ANATOMY & PHYSIOLOGY Midterms PDF

Summary

This document is an outline for midterms. It covers the skeletal system, muscular system, and nervous system. It includes topics like bones of the shoulder girdle, muscles for ankle and foot movement, and the organization of muscle tissue.

Full Transcript

ANATOMY &
PHYSIOLOGY
LEC / PROF. BERNARD S. BARRANCO, RN, MAN
______________________________________________________________________________________________________________
MIDTERMS

OUTLINE K. Muscles for Ankle and Foot Movement
IV. Muscle Origin, Insertion, Action Reference
I. The Skeletal System (cont.)
V. The Nervous System
A. Appendicular Skeleton
A. Functions of the Nervous System
B. Bones of the Shoulder Girdle
B. Organization of the Nervous System
C. Bones of the Upper Limb
C. Functional Classification of Nervous
D. Bones of the Pelvic Girdle
System
E. The Pelvis
D. Structures and Functions
F. Bones of the Lower Limbs
E. Parts of a Neuron
G. Joints
F. Types of Neuron
H. Functional Classification of Joints
G. Nerve Properties Related to Function
I. Inflammatory Conditions Associated
H. Resting Membrane Potential
with Joints
I. Generating Action Potentials
II. The Muscular System
J. Neuromuscular Junction
A. Functions of the Muscular System
K. Reflexes
B. Three Types of Muscular Tissue
VI. The Central Nervous System
C. Skeletal Muscle Fibers
A. Brain
D. Organization of Muscle Tissue
B. Regions of the Brain
E. Skeletal Muscle Arrangement
C. Cerebrum
F. Structure and Organizational Levels of
D. Corpus Callosum
Skeletal Muscle
E. Cerebral Cortex
G. Sarcomere Arrangement
F. Diencephalon
H. Sarcomere Structure
G. Brain Stem
I. Thick Filament Structure
H. Cerebellum
J. Thin Filament Structure
I. Protector of the Nervous System
K. Physiology of Skeletal Muscle
VII. The Peripheral Nervous System
Contraction: Neurotransmitter Release
A. Cranial Nerves
L. Sliding Filament Theory
B. Spinal Nerves
M. Phyisology of Skeletal Muscle
C. Autonomic Nervous System
Contraction: Power Stroke
VIII. References
N. Phyisology of Skeletal Muscle
IX. Trans Authorship
Contraction: Depolarization
O. Lever Systems
P. Muscle Attachments I. THE SKELETAL SYSTEM (cont.)
Q. Basic Body Movement
R. Interaction