HES 234 Exam 2 Review PDF

Summary

This review document outlines different types of joints and their classifications, emphasizing various aspects of human anatomy and physiology, including joint mobility, stability, and related injuries. It covers topics like hinge joints, gliding joints, and more.

Full Transcript

**HES 234 Review for Exam \#2**

**Joints/articulations/arthroses**

Mobility vs. stability

**3 types of joints based on functional classification**

Synarthroses - immovable

Amphiarthroses -- Slightly movable

Diarthroses -- highly/freely movable

**Types of Synarthroses**

Suture -- b/w skull bones

Gomphosis -- teeth in socket (periodontal ligament)

Synchondrosis -- hyaline cartilage separates bones (epiphyseal plates,
xyphoid process and body of sternum, 1^st^ costosternal joint)

Synostosis -- previous joint that has been fused by bone (frontal
suture, closed epiphyseal plate)

**Types of Amphiarthroses**

Syndesmosis -- large space between bones with little movement possible
(interosseous ligament) (distal tibofibular joint)

Symphysis -- bones separated by pad of fibrous cartilage (pubic
symphysis and intervertebral joints where intervertebral discs form
joints between vertebral bodies)

**Types of Diarthroses (Synovial joints)** -- most common joint, joint
cavity separates bones, hyaline cartilage covers joint surfaces,
synovial membrane produces synovial fluid.

Accessory structures: fat pads, cartilages (menisci), ligaments,
tendons, bursae

**Gliding (Plane) joints** -- no angulation

[Acromioclavicular, Claviculosternal], [intercarpal,
intertarsal joints, vertebrocostal joints], [sacroiliac
joints]**.,** [vertebral facet joints]

**Hinge joints** monaxial movement

[Elbow, knee], [ankle, interphalangeal]

**Pivot joints --** Rotation only

[Atlas/Axis, Proximal radioulnar joint]

**Ellipsoid joints --** biaxial

[Radiocarpal joint], [metacarpophalangeal joints (2-5),
metatarsophalangeal joints]

**Saddle joints --** biaxial

[First carpometacarpal joint]

**Ball and Socket joints --** triaxial

[Shoulder and hip joints]

**Types of motion**

Linear motion (gliding)

Angular motion

Rotation

**Axes/planes of angular motion**

Monaxial

Biaxial

Triaxial

Flexion/Extension, Abduction/Adduction, Opposition, Inversion/Eversion,
Protraction/Retraction, Elevation/Depression, Cicumduction, Rotation
(C1/C2, Supination/Pronation)

**Injuries**

Sprain - ligament

Strain -- tendon/muscle

Dislocation

Complete (luxation)

Articulating surfaces forced out of position

Partial (subluxation)

**Spinal Joints**

3 joint complex

2 facet joints (gliding diarthroses)

Symphysis joint b/w vertebral bodies

C1/C2 exception -- no disc (pivot joint)

**Spinal ligaments**

Anterior longitudinal ligament

Posterior longitudinal ligament

Ligamentum flavum (yellow ligament)

**Intervertebral discs**

Annulus fibrosus and nucleus pulposus

IVD herniations

**Whiplash**

Sprain/Strain injury to the neck

**The pectoral girdle**

-2 clavicles

\- 2 Scapulae

Acromioclavicular joint -- gliding diarthrosis

Sternoclavicular joint -- gliding diarthrosis

AC joint separation -- disruption of ac joint and surrounding ligaments

**The glenohumeral joint** (shoulder joint) -- ball and socket joint

Supported by glenoid labrum, rotator cuff muscles, numerous other
ligaments and muscles

Rotator cuff muscles -- Supraspinatus\*\*, Infraspinatus, Subscapularis,
Teres minor

Injury -- labrum tear

**The elbow joint** -- hinge joint diarthrosis

Humeroulnar joint -- trochlea of humerus and trochlear notch of ulna

Humeroradial joint -- capitulum of humerus and head of radius

Supporting muscles -- Biceps brachii -- flexes and Triceps Brachii --
extends

Ligaments -- Annular (radial head in radial notch), Ulnal collateral
lig., radial collateral lig.

