Orthopedic Injuries Notes

Orthopaedic Injuries

National EMS Education Standard Competencies

  • Trauma: Applies fundamental knowledge to provide basic emergency care and transportation based on assessment findings for an acutely injured patient.
  • Orthopaedic Trauma:
    • Recognition and management of:
      • Open fractures
      • Closed fractures
      • Dislocations
      • Amputations
    • Pathophysiology, assessment, and management of:
      • Upper and lower extremity orthopaedic trauma
      • Open fractures
      • Closed fractures
      • Dislocations
      • Sprains/strains
      • Pelvic fractures
      • Amputations/replantation
  • Medicine: Applies fundamental knowledge to provide basic emergency care and transportation based on assessment findings for an acutely ill patient.
  • Nontraumatic Musculoskeletal Disorders:
    • Anatomy, physiology, pathophysiology, assessment, and management of:
      • Nontraumatic fractures

Introduction

  • The musculoskeletal system provides:
    • Form
    • Upright posture
    • Movement
    • Protection of vital internal organs
  • Bones, muscles, tendons, cartilage, and ligaments are still at risk of injury.
  • Musculoskeletal injuries are common reasons for seeking medical attention.
  • Easily identified due to pain, swelling, and deformity.
  • Can result in short- or long-term disability.

Anatomy and Physiology of the Musculoskeletal System

  • Three types of muscles: skeletal, smooth, and cardiac.
  • Skeletal Muscle:
    • The major muscle type involved in musculoskeletal injuries.
    • Attaches to bones and crosses at least one joint.
    • Also called voluntary muscle.
    • Makes up the largest portion of the body’s muscle mass.
    • Supplied with arteries, veins, and nerves for oxygen, nutrients, waste removal, and nervous stimuli.
    • Attached to bone by tendons.
  • Smooth Muscle:
    • Performs automatic work of the body.
    • Contracts and relaxes to control movement within tubular structures.
  • Cardiac Muscle:
    • Specially adapted involuntary muscle.
    • Has its own regulatory system.

The Skeleton

  • Gives recognizable human form.
  • Protects vital organs.
  • Allows movement.
  • Made up of approximately 206 bones.
  • Produces blood cells (in bone marrow).
  • Serves as a reservoir for minerals and electrolytes.
  • Skull: Protects the brain.
  • Thoracic cage: Protects the heart, lungs, and great vessels.
  • Pectoral girdle: Consists of two scapulae and two clavicles.
  • Upper Extremity:
    • Extends from shoulder to fingertips.
    • Composed of the upper arm (humerus), elbow, and forearm (radius and ulna).
  • Hand:
    • Contains three sets of bones:
      • Wrist bones (carpals)
      • Hand bones (metacarpals)
      • Finger bones (phalanges)
  • Pelvis:
    • Supports body weight.
    • Protects bladder, rectum, and female reproductive organs.
    • Pelvic girdle is formed by the ischium, ilium, and pubis.
    • Bones are fused to form the innominate (hip) bone.
  • Lower Extremity:
    • Consists of bones of the thigh, leg, and foot.
      • Femur (thigh bone)
      • Femoral head
      • Tibia and fibula
      • Patella (kneecap)
  • Foot:
    • Consists of three classes of bones:
      • Ankle bones (tarsals)
      • Foot bones (metatarsals)
      • Toe bones (phalanges)
  • Bones of the skeleton provide a framework for muscle and tendon attachment.
  • Joints:
    • Formed where two bones come into contact.
    • Held together in a tough fibrous capsule.
    • Lubricated by synovial fluid.
    • Allows motion.

