Midfoot Strains and Sprains and Lisfranc Injuries









Introduction



Jason M. Jennings, MD, DPT
Mark E. Easley, MD

Epidemiology of Tarsometatarsal Complex Injuries (Lisfranc Complex Injuries)





  • Tarsometatarsal (TMT) complex injuries are rare and often subtle in athletes both clinically and radiographically. They typically occur secondary to a low-energy indirect force in contrast to the majority of nonathletic injuries, which result from high-energy direct forces (i.e., motor vehicle accident).



  • Midfoot sprains in athletes represent a spectrum of injuries to the Lisfranc ligament complex from partial sprains with no diastasis (stage I) to complete tears with frank diastasis (stages II and III) ( Figure 43-1 ).




    FIGURE 43-1


    Nunley and Vertulla classification of ligamentous Lisfranc injuries

    (Adapted from Nunley JA, Vertullo CJ: Classification, investigation, and management of midfoot sprains. Lisfranc injuries in the athlete. Am J Sports Med 30(6):871-878, 2002, with permission.)



  • Twenty percent misdiagnosed at initial presentation, with 40% receiving no treatment in the first week.



Incidence





  • Increased incidence in athletes secondary to greater appreciation and recognition



  • Four percent of college football players per year




    • 29.2% of these players were offensive linemen




Age





  • Most common in third decade



Sex





  • Males affected two to four times more often than females



Sport





  • Most common sports: football, equestrian, windsurfing, gymnastics, basketball, baseball, other



  • Women’s gymnastics is one of the highest injury-producing sports, with many of these injuries requiring surgical intervention.



Position





  • Offensive lineman



Pathophysiology


Intrinsic Factors





  • The midfoot is typically divided into three columns:




    • Medial column: navicular, medial cuneiform, and the first metatarsal



    • Middle column (most rigid): articulation between the second and third metatarsals with their respective articulation



    • Lateral column (most mobile): articulation between the fourth and fifth metatarsals and the cuboid




  • The Lisfranc ligament is located between the medial cuneiform and the base of the second metatarsal providing stability between the medial and middle columns.



  • There is no ligamentous attachment between the first and second metatarsal joint.



  • The plantar ligaments are stronger than the dorsal ligaments which may account for dorsal dislocations when they occur.



  • The base of the second metatarsal is recessed between the medial and lateral cuneiforms creating the “keystone” in the shape of a Roman arch, which provides inherent osseous stability.



  • In patients with injuries to the Lisfranc joint, the medial mortise depth (medial aspect of the TMT joint, between the medial cuneiform and the base of the second metatarsal) has been shown to be shallower, decreasing osseous stability and thus increasing risk to injury.



Extrinsic Factors





  • Interface between the athletic shoe and playing field, particularly artificial turf



  • Regular turf injuries in American football may be influenced by type of shoe or cleat worn and the forces on the foot when another athlete falls on it in a compromised position.



  • Stirrup creating a fulcrum effect on the forefoot as seen in windsurfing and equestrian sports ( Figure 43-2 )




    FIGURE 43-2


    Mechanism of a windsurfing injury—a fall backward causing forced equines of the fixed forefoot.

    (Adapted from Curtis MJ, Myerson M, Szura B: Tarsometatarsal joint injuries in the athlete. Am J Sports Med 21:497-502, 1993, with permission.)



Traumatic Factors





  • Athletic injuries of the TMT complex can be divided into three broad categories:




    • Plantar flexion injury: axial force applied along the longitudinal axis ( Figure 43-3 )




      FIGURE 43-3


      A, Plantarflexion of the foot driven into the ground by an opposing player falling on the hindfoot or leg. B, Another mechanism demonstrates a player’s plantarflexed foot coming down on another player’s leg during a pileup .

      (Adapted from Meyer SA, Callaghan JJ, Albright JP, Crowley ET, Powell JW: Midfoot sprains in collegiate football players. Am J Sports Med 22:392-401, 1994, with permission.)



