Human Anatomy & Physiology I PDF

Summary

These lecture notes cover human anatomy and physiology, focusing on joints. They detail different types of joints, their classifications, stability factors, and the movements they allow. The lecture notes also include sample questions.

Full Transcript

BIOL243 – HUMAN ANATOMY &
PHYSIOLOGY I
Charles Smith, PhD CSCS
HUMAN ANATOMY & PHYSIOLOGY
Ch. 8 – Joints & Articulations
JOINT CLASSIFICATION
Classified based on Structure and Function
Like anything else in anatomy…
Structural Classifications: Functional Classifications:
What binds the joint together? Is a How much movement is allowed?
joint cavity present?
Synarthroses = immovable
Fibrous
Amphiarthroses = slightly movable
Cartilaginous
Diarthroses = freely movable
Synovial
Note: synarthroses & amphiarthroses mostly
Only one with joint cavity found in axial skeleton; most appendicular joints
are diarthroses
FIBROUS & CARTILAGINOUS JOINTS
Fibrous Joints: joined by dense, fibrous connective tissue
3 Types:
Sutures: “seams”, seen only in bones of skull
Synarthrotic (immovable) joints for protection of brain
Syndesmoses: connected by ligaments & fibrous tissues (i.e., b/w tibia & fibula OR radius & ulna)
Can be amphiarthrotic (slightly movable) depending on ligament length
Gomphoses: “peg-in-socket”; only seen for teeth

Cartilaginous Joints: bones united by cartilage
2 Types:
Synchondroses: plate of hyaline cartilage connects bones
i.e., synarthrotic epiphyseal plate connecting bone shaft to ends
Symphyses: fibrocartilage in joint; strong
Often act as shock absorber & permit limited movement (amphiarthrotic)
i.e., intervertebral joints & pubic symphysis (between ischium)
SYNOVIAL JOINTS
Bones separated by fluid-filled joint cavity
6 General Features:
Articular cartilage: hyaline cartilage covering ends of bones
Joint (Synovial) Cavity: fluid-filled space separating articulating
bones
Articular (Joint) Capsule: two-layers thick (fibrous layer &
synovial membrane)
Synovial Fluid: viscous, plasma filtrate with hyaluronic acid
lubricating & nourishing articular cartilage
Reinforcing Ligaments: provide stability
Nerves & Blood Vessels: detect pain, monitor stretch; supply
filtrate for synovial fluid
May also contain:
Articular Discs (menisci & labra) : fibrocartilage separating &
improving “fit” of articulating bone surfaces; stabilize joint;
mitigate wear & tear; shock absorption
Bursae: bags of synovial fluid surrounding joint; reduce friction
between ligaments, muscles, skin, tendons, or bone
HOW STABLE ARE SYNOVIAL JOINTS?
3 Factors:
1. Shape of Articular Surface (minor)
Shallow contact surface = less stable; deeper surface = more stable
Shallow surface less stable than ball-and-socket
Better fit = more stable
2. Number and Location of Ligaments (limited)
More ligaments = stronger joint
3. Muscle Tone as they cross Joint (MAJOR)
Keep tendons taut
Extremely important for stability of shoulder, knee, and foot arches
 MOVEMENTS ALLOWED BY SYNOVIAL JOINTS
Flexion: bending movement
decreasing joint angle
Moves articulating segments closer
together
Ankle “flexes” in two directions:
Dorsiflexion moves toes toward shank
Plantar flexion moves toes away from shank
Extension: reverse of flexion
increasing joint angle
Straightens flexed limb/joint
Hyperextension: extension movement
beyond return to anatomical position
 MOVEMENTS ALLOWED BY SYNOVIAL JOINTS
Abduction: movement away from midline
For fingers & toes = spreading them apart
The ankle joint performs foot eversion turning sole of
foot laterally
Adduction: reverse of abduction moving back
toward midline
For fingers & toes = return to anatomical position
The ankle joint performs foot inversion turning sole of
foot medially
Circumduction: circular movement involving
flexion, abduction, extension & adduction of
limb
 MOVEMENTS ALLOWED BY SYNOVIAL JOINTS
Rotation: turning of bone around its
own long axis
Internal (medial) rotation: rotation towards
midline
External (lateral) rotation: rotation away
from midline
Radial & Ulnar rotation named based
upon palm positioning
Supination
Supination: palms face anteriorly Pronation
(radius rotates P
(radius and ulna
are parallel)
(anatomical position) over ulna)