Mechanism of Injury

  • Significant force generally required to cause fractures and dislocations.
    • Direct blows
    • Indirect forces
    • Twisting forces
    • High-energy forces

Fractures

  • A break in the continuity of the bone.
  • Classified as either closed or open, based on skin damage.
  • Treat any injury breaking the skin as a possible open fracture.
  • Described by whether the bone is moved from its normal position.
    • Nondisplaced fracture: Simple crack of the bone.
    • Displaced fracture: Produces actual deformity or distortion of the limb.
      *Types of Fractures:
    • Comminuted: Bone broken into more than two fragments.
    • Epiphyseal: Fracture in the growth section of a child’s bone.
    • Greenstick: Incomplete fracture that passes only partway through the shaft of a bone.
    • Incomplete: Fracture that does not run completely through the bone.
    • Oblique: Fracture at an angle across the bone.
    • Pathologic: Fracture of weakened or diseased bone.
    • Spiral: Fracture caused by a twisting force, resulting in an oblique fracture around and through the bone.
    • Transverse: Fracture that occurs straight across the bone.
  • Signs of Fractures:
    • Deformity
    • Tenderness
    • Guarding
    • Swelling
    • Bruising
    • Crepitus
    • False motion
    • Exposed fragments
    • Pain
    • Locked joint

Dislocations

  • Disruption of a joint in which the bone ends are no longer in contact.
  • Sometimes a dislocated joint will spontaneously reduce.
  • Confirm the dislocation with the patient history.
  • A dislocation that does not reduce is a serious problem.
  • Signs and Symptoms:
    • Marked deformity
    • Swelling
    • Pain aggravated by any attempt at movement
    • Tenderness on palpation
    • Loss of normal joint motion
    • Numbness or impaired circulation

Sprains

  • Occur when a joint is twisted or stretched beyond its normal range of motion.
  • Can range from mild to severe.
  • Most vulnerable joints: knees, shoulders, and ankles.
  • Severe deformity does not typically occur.
  • Signs and Symptoms:
    • Guarding
    • Swelling and ecchymosis
    • Pain
    • Instability of the joint

Strain

  • A stretching or tearing of the muscle.
  • Causes pain, swelling, and bruising of the soft tissues in the area.
  • Often no deformity is present and only minor swelling is noted at the site of the injury.

Amputations

  • An injury in which an extremity is completely severed from the body.
  • Can damage every aspect of the musculoskeletal system.

Complications

  • Orthopaedic injuries can lead to systemic changes or illnesses.
  • Likelihood of complications related to:
    • Strength of the force that caused the injury
    • Injury’s location
    • Patient’s overall health
  • Preventing contamination following an open fracture:
    • Brush away any debris on the skin.
    • Do not enter or probe the fracture site.
  • Long-term disability is one of the most devastating consequences of an orthopaedic injury.
  • Reduce risk/duration of long-term disability by:
    • Preventing further injury
    • Reducing the risk of wound infection
    • Minimizing pain by the use of cold and analgesia
    • Transporting patients to an appropriate medical facility

Assessing the Severity of Injury

  • The Golden Hour is critical for life and for preserving limb viability.
  • Prolonged hypoperfusion can cause significant damage.
  • Any suspected open fracture or vascular injury is a critical emergency.
  • Most injuries are not critical.

Patient Assessment

  • Always look at the big picture.
  • Distinguish mild injuries from severe injuries.
  • Severe injuries may compromise neurovascular function, which could be limb threatening.

Scene Size-Up

  • Scene Safety:
    • Identify the forces associated with the MOI.
    • Use standard precautions.
    • Consider that there may be hidden bleeding.
    • Evaluate the need for additional support.
  • Mechanism of Injury/Nature of Illness:
    • Look for indicators of the MOI.
    • Be alert for both primary and secondary injuries.
    • Consider what injuries the MOI would lead you to expect.

Primary Assessment

  • Focus on identifying and managing life threats.
  • Treat patient according to level of consciousness and XABCs.
  • Address bleeding and treat for shock.
  • Check for responsiveness using the AVPU scale.
  • Ask about the chief complaint.
  • Administer high-flow oxygen to all patients whose level of consciousness is less than alert and oriented.
  • Ask about the MOI.
  • If there was significant trauma, the musculoskeletal injuries may be a lower priority.
  • Airway and Breathing:
    • Fractures and sprains usually do not create airway and breathing problems.
    • Evaluate the chief complaint and MOI.
  • Circulation:
    • Determine whether the patient has a pulse, has adequate perfusion, or is bleeding.
    • If the skin is pale, cool, or clammy and capillary refill time is slow, treat for shock.
    • Maintain a normal body temperature.
  • Transport Decision:
    • Provide rapid transport if the patient has an airway or breathing problem or significant bleeding.
    • A patient who has a significant MOI but whose condition appears stable should also be transported promptly.
    • Patients with a simple MOI may be further assessed on scene.