    • Forefoot forcefully abducted with hindfoot fixed (i.e., windsurfing and equestrian sports) (see Figure 43-2 )



    • Crush to the dorsum of the foot




  • These mechanisms are oversimplifications, because there are probably varying patterns of each force (e.g., rotational).



Clinical Presentation and Examination





  • The presentation is often subtle, and one should have a high index of suspicion when the athlete presents with a midfoot “sprain.”



  • “Pop” felt over the dorsal aspect of the foot



  • Inability to weight-bear



Abnormal Findings





  • Physical examination findings are often subtle.



  • Inability to weight-bear



  • Variable amount of edema



  • Variable deformity



  • Plantar arch ecchymosis



  • Diastasis between the first and second toes



  • Tender to palpation over the TMT complex



  • Pain with pronation and abduction of the forefoot



  • Pain with passive plantar flexion, dorsiflexion, abduction, and adduction of the first and second metatarsal complex



  • Coronal plane stress across the forefoot



Imaging





  • Despite being associated with relatively minor radiographic changes, subtle TMT complex injuries can be a source of considerable morbidity in athletes.



  • Twenty to fifty percent of tarsometatarsal injuries are missed on initial non–weight-bearing radiographs.



  • False negative findings are associated with inability to weight-bear secondary to pain. If weight bearing is limited by pain, ankle block anesthesia may be used.



  • Standard weight-bearing radiographs




    • Anteroposterior: The medial border of the second metatarsal should be in alignment with the medial border of the middle cuneiform. With significant Lisfranc joint disruption this alignment will be compromised.



    • 30° internal oblique: The medial border of the fourth metatarsal should be aligned with the medial border of the cuboid. Disruption is indicative of a lateral column injury.



    • Lateral view: Note the continuity of the dorsal cortex of the first and second metatarsal to the medial and middle cuneiform. Flattening of the longitudinal arch, which is correlated with a worse functional outcome, is noted by measuring the distance from the plantar aspect of the fifth metatarsal and the plantar aspect of the medial cuneiform.



    • Fleck sign: a small avulsion fragment noted over the lateral edge of the medial cuneiform or the medial aspect of the second metatarsal, which is indicative of a Lisfranc injury ( Figure 43-4 )




      FIGURE 43-4


      Radiograph of the foot demonstrating the fleck sign.



    • Associated injuries: base of second metatarsal, navicular, cuneiform, cuboid, or other




  • Stress radiographs (pronation and abduction) may be used to assist with diagnosis if weight-bearing and non–weight-bearing radiographs are normal or equivocal. Adequate anesthesia must be utilized secondary to pain when performing this maneuver. Many physicians will opt for MRI prior to performing stress radiographs.



  • MRI: sensitive study for the diagnosis of subtle (stage I) midfoot ligamentous injuries when compared with intraoperative findings



  • Bone scintigraphy: diagnosis of subtle (stage I) midfoot injuries or those with delayed diagnosis



  • CT: Sensitive for fracture but remains limited in the athletic low-energy TMT complex injury for assessment of instability, and without weight-bearing stress or clear diastasis, the status of the joint stability remains unclear.



Differential Diagnosis





  • Midfoot sprain is a tarsometatarsal complex injury until proved otherwise.



Treatment


Nonoperative Management





  • Non–weight-bearing immobilization



  • Weight-bearing immobilization



Guidelines for Choosing Among the Nonsurgical Treatment Options





  • Stage I (no diastasis) Lisfranc ligament sprain



  • It is the authors’ preference to allow the patient to weight bear as tolerated in a cam walker for the first 6 weeks. Serial weight-bearing radiographs are obtained at 2 and 6 weeks to assure there is no diastasis or instability.



