(1/3), Level 3 There will be a pain in the lower leg on weight-bearing although . traveling traction), placed in metaphyseal segment at the concavity of the deformity, posteriorly placed blocking screw in proximal fragment and laterally placed blocking screw in the metaphyseal fragment help direct the nail more centrally, avoiding valgus/procurvatum deformities, increase biomechanical stability of bone/implant construct by 25%, not associated with increased infections, wound complications, and nonunion compared to closed-nailing techniques, ensure fracture is reduced before reaming, overream by 1.0-1.5mm to facilitate nail insertion, confirm guide wire is appropriately placed prior to reaming, should be "center-center" in the coronal and sagittal planes distally at the physeal scar, anterior aspect of nail should be lined up with axis of tibia when inserting nail - typically should line up with 2nd metatarsal in absence of tibial deformity, statically lock proximal and distally for rotational stability, no indication for dynamic locking acutely, number of interlocking screws is controversial, two proximal and two distal screws in presence of <50% cortical contact, consider 3 interlock screws in short segment of distal or proximal shaft fracture, prefer multiplanar screw fixation in these short segments, lateral may have more soft tissue interference but may be preferred in setting of soft tissue/wound issues, generally, minimally invasive plating is used to preserve soft tissues, plate attached to external jig to allow for percutaneous insertion of screws, must ensure appropriate contour of plate to avoid malreduction, higher risk for wound issues, particularly in open fractures, superficial peroneal nerve (SPN) commonly at risk laterally, below knee amputation (BKA) vs. above knee amputation (AKA) based on degree of soft tissue damage, standard BKA vs. ertl/bone block technique, infrapatellar nailing with patellar tendon splitting and paratendon approach, suprapatellar nailing may have lower rate of anterior knee pain, more common if nail left proud proximally, lateral radiograph is best radiographic views to evaluate proximal nail position, pain relief unpredictable with nail removal, all tibial shaft fractures - between 8-10%, higher in proximal 1/3 tibia fractures - up to 50%, patellar tendon pulls proximal fragment into extension, while hamstring tendons and gastrocnemius pull the distal fragment into flexion (procurvatum), distal 1/3 fractures have a higher rate of valgus malunion with IM nailing compared to plating, definitive management with casting or external fixation, most common deformity is varus with nonsurgical management, varus malunion may place patient at risk for ipsilateral ankle pain and stiffness, starting point too medial with IM nailing, adequate reduction, proper start point when nailing, if malalignment is noted immediately after surgery, return to operating room is appropriate with removal of nail, reduction and nail reinsertion, if malunion is appreciated at later followup, eventual nail removal and tibial osteotomy can be considered, most appropriate for aseptic, diaphyseal tibial nonunions, oblique tibial shaft fractures have the highest rate of union when treated with exchange nailing, consider revision with plating in metaphyseal nonunions, BMP-7 (OP-1) has been shown equivalent to autograft, often used in cases of recalcitrant non-unions, compression plating has been shown to have a 92-96% union rate after open tibial fractures initially treated with external fixation, fibular osteotomy of tibio-fibular length discrepancy associated with healed or intact fibula, highest after IM nailing of distal 1/3 tibia fractures, increases risk of adjacent ankle arthrosis, should always assess rotation in operating room, obtain perfect lateral fluoroscopic image of knee, then rotate c-arm 105-110 degrees to obtain mortise view of ipsilateral ankle, may have reduced risk with adjunctive fibular plating, LISS plate application without opening for distal screw fixation near plate holes 11-13 put superficial peroneal nerve at risk of injury due to close proximity, saphenous nerve can be injured during placement of locking screws, transient peroneal nerve palsy can be seen after closed nailing, EHL weakness and 1st dorsal webspace decreased sensation, usually nonoperatively with variable recovery expected, severe soft tissue injury with contamination, longer time to definitive soft tissue coverage, may require I&D or eventual removal of hardware, use of wound vacuum-assisted closure does not decrease risk of