History Taking

  • Obtain a medical history and be alert for injury-specific signs and symptoms and any pertinent negatives.
  • Obtain a SAMPLE history for all trauma patients.
  • OPQRST is too lengthy when ABCs require immediate attention.

Secondary Assessment

  • Physical Examinations:
    • If significant trauma has occurred, start with a secondary assessment of the entire body.
    • Begin with the head and work systematically toward the feet.
    • Use DCAP-BTLS to assess the musculoskeletal system.
    • When lacerations are present in an extremity, consider an open fracture.
    • Any injury or deformity of the bone may be associated with vessel or nerve injury.
    • Assess neurovascular function.
    • Use the 6 Ps of musculoskeletal assessment.
    • Obtain a baseline set of vital signs.

Reassessment

  • Repeat the primary assessment.
    • Every 5 minutes for an unstable patient
    • Every 15 minutes for a stable patient
  • Assess the overall condition, stabilize the XABCs, and control any serious bleeding.
  • In a critically injured patient, secure the patient to a long backboard and transport.
  • If the patient has no life-threatening injuries, take extra time at the scene to stabilize his or her condition.
  • The main goal is stabilization in the most comfortable position that allows for maintenance of good circulation distal to the injury.
  • Communication and Documentation:
    • Include a description of the problems found during your assessment.
    • Report problems with the ABCs, open fractures, and compromised circulation.
    • Document complete descriptions of injuries and the MOIs associated with them.

Emergency Medical Care

  • Perform a primary assessment.
  • Stabilize the patient’s XABCs.
  • Perform a secondary assessment of either the entire body or the specific area of injury.
  • Follow standard precautions.
  • Be alert for internal bleeding.

Splinting

  • A splint is a flexible or rigid device that is used to protect and maintain the position of an injured extremity.
  • Splint all fractures, dislocations, and sprains before moving the patient, unless he or she is in immediate danger.
  • Splinting reduces pain and makes it easier to transfer and transport the patient.
  • Splinting Principles - Splinting will help to prevent:
    • Further damage to muscles, the spinal cord, peripheral nerves, and blood vessels
    • Laceration of the skin
    • Restriction of distal blood flow
    • Excessive bleeding of the tissues
    • Increased pain
    • Paralysis of extremities
  • General principles of splinting:
    • Remove clothing from the area.
    • Note and record the patient’s neurovascular status.
    • Cover open wounds with a dry, sterile dressing.
    • Do not move the patient before splinting an extremity unless there is danger.
    • Stabilize the joints.
    • Pad all rigid splints.
    • Maintain manual stabilization.
    • If you encounter resistance, splint the limb in its deformed position.
    • Immobilize all suspected spinal injuries in a neutral, in-line position.
    • When in doubt, splint.

Rigid Splints

  • Made from firm material.
  • Applied to the sides, front, and/or back of an injured extremity.
  • Prevent motion at the injury site.
  • Take two EMTs to apply.
  • Two situations in which you must splint the limb in the position of deformity:
    • When the deformity is severe
    • When you encounter resistance or extreme pain when applying gentle traction to the fracture of a shaft of a long bone

Formable Splints

  • Most likely to use structural aluminum (SAM) splints and vacuum splints
  • Other splints:
    • Air splints
    • Pillow splints
    • Sling and swathe bandages
    • Vacuum splints

Pelvic Binder

  • Used to splint the bony pelvis to reduce hemorrhage from bone ends, venous disruption, and pain
  • Meant to provide temporary stabilization

Hazards of Improper Splinting

  • Compressions of nerves, tissues, and blood vessels
  • Delay in transport of a patient with a life-threatening injury
  • Reduction of distal circulation
  • Aggravation of the injury
  • Injury to tissue, nerves, blood vessels, or muscles

Transportation

  • Very few musculoskeletal injuries justify the use of excessive speed during transport.
  • A patient with a pulseless limb must be given a higher priority.
  • If the treatment facility is an hour or more away, transport by helicopter or immediate ground transportation.

