fibula fracture orthobullets

Fibular Fracture - Physiopedia Accept Low-energy, nondisplaced (aligned) fractures, sometimes called toddlers fractures, occur from minor falls and twisting injuries. All Rights Reserved. Treatment for tibia and fibula fractures ranges from casting to surgery, depending on the type and severity of the injury. (0/3), Level 2 Fourth and fifth proximal/middle phalangeal shaft fractures and select metacarpal fractures. Fibular Avulsion Fracture - FootEducation Fibula bone fracture is a common injury seen in the emergency room. Diaphyseal tibial fractures are the most common long bone fracture. Fibula fractures - UpToDate Common proximal tibial fractures include: This type of fracture takes place in the middle, or shaft (diaphysis), of the tibia. There are three types of tibial shaft fractures: These fractures occur at the ankle end of the tibia. Anteroposterior (A) and lateral (B) radiographic evaluation of the entire length of the fibula is essential to avoid missing a Maisonneuve fracture and the associated syndesmotic injury. Distal tibial metaphyseal fractures usually heal well after setting them without surgery and applying a cast. These fractures occur in the knee end of the tibia and are also called tibial plateau fractures. High-energy fractures, such as those caused by serious car accidents or major falls, are more common in older children. Transverse comminuted fracture of the fibula above the level of the syndesmosis, 2. Fractures of the fibula often involve a syndesmotic injury (called Maisonneuve fractures). C3: proximal fracture of the fibula. Pain will usually have developed gradually over time, rather than at a specific point in time that the athlete can recognise as when the injury occurred. Numbness or paresthesias may arise if damage to the peroneal nerve has occurred. Fractures of the proximal head and neck of the fibula are associated with substantial damage to the knee (. a combined posterior drawer and external rotation force is then applied to the knee to assess for an increase in posterolateral translation (lateral tibia externally rotates relative to lateral femoral condyle), knee positioned at 90 and external rotation and valgus force applied to tibia, as the knee is extended the tibia reduces with a palpable clunk, tibia reduces from a posterior subluxed position at ~20 of flexion to a reduced position in full extension (reduction force from IT band transitioning from a flexor to an extensor of the knee), altered sensation to dorsum of foot and weak ankle dorsiflexion, approximately 25% of patients have peroneal nerve dysfunction, may see avulsion fracture of the fibula (arcuate fracture ) or femoral condyle, side-to-side difference 2.7-4 mm = isolated LCL tear, primary varus = tibiofemoral malalignment, secondary varus = LCL deficiency with increased lateral opening, triple varus = remaining PLC deficient, overall varus recurvatum alignment, necessary to determine mechanical axis and if a, look for injury to the LCL, popliteus, and biceps tendon, coronal oblique thin-slice through the fibular head are best at visualizing the PLC structures, hinged knee brace locked in extension x4 weeks, followed by progressive functional rehabilitation, midsubstance repair have 40% failure rate following repair, repair of LCL, popliteus tendon and/or popliteofibular ligament should be performed if structures can be, anatomically reduced to their attachment site, avulsion fracture of fibular head can be treated with screws or suture anchors, avulsion injuries where repair is not possible or tissie is poor quality, goal is to reconstruct LCL and the popliteofibular ligament using a free tendon graft (semitendinosus or achilles), soft tissue graft passed through bone tunnel in fibular head, limbs are then crossed to create figure-of-eight and fixed to lateral femur to a single tunnel, trans-tibial double-bundle reconstruction, split achilles tendon is fixed to isometric point of the femoral epicondyle, one tibia-based limb and one fibula-based limb, fibula-limb is fixed to the fibular head with a bone tunnel and transosseous sutures to reconstruct the LCL, tibia-limb is brought through the posterior tibia to reconstruct the popliteofibular ligament, proximal attachment site at anatomic femoral LCL attachment, through the fibular head lateral to medial, docking into the tibial tunnel posterior to anterior with graft #2, graft #2 reconstructs the popliteus tendon, proximal attachment site at the anatomic popliteus tendon attachment, docking into the tibial tunnel posterior to anterior with graft #1, hinged knee brace, nonweightbearing for 6 weeks, range of motion protocols differ between surgeons, some advocate for passive