kin 188 mechanisms and types of injuries

1. KIN 188 Prevention and Care of Athletic Injuries Mechanisms and Types of Injuries Terminology

Injury mechanisms

Soft tissue injuries

Bone injuries

Nerve injuries

Force and its effects

Torque and its effects

Force is a push or pull acting on the body

There are 2 potential effects of force application

Acceleration or change in velocity

Deformation or change in shape

Greater stiffness of material = less likelihood that deformation will be seen

Greater elasticity of material = more likelihood that deformation will be temporary

When tissues exposed to force, 2 factors determine whether or not injury will occur

Size or magnitude of force

Material properties of involved tissues

Load deformation curve

With small loads, response of tissue is elastic

When load removed, material returns to normal shape and size

Within elastic region, greater material stiffness leads to a steeper slope of the line

With higher loads (exceeding yield point of material), response is plastic

When load removed, some amount of deformation will remain

Loads exceeding ultimate failure point of material result in mechanical failure of the tissue

Direction of force application also has injury implication potential

Many tissues are anisotropic better able to resist force from certain directions that others

Force acting along long axis of structure is axial force

Axial loading producing a crushing/squeezing effect is called compressive force

Axial loading opposite compressive forces is called tensile force

Force acting parallel to plane passing through structure is shear force

Stress

Magnitude of stress produced by force application also factors into injury mechanism

Stress is force divided by surface area over which the force is applied

When given force distributed over large area, resulting stress is less than if force were concentrated over smaller area and vice versa

High magnitude of stress, rather than high magnitude of force, tends to result in injury to tissue

Strain

Amount of deformation a structure undergoes in response to an applied force

Compressive forces produce shortening and widening of structure

Tensile forces produce lengthening and narrowing of structure

Shear forces result in internal changes in structure

Ultimate strength of tissues determines amount of strain a structure can withstand before being injured

Generically thought of as a rotary force

Excessive torque in the body can produce injury

Simultaneous application of forces from opposite directions at different points along a structure generates torque known as bending moment compression on one side and tension on the other

Application of torque about the long axis of a structure causes torsion (twisting) which results in shear forces throughout the structure

Skin injuries

Contusions

Strains

Sprains

Cramps/spasms

Myositis/fasciitis

Tendinitis and tenosynovitis

Myositis ossificans

Bursitis

Abrasions

Shear injuries occurring when skin scraped, usually in one direction, against a rough surface

Blisters

Caused by repeated applications of shear forces in one or more directions with formation of fluid pocket between dermis and epidermis

Incisions

Clean cut produced by application of tensile force to skin as its stretched along a sharp edge

Lacerations

Irregular tear in skin typically resulting from a combination of tension and shear forces

Avulsions

Severe laceration resulting in complete separation of skin from underlying tissue

Punctures

Results when sharp, cylindrical object penetrates the skin with tensile loading

Commonly referred to as bruises

Result from direct compressive forces

Severity based upon area and depth over which blood vessels are ruptured

Mild little or no ROM restriction

Moderate noticeable reduction in ROM

Severe may rupture associated fascia causing muscle tissue to protrude from injured area

Ecchymosis - discoloration

Hematoma hard mass composed of blood and dead tissue at site of trauma

Strains occur to muscles and tendons

Sprains occur to ligaments and joint capsules

Typically occur from application of abnormally high tensile forces that damages the tissue

Most susceptible area of muscle/tendon injury is at/near musculotendinous junction

Most susceptible area of ligament/joint capsule is mid-substance (strongest near bony attachments)

Strains and sprains categorized as first, second or third degree injuries

First degree (mild)

Microtrauma with minimal associated symptoms

Second degree (moderate)

Partial tearing of tissue, detectable weakness and joint instability

Third degree (severe)

Complete rupture of tissue, loss of ROM and joint stability

Painful, involuntary muscle contractions

Cramps appear to be brought on by biochemical imbalance and/or muscle fatigue

Spasms can be caused by biochemical action or secondary to trauma (natural splinting mechanism)

Inflammation of muscle connective tissue (myositis) or inflammation of sheaths of fascia surrounding portions of muscle (fasciitis)

Develop over time from repeated stresses that irritate those tissues

Tendinitis

Inflammation of tendon itself little blood supply

Associated with degenerative changes in tendon (tendinosis)

