Rosen & Barkin's 5-Minute Emergency Medicine Consult (713 page)

Read Rosen & Barkin's 5-Minute Emergency Medicine Consult Online

Authors: Jeffrey J. Schaider,Adam Z. Barkin,Roger M. Barkin,Philip Shayne,Richard E. Wolfe,Stephen R. Hayden,Peter Rosen

Tags: #Medical, #Emergency Medicine

BOOK: Rosen & Barkin's 5-Minute Emergency Medicine Consult
6.77Mb size Format: txt, pdf, ePub
  • High- vs. low-energy injury
  • Amount of soft tissue injury is prognostic and determined by the degree of energy involved.
  • Indirect force—frequently low-energy trauma:
    • Rotary and compressive forces often result in oblique and spiral fractures.
  • Skiing, fall, child abuse
  • Direct force—high-energy trauma:
    • Direct blow to leg often results in transverse and comminuted fractures.
  • Pedestrian vs. auto, motor vehicle crash (MVC):
    • Bending force over a fulcrum often produces comminution with a wedge-shaped butterfly fragment.
  • Skier’s boot top, football tackle, MVC
Pediatric Considerations
  • Bicycle spoke injury:
    • Foot and lower leg get caught between frame and wheel spoke
    • Crush injury is the primary problem.
    • Initial benign appearance of the soft tissues is often deceiving:
      • Full-thickness skin loss can occur in days.
    • Orthopedic surgery consultation should be obtained for all spoke-injury patients with associated fractures.
  • Toddler fracture:
    • Spiral fracture involving the distal 3rd of the tibia with intact fibula secondary to rotational force (turning on planted foot)
    • Age range is 9 mo–6 yr, most often when learning to walk.
    • Fractures in midshaft or more transverse are suggestive of nonaccidental trauma.
DIAGNOSIS
SIGNS AND SYMPTOMS
History
  • History of trauma
  • Pain is usually immediate, severe, and well localized to the fracture site.
Physical-Exam
  • Visible or palpable deformity at the fracture site
  • Significant soft tissue damage with high-energy trauma
  • Inability to bear weight if tibia involved:
    • May be able to walk if isolated fibular fracture
  • Foot drop on affected leg from injury to the peroneal nerve as it wraps around the fibular head
  • Compartment syndrome
Pediatric Considerations
  • Rely on parents for historical information.
  • Child may present limping with no obvious deformity.
ESSENTIAL WORKUP
  • Careful assessment of soft tissues
  • Careful neurovascular exam (compare with contralateral side)
  • Examine for associated injuries.
  • Completely expose patient and put into gown.
  • Assessment for compartment syndrome
ALERT
  • Compartment syndrome
  • Occurs in 8% of diaphyseal fractures, more common in younger patients
  • Relatively common complication of tibial fractures and may not appear until 24 hr after injury
  • Pain disproportionate to that expected
  • Patient may have swollen, tight compartment, but does not always have pain on palpation of compartment.
  • Pain on passive stretch of foot, toes
  • Sensory deficit
  • Motor weakness is a late finding.
  • Pulselessness is not a sign of compartment syndrome:
    • Palpable pulses are almost always present in compartment syndrome unless there is underlying arterial injury.
  • 4 leg compartments: Anterior, lateral, deep posterior, and superficial posterior
  • Anterior compartment:
    • Deep peroneal nerve
    • Sensation of 1st web space
    • Ankle and toe dorsiflexion
    • Anterior tibial artery feeds dorsalis pedis artery
  • Lateral compartment:
    • Superficial peroneal nerve
    • Sensation of dorsum of foot
    • Foot eversion
  • Deep posterior compartment:
    • Tibial nerve
    • Sensation to sole of foot
    • Ankle and toe plantar flexion
    • Posterior tibial and peroneal arteries
  • Superficial posterior compartment:
    • Branch of sural cutaneous nerve
    • Sensation to lateral foot
DIAGNOSIS TESTS & NTERPRETATION
Lab

Include creatine phosphokinase levels if concerned about compartment syndrome

Imaging
  • Anteroposterior and lateral views of the leg, knee, and ankle
  • Bone scan at 1–4 days for toddler fracture and stress fractures if radiographs unrevealing
  • CT scan for complex fracture pattern to evaluate for rotational malalignment
  • CT or MRI for pathologic fracture
  • MRI for stress fractures may be necessary.
Diagnostic Procedures/Surgery

Compartment pressures:

  • Pressures >30 mm Hg are an indication for orthopedic consultation and fasciotomy.
  • Delta P or difference between diastolic BP and compartment pressure <20 is indicative of compartment syndrome
  • Repeated pressure measurements over time, taken within 5 cm of fracture site, are necessary.
Pediatric Considerations