infection, Proximal Humerus Fracture Nonunion and Malunion, Distal Radial Ulnar Joint (DRUJ) Injuries. Located posterolaterally to the tibia, it is much smaller and thinner. (0/3), Level 2 muscles of the posterior compartment ( tibial nerve) Approach. Similar to a nondisplaced medial malleolus fracture, a nondisplaced lateral malleolus fracture can often be treated with a short leg cast or walking boot. Weber C fractures can be further subclassified as 6. Lateral short oblique or spiral fracture of fibula (anterosuperior to posteroinferior) above the level of the joint, 4. Damage to this nerve may result in deficits in those movements. Type of screw fixation for repairing the syndesmosis: Differences have not been found between syndesmotic screws that engage 3 or 4 cortices (, The position of the ankle when fixation is applied is not important, but the syndesmosis must be reduced anatomically (, The use of bioabsorbable screws may obviate the need for screw removal (. At its most proximal part, it is at the knee just posterior to the proximal tibia, running distally on the lateral side of the leg where it . For prognostic reasons, severely comminuted, contaminated barnyard injuries, close-range shotgun/high-velocity gunshot injuries, and open fractures presenting over 24 hours from injury have all been included in the grade III group. Usually, it gets worse with activity and better with rest. Distal tibial physeal fractures in children that may require open reduction. leads to spiral fracture pattern with fibula fracture at a different level. Are you sure you want to trigger topic in your Anconeus AI algorithm? Then the injury is cleaned to remove any debris and bone fragments. The fibula is one of the two long bones in the leg, and, in contrast to the tibia, is a non-weight bearing bone in terms of the shaft. Diagnosis is made with plain radiographs of the ankle. Fractures of the proximal head and neck of the fibula are associated with substantial damage to the knee (. 2023 Lineage Medical, Inc. All rights reserved. The fibula is a slender bone that lies posterolaterally to the tibia. C1: diaphyseal fracture of the fibula, simple. may be done supine with bump under affected limb or in lateral position. Stromsoe K, Hoqevold HE, Skjeldal S, et al. Located posterolaterally to the tibia, it is much smaller and thinner. The fibular shaft is an origin for multiple muscles of the leg, including musclesof the anterior compartment (extensor digitorum longus, extensor hallucis longus, peroneus tertius), the lateral compartment (peroneus longus, peroneus brevis), the superficial posterior compartment (soleus), and the deep posterior compartment (tibialis posterior and flexor hallucis longus). Fractures may involve the knee, tibiofibular syndesmosis, tibia, or ankle joint. Obtain AP and lateral views of the shafts of the tibia and fibula. mechanism of injury. usually associated with an injury to the medial side In rare cases, external fixation or ORIF is more appropriate depending on the location and orientation of the fracture. - frx above the syndesmotic result from external rotation or abduction forces that also disrupt. One reason for this may be the treatment for the vast majority of isolated fibula shaft fractures is non-operative - this con ; Patients may report a history of direct (motor vehicle crash or axial loading) or indirect . Read More, Copyright 2007 Lippincott Williams & Wilkins. The deep peroneal nerve innervates the musculature of the anterior compartment and is responsible for the dorsiflexion of the foot and toes. The treatment of an open tibial fracture starts with antibiotics and a tetanus shot to address the risk of infection. Diagnosis can be suspected with a knee effusion and a positive dial test but MRI studies are required for confirmation. 2023 Lineage Medical, Inc. All rights reserved. The tibia is a larger bone on the inside, and the fibula is a smaller bone on the outside. lawnmower) or iatrogenic during surgical dissection, (patterned off adult Lauge-Hansen classification), Adduction or inversion force avulses the distal fibular epiphysis (SH I or II), Rarely occurs with failure of lateral ligaments, Further inversion leads to distal tibial fracture (usually SH III or IV, but can be SH I or II), Occasionally can cause fracture through medial malleolus below the physis, Plantarflexion force displaces the tibial epiphysis posteriorly (SH I or II), Thurston-Holland fragment is composed of the posterior tibial metaphysis and displaces posteriorly, External rotation force leads to distal tibial fracture (SH