Tenosynovitis

Inflammation of tendon sheath highly vascular

If acute, often accompanied by crepitus and swelling

If chronic, of presents with nodule formation in sheath

Typically classified in four stages

Stage 1: pain after activity only

Stage 2: pain during activity, does not restrict performance

Stage 3: pain during activity, restricts performance

Stage 4: chronic, unremitting pain, even at rest

Accumulation of mineral deposits in muscle (ectopic calcification) secondary to prolonged chronic inflammation

If occurs in tendons, referred to as calcific tendinitis

Common site is quadriceps muscle group secondary to moderate or severe contusion

Hardened mass often palpable and can be visualized on x-ray after ~3 weeks

Irritation of fluid-filled sacs that serve to reduce friction in the tissues surrounding joints

May be associated with single traumatic event or secondary to repeated applications of stress with overuse conditions

Common to olecranon area (elbow) and pre-patellar area (knee)

Fracture disruption in continuity of a bone

Type of fracture depends upon type of mechanical loading that caused it as well as on health of bone at the time of injury

Closed fracture bone ends remain intact within surrounding soft tissue

Open/compound fracture one or both bone ends protrudes from the skin

Depressed

Broken bone portion driven inward most common on flat bones of skull

Transverse

Break in straight line across axis of bone

Comminuted

Bone fragments into several pieces

Oblique

Break diagonally across axis of bone

Spiral

S-shaped fracture from torsion forces

Greenstick

Incomplete fractures children (like green stick)

Avulsion

Bone fragment pulled off by attached ligament or tendon

Impacted

Bone driven into another bone causing injury

Stress fractures (aka fatigue fractures)

From repeated low-magnitude forces (overuse injury)

Worsen over time if untreated

Begin as small disruption in continuity of outer layer of bone and can progress to through fracture with or without displacement

Most common in metatarsals, tibia, femoral neck, pubis bone, pars interarticularis of spine segments

Epiphyseal injuries (Salter classifications)

Type I: complete separation of epiphysis from metaphysis with no fracture to bone

Type II: separation of epiphysis and a small portion of the metaphysis

Type III: fracture of the epiphysis

Type IV: fracture of a part of the epiphysis and metaphysis

Type V: compression of the epiphysis without fracture resulting in compromised epiphyseal function

Tension vs. compression

Tensile injury grades

Compression considerations

Symptoms of nerve injuries

Tensile nerve injuries typically associated with high-speed impacts/collisions in contact sports

Nerve roots particularly susceptible to tensile forces cervical spine/brachial plexus stingers

Compressive forces pinch on nerves

Direct mechanical force on nerve tissue

Indirect pressure from swelling in associated area

Grade I neuropraxia

Temporary loss of sensation/motor function without axon disruption

Typically resolves in a few days to a few weeks

Grade II axonotmesis

Significant motor and mild sensory function loss from axon disruption

Typically lasts at least a couple of weeks

Grade III neurotmesis

Complete rupture of nerve tissue with associated motor and sensory deficits that are typically permanent

Severity of nerve compression injury dependent upon magnitude and duration of loading and on whether the applied compression is direct or indirect

Nerve function highly dependent upon oxygen, so associated vascular injury caused by compressive injury results in further damage to the nerve

Hypoesthesia

Altered sensation of nerve

Hyperesthesia

Heightened sensitivity of nerve

Paresthesia

Numbness, prickling, tingling sensations

Neuralgia

Chronic pain along nerve distribution/path secondary to irritation and/or inflammation

Sagittal

Separates into left and right segments

Frontal/coronal

Separates into anterior and posterior segments

Transverse

Separates into superior and inferior segments

Anterior toward front of body

Posterior toward back/rear of body

Superior (cephal) toward head

Inferior (caudal) toward tail

Proximal closer to trunk

Distal further from trunk

Medial toward midline of body

Lateral away from midline of body

Abduction movement away from midline

Adduction movement toward midline

Pronation foot: lowering medial arch, hand: turning palm down

Supination foot: raising medial arch, hand: turning palm up

Flexion to bend (joint angle increases)

Extension to extend (joint angle decreases)

Internal rotation rotary movement toward midline

External rotation rotary movement away from midline

Varus distal segment of body part toward midline

Valgus distal segment of body part away from midline

kin 188 mechanisms and types of injuries

Business

tensile injury

soft tissue

injury mechanisms

shear forces

nerve injuries

bone injuries

load removed

axon disruption