Surgical Indications





  • Absolute: Stage II and III Lisfranc ligament sprains, displaced fractures, subluxation/dislocation



  • Relative: continued pain and failed conservative treatment for stage I injuries



  • Table 43-1 lists five steps that can be used to determine the need for surgical intervention based on imaging studies



    Table 43-1

    Stepwise Evaluation of a Patient with Lisfranc Injury to Determine Whether to Perform Nonsurgical or Surgical Treatment








































    Step Study Result Recommendation Rationale
    1 Physical examination Plantar bruising, painful piano key test, midfoot swelling Obtain weight-bearing radiographs unless injury is obvious with non–weight-bearing images Weight-bearing radiographs are always useful, but oblique views may be helpful for the tentative patient.
    2 Radiography Loss of arch on comparative weight-bearing lateral radiograph, widening between the first and second metatarsal vases or comparative AP views, fleck sign ORIF is indicated with positive results. External rotation views are necessary when there is uncertainty based on plain radiographs or the patient cannot bear weight. When uncertainty remains, MRI is useful. Any measurable subluxation is an indication for ORIF. When in doubt, proceed with further tests. On MIR, edema indicates midfoot injury, and subluxation confirms Lisfranc injury.
    3 MRI Edema at the tarsometatarsal joint, bone bruise, subluxation, or ligament tear If edema but no ligament tear or subluxation, then CT is recommended. Perform ORIF in the presence of subluxation or a clear ligament tear. MRI is more sensitive to edema in subtle injuries. CT may better illustrate subluxation, but MRI may show both.
    4 CT 1 mm of subluxation Strong evidence for Lisfranc injury when edema is noted on MRI and subluxation on CT. ORIF is indicated. MRI with edema and no ligament tear combined with normal CT requires stress examination under anesthesia, with possible ORIF.
    5 Stress examination Subluxation ORIF When negative, treat as a sprain

    From Watson TS, Shurnas PS, Denker J: Treatment of Lisfranc joint injury: Current concepts. JAAOS 18(12):718–728, 2010.



Aspects of History, Demographics, or Exam Findings That Affect Choice of Treatment





  • Low-energy (athletes) versus high-energy injury



  • Associated injuries



  • Operative treatment is generally indicated for all obvious displaced injuries (stage II and III injuries).



  • The patient with minimal ambulatory ability, an insensate foot, or preexisting inflammatory arthritis may be best treated nonoperatively.



Aspects of Clinical Decision Making When Surgery Is Indicated





  • Open versus closed injury



  • Vascular status



  • Compartment syndrome



  • Timing of surgery



  • Delay in diagnosis



  • ORIF versus arthrodesis versus percutaneous screw fixation



  • Postoperative management and the patient’s ability to comply with the strict non–weight-bearing status and rehabilitation protocol



