical consequences of instability:

Mortise widening:

Normal tibiofibular clear space: 2-5mm
Even 1mm lateral displacement of fibula reduces tibiotalar contact area by 42%
Contact pressure increases by 40% with 1mm malreduction
Creates asymmetric loading pattern on tibial plafond

Altered ankle kinematics:

Loss of normal syndesmotic motion during dorsiflexion
Fibula cannot translate laterally as talus widens anteriorly
Abnormal talar position in mortise during gait cycle
Increased shear stress on articular cartilage

Progressive cartilage degeneration:

Chronic overload of medial or lateral tibial plafond
Subchondral bone stress and microfracture
Cartilage breakdown over months to years
Post-traumatic osteoarthritis develops

The 1mm Rule - Biomechanical Basis

Cadaver studies show that 1mm of lateral fibular displacement reduces tibiotalar contact area by 42% and increases peak contact pressure by 40%. This explains why anatomic reduction is essential - even small degrees of malreduction lead to accelerated arthritis.

Factors affecting healing:

Ligament vascularity: syndesmotic ligaments have lower blood supply than lateral ankle ligaments
Constant stress: weight bearing continuously stresses the healing syndesmosis
Fibrous vs anatomic healing: without fixation, ligaments may heal in elongated position
Scar tissue formation: interposition prevents anatomic healing

Anatomy and Biomechanics of the Syndesmosis

Syndesmotic ligament complex:

The distal tibiofibular joint (syndesmosis) is a fibrous joint stabilized by four primary ligament structures:

1. Anterior Inferior Tibiofibular Ligament (AITFL):

Origin: anterior tubercle of tibia (Chaput tubercle)
Insertion: anterior aspect of fibula
Most commonly injured (tears first in external rotation)
Oriented obliquely downward from tibia to fibula
Provides 35% of syndesmotic stability

2. Interosseous Ligament (IOL):

Distal continuation of the interosseous membrane
Provides 22% of syndesmotic stability
Disrupts after AITFL in sequential injury pattern

3. Posterior Inferior Tibiofibular Ligament (PITFL):

Origin: posterior tubercle of tibia (Volkmann tubercle)
Insertion: posterior aspect of fibula
Strongest component (42% of stability)
Tears last in external rotation injuries
Superficial and deep components

4. Inferior Transverse Ligament (ITL):

Deep portion of PITFL
Creates a labrum-like extension posteriorly
Contacts the posterior talus

Sequential Failure Pattern

In external rotation injuries, the ligaments fail in a predictable sequence: AITFL first, then IOL, then PITFL. Complete syndesmotic disruption requires failure of all three. The PITFL is the strongest and is the key stabilizer - if intact, the syndesmosis is usually stable.

Biomechanics of the ankle mortise:

Talar dome is wider anteriorly by 2-3mm
During dorsiflexion, the wider anterior talus pushes the fibula laterally, causing physiologic widening (up to 1-2mm)
The syndesmotic ligaments allow this normal physiologic motion while preventing excessive separation
Contact area: syndesmotic ligaments contribute to tibiotalar contact mechanics

Functional anatomy:

1mm Malreduction Rule

Even 1mm of lateral fibular displacement increases tibiotalar contact pressures by 40% and significantly increases risk of post-traumatic arthritis. Anatomic reduction is essential - "close enough" is not acceptable for syndesmotic injuries.

Fibular length: shortening of more than 2mm causes altered ankle biomechanics
Fibular rotation: external rotation malreduction narrows the mortise posteriorly
Syndesmotic width: must restore anatomic tibiofibular relationship

Classification Systems

West Point Ankle Grading System

This is the most commonly used classification for syndesmotic instability:

Grade	Description	Stability	Treatment
Latent	Ligament disruption but no diastasis on static or stress films	Stable	Conservative
Subluxation	Diastasis only with stress testing, reduces spontaneously	Unstable	Consider fixation (depends on activity level)
Dislocation	Frank diastasis on static radiographs	Unstable	Operative fixation mandatory

Clinical Application

The West Point classification guides treatment. Latent injuries can be treated conservatively with protected weight bearing. Subluxation injuries may be managed conservatively in low-demand patients but often require fixation in athletes. Dislocation injuries always require operative fixation.

This classification is based on the clinical finding and assists in treatment decisions.