**Elbow Injuries**

Medial epicondylitis =golfer's elbow/damage to ulnar collateral ligament
= pitcher's elbow

Lateral epicondylitis = tennis elbow

**The wrist -- mostly gliding joints**

**The pelvic girdle**

Pelvis bones -- ilium, ischium, pubis = innominate

Sacrum

Coccyx

**The hip joint** -- ball and socket diarthrosis

Stable

Head of femur in acetabulum of innominate

Labrum and ligament of femoral head increases stability

Many surrounding ligaments and muscles

**Injuries** -- Dislocations, Sprains, Strains, Labrum tears, Fractures
of femoral neck

**The knee joint**- hinge diarthrosis

Femur-Tibia articulations -- Lateral and medial condyles

Patella- Femur articulation

Ligaments

Anterior and posterior cruciate ligaments

Medial and lateral collateral ligaments

Menisci

Medial and lateral menisci -- give knee lateral stability

Other structures

Fat pads, bursae

Injuries

ACL, MCL/LCL, meniscus, Unhappy triad (ACL, MCL, meniscus)

"Plant and twist"

**The ankle joint** -- Hinge diarthrosis (talus and tibia articulation)

Lateral ligament [-- most commonly sprained] **-- Anterior
talofibular ligament**, then calcaneofibular, and posterior talofibular

Medial ligament -- Deltoid ligament

**Arthritis**

Osteoarthritis -- most common -- joint degeneration

Rheumatoid arthritis -- autoimmune -- inflammation of synovial membrane
-- joint destruction

Gouty arthritis (Gout) -- Uric acid deposition

**Arthroscopy** -- procedure to look inside and repair a joint

**Arthroplasty** -- surgical replacement of a joint

**Muscles Physiology/Histology**

3 types of muscle --

skeletal (striated) (voluntary), cardiac (striated) (involuntary),
Smooth (nonstriated) (involuntary)

**Muscle connective tissue** -- Dense regular CT proper -- become tendon
at ends of muscle

Epimysium-surrounds outside of muscle

Perimysium -- surrounds fascicles

Endomysium -- surrounds fibers

**Muscle -- fascicles -- fibers (cells) -- myofibrils (multiple
sarcomeres) -- myofilaments (actin and myosin)**

Skeletal muscle fibers --

Very long cells/hundreds of nuclei/ made through fusion of myoblasts in
utero

**Muscle terminology:**

Cell= fiber

Cytoplasm= sarcoplasm

Plasma membrane= sarcolemma

Ca++ storage organelle= sarcoplasmic reticulum

**Sarcomere** -- smallest/basic functional unit of skeletal muscle

Made up of 2 Z-discs and the actin and myosin filaments between them.

Multiple sarcomeres connected end to end = myofilament

Sarcolemma resting potential = -90mV (don't have to know the numbers)

Sarcolemma action potential threshold = -55mV

**Steps in muscle contraction (excitation-contraction)**

1\. Action potential is generated in the central nervous system and
travels down motor neuron to neuromuscular junction.

2\. Neuron releases Acetylcholine (ACh) at the NMJ.

3\. ACh diffuses across space between the neuron and the muscle motor end
plate (synaptic cleft)

4\. Ach binds to Ach receptor proteins on the surface of the sarcolemma
at the motor end plate and is then quicky broken down by
acetylcholinesterase.

5\. This binding of Ach to its receptors triggers Na+ channels to open.

6\. Na+ rushes in and depolarizes the sarcolemma from -90mV to -55mV
(don't have to know the numbers)

7\. An action potential in the muscle fiber is triggered.

8\. The action potential of the muscle fiber spreads quickly across the
surface of the cell like a wave causing Na+ channels to open for a brief
period of time.

9\. As the wave of depolarization passes an area of the sarcolemma, Na+
channels close and repolarization of the sarcolemma and a return to
resting potential occurs.

10\. The wave of depolarization spreads into the t-tubules, which are
situated next to sarcoplasmic reticuli.

11\. The depolarization of the sarcolemma next to the sarcoplasmic
reticuli causes them to release Ca++ into the sarcoplasm.

12\. Ca++ bind to troponin and the troponin/tropomyosin complex moves off
of the actin active sites.

13\. Myosin heads bind to the active sites (cross-bridging) and then
undergo a powerstoke.

14\. Upon completion of a powerstroke, each myosin head releases an ADP
and Phosphate molecule

15\. An ATP molecule then binds to a myosin head which causes the myosin
head to detach from the actin filament.

16\. After detachment, the ATPase enzyme splits the ATP molecule into ADP
and a phosphate molecule and the energy released is used to "reposition"
the myosin head.

\*\*Powerstrokes and "reposition" of myosin heads continue as long as
there continues to be Ach release and action potentials in the muscle
fiber and Ca++ and ATP present in the sarcoplasm.

\*\*As powerstokes occur, actin and myosin filaments slide past one
another, shortening the distance between Z-discs (shortening
sarcomeres). This causes a pull on the connective tissues and a tension
production in the tendons of the muscle.

**Relaxation of muscle fiber**

1\. If action potentials end, Ca++ is quickly taken back up by
sarcoplasmic reticuli.

2\. Ca++ no longer is bound to troponin and this causes the
troponin/tropomyosin complex to once again cover the actin active sites.

