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PRINCIPLES OF FRACTURES Dr.David Samaroo MBBS,MS Department of Orthopedic Surgery Georgetown Public Hospital Corporation, University of Guyana School of Medicine. Mechanism of Injury Types of Trauma Mechanism of Injury Types of Force GENERAL CONSIDERATIONS IN MUSCULOSKELETAL TRAUMA Assessment & treatment,principles of splinting Signs of a Fracture……dislocations,sprains/strains Classification of fractures Imaging Nonunion Malunion Complications of fractures COST OF MUSCULOSKELETAL TRAUMA Trauma is the “neglected disease” Leading cause of death for people aged 1 to 44 yrs of all races & social levels More than 100,000 persons in USA die from accidents; 500,000 are permanently disabled Cost over $40 billion per year Generates over 3.5 million admissions to acute-care hospitals per year Local figures unavailable,you are the ones to make them available Mechanism of Injury Types of Trauma Penetrating Trauma Compression (Blunt) Trauma Bending Trauma Hyperflexion Hyperextension Mechanism of Injury Types of Trauma Penetrating Trauma Compression (Blunt) Trauma Bending Trauma Hyperflexion Hyperextension Severe Contusion of Foot Mechanism of Injury Types of Trauma Penetrating Trauma Compression (Blunt) Trauma Bending Trauma Hyperflexion Hyperextension Cervical (C5-C6) Fracture Dislocation Mechanism of Injury Types of Trauma Penetrating Trauma Compression (Blunt) Trauma Bending Trauma Hyperflexion Hyperextension Dorsal Dislocation, Long Finger Middle Joint (PIP Joint) Mechanism of Injury Types of Trauma Rotational Trauma Distraction Trauma Crush Trauma Deceleration Trauma Acceleration Trauma Normal Tibia Left Spiral Fracture Tibia Right Mechanism of Injury Types of Trauma Rotational Trauma Distraction Trauma Crush Trauma Deceleration Trauma Acceleration Trauma Brachial plexus injury/Dislocation of Right Shoulder Mechanism of Injury Types of Trauma Rotational Trauma Distraction Trauma Crush Trauma Deceleration Trauma Acceleration Trauma Crush Injury, Leg Mechanism of Injury Types of Trauma Rotational Trauma Distraction Trauma Crush Trauma Deceleration Trauma Acceleration Trauma Mechanism of Injury Types of Trauma Rotational Trauma Distraction Trauma Crush Trauma Deceleration Trauma Acceleration Trauma Car struck from behind “accelerates” passengers, producing an extension injury to the neck! Acceleration Trauma Mechanism of Injury Types of Force Mechanism of Injury Types of Force Direct Force Indirect Force Twisting Force High Energy Force Direct Mid-Shaft Fracture, Femur Mechanism of Injury Types of Force Direct Force Indirect Force Twisting Force High Energy Force Indirect Posterior Dislocation, Elbow Mechanism of Injury Types of Force Direct Force Indirect Force Twisting Force High Energy Force Twisting Subtalar Dislocation, Ankle Mechanism of Injury Types of Force Direct Force Indirect Force Twisting Force High Energy Force High Energy Fractured Pelvis GENERAL CONSIDERATIONS IN MUSCULOSKELETAL TRAUMA Assessment & treatment priorities are established according to type of injury, stability of vital signs, & mechanism of injury Assessment:1)Rapid primary evaluation 2)Restoration of vital function 3)Detailed secondary evaluation 4)Definitive care GENERAL CONSIDERATIONS IN MUSCULOSKELETAL TRAUMA ABCs of Trauma Care: Airway maintenance (with c spine control) Breathing and ventilation Circulation (with hemorrhage control) Disability (neurologic status) Exposure & environmental control (undress pt but prevent hypothermia) GENERAL CONSIDERATIONS IN MUSCULOSKELETAL TRAUMA Pre-Hospital Principles: Joints above & below fracture should be immobilized Splints can be improvised with pillows, blankets, or clothing Immobilization doesn’t need to be absolutely rigid Overt bleeding should be tamponaded with dressing & firm pressure Tourniquets should be avoided, unless it is obvious that pts life is in danger Injury Management Splinting Immobilizes the Injury Reduces Pain Prevents further damage to blood vessels, nerves and skin adjacent to the injury Decreases Bleeding Facilitates Transport Principles of Splinting Dress all wounds Immobilize the joints above and below