Clinical Presentation and Examination

History:

Mechanism: external rotation injury, twisting on planted foot, direct blow
Pain location: anterior ankle, just above the joint line (compared to lateral ankle sprain which is more distal)
Inability to bear weight immediately after injury
Prolonged symptoms: pain lasting weeks (vs days for typical lateral sprain)

Red flags suggesting syndesmotic injury:

High-energy mechanism
Persistent pain despite treatment for "ankle sprain"
Proximal fibular tenderness (Maisonneuve)
Pain with ambulation more than 2 weeks post-injury

Physical examination:

Squeeze Test:

Compress tibia and fibula together at mid-calf level
Positive: pain at the ankle (distal syndesmosis), not at the compression site
Sensitivity: 30-92%, Specificity: 88-95%
Most sensitive clinical test for syndesmotic injury

External Rotation Stress Test:

Stabilize leg, externally rotate foot with knee flexed to 90 degrees
Positive: pain at anterior or posterior syndesmosis
Sensitivity: 20-71%, Specificity: 85-97%
Most specific clinical test

Cotton Test (Fibular Translation Test):

Grasp calcaneus and talus, translate laterally
Positive: greater than 2mm lateral shift of fibula relative to tibia
More commonly performed intraoperatively under anesthesia
Compares to contralateral side

Dorsiflexion-External Rotation Test:

Dorsiflex ankle and apply external rotation force
Positive: pain at syndesmosis
May be difficult to perform acutely due to pain

Test Interpretation

No single clinical test is perfectly sensitive. If the mechanism and presentation suggest syndesmotic injury, proceed with imaging even if tests are negative. Combine clinical tests to improve diagnostic accuracy.

This section covers the examination findings used to assess syndesmotic stability.

Investigations and Imaging

Clinical Imaging Gallery

Syndesmotic diastasis on plain radiographs — Two-panel ankle radiographs demonstrating syndesmotic diastasis. Left panel (AP view): Note the widened tibiofibular clear space indicating disruption of the syndesmotic ligaments. The Chinese character (左) indicates this is the left ankle. Right panel (lateral view): Shows the distal tibia-fibula relationship from the lateral perspective. On AP view, tibiofibular clear space greater than 6mm at 1cm above the plafond indicates instability. Always compare to the contralateral ankle when in doubt.Credit: PMC Open Access - CC BY 4.0

TightRope suture button device components — Photograph showing the components of a TightRope (Arthrex) suture button device used for flexible syndesmotic fixation. Components include the metal buttons (endobuttons), FiberWire suture, and associated tensioning hardware. This flexible fixation construct has become popular as an alternative to rigid screw fixation, allowing 1-2mm of physiologic motion at the syndesmosis while maintaining stability. Evidence shows equivalent outcomes to screw fixation with the advantage of avoiding routine hardware removal.Credit: PMC Open Access - CC BY 4.0

Standard ankle series (AP, mortise, lateral):

AP view measurements:

Tibiofibular overlap: should be greater than 6mm
- Less than 6mm suggests diastasis
Tibiofibular clear space: measure 1cm above plafond
- Greater than 6mm suggests instability

Mortise view measurements (most important):

Medial clear space: distance between medial malleolus and talus
- Should be equal to superior clear space (ankle joint space)
- Widening greater than 1mm compared to superior = deltoid injury
Tibiofibular clear space: greater than 6mm abnormal
Tibiofibular overlap: less than 1mm abnormal
Talocrural angle: should be symmetric

Lateral view:

Assess for posterior malleolus fracture (associated with PITFL injury)
Greater than 25% articular surface involvement may need fixation

The 6mm Rule

On the mortise view, a tibiofibular clear space greater than 6mm is the most reliable plain radiograph sign of syndesmotic diastasis. Also check tibiofibular overlap: less than 6mm on AP or less than 1mm on mortise is abnormal.

Weight-bearing radiographs:

May reveal diastasis not apparent on non-weight-bearing films
Useful in chronic or subtle cases

Plain radiographs are the initial imaging modality and often diagnostic.