3\. No more cross-bridging can occur.

4\. Fiber returns to resting length through:

Elastic recoil, gravity and opposing muscle action (antagonist action)

**ATP production:**

Muscle cells store enough ATP for a second of contraction, then it must
be made.

ATP can be recycled with the use of creatine phosphate

ADP + creatine phosphate = ATP + creatine (enzyme used is creatine
phosphokinase)

ATP + creatine = creatine phosphate + ADP

This process can last about 15 seconds

**Anaerobic Glycolysis**

Production of ATP from glucose without the use of oxygen

Produces enough ATP to keep muscle functioning a little while longer

Causes build up of lactic acid

**Aerobic metabolism**

Production of ATP from glucose, fat or protein with the use of oxygen.

Uses the Kreb's Cycle to produce a lot of ATP

Can sustain muscle fiber contraction for long periods of time

**Slow twitch and fast twitch muscle fibers**

Red meat vs. white meat (myoglobin and blood supply)

**ST fibers** -- High aerobic capacity, slow to contract, less powerful
than Ft fibers, small motor units

**Fta fibers** -- (intermediate fibers), medium aerobic capacity, high
anaerobic capacity, fast contraction speed

**Ftb fibers** -- Low aerobic capacity, high anaerobic capacity, fast
contraction speed, large motor units

**Muscle hypertrophy**-

We can increase the size of our muscles by working out

The increase in size is an increase in fiber size, not an increase in
fiber numbers.

More actin and myosin filaments are added to the fibers to make them
larger.

**Muscle atrophy --** Due to lack of use

Loss of muscle mass due to a reduction in the number of actin and myosin
filaments in our fibers

**Motor unit =** motor neuron and the muscle fibers it innervates

Small motor units = fine motor control

Large motor units = strength

**Length-Tension relationship skeletal muscles**

If a muscle and its fibers and sarcomeres are overly shortened at the
beginning of contraction, less force(tension) can be produced.

If a muscle and its fibers and sarcomeres are overly stretch at the
beginning of contraction, less force (tension) can be produced.

If a muscle and its fibers and sarcomeres are just the right length with
some overlap of actin and myosin, but not too much overlap, then the
maximal amount of tension can be produced.

"the Goldylocks zone"

3 Phases of a muscle fiber twitch

Latent phase

Contraction phase

Relaxation phase

Stimulus frequency and tension production

\*Higher stimulus frequency=more tension production

Subsequent stimuli arrive right at the end of the relaxation phase =
**Treppe**

Subsequent stimuli arrive before end of relaxation phase = **Wave
summation**

Wave summation tops out as **incomplete tetanus**.

Subsequent stimuli arriving very close together = **Complete tetanus**

\*\*\*Normal muscle contraction involves Complete tetanus of multiple
muscle fibers in a muscle\*\*\*

**Parts of a muscle**

Origin -- fixed end

Belly -- where all the fibers are (middle)

Insertion -- movable end

Skeletal muscle shapes

Parallel

Convergent

Circular

Pennate -- Unipennate, Bipennate, multipennate

Bipennate produces more tension because there are more muscle
fibers/unit area

**Muscles and their actions**

Agonist (prime-mover) does the action (biceps brachii -- flexes elbow)

Synergist -- helps the prime mover do the action (brachialis)

Antagonist -- muscle that opposes the action and must relax for action
to occur (triceps brachii)

Fixator(s) -- prevents movement at another joint (Rotator cuff, deltoid,
rhomboids)

**Types of muscle contraction**

Isometric -- tension production without a change in length

Isotonic -- tension production with a change in length

Concentric -- shortening of the muscle

Eccentric -- lengthening of the muscle

**Intrinsic vs. Extrinsic muscles**

**Common flexor and extensor origin for wrist and hand muscles**

**Anterior muscles acting on the hip**

Iliopsoas -- primary hip flexor

**Lateral thigh muscles**

Tensor Fasciae Latae

Iliotibial band

Gerdy's tubercle

**Flexors of the knee**

Hamstring muscles

Biceps femoris

Semitendinosis

Semimembranosis

**Extensors of the knee**

Quadriceps muscles

Rectus femoris

Vastus lateralis

Vastus medialis

Vastus intemedius

**Sartorius** -- "tailors muscle"

Crosses leg

**Gracilis** -- Adductor muscle of hip

**Pes Anserine**

Insertion of Sartorius, Gracilis and Semitendinosis

Pes anserine bursitis

**Compartments of the leg**

Anterior

Lateral

Deep posterior

\*Superficial posterior

Gastrocnemius -- plantar flexion

Soleus -- plantar flexion

Common tendon = calcaneal tendon