Pronation: palms face posteriorly S
TYPES OF SYNOVIAL JOINTS
TYPES OF SYNOVIAL JOINTS
TYPES OF SYNOVIAL JOINTS
SELECT SYNOVIAL JOINTS
There are a lot of synovial joints in the body
All serve different purposes which are important for day-to-day function
Let’s cut it down to 5 (for now)
1. Temporomandibular Joint (Jaw)
2. Glenohumeral Joint (Shoulder)
3. Humeroulnar Joint (Elbow)
4. Coxal Joint (Hip)
5. Tibiofemoral Joint (Knee)
1. TEMPOROMANDIBULAR JOINT (TMJ)
Mandibular condyle articulates with
temporal bone forming a modified
hinge joint
Does more than “hinge” to elevate &
depress mandible
Also glides creating lateral movement
Helps with chewing/grinding of foods
Protracts & Retracts pushing chin outward
or inward, respectively
2. GLENOHUMERAL (SHOULDER) JOINT
Large humeral head (ball) fits in shallow
glenoid cavity of scapula (socket)
Allows for high degree of movement, but relatively
low stability
Fibrocartilaginous glenoid labrum helps to add depth
Prone to tearing in sports where frequent overhead shoulder
movements are required (i.e., baseball, volleyball, & tennis)
Stability reinforced by:
Coracohumeral & Glenohumeral ligaments (anteriorly)
Muscle Tendons (majority of stability)
Biceps & Deltoid Tendons (anteriorly)
Rotator Cuff Tendons encircle shoulder
Subscapularis
Supraspinatus
Infraspinatus
Teres Minor
3. HUMEROULNAR (ELBOW) JOINT
Humerus articulates distally with radius
& ulna forming hinge joint allowing only
flexion & extension movements
Lateral movement still possible but
restricted by
Ulnar Collateral Ligament (UCL)
If torn/ruptured, repaired via Tommy John surgery
Common in throwing sports
Radial Collateral Ligament (RCL)
Radial articulation with ulna allows for
pronation & supination movements
Radial head held in place by anular ligament
4. COXAL (HIP) JOINT
Large, spherical head of femur (ball) articulates with
deep acetabulum on pubis (socket)
Provides most of joint’s stability, but limits range of motion
(compared to shoulder)
Stability also provided by:
Iliofemoral ligament
Pubofemoral ligament
Ischiofemoral ligament
Ligament head of femur
Large muscle masses surrounding (i.e., glute max, quadriceps)