a suspected fracture With injuries at or near joints, immobilize the bones above and below the injury Stabilize the injury site during splint application Principles of Splinting Use gentle in-line manual traction to realign displaced long bone fractures Expect to encounter increased pain and some resistance when attempting to realign a deformed limb Immobilize all suspected spinal injuries in a neutral in-line position on a spineboard Principles of Splinting If the patient demonstrates major signs of shock, align the limb as close to its normal anatomic alignment as possible on a spineboard (immobilization of total body), and provide rapid transport Total Body Immobilization When in doubt: SPLINT! Rigid Splints Quick Splint Cardboard Splint Ladder Splint SAM Splint Soft Splints Air Splint Sling and Swathe Vacuum Splint Blanket Roll Traction Splint When standard splints are unavailable, improvisation is better than doing nothing! UPPER EXTREMITY All fractures can be immobilized by securing the extremity to the chest! LOWER EXTREMITY All fractures can be immobilized by securing the injured extremity to the opposite lower extremity! GENERAL CONSIDERATIONS IN MUSCULOSKELETAL TRAUMA ORTHOPEDIC EXAM Assess axial skeleton, pelvis, & extremities Depends on overall central neurologic status Assess for swelling, hematomas, open wounds Palpate entire spine, pelvis, & each joint Exam pelvis by compression of iliac wings in mediolateral direction & pubis Must document neurologic status to fullest extent possible, motor & sensory, all major nerves & dermatomes inupper & lower extremities Must document all reflexes Signs of a Fracture Tenderness Swelling and Ecchymosis Deformity Crepitus Exposed Fragments False Motion Inability to Use the Limb Seven Signs of Fracture Tenderness Swelling and Ecchymosis Deformity Crepitus Exposed Fragments False Motion Inability to Use the Limb Fractured Patella Seven Signs of Fracture Tenderness Swelling and Ecchymosis Deformity Crepitus Exposed Fragments False Motion Inability to Use the Limb Angulated Fracture, Radius and Ulna Seven Signs of Fracture Tenderness Swelling and Ecchymosis Deformity Crepitus Exposed Fragments False Motion Inability to Use the Limb Crepitus In a complete fracture, the sounds of bone ends clicking or rubbing against each other; denotes an unstable fracture! Seven Signs of Fracture Tenderness Swelling and Ecchymosis Deformity Crepitus Exposed Fragments False Motion Inability to Use the Limb Open Ankle Fracture Seven Signs of Fracture Tenderness Swelling and Ecchymosis Deformity Crepitus Exposed Fragments False Motion Inability to Use the Limb False Motion The unusual visual sensation of observing motion at a long bone fracture site where “there is no joint!” Seven Signs of Fracture Tenderness Swelling and Ecchymosis Deformity Crepitus Exposed Fragments False Motion Inability to Use the Limb Fracture, Right Clavicle Right Arm Protected Seven Signs of Fracture The presence of any one of the seven fracture signs just listed is sufficient to assess this injury! Types of Injury Dislocation Disruption of a joint such that the bone ends are no longer in contact Must have torn ligaments and joint capsule Signs of Dislocation Tenderness Deformity (usually marked) Swelling and Ecchymosis Loss of normal joint motion Common Dislocations Shoulder Finger Hip Elbow Anterior Dislocation, Right Shoulder Common Dislocations Shoulder Finger Hip Elbow Dislocation, Middle Joint (PIP Joint), Ring Finger Common Dislocations Shoulder Finger Hip Elbow Posterior Hip Dislocation Common Dislocations Shoulder Finger Hip Elbow Posterior Elbow Dislocation Types of Injury Fracture-Dislocation A combined injury with joint dislocation and an adjacent bone fracture Fracture–Dislocation, Ankle Types of Injury Sprain Partial or complete temporary joint dislocation Ligaments are torn partially or completely May produce as much structural damage as a dislocation Sprain, Left Ankle Types of Injury Strain “Muscle Pull” Stretching or tearing of muscle, or muscle fascia (covering) Occurs frequently in the lower back secondary to poor posture and poor abdominal muscle control Types of Injury