ROM immediately 0-90, others immobilize for 2 weeks, then begin motion, at 6 weeks, begin weightbearing and closed-chain strenghtening, return to activities / sports ~ 6 to 9 months, operative treatment has improved outcomes compared to nonoperative treatment, repair has higher failure rate than reconstruction, particularly for midsubstance injuries, but also for soft tissue avulsions, anatomic reconstruction restores rotatory stability, but not all varus stability on stress testing, PLC reconstruction, +/- ACL reconstruction, +/-, acute and chronic combined ligament injuries, PLC reconstruction should be performed at same time or prior to (as staged procedure) ACL or PCL to prevent early cruciate failure, indicated in patients with varus mechanical alignment, failure to correct bony alignment jeopardizes ACL and PLC reconstruction success, ACL reconstruction + PLC repair 33% achieved IKDC grade A or B compared to 88% of patients who underwent ACL + PLC reconstruction, failure to identify a PLC injury will lead to failure of ACL or PCL reconstruction, Spontaneous Osteonecrosis of the Knee (SONK), Osgood Schlatter's Disease (Tibial Tubercle Apophysitis), Anterior Superior Iliac Spine (ASIS) Avulsion, Anterior Inferior Iliac Spine Avulsion (AIIS), Proximal Tibiofibular Joint Ganglion Cysts, Pre-Participation Physical Exam in Athlete, Concussions (Mild Traumatic Brain Injury). There are several ways to classify tibia and fibula fractures. Although tibia and fibula shaft fractures are amongst the most common long bone fractures, there is little literature citing the incidence of isolated fibula shaft fractures. paralyzed), or those unfit for surgery, angulation and rotational alignment are well maintained with casting, however, shortening is hard to control, risk of shortening higher with oblique and comminuted fracture patterns, risk of varus malunion with midshaft tibia fractures and an intact fibula, high success rate if acceptable alignment maintained, non-union occurs in approximately 1% of patients treated with closed reduction, all open tibia fractures require an emergent I&D, surgical debridement within 12-24 hours of injury, wounds should be irrigated and dressed with saline-soaked gauze in the emergency department before splinting, all open tibia fractures require immediate antibiotics, should be administered within 3 hours of injury, standard abx for open fractures (institution dependent), cephalosporin given continuously for 24 hours, after definitive surgery in Grade I, II, and IIIA open fractures, aminoglycoside added in Grade IIIB injuries, tetanus vaccination status should be confirmed and appropriate prophylaxis should be administered if necessary, early antibiotic administration is the most important factor in reducing infection, emergent and thorough surgical debridement is also an, must remove all devitalized tissue including cortical bone, open fractures with soft tissue defects/contamination, uniplanar, circular, hybrid external fixators all available, should be converted to intramedullary nail within 7-21 days, ideally less than 7 days, longer time to union and worse functional outcomes, high rate of pin tract infections; avoid intra-articular placement given risk for septic arthritis, unacceptable alignment with closed reduction and casting, soft tissue injury that will not tolerate casting, ipsilateral limb injury (i.e., floating knee), reamed nailing allows for larger diameter nail, provisional reduction techniques (blocking screws, plating, etc), particularly useful for proximal 1/3 tibial shaft fractures, for closed tibia fractures treated with nailing, risks for nonunion: gapping at fracture site, open fracture and transverse fracture pattern, shorter immobilization time, earlier time to weight-bearing, and decreased time to union compared to casting, decreased malalignment compared to external fixation, improved fracture alignment with suprapatellar nailing, reamed may have higher union rates and lower time to union than unreamed nails in closed fractures (controversial), reamed nails are safe for use with open fractures, with no evidence of decreased nonunion rates in open fractures, recent studies show no adverse effects of reaming (infection, embolism, nonunion), reaming with the use of a tourniquet is not associated with thermal necrosis of the tibial shaft, despite prior studies suggesting otherwise, higher rate of locking screw breakage with unreamed nailing, proximal tibia fractures with inadequate proximal fixation from IM nailing, distal tibia fractures with inadequate distal fixation from IM nail, tibia fractures in the setting of adjacent implant/hardware (i.e.

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