Injuries of the Clavicle and Scapula

  • The clavicle is one of the most commonly fractured bones in the body.
  • Occur commonly in children
  • A patient will report pain in the shoulder and hold the arm across the front of the body.
  • Swelling and point tenderness occur over the clavicle.
  • Fractures of the scapula occur much less frequently because the bone is well protected by many large muscles.
  • Almost always the result of a forceful, direct blow to the back
  • The associated chest injuries pose the greatest threat of long-term disability.
  • Acromioclavicular joint is frequently separated during sports.
  • These fractures can be splinted effectively with a sling and swathe.

Dislocation of the Shoulder

  • The humeral head most commonly dislocates anteriorly.
  • Shoulder dislocations are very painful.
  • Stabilization is difficult because any attempt to bring the arm in toward the chest wall produces pain.
  • Splint the joint in whatever position is more comfortable for the patient.

Fracture of the Humerus

  • Occur either proximally, in the midshaft, or distally at the elbow
  • Consider applying traction to realign the fracture fragments before splinting them.
  • Splint the arm with a sling and swathe.

Elbow Injuries

  • Different types of injuries are difficult to distinguish without x-ray examinations.
  • Fracture of the distal humerus
    • Common in children
    • Fracture fragments rotate significantly, producing deformity and causing injuries to nearby vessels and nerves.
  • Dislocation of the elbow
    • Typically occurs in athletes
    • The ulna and radius are most often displaced posteriorly.
  • Fracture of olecranon process of ulna
    • Can result from direct or indirect forces
    • Often associated with lacerations and abrasions
    • Patient will be unable to extend the elbow.
  • Fractures of the radial head
    • Often missed during diagnosis
    • Generally occurs as a result of a fall on an outstretched arm or a direct blow to the lateral aspect of the elbow
    • Attempts to rotate the elbow or wrist cause discomfort.
  • Care of elbow injuries
    • All elbow injuries are potentially serious and require careful management.
    • Always assess distal neurovascular functions periodically.
    • Provide prompt transport for all patients with impaired distal circulation.

Fractures of the Forearm

  • Common in people of all age groups
  • Seen most often in children and elderly
  • Usually the radius and the ulna break at the same time.
  • To stabilize fractures, you can use a padded board, air, vacuum, or pillow splint.

Injuries of the Wrist and Hand

  • Must be confirmed by x-ray exams
  • Dislocations are usually associated with a fracture.
  • Isolated, nondisplaced fracture of a carpal bone is common.
  • Any questionable wrist injury should be splinted and evaluated in the ED.

Fractures of the Pelvis

  • Often results from direct compression in the form of a heavy blow
  • May be accompanied by life-threatening loss of blood
  • Open fractures are quite uncommon.
  • Bone fragments can lacerate the rectum, vagina, and bladder.
  • Suspect a fracture of the pelvis in any patient who has sustained a high- velocity injury and complains of discomfort in the lower back or abdomen.
  • Assess for tenderness.
  • Injury to the bladder or the urethra may cause lower abdominal tenderness and evidence of hematuria or blood.

Dislocation of the Hip

  • Dislocates only after significant injury
  • Most dislocations are posterior.
  • Suspect a dislocation in any patient who has been in an automobile crash and has a contusion, laceration, or obvious fracture in the knee region.
  • Posterior dislocation is frequently complicated by injury to the sciatic nerve.
  • Distinctive signs:
    • Severe pain in the hip
    • Strong resistance to movement of the joint
    • Tenderness on palpation
  • Do not attempt to reduce the dislocated hip in the field.
  • Splint the dislocation.
    • Place the patient supine on a backboard.
    • Support the affected limb with pillows.
    • Secure the entire limb to the backboard with long straps.
    • Provide prompt transport.