Evidence


  • Curtis MJ, Myerson M, Szura B: Tarsometatarsal joint injuries in the athlete. Am J Sports Med 1993; 21: pp. 497-502.
  • This study was a retrospective review of 19 patients who injured the tarsometatarsal joint complex during athletic competition. Stress fluoroscopy of the articulation under anesthesia was used to supplement clinical and radiographic examination. Poor functional results were seen in those where diagnosis was delayed and inadequately treated unstable injuries with nonoperative immobilization. (Level III evidence)
  • DeOrio M, Erickson M, Usuelli FG, et. al.: Lisfranc injuries in sport. Foot Ankle Clin N Am 2009; 14: pp. 169-186.
  • This article reviews anatomy, classification, diagnosis, and treatment of Lisfranc injuries in sport. In addition, the authors’ preferred operative technique is discussed in detail. (Level V evidence)
  • Faciszewski T, Burks RT, Manaster BJ: Subtle injuries of the Lisfranc joint. J Bone Joint Surg 1990; 72A: pp. 1519-1522.
  • Fifteen patients with 18 subtle Lisfranc joint disruption demonstrated weight-bearing. Lateral radiographs are needed to identify flattening of the longitudinal arch. Maintenance of the longitudinal arch was associated with better functional outcomes. (Level III evidence)
  • Meyer SA, Callaghan JJ, Albright JP, et. al.: Midfoot sprains in collegiate football players. Am J Sports Med 1994; 22: pp. 392-401.
  • This retrospective study of 23 collegiate football players demonstrated an incidence of 4% of football players per year, with 29.2% of these players offensive lineman. The patients were followed for a mean of 30.8 months and most of despite a prolonged restriction from activity most of the players reported minor residual problems. (Level III evidence)
  • Myerson MS, Cerrato RA: Current management of tarsometatarsal injuries in the athlete. J Bone Joint Surg 2008; 90-A: pp. 2521-2533.
  • This instructional course lecture presents the anatomy, clinical presentation, diagnostic imaging, nonoperative and operative management of tarsometatarsal injuries in the athlete. (Level V evidence)
  • Nunley JA, Vertullo CJ: Classification, investigation, and management of midfoot sprains. Lisfranc injuries in the athlete. Am J Sports Med 2002; 30: pp. 871-878.
  • This retrospective cohort study utilized weight bearing radiographs and bone scintigrams to diagnose Lisfranc injuries in 15 athletes who were treated operatively versus nonoperatively according to the following classification system: nonoperative management for stage I injuries (nondisplaced) and anatomic reduction with fixation of stage II (diastasis with no arch height loss) and stage III (diastasis with arch height loss) injuries (Figure 1). Excellent outcomes were reported in 93% of their patients. They concluded that weight-bearing radiographs and bone scintigrams are sensitive, reproducible, and relatively inexpensive methods to investigate this injury. Anatomic alignment was the key to excellent functional outcomes.(Level IV evidence)
  • Peicha G, Labovitz J, Seibert FJ, et. al.: The anatomy of the joint as a risk factor for Lisfranc dislocation and fracture-dislocation. An anatomical and radiological case control study. J Bone Joint Surg Br 2002; 84: pp. 981-985.
  • This case control study of 33 patients with Lisfranc injuries evaluated the relationship between the medial and lateral cuneiforms to determine if there were anatomical features that may predispose these patients to injury. The depth of the medial mortise (medial aspect of the tarsometatarsal joint, between the medial cuneiform and the base of the second metatarsal) in patients with injuries to the Lisfranc joint was found to be shallower than the control group. (Level III evidence)
  • Raikin SM, Elias I, Dheer S, et. al.: Prediction of midfoot instability in subtle Lisfranc injury. Comparison of magnetic resonance imaging with intraoperative findings. J Bone Joint Surg Am 2009; 91: pp. 892-899.
  • This retrospective review of 21 tarsometatarsal complex injuries correlated conventional MRI with manual stress radiographic evaluation and surgical findings. The strongest predictor of instability, and thus an unstable midfoot, was disruption (rupture or grade 2 sprain) of the plantar ligament between the medial cuneiform and the bases of the second and third metatarsals, with sensitivity, specificity, and positive predictive value of 94%, 75%, and 94%, respectively. The appearance of a normal ligament is suggestive of a stable midfoot. An MRI may alleviate the need for stress radiographic evaluation under anesthesia. (Level II evidence )
  • Shapiro MS, Wascher DC, Finerman GA: Rupture of Lisfranc’s ligament in athletes. Am J Sports Med 1994; 22: pp. 687-691.
  • Nine athletes with Lisfranc ligament disruptions were presented in this retrospective review article. Nonoperative management was successful in returning the athletes back to competition in an average of 4 months. (Level III evidence)
  • Watson TS, Shurnas PS, Denker J: Treatment of Lisfranc joint injury: Current concepts. J Am Acad Orthop Surg 2010; 18: pp. 718-728.
  • This review article outlines current concepts regarding classification, diagnosis, and treatment of injuries to the Lisfranc complex. (Level V evidence)

    • Multiple Choice Questions




    • QUESTION 1.

      Which statement is false regarding the tarsometatarsal complex?



      • A.

        The Lisfranc ligament is located between the medial cuneiform and the base of the second metatarsal.


      • B.

        The plantar ligaments are stronger than the dorsal ligaments.


      • C.

        The ligamentous attachment between the first and second metatarsal provides most of the structural support.


      • D.

        The base of the second metatarsal is recessed between the medial and lateral cuneiforms.



    • QUESTION 2.

      Which imaging modality has limited use in the diagnosis of pure ligamentous tarsometatarsal complex injuries?



      • A.

        Weight-bearing radiographs


      • B.

        Stress radiographs


      • C.

        MRI


      • D.

        Bone scintigraphy


      • E.