II), Thurston-Holland fragment displaces posteromedially, Easily visible on AP radiograph (fracture line extends proximally and medially), Further external rotation leads to low spiral fracture of fibula (anteroinferior to posterosuperior), External rotation force leads to distal tibial fracture (SH I or II) and transverse fibula fracture, Occasionally can be transepiphyseal medial malleolus fracture (SH II), Distal tibial fragment displaces laterally, Thurston-Holland fragment is lateral or posterolateral distal tibal metaphysis, Can be associated with diastasis of ankle joint, Leads to SH V injury of distal tibial physis, Can be difficult to identify on initial presentation (diagnosis typically made when growth arrest is seen on follow-up radiographs), distal fibula physeal tenderness may represent non-displaced SHI, full-length tibia (or proximal tibia) to rule out Maisonneuve-type fracture, assess fracture displacement (best obtained post-reduction), non-displaced (< 2mm) isolated distal fibular fracture, displaced (> 2mm) SH I or II fracture with, acceptable closed reduction (no varus, < 10 valgus, < 10 recurvatum/procurvatum, < 3mm physeal widening), or II fracture with unacceptable closed reduction (varus, > 10 valgus, > 10 recurvatum/procurvatum, > 3mm physeal widening) and > 2 years of growth remaining, displaced SH I or II fracture with unacceptable closed reduction (varus, > 10 valgus, > 10 recurvatum/procurvatum, > 3mm physeal widening) and < 2 years of growth remaining, requires adequate sedation and muscle relaxation, only attempt reduction two times to prevent further physeal injury, NWB short-leg cast if isolated distal fibula fracture, NWB long-leg cast if distal tibia fracture, interposed periosteum, tendons, or neurovascular structures, percutaneous manipulation with K wires may aid reduction, open reduction may be required if interposed tissue present, transepiphyseal fixation best if at all possible, high rate associated with articular step-off > 2mm, medial malleolus SH IV fractures have the highest rate of growth disturbance, 15% increased risk of physeal injury for every 1mm of displacement, can represent periosteum entrapped in the fracture site, partial arrests can lead to angular deformity, distal fibular arrest results in ankle valgus defomity, medial distal tibia arrest results in varus deformity, complete arrests can result in leg-length discrepancy, if < 20 degrees of angulation with < 50% physeal involvement and > 2 years of growth remaining, bar of >50% physeal involvement in a patient with at least 2 years of growth, fibular epiphysiodesis helps prevent varus deformity, if < 50% physeal involvement and > 2 years of growth remaining, contralateral epiphysiodesis if near skeletal maturity with significant expected leg-length discrepancy, typically seen in posteriorly displaced fractures, can occur after triplane fractures, SH I or II fractures, usually leads to an increased external foot rotation angle, anterior angulation or plantarflexion deformity, occurs after supination-plantarflexion SH II fractures, occurs after external rotation SH II fractures, treatment options include physical therapy, psychological counseling, drug therapy, sympathetic blockade, Pediatric Pelvis Trauma Radiographic Evaluation, Pediatric Hip Trauma Radiographic Evaluation, Pediatric Knee Trauma Radiographic Evaluation, Pediatric Ankle Trauma Radiographic Evaluation, Distal Humerus Physeal Separation - Pediatric, Proximal Tibia Metaphyseal FX - Pediatric, Chronic Recurrent Multifocal Osteomyelitis (CRMO), Obstetric Brachial Plexopathy (Erb's, Klumpke's Palsy), Anterolateral Bowing & Congenital Pseudoarthrosis of Tibia, Clubfoot (congenital talipes equinovarus), Flexible Pes Planovalgus (Flexible Flatfoot), Congenital Hallux Varus (Atavistic Great Toe), Cerebral Palsy - Upper Extremity Disorders, Myelodysplasia (myelomeningocele, spinal bifida), Dysplasia Epiphysealis Hemimelica (Trevor's Disease). Open reduction and internal fixation is the surgery that can be used to reposition and physically connect the bones in an open fracture. Fibular fractures in adults are typically due to trauma. Treatment may be nonoperative or operative depending on patient age, fracture displacement, and fracture morphology. Treatment is generally operative with intramedullary nailing. They are also called tibial plafond fractures. Repair of the deltoid ligament tear is not believed to be necessary (. The tibia is much thicker than the fibula. 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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