Fractures of the Proximal Femur

  • Common fractures, especially in older people and patients with osteoporosis
  • Break goes through the neck of the femur, the interochanteric region, or across the proximal shaft of the femur.
  • Patients display characteristic deformity.
    • Lie with the leg externally rotated, and injured limb is usually shorter than the opposite, uninjured limb.
  • Assess the pelvis for any soft-tissue injury and bandage appropriately.
  • Assess pulses and motor and sensory functions.
  • Splint the lower extremity and transport to the emergency department.

Femoral Shaft Fractures

  • Can occur in any part of the shaft, from the hip region to the femoral condyles just above the knee joint
  • Large muscles of the thigh spasm in an attempt to “splint” the unstable limb.
  • Produces significant deformity and shortened limb
  • There is often significant blood loss.
  • Bone fragments may penetrate or press on important nerves and vessels.
  • Carefully and periodically assess the distal neurovascular function.
  • Cover any wound with a dry, sterile dressing.
  • These fractures are best stabilized with a traction splint.

Traction Splints

  • Used primarily to secure fractures of the femur
  • Goals of in-line traction:
    • To stabilize the fracture fragments
    • To align the limb sufficiently
    • To avoid potential neurovascular compromise
  • Do not use for any of these conditions:
    • Injuries of the upper extremity
    • Injuries close to or involving the knee
    • Injuries of the pelvis
    • Partial amputations or avulsions with bone separation
    • Lower leg, foot, or ankle injury

Injuries of Knee Ligaments

  • Many different types of injuries occur in this region.
    • Ligament injuries
    • Dislocated patella
    • Bony elements can fracture.
  • With ligament injuries you will generally find:
    • Swelling
    • Occasional ecchymosis
    • Point tenderness at the injury site
    • A joint effusion
  • Splint all suspected knee ligament injuries.

Dislocation of the Knee

  • These are true emergencies that may threaten the limb.
  • Ligaments may be damaged or torn.
  • Direction of dislocation refers to the position of the tibia with respect to the femur.
  • Posterior dislocations
  • Medial dislocations
  • Complications may include:
    • Limb-threatening popliteal artery disruption
    • Injuries to the nerves
    • Joint instability
  • If adequate distal pulses are present, splint the knee and transport promptly.

Fractures About the Knee

  • May occur at the distal end of the femur, at the proximal end of the tibia, or in the patella
  • If there is an adequate distal pulse and no significant deformity, splint the limb with the knee straight.
  • If there is an adequate pulse and significant deformity, splint the joint in the position of deformity.
  • If the pulse is absent below the level of injury, contact medical control.
  • Never use a traction splint.

Dislocation of the Patella

  • Most commonly occurs in teenagers and young adults in athletic activities
  • Usually, the dislocated patella displaces to the lateral side and produces significant deformity.
  • Splint the knee in the position in which you find it.

Injuries of the Tibia and Fibula

  • Fracture may occur at any place between the knee joint and the ankle joint.
  • Often, both bones fracture at the same time.
  • Stabilize with a padded, rigid long leg splint or an air splint.
  • Correct severe deformity with gentle longitudinal traction.

Ankle Injuries

  • The ankle is a commonly injured joint.
  • Range from a simple sprains to severe fracture-dislocations
  • Any ankle injury that produces pain, swelling, localized tenderness, or the inability to bear weight must be evaluated by a physician.
  • Management
    • Dress all open wounds.
    • Assess distal neurovascular function.
    • Correct any gross deformity by applying traction.
    • Before releasing traction, apply a splint.