        CT scan




    Answer Key




    • QUESTION 1.

      Correct answer: C (see Intrinsic Factors that Predispose to Injury)


    • QUESTION 2.

      Correct answer: E (see Imaging Studies)





    Nonoperative Rehabilitation of Midfoot Sprains (Stage I Ligamentous Lisfranc Injuries)



    Eric R. Schweitzer, DPT, OCS, MTC
    Lacy D. Jennings, DPT, SCS, MTC
    Mark E. Easley, MD
    Jason M. Jennings, MD, DPT



    Guiding Principles of Rehabilitation





    • Understand:




      • Stage I ligamentous Lisfranc injuries in athletes (see Introduction )



      • Importance of serial radiographs throughout rehabilitation progression



      • Specific intrinsic rehabilitation strengthening exercises for the Lisfranc injury




    • Proper selection of exercise and sport-specific progressions



    • Provide thorough rehabilitation and treatment so to restore normal foot and lower extremity function



    • Patient education regarding injury prevention and footwear modification




    Phase I (weeks 0 to 6)


    Protection





    • Controlled ankle motion (CAM) boot immobilization at all times except for physical therapy–specific exercises



    • Weight-bearing as tolerated with crutches. Pain to dictate how much weight.



    • Heel lift in the opposite shoe to avoid pelvic asymmetries



    • Weight-bearing radiographs at the 2- and 6-week marks. Any diastasis indicates failed nonoperative management.



    Timeline 43-1

    Nonoperative Rehabilitation of Midfoot Sprains














    PHASE I (weeks 0 to 6) PHASE II (weeks 6 to 10) PHASE III (weeks 10 to 12) PHASE IV (weeks 12+)



    • Cast (or CAM boot) immobilization, WBAT with crutches



    • Cardiovascular conditioning: UBE, pool, bike



    • Aquatic therapy: initiated at week 2 starting in shoulder deep water



    • Elevated ankle pumps, circles, ABCs



    • Using basic LE program with gait training WBAT



    • PRICE for inflammation



    • LE stretching neighboring joints and proximal joint strengthening core, hip, and knee



    • Contralateral limb proprioceptive training



    • X-ray at 2 and 6 weeks to determine removal of boot and WB progressions




    • PWB → WBAT over 1 week with the use of custom orthotic and



    • Stiff sole shoe



    • Aquatic therapy progressions:




      • Shoulder → waist deep water



      • Double leg → single leg exercises



      • Hop → jump



      • Fast walk → jog → run




    • Proprioception progressions:




      • Partial weight bearing → full weight bearing




    • Double leg exercise → single leg exercise



    • Eyes open → eyes closed



    • Level surface → uneven surface



    • Perturbations:




      • Submaximal → maximal



      • Slow → fast



      • Known (proactive) → unknown (reactive) patterns



      • Strengthening:



      • Intrinsic foot musculature



      • Gastrocnemius/soleus, tibialis anterior, tibialis posterior and peroneal longus/brevis



      • Strengthening progressions




    • Submaximal → maximal intensity



    • Short arc → full arc



    • Isometric → concentric → eccentric



    • Gait training on land (aquatic → land)



    • Plyometrics progressions:




      • Aquatic → land



      • In place → forward, backward and lateral over tape



      • Bilateral → Single leg



      • Flat ground → small box (2 inch) gradually increasing the size as needed for particular sport



      • One plane of movement (frontal) → multiple planes of movement (frontal and transverse)




    • May begin land and jogging on the treadmill at week 8 if the athlete is able to tolerate



    • Weight-bearing radiographs at 10 weeks. Evidence of diastasis is failure of nonoperative intervention.