Imaging Modality Comparison

Modality	Advantages	Limitations	Best Use
Plain radiographs (mortise)	Fast, low cost, readily available. Clear space and overlap measurements	May miss latent instability	Initial screening, frank diastasis
Stress radiographs	Gold standard for latent instability. Bilateral comparison	Requires contralateral views, can be painful	Equivocal cases, isolated syndesmotic injury
MRI	Visualizes ligaments, assesses associated injuries	Expensive, longer acquisition time	Chronic pain, pre-operative planning
CT scan	Excellent for bony detail, post-operative reduction assessment	Radiation, poor soft tissue detail	Posterior malleolus, assess reduction quality

Management Algorithm

Indications for conservative management:

West Point latent (stable on stress testing)
Isolated AITFL sprain without diastasis
No associated fractures
Patient can bear weight without significant pain

Acute phase (0-2 weeks):

RICE protocol: rest, ice, compression, elevation
Controlled Ankle Motion (CAM) boot or below-knee cast
Non-weight bearing initially, progress as tolerated
NSAIDs for pain (short course to avoid delayed healing)
Crutches until comfortable single-leg standing

Intermediate phase (2-6 weeks):

Progress to protected weight bearing in boot
Begin gentle range of motion exercises
- Alphabet exercises
- Plantarflexion and dorsiflexion
- Avoid inversion/eversion initially
Progressive resistance exercises
Continue boot for 4-6 weeks total

Late phase (6-12 weeks):

Wean from boot to lace-up ankle brace
Proprioceptive training: balance exercises, single leg stance
Strengthening: gastrocnemius, tibialis anterior, peroneals
Sport-specific drills (if athlete)
Gradual return to activity

Return to sport criteria:

No pain with weight bearing or running
Full range of motion compared to contralateral
Single leg hop test 90% of contralateral
Typically 8-12 weeks (2-3x longer than lateral ankle sprain)

Why Longer Recovery?

High ankle sprains take significantly longer to heal than lateral ankle sprains because: (1) the syndesmotic ligaments are under constant stress with weight bearing; (2) the mortise must remain stable during dynamic activities; (3) incomplete healing leads to chronic instability and pain.

Follow-up radiographs at 2-4 weeks to ensure no delayed diastasis develops.

Surgical Technique

Traditional syndesmotic screw fixation:

Setup:

Patient supine, bump under ipsilateral hip
Thigh tourniquet (optional)
Fluoroscopy available (AP, mortise, lateral views)

Step 1: Reduction of syndesmosis

Ensure fibular length restored (if fracture present)
Position ankle in dorsiflexion and neutral rotation
- Dorsiflexion widens anterior talus, preventing over-compression
Apply reduction clamp from fibula to tibia
- Place clamp 2cm above joint line
- Apply gentle compression (avoid over-compression)
Confirm reduction on fluoroscopy:
- AP: tibiofibular overlap greater than 6mm
- Mortise: clear space less than 6mm, overlap greater than 1mm
- Lateral: fibula centered in incisura

Step 2: Screw insertion

Insert screw 2-3cm above tibial plafond
Direction: 30 degrees anterior to posterior (parallel to joint line)
Size: 3.5mm or 4.5mm cortical screw
Drill perpendicular to long axis of fibula
Purchase: 3 cortices (both fibular cortices + near tibial cortex) or 4 cortices (all four)
- 3 cortices: allows some motion, screw less likely to break
- 4 cortices: more rigid, higher breakage rate
Do not lag the screw (use non-lag technique)

Step 3: Optional second screw

Some surgeons place 2 screws for increased stability
Second screw 1-2cm proximal to first
Same trajectory and technique

Step 4: Confirm reduction

Remove clamp
Obtain final fluoroscopy images (AP, mortise, lateral)
Ensure clear space, overlap, and fibular position anatomic

Screw removal:

Remove at 8-12 weeks if non-bioabsorbable
Prevents screw breakage with weight bearing
Protected weight bearing until screw removed or bioabsorbable screw incorporated

Tricortical vs Quadricortical

Tricortical fixation (3 cortices) is increasingly favored because it provides adequate stability while allowing some physiologic motion and has a lower screw breakage rate. Quadricortical fixation is more rigid but requires screw removal before full weight bearing.

This is the traditional technique with proven long-term results.