Foot Injuries

  • Can result in the dislocation or fracture of one or more of the tarsals, metatarsals, or phalanges of the toes
  • Frequently, the force of injury is transmitted up the legs to the spine.
  • If you suspect a foot dislocation, assess for pulses and motor and sensory functions.
  • Associated with significant swelling but rarely with gross deformity
  • To splint the foot, apply a rigid padded board splint, an air splint, or a pillow splint.
  • Leave the toes exposed.

Strains and Sprains

  • General treatment is similar to that of fractures
  • RICES
    • Rest
    • Ice
    • Compression
    • Elevation
    • Splinting

Amputations

  • Surgeons can occasionally reattach amputated parts.
  • Make sure to immobilize the part with bulky compression dressings.
  • Do not sever any partial amputations.
  • Control any bleeding from the stump.
  • If bleeding is severe, quickly apply a tourniquet.
  • With a complete amputation, wrap the clean part in a sterile dressing, and place it in a plastic bag.
  • Follow local protocols regarding how to preserve amputated parts.
  • Put the bag in a cool container filled with ice.
  • The goal is to keep the part cool without allowing it to freeze or develop frostbite.

Compartment Syndrome

  • Most often occurs with a fractured tibia or forearm of children
  • Typically develops within 6 to 12 hours after injury, as a result of:
    • Excessive bleeding
    • A severely crushed extremity
    • The rapid return of blood to an ischemic limb
  • Characterized by:
    • Pain that is out of proportion to the injury
    • Pain on passive stretching of muscles within the compartment
    • Pallor
    • Decreased sensation
    • Decreased power
  • If you suspect the patient has compartment syndrome:
    • Splint the affected limb, keeping it at the level of the heart
    • Transport immediately.
    • Reassess neurovascular status frequently during transport.

Review Questions

  • Skeletal muscle is also referred to as striated muscle because of its characteristic stripes (striations), attaches to the bones and usually crosses at least one joint, forming the major muscle mass of the body. This type of muscle is also called voluntary muscle because it is under direct voluntary control of the brain.
  • A sprain is a joint injury in which there is both partial or temporary dislocation of the bone ends and partial stretching or tearing of the supporting ligaments. Sprains are typically marked by swelling, pain, and ecchymosis.
  • In order to assess sensory and motor functions (eg, Can you feel? Can you move?), the patient must be conscious, alert, and able to follow commands. False motion, distal pulses, and capillary refill are objective findings; therefore, they can be assessed in unresponsive patients.
  • The purpose of splinting a fracture is to prevent motion of the bony fragments, thus minimizing the possibility of neurovascular damage. Splinting is not intended to force bony fragments into anatomic alignment, nor will it reduce swelling (ice reduces swelling). You should never try to reduce a fracture.
  • In this particular case, it is more practical—and less time- consuming—to secure the patient to a long backboard. He is in shock and requires rapid transport. Taking the time to apply traction splints, air splints, or board splints will only delay transport.
  • The quickest and most effective way to immobilize a fractured clavicle (collarbone) is to apply a sling and swathe. The sling will help minimize movement of the clavicle itself, while the swath will minimize movement of the arm on the affected side.
  • When caring for a patient with an orthopaedic injury, you should first manually stabilize the injury site; this will prevent further injury. You should then assess pulse, motor functions, and sensory functions distal to the injury. Splint the injury using the appropriate technique, and then reassess pulse, motor functions, and sensory functions. Do not intentionally assess for crepitus; this is a coincidental finding that you may encounter during your assessment and should not be elicited.
  • Prior to splinting an open extremity fracture, you should cover the wound with a dry, sterile dressing. This will help control any bleeding and decreases the risk of infection. Irrigating an open fracture should be avoided in the field; this also increases the risk of infection—especially if foreign material is flushed into the wound.
  • The pelvic cavity can accommodate a large volume of blood. Shock in a patient with a pelvic injury is usually due to injury to femoral veins or arteries. Bilateral femur fractures can also cause severe blood loss (up to 1 liter per femur).
  • The patient likely has a dislocated knee. You should immobilize any joint injury in the position in which it was found—especially if distal pulses are present and strong. Attempting to straighten a dislocated joint may cause damage to the nerves and/or vasculature.