    • Continue progressions per phase II



    • Sport-specific training progressions




      • Aquatic → land



      • In-line activity → cutting



      • Wide arching → tighter sharp turns



      • Slow → fast




        • Flat surface → uneven surface



        • Know → unknown game situations





    • Progression of plyometrics (sport-specific)



    • Rarely the patient is able to return to sport during this phase




    • Assessment of footwear (i.e., cleats and stirrup)



    • Assessment of field as related to footwear (i.e., natural grass vs. artificial turf)



    • A stiff insoled shoe with a custom orthotic should be worn when the athlete returns to sport



    • Continue sport-specific training as needed



    • Return to sport



    • If the athlete is still experiencing pain or unable to progress according to the rehabilitation protocol refer back to MD (orthopaedic foot and ankle specialist)



    Management of Pain and Swelling





    • Elevate lower leg above heart level



    • Nonsteroidal anti-inflammatory drugs (NSAIDs)



    • Ice



    • Ace wrap/compression



    • Ankle pumps, circles, ABCs



    Therapeutic Exercises





    • Core exercises, upper extremity and contralateral lower extremity strengthening




      • Upper body ergometer is utilized for cardiovascular fitness




    • Aquatic therapy: initiated at week 2. Basic progressions as follows:




      • Shoulder → waist deep water



      • Double leg → single leg exercises




    Sensorimotor Exercises





    • Contralateral limb proprioceptive training including single leg balance



    • Early pain-free protected weight-bearing (CAM walker), for proprioceptive input



    Milestones/Criterion-Based Rehabilitation Guidelines to Progress to the Next Stage





    • Stable radiographic alignment with no evidence of diastasis at 2 and 6 weeks.



    • Minimal tenderness with palpation over the Lisfranc complex—progress to Phase II.



    • Diastasis indicates failure of nonoperative management.



    Phase II (weeks 6 to 10)


    Protection





    • At 6 weeks, a custom-molded orthosis is prescribed and the athlete is allowed to ambulate in a stiff-soled shoe.



    • As weight-bearing is introduced, initially reduce forefoot loading during push off.



    • Midfoot taping may assist in plantarflexion of the first ray, which helps to stabilize forefoot and support longitudinal arch in beginning stages of functional training ( Figure 43-5 ).




      FIGURE 43-5


      Lisfranc taping technique. Tape begins and ends on dorsomedial aspect of the first metatarsal and loops around the heel as pictured. The tape aims to improve plantarflexion of the first ray, as can be seen in the positional relationship versus the second ray in the picture. A horizontal anchor across the midfoot is also shown.

      (From Wadsworth DJ, Eadie NT: Conservative management of subtle Lisfranc injury: A case report. J Orthop Sports Phys Ther 35:154–164, 2005, with permission.)



    Management of Pain and Swelling





    • Gradual increase in pain-free weight-bearing therapeutic exercise will help to further reduce pain and edema. Continue with elevation as in Phase I. Begin with selective modalities as needed (i.e., ice and electrical stimulation).



    Techniques for Progressive Increase in Range of Motion


    Manual Therapy Techniques





    • No joint mobilizations because of emphasis on stabilization of the midfoot



    Stretching/Flexibility Techniques for the Musculotendinous Unit





    • Gastrocnemius/soleus complex stretching with care not to fulcrum across the midfoot region (i.e., standing wall stretch recommended over long sit towel stretching) ( Figure 43-6 ).




      FIGURE 43-6


      Ankle dorsiflexion measurement and treatment in weight bearing. Measure how far the athlete can slide foot away, keeping the heel planted, and touch the knee to the wall. Hold the subtalar joint in neutral throughout the test. Measure from tip of the hallux to the wall.

      (From Hudson Z: Rehabilitation and return to play after foot and ankle injuries in athletes. Sports Med Arthrosc Rev 17:203–207, 2009.)



    • Continue stretching proximal musculature as needed.



    Other Therapeutic Exercises





    • Continue core, hip, and knee therapeutic exercise. Treatment adjusted based on residual deficits found in ongoing reevaluations.



    • Progression of aquatic therapy regimen—basic progressions as the athlete tolerates:




      • Shoulder → waist-deep water



      • Double leg → single-leg exercises



      • Hop → jump



      • Fast walk → jog → run




    Activation of Primary Muscles Involved



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    Apr 5, 2019 | Posted by in PHYSICAL MEDICINE & REHABILITATION | Comments Off on Midfoot Strains and Sprains and Lisfranc Injuries

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