Fracture • • Any break in the continuity of a bone May vary from a simple crack to a completely shattered bone FRACTURE CLASSIFICATION Location of bone -Epiphyseal -Metaphyseal -Diaphseal Integrity of skin & soft tissue envelope -Open vs. Closed Amount of displacement Nondisplaced Displaced Incomplete/Complete Angulated Distracted FRACTURE CLASSIFICATION Orientation/Extension of Fracture Line -Transverse -Torus -Comminuted -Greenstick -Oblique -Impaction -Segmental -Compression -Spiral -Depression -Intra-articular -Stress (Fatigue) -Pathologic -Linear Closed Fracture, Base of Thumb Closed Dorsally Angulated Forearm Fracture Open Fracture, Tibia Open Fracture, Forearm Open Fractures Are More Serious! Blood Potential loss contamination with risk of infection Fracture Classification Closed/Open Incomplete/Complete Displaced/Displaced Incomplete Fracture, Distal Radius Complete Fracture, Femur Fracture Classification Closed/Open Incomplete/Complete Non-Displaced/Displaced Non-Displaced Fracture, Distal Tibia and Fibula Displaced/Angulated Forearm Fractures Types of Fracture Comminuted – fractured into more than two segments Pathologic – fracture through diseased bone Epiphyseal – fracture passes through the growth plate Comminuted Femur Fracture Types of Fracture Comminuted – fractured into more than two segments Pathologic – fracture through diseased bone Epiphyseal – fracture passes through the growth plate Pathologic Lytic lesion (darker = tumor) in proximal phalanx of finger, with associated transverse fracture Other Types of Fracture Comminuted – fractured into many pieces Pathologic – fracture through diseased bone Epiphyseal – fracture through the growth plate Epiphyseal (growth-line) Fracture, Distal Femur GENERAL CONSIDERATIONS IN MUSCULOSKELETAL TRAUMA CONFIGURATION OF FRACTURES: Intra-articular (fx line crosses articular cartilage & involves joint) Displaced (expressed in mm or cm or % in direction of displacement of distal fragment) Nondisplaced Angulated (expressed in degrees in direction of apex) Comminuted (more than 1 piece at one fx location) GENERAL CONSIDERATIONS IN MUSCULOSKELETAL TRAUMA IMAGING STUDIES: Polytrauma pts: c-spine, chest, pelvis Long bone fx requires complete evaluation of joint proximally & distally to fx Long bone x-rays, minimum of 2 views AP & Lateral CT scans visualize complex fx patterns esp with joint involvement MRI scans give soft tissue details Bone scan: indicative of blood flow & therefore of bone formation or destruction GENERAL CONSIDERATIONS IN MUSCULOSKELETAL TRAUMA “Clearing” the Cervical Spine: X-ray: A-P views, Lateral views, Open mouth odontoid view Open mouth: lateral masses of C1 should line up with body of C2 Must see down to C7, if can’t then Swimmer’s view, lateral cervical spine x-ray with arm abducted & elevated May need flex/ext views to determine ligamentous stability GENERAL CONSIDERATIONS IN MUSCULOSKELETAL TRAUMA “Clearing” the Cervical Spine: Amount of total overhang of C1 over C2 should be less than 3 mm Lateral view, anterior border of bodies of cervical segments should describe an arc No diastasis of spinous processes Joints & facet joints should all be visible Watch orientation from one cervical spine level to another, r/o cervical fx, jumped facets, or dislocations GENERAL CONSIDERATIONS IN MUSCULOSKELETAL TRAUMA NONUNION: Nonunion: fx that fails to show progressive healing ,there are permanent radiologic signs the situation is permanent CLASSIFICATION OF NONUNIONS: Hypertrophic: “elephant’s foot ”, “horse’s foot ” flared out with viable bone ends,fracture visible ,fracture filled with cartilage and fiberous tissue Atrophic: nonviable bone ends,rounded,osteoporotic If left untreated, may develop into pseudoarthrosis (false joint) Causes of non union General Specific Diastasis of fx fragment Compromise blood supply Excessive motion Infection GENERAL CONSIDERATIONS IN MUSCULOSKELETAL TRAUMA CAUSES OF NONUNION: 1) General: age, nutrition, steroids, anticoagulants, radiation, burns, immunosupression -predisposure to nonunion 2)Diastasis of fx fragment a. Soft tissue interposition b. Distraction from traction or internal fixation