Oblique radiograph to detect nondisplaced fractures

DIFFERENTIAL DIAGNOSIS
  • Stress fracture
  • Pathologic fracture
  • Osteomyelitis
Pediatric Considerations
  • Sarcoma
  • Pathologic fracture
  • Osteomyelitis
  • Nonaccidental trauma
TREATMENT
PRE HOSPITAL
  • Look for associated injuries in high-energy mechanisms.
  • Assess for neurologic or vascular compromise.
  • Adequate immobilization is essential to prevent further injury.
INITIAL STABILIZATION/THERAPY
  • Manage airway and resuscitate as indicated.
  • Life-threatening injuries take precedence.
  • Immobilize extremity.
  • Apply ice
  • Strict NPO
  • Pain control
ED TREATMENT/PROCEDURES
  • Closed fractures:
    • Gentle attempt at reduction if fracture is displaced (do not attempt multiple reductions; may increase risk for compartment syndrome).
    • Immobilization:
      • Well-padded long leg posterior splint
      • Knee in 10–20° of flexion
    • Avoid circumferential cast.
    • If pain persists after immobilization, suspect:
      • Compartment syndrome
      • Avoid elevation of leg in suspected compartment syndrome; it lowers perfusion to the extremity.
      • Nerve compression
    • Crutches
  • Open fractures:
    • Remove contaminants and cover wound with moist, sterile dressing.
    • Antibiotics
    • Tetanus prophylaxis
    • Immobilization with well-padded long leg posterior splint
    • Immediate orthopedic surgery consultation for débridement and fracture fixation
  • Isolated fibular fracture:
    • Usually treated symptomatically:
      • Padded splint
      • Elevation
      • Ice
      • No weight bearing until swelling resolves
    • Crutches if not bearing weight
MEDICATION
  • Gram-positive cocci coverage for open fractures: Cefazolin 2 g loading dose then 1 g (peds: 50 mg/kg/d) IV/IM q8h
  • Gustilo–Anderson type III, add gram-negative rod coverage: Gentamicin 3–5 mg/kg (peds: 2.5 mg/kg) IV q8h
  • Farming accident, add
    Clostridium
    spp coverage: Penicillin G 10 million IU (peds: 250,000–400,000 IU/kg/d) IV q6h
  • Tetanus 0.5 mL IM and tetanus immune globulin 250 U IM as indicated by the type of wound and the number of primary immunizations
  • If penicillin allergic: Vancomycin 1 g (peds: 10 mg/kg) IV q12h
FOLLOW-UP
DISPOSITION
Admission Criteria
  • Multiple trauma
  • High-energy mechanism
  • Soft tissue involvement
  • Risk for compartment syndrome
  • All open fractures
  • Displaced, angulated, transverse, shortened, comminuted, and otherwise unstable fractures
  • Intra-articular involvement
  • Neurovascular compromise
  • Inadequate pain control
  • Pathologic fracture
  • Nonaccidental trauma in children
Discharge Criteria
  • Minimally displaced fracture with low-energy injury mechanism
  • Close orthopedic follow-up
  • Return parameters for compartment syndrome in a reliable patient
  • If fracture is >48 hr old, compartment syndrome is unlikely to develop; if it has not occurred, discharge criteria may be more liberal.
FOLLOW-UP RECOMMENDATIONS
  • Most pediatric fractures are treated with long leg cast for 4–6 wk.
  • Nondisplaced and minimally displaced fractures in adults may be treated with long leg cast and closed reduction.
  • Open contaminated fractures may be treated with external fixation and débridements.
  • Treatment with intramedullary nail allows for early mobilization and weight bearing as tolerated.
  • Kirschner wires are sometimes used in the treatment.
PEARLS AND PITFALLS
  • High incidence of associated injuries in high-energy trauma:
    • Associated injuries commonly include:
      • Femoral fractures (“floating knee injury”)
      • Head trauma
      • Spine fractures
    • Deep venous thrombosis occurs in 10–25% of patients following tibial fracture.
ADDITIONAL READING
  • Browner BD. Fractures of the tibial shaft. In:
    Skeletal Trauma.
    4th ed. Philadelphia, PA: WB Saunders Co.; 2008.
  • Green NE, Swiontkowski MF. Fractures of the tibia and fibula. In:
    Skeletal Trauma in Children
    . Philadelphia, PA: Elsevier; 2008.
  • Newton EJ, Love J. Emergency department management of selected orthopedic injuries.
    Emerg Med Clin North Am
    . 2007;25(3):763–793, ix–x.
  • Park S, Ahn J, Gee AO, et al. Compartment syndrome in tibial fractures.
    J Orthop Trauma
    . 2009;23(7):514–518.

Other books

Secrets by Lesley Pearse
Look at You Now by Liz Pryor
Microsiervos by Douglas Coupland
Seducing the Princess by Hart Perry, Mary
The Silent Waters by Brittainy Cherry
Tamberlin's Account by Munt, Jaime
Clouds without Rain by P. L. Gaus
The Farmer Next Door by Patricia Davids