A&P Lesson 10-11
Suture
-bones interlocked -are bound by dense fibrous connective tissue -are found ONLY in skull
Saddle joint
have complex articular faces and fit together like a rider in a saddle. Each face in concave along one axis and convex along the other. movement- angular, biaxial examples- First carpometacarpal joint
Ball-and-socket joint
in a ball-and-socket joint, the round head of one bone rests within a cup-shaped depression in another movement- angular circumduction, and rotation, triaxial examples- Shoulder joint and hip joint
Most common Knee Injury
lateral surface of leg struck pushing it medially (tears medial meniscus) -May lead to chronic problems, development of "trick knee" - feeling of knee being unstable
The Knee Joint
-A complicated hinge joint -Transfers weight from femur to tibia
The elbow joint
-A stable hinge joint -With articulations involving humerus, radius, and ulna
Synarthroses (Immovable joints)
- are very strong - edges of bones may touch or interlock -four types of synarthrotic joints: 1) Suture 2) Gomphosis 3) Synchondrosis 4) Synostosis
Processes of the Shoulder Joint
-Acromion (clavicle) and coracoid process (scapula) -Project laterally, superior to the humerus -Help stabilize the joint
Fat Pads
-Adipose tissue superficial to the joint capsule -protect articular cartilages
The Hip Joint
-Also called COXAL joint -Strong ball-and-socket diarthrosis -Wide range of motion
Intervertebral ligaments
-Bind vertebrae together -Stabilize the vertebral column
Bone and Aging
-Bone mass decreases -Bones weaken -Increases risk of hip fracture, hip dislocation, or pelvic fracture
Disorders in other body systems can cause:
-Bone tumors -Osteoporosis -Arthritis -Rickets (vitamin D deficiency)
intervertebral joints
-C2 to L5 spinal vertebrae articulate: -At inferior and superior articular processes (gliding joints) -Between adjacent vertebral bodies (symphyseal joints); adjacent vertebral bodies separated by fibrocartilage intervertebral discs; little gliding occurs here.
injuries (regarding synovial joints)
-DISLOCATION (luxation) - caused by extreme stress on joint -articulating surfaces forced out of position -damages articular cartilage, ligaments, joint capsule -Shoulder joint most prone to this injury SUBLUXATION -a partial dislocation note: "double jointed" people have weakly stabilized joints that are prone to dislocation or partial dislocation
rotation of synovial joints
-Direction of rotation from anatomical position -relative to longitudinal axis of body -LEFT and RIGHT rotation -MEDIAL rotation (inward rotation); rotates toward axis; ex. bend arm at elbow, move hand to chest -LATERAL rotation (outward rotation); rotates away from axis; ex. bent arm at elbow, move hand away from chest -PRONATION; rotates forearm, radius over ulna -SUPINATION; forearm in anatomical position note: pronation and supination are not the same as medial rotation and lateral rotation, respectively
Gomphosis
-Fibrous connection (periodontal ligament) -Binds teeth to sockets
Structures of the Hip Joint
-Head of femur fits into sockets of acetabulum of coxal bone Which is extended by fibrocartilaginous acetabular labrum - increases joint cavity depth and helps seal in synovial fluid -Hip fractures of femoral neck or between trochanters more common than dislocations
Articulations of the elbow
-Humeroulnar joint- Strongest and largest joint at elbow; Trochlea of humerus and trochlear notch of ulna; Limited movement -Humeroradial joint- Smaller joint; Capitulum of humerus and head of radius
Synchondrosis
-Is a rigid cartilaginous bridge between two bones: -Epiphyseal cartilage of long bones -Between vertebrosternal ribs and sternum
Arthritis
-Joint inflammation -all forms of rheumatism that damage articular cartilages of synovial joints -can be caused by bacterial/viral infection, injury, physical stress, metabolic problems
Planes (Axes) of Dynamic Motion
-Monaxial (1 axis)- ex. forward/backwards -Biaxial (2 axes)- ex. forward/backwards, & side to side -Triaxial (3 axes)- ex. forward/backwards, side to side, & angular
Amphiarthroses
-More movable than synarthrosis -Stronger than freely movable joint (diarthrosis) Two types of amphiarthroses: 1) Syndesmosis- bones connected by ligaments (ex. distal end of tibia and fibula) 2) Symphysis- Bones separated by fibrocartilage (ex. Pubic symphysis connects left and right coxyl bones)
Factors that stabilize synovial joints
-Prevent injury by limiting range of motion 1) Collagen fibers (joint capsule, ligaments) 2) Shape of articulating surfaces and menisci 3) Presence of other bones, muscles, or fat pads 4) Tension in the tendons of articulating bones Note: pain receptors ARE NOT found on the inside of synovial joints. Pain felt due to joint damage results from nerve that monitor the capsule, ligaments, and tendons.
joint immobilization
-Reduces flow of synovial fluid -Can cause arthritis symptoms -Treated by continuous passive motion or CPM (therapy)
Bursae
-Singular, bursa, a pouch -Pockets of synovial fluid, lined by synovial membrane -Cushion areas where tendons or ligaments rub BURSITIS- inflamed bursae causing pain. -can result from repetitive motion, irritation, trauma, or infection (ex. bunions)
Bone Support Body Systems
-Support and protect other systems -Store fat, calcium, and phosphorus -Manufacture cells for immune system
Articulations of the Knee Joint
-Two femur-tibia articulations At medial and lateral condyles -One between patella and patellar surface of femur
Joints
-a joint cannot be both mobile and strong (or rolled) -The greater the mobility, the weaker the joint -Mobile joints are supported by muscles and ligaments, not bone-to-bone connections
synovial joints (diarthroses)
-also called movable joints -at ends of long bones -within articular capsules -lined with synovial membrane
Tendons
-attach to muscles around joint -Help support joint
synovial fluid
-contains slippery proteoglycans secreted by fibroblasts -resembles interstitial fluid, not much in joint (ex. knee joint only has up to 3 mL of fluid)
Cartilages (in the joints)
-cushion the joint -fibrocartilage pad called a MENISCUS (or articualr disc; plural, menisci), located between opposing bones in synovial joint
Synostosis
-fused bones, immovable -metopic suture of skull (fuses two sides of frontal bone) -epiphyseal lines of long bones
Special Movements at Synovial Joints
-include specific articulations or unusual types of movements 1) Inversion- twists sole of foot medially 2) Eversion- twists sole of foot laterally 3) Dorsiflexion- flexion at ankle (lifting toes) 4) Plantar flexion- extension at ankle (pointing toes) 5) Opposition- Thumb movement toward fingers or palm (grasping) 6)Reposition- opposite of opposition 7)Protraction- moves anteriorly; in the horizontal plane (pushing forward) 8) Retraction- opposite of protraction, moving posteriorly (pulling back) 9) Elevation- moves in superior direction (up) 10) Depression- moves in inferior direction (down) 11) Lateral flexion- bends vertebral column from side to side.
articualr cartilages
-pad articulating surfaces within articular capsules; prevents bones from touching -Smooth surfaces lubricated by synovial fluid -has consistency of heavy molasses -functions to reduce friction
Intervertebral Discs
-pads of fibrocartilage -separate vertebral bodies -Consists of: 1)ANULUS FIBROSUS- tough outer layer; attaches disc to vertebrae through collagen fibers 2)NUCLEUS PULPOSUS- Elastic, gelatinous core;absorbs shocks, gives disc resiliency Note: discs account for almost 1/4 length of vertebral column superior to sacrum. As we age, discs lose water content- less cushioning and also shortens our height
gliding movement of synovial joints
-two surfaces slide past each other ex) between carpal or tarsal bones, clavicle and sternum
angular movements of synovial joints
1) Flexion- angular motion in the anterior-posterior plane, REDUCES angle between elements 2) Extension- angular motion in the anterior-posterior plane; INCREASES angle between elements 3) Hyperextension- angular motion; extension past anatomical position ex) extension of neck when you tilt your head back & look up at the ceiling, extend your leg behind you, or flick your wrist. 4) Abduction- angular motion in the frontal plane; moves away from longitudinal axis 5) Adduction- angular motion in the frontal plane; moves toward longitudinal axis 6) Circumduction- angular motion in a circular motion without rotation
Seven Major Supporting Ligaments (of the knee joint)
1) Patellar ligament (anterior)- attaches to tibia 2&3) Two popliteal ligaments (posterior) 4&5) Anterior and Posterior Cruciate ligaments (ACL/PCL) (inside joint capsule) 6) Tibial collateral ligament (medial) 7) Fibular collateral ligament (lateral)
Structural Classifications of joints
1) bony joint - synotoses (synarthroses); joined by bone 2) fibrous joint - sutures and gomphoses (synarthroses); syndesmoses (amphiarthroses); joined by collagen fibers 3) cartilaginous joint - synchondroses (synarthroses) and symphyses (amphiarthroses) joined by cartilage 4) synovial joint - (only diarthroses) joined by thin fluid-filled space
Factors Affecting Bone Strength
1. Age 2. Physical stress 3. Hormone levels 4. Calcium and phosphorus uptake and excretion 5. Genetic and environmental factors
Classification of joints
1. Functional classification is based on range of motion of the joint 2. Structural classification relies on the anatomical organization of the joint Note: Be careful distinguishing the difference between Function and Structural classifications
What are the THREE types of dynamic motion?