c. Malposition d. Loss of bone GENERAL CONSIDERATIONS IN MUSCULOSKELETAL TRAUMA CAUSES OF NONUNION: 3)Compromised blood supply a. Damage to nutrient vessels b. Stripping or injury to periosteum & muscle c. Free fragments; severe comminution d. Avascularity due to internal fixation devices GENERAL CONSIDERATIONS IN MUSCULOSKELETAL TRAUMA CAUSES OF NONUNIONS: 4) Excessive motion: inadequate immobilization 5) Infection a) Bone death (sequestrum) b) Osteolysis (Gap) c) Loosening of implants (motion) GENERAL CONSIDERATIONS IN MUSCULOSKELETAL TRAUMA NONUNION OF FRACTURES: Delayed union: fx that has not gone on to full bony healing after 6 months Areas prone to nonunion: Distal tibial diaphysis Proximal diaphysis of 5th metatarsal Segmental fx Transcervical hip fx,scaphoid,talus GENERAL CONSIDERATIONS IN MUSCULOSKELETAL TRAUMA TREATMENT OF NONUNIONS: Correction of cause, if possible Stabilization of bone ends Eradication of infection Restoration of blood supply Surgical excision of interposing tissues Bone graft of fracture gaps at time of internal fixation GENERAL CONSIDERATIONS IN MUSCULOSKELETAL TRAUMA MALUNION OF FRACTURE: Fx that has healed with unacceptable amt of angulation, rotation,or overriding Shortening is better tolerated in upper ext than lower ext Angular deformity better tolerated in humerus than femur or tibia Shortening more than 1 inch is poorly tolerated in lower extremity GENERAL CONSIDERATIONS IN MUSCULOSKELETAL TRAUMA COMPLICATIONS: Compartment Syndrome Acute Respiratory Distress Syndrome (Fat Embolism Syndrome) Thromboembolic Disease Atelectasis Ectopic (Heterotopic) Bone Formation GENERAL CONSIDERATIONS IN MUSCULOSKELETAL TRAUMA COMPARTMENT SYNDROME: Pathologic developments in a closed space in body caused by buildup of pressure Pressure rises from edema or bleeding within compartment, compromising circulation to compartment, can result in necrosis of muscle & nerve damage Causes: Fracture, soft-tissue injury, arterial injury, burn, abnl external compression from immobilization GENERAL CONSIDERATIONS IN MUSCULOSKELETAL TRAUMA COMPARTMENT SYNDROME: Characteristics: Pain Pulselessness Pallor Paresthesias Paralysis -Pulses generally remain intact until late -Paresthesias occur only when significantly advanced -Paresis, if present, is an unreliable finding -Pain with passive stretching is subjective GENERAL CONSIDERATIONS IN MUSCULOSKELETAL TRAUMA COMPARTMENT SYNDROME Pressure is key component Palpation of soft compartment doesn’t rule out compartment syndrome Intracompartmental pressure readings greater than 30-40 mmHg are indications for fasciotomy Late fasciotomy may result in muscle damage or possible necrosis with resulting infection GENERAL CONSIDERATIONS IN MUSCULOSKELETAL TRAUMA COMPARTMENT SYNDROME: Forearm: Extensile volar incision to permit complete release, including carpal tunnel distally & lacertus fibrosis proximally; Dorsally, a longitudinal incision is used Calf: Two incisions are used to release the four compartments of leg Longitudinal incision over anterior intermuscular septum for anterior & lateral compartments Posteromedially, second incision for superficial & deep posterior compartments GENERAL CONSIDERATIONS IN MUSCULOSKELETAL TRAUMA Fat Embolism Syndrome: Special ortho manifestation of ARDS Caused by release of marrow content into circulation e.g. s/p fracture Lungs show fat droplets, usually diffusely distributed throughout pulmonary vasculature Can occur when medullary canal of a long bone is pressurized during IM alignment jigs of TKA Dx: Decrease in arterial Po2, Increase systemic Pco2, infiltrates on chest X-ray, presence of petechiae, & mental confusion Rx: Minimize hypoxemia with ventilatory support GENERAL CONSIDERATIONS IN MUSCULOSKELETAL TRAUMA HETEROTOPIC BONE FORMATION Occurs in 10% of trauma cases May cause pain or joint motion restriction or ankylosis Without head trauma can be seen on x-ray 1-2 months after trauma Much more common in head injury pts, release of humeral modulators Resection may be indicated by 6 months if NL alkaline phosphatase & mature x-ray appearance May benefit from low dose radiation (7Gy) & indomethacin for 3-6 weeks