Like shoulder, has an acetabular labrum deepening
socket making dislocations rare
However, tearing common in dancers, gymnastics, and
other activities where high ROM movements necessary and
common
5. TIBIOFEMORAL (KNEE) JOINT
Largest most complex joint of body
Really a combo of 2 joints:
Femoropatellar joint: plane joint allowing patella to glide during knee flexion
Tibiofemoral joint: actual articulation of femoral condyles to medial/lateral
menisci on tibial plateau creating hinge joint
Anteriorly, quadriceps tendon gives rise to 3 ligaments
attaching patella to tibia at tibial tuberosity
12 bursae associated with knee joint
Assist in smooth, free movement
Numerous ligaments stabilize joint, but most crucially are:
Medial & Lateral Collateral Ligaments (MCL/LCL)
Prevent medial & lateral collapse of knee
Minimize lateral translation of femur on tibia
Anterior & Posterior Cruciate Ligaments (ACL/PCL)
Prevent hyperextension & hyperflexion of knee
Minimize sagittal translation of femur on tibia
CLINICAL CONNECTION –KNEE INJURIES
Knee absorbs a lot of vertical forces (and is very
good at this)
However, is very susceptible to horizontal & torsional
forces
Most common injuries involve the 3 C’s:
Collateral Ligaments
Cruciate Ligaments
Cartilages (menisci)
Lateral blows to extended knee can result in
Unhappy Triad injury
Damage to MCL, ACL, and medial meniscus
ACL can be damaged in running with sudden
directional changes
Or landings where knee shifts forwards and collapses
inwards
COMMON JOINT INJURIES
Cartilage Tears
Usually caused by compression or shear (rotational) stress
Fragments may cause joint to lock or bind
Repaired with surgery as cartilage will not repair itself
With meniscal removal, joint movement is restored but is less stable
Sprains
Reinforcing ligaments get overly stretched or torn
i.e., ankle, knee, lumbar region
Partial tears will repair but slowly (8 – 12 wks)
Poor vascularization
If completely torn, surgical repair needed (either sewing back together or grafting)
Dislocations (Luxations)
Bones forced out of alignment (usually with accompanying sprain and/or tear)
Usually caused by serious fall or collision
Must be reduced (pushed back in place) to treat
All conditions require rest & immobilization for healing
TENDONITIS & BURSITIS
Inflammatory conditions involving either joint tendons or bursa
Tendonitis usually due to overuse inflaming tendon sheath
Bursitis usually caused by a direct blow or friction on the tendon
Rest up, ice down, and talk NSAIDs (if really bad)
ARTHRITIS
Umbrella of >100 inflammatory or degenerative conditions which damage
joints
Most widespread crippling disease in US
Characterized by pain, stiffness (esp. in morning), and swelling in joint
Most acute forms caused by bacteria (antibiotics treatment)
4 Chronic Forms:
1. Osteoarthritis (OA)
2. Rheumatoid Arthritis (RA)
3. Gouty Arthritis
4. Lyme Disease
CHRONIC ARTHRITIS
1. Osteoarthritis (OA) 3. Gouty Arthritis
Most common, but irreversible “wear & tear”
Excess uric acid crystals get deposited in joint
Cartilage broken down faster than it can be replaced & soft tissue (esp. around big toe)
Friction creates bone spurs (osteophytes)
Ends of bones thicken restricting movement
If untreated, can actually fuse joint &
“Crunching” noise (crepitus) can at times be heard immobilize it
Can only moderate activity & take pain relievers (as More common in men
necessary)
Some joints may be surgically replaced (i.e., knee, hip,
4. Lyme Disease
shoulder) Autoimmune condition acquired from
2. Rheumatoid Arthritis (RA) spirochete bacteria in deer tick bites
Chronic, inflammatory, autoimmune disease Along with acute rash & flu-like symptoms,
Causes joint pain, swelling, weakness, can cause joint pain & arthritis
cardiovascular problems Usually abate with antibiotic treatment, but some
Especially affects hands & feet symptoms may persist
Usually arises between ages 40 – 50 yrs; affects If untreated, may cause neurological symptoms
women 3x more frequently
JOINTS SUMMARY
Joints are characterized both by their structure and function
What holds it together? Is there a joint cavity? How much can it move?
While many of these types are immovable (or have limited movement), most joints
in our extremities are movable, synovial joints
Synovial Joints can be subclassed based upon how the articulating structures
interact & how they move
Each movement has its own characteristics
Synovial joints get stabilized in part by the joint structure itself and ligaments but
largely by the surrounding musculature
Due to use and life, these joints are prone to injury and disorders
Some of which are traumatic, some are part of life/aging, others are due to outside
circumstances
SAMPLE QUESTIONS
1. What is the term used for a joint which is immovable?
2. What kind of movement is described as the lateral translation of a
body part away from midline?
3. Which type of synovial joint is characterized by a rounded head
sitting with a cup-like groove allowing high degrees of movement (i.e.,
the shoulder)?
4. Tearing of which elbow ligament is repaired by Tommy John surgery?
5. Which form of chronic arthritis is characterized as simply general
wear and tear on the cartilage of the joint?
 COPYRIGHT

© Pearson
Edited by Charles Smith, PhD CSCS 2024