1. Linear movement (gliding) 2. Angular movement 3. Rotation
Functional classifications of joints
1. Synarthrosis (immovable joint) 2. Amphiarthrosis (slightly movable joint) 3. Diarthrosis (freely movable joint)
functions of synovial fluid
1. lubrication- articular cartilage act as sponge filled with fluid. Compression of it pushes some fluid out 2. nutrient distribution- fluid circulates as joint moves, provides nutrients to chondrocytes in area 3. shock absorption- viscosity of fluid increases with increases pressure
Vertebral Joints
AKA symphyseal joints -as vertebral column moves: 1)NUCLEUS PULPOSUS shifts 2)Disc shape conforms to motion
Rheumatoid Arthritis
An inflammatory condition Caused by infection, allergy, or autoimmune disease Involves the immune system- body attacks its own tissue (the joints)
The Articular Capsule and Joint Cavity (knee joint)
Has fibrocartilage pads (medial and lateral menisci): -Located at femur-tibia articulations -Cushion and stabilize joint -Give lateral support
Bone recycling
Living bones maintain equilibrium between: -Bone building (osteoblasts) -And breakdown (osteoclasts) *refer to previous lesson on osseous tissue
Shoulder Muscles (Rotator Cuff)
Primary mechanism for supporting shoulder joint and limiting ROM. -Supraspinatus -Infraspinatus -Subscapularis -Teres minor 5 ligaments support the shoulder joint
Degenerative changes (effects of aging on joints)
Rheumatism and Arthritis
Damage to Intervertebral Discs
Slipped Disc: -Bulge in anulus fibrosus (vertebral foramen) -Invades vertebral canal -caused by weakened posterior longitudinal ligaments of the vertebrae Herniated Disc: -Nucleus pulposus breaks through anulus fibrosus -Presses on spinal cord or nerves
Types of Movement at Synovial Joints
Terms describe: -Plane or direction of motion -Relationship between structures
Rheumatism
a pain and stiffness of skeletal and muscular systems
The Shoulder Joint
aka GLENOHUMERAL JOINT -Ball-and-socket diarthrosis; between head of humerus and glenoid cavity of scapula -Allows more motion than any other joint (is less stable) -Supported by skeletal muscles, tendons, ligaments; most support provided by skeletal muscles of the rotator cuff, some support by tendons and ligaments; damage to musces common in sports that strain the shoulder (baseball/softball pitchers, quarterbacks)
osteoarthritis
aka degenerative arthritis/ degenerative joint disease (DJD) -caused by wear and tear of joint surfaces, or genetic factors affecting collagen formation -generally in people over the age of 60- 25% women, 15% men
Plane Joint
aka gliding joints, have flattened or slightly curved surfaces that slide across one another, but the amount of movement is very slight. movement- Gliding, slight, nonaxial. examples- Acromioclavicular and claviculosternal joints; intercerpal joints; vertebrocostal joints; sacro-iliac joints
Articulation
body movement occurs at joints (articulations) where two bones connect
what are the five accessory structures?
cartilage, fat pads, ligaments, tendons, bursae
Ligaments
continuous with periostea of articulating bones (no direct blood supply) -support, strengthen joints -SPRAIN- ligaments with torn collagen fibers
gouty arthritis
crystal arthritis -Occurs when crystals (uric acid or calcium salts) form within synovial fluid -Due to metabolic disorders
joint structure
determines direction and distance of movement (ROM) Joint strength decreases as mobility increases Stronger joints=less mobile
Hinge Joints
permit angular motion in a single plane, like the opening and closing of a door movement- angular, monaxial examples- Elbow joint; Knee joint; Ankle joint; Interphalangeal joint
Pivot joint
pivots joints only permit rotation movement- rotation, monaxial examples- Atlanto-axial joint; Proximal radio-ulnar joint
shoulder separation vs dislocation
shoulder separation can result from hit to superior surface of shoulder (forcing acromion downward) Shoulder separation= dislocation of the shoulder joint (at acromion of scapula and clavicle - at the acromioclavicular joint) -Relatively common Note: dislocation shoulder is different from shoulder separation. Dislocated shoulder= dislocation at glenohumeral joint between the humerus and glenoid cavity.
Condylar joint
{AKA ellipsoidal joint} oval shaped condyle of one bone fits into elliptical cavity (depression) of other bone; back and forth motion, but not rotation movement- angular, biaxial Ex: metacarpophalangeal joints 2-5; Radiocarpal joint; Metatarsophalangeal joints.