Complications

Intraoperative complications:

1. Malreduction (20-50% incidence):

Over-compression of syndesmosis
Fibular malposition (rotation, translation)
Recognition: intraoperative fluoroscopy on multiple views
Prevention: ankle in dorsiflexion, neutral rotation, gentle clamp application

2. Intra-articular screw placement:

Screw placed too distal or wrong trajectory
Recognition: pain, limited motion, radiographic signs
Prevention: stay 2cm above plafond, confirm on lateral view

3. Neurovascular injury:

Superficial peroneal nerve (at fibular incision site)
Deep peroneal nerve or anterior tibial vessels (rare, with anterior approach)
Prevention: careful dissection, knowledge of anatomy

Early post-operative complications:

4. Wound complications:

Incidence: 5-10% in ankle fracture surgery
Risk factors: diabetes, smoking, soft tissue injury
Prevention: delay surgery if blisters present, careful soft tissue handling

5. Screw breakage (early):

If weight bearing too early with rigid fixation
Usually asymptomatic if syndesmosis healed
Prevention: protected weight bearing until screw removal or union

6. Loss of reduction:

Syndesmosis re-widens despite fixation
May indicate inadequate fixation or continued instability
Management: revision fixation if detected early

These complications can often be prevented with careful technique and appropriate post-operative protocols.

Postoperative Care and Rehabilitation

Post-operative protocol for screw fixation:

Phase 1: Protection (0-2 weeks)

Splint or boot with non-weight bearing
Elevate leg above heart level
Ice for swelling control
DVT prophylaxis if indicated
Suture removal at 10-14 days

Phase 2: Early mobilization (2-6 weeks)

Transition to CAM boot
Non-weight bearing continues (if quadricortical screw)
Partial weight bearing (if tricortical screw, some protocols)
Begin gentle ROM exercises (plantarflexion/dorsiflexion)
Avoid inversion/eversion

Phase 3: Screw removal and progressive loading (6-12 weeks)

Screw removal at 8-12 weeks (if not bioabsorbable)
After removal, progress to full weight bearing over 2 weeks
Wean from boot to ankle brace
ROM exercises progress to include inversion/eversion
Begin strengthening exercises

Phase 4: Return to activity (12+ weeks)

Progress strengthening
Proprioceptive training: balance board, single leg exercises
Sport-specific drills
Gradual return to sport at 12-16 weeks post-screw removal

Total timeline: 20-28 weeks (5-7 months) from surgery to full sport

Why Remove Screw?

Screws are removed to prevent breakage and allow resumption of full activity. Screw breakage rate is 25-50% if left in place beyond 12 weeks with weight bearing. Broken screws are usually asymptomatic but can be difficult to remove later if needed.

This protocol protects the syndesmosis during ligament healing.

Prevention and Return to Sport

Prevention strategies:

1. Neuromuscular training:

Proprioceptive exercises in pre-season training
Balance and agility drills
Core and hip strengthening (improves lower extremity control)

2. Ankle bracing or taping:

Prophylactic bracing in high-risk sports (football, basketball)
Reduces incidence of ankle injuries by 30-50%
Lace-up braces or high-top shoes provide lateral support

3. Field maintenance:

Avoid holes, uneven surfaces
Proper footwear for surface type

4. Conditioning:

Adequate warm-up before activity
Gradual increase in training intensity
Avoid fatigue (injury risk increases when fatigued)

Return to sport decision-making:

Objective criteria (must meet all):

Pain-free: no pain with weight bearing, running, cutting
ROM: full dorsiflexion (critical for push-off), equal to contralateral
Strength: 90% of contralateral on single leg heel raise, hop test
Functional testing: single leg hop greater than 90% of contralateral
Radiographic stability: no diastasis on stress views

Subjective criteria:

Athlete confidence with cutting and jumping
No apprehension or fear of re-injury

Graduated return protocol:

Week 1: straight-line jogging (50% effort)
Week 2: increased pace, longer distances (75% effort)
Week 3: change of direction, cutting at 50% speed
Week 4: sport-specific drills at increasing intensity
Week 5: non-contact practice
Week 6+: full contact practice, then return to competition

Timeline expectations:

Conservative treatment: 8-12 weeks
Screw fixation: 20-28 weeks (including screw removal time)
Suture button: 12-16 weeks

Re-injury prevention:

Continue proprioceptive training indefinitely
Use ankle brace for 6-12 months after return
Maintain strength and conditioning

High Re-injury Risk

Athletes who return to sport before meeting objective criteria have a significantly higher re-injury rate. The prolonged recovery time for syndesmotic injuries is frustrating for athletes but essential for proper healing. Premature return leads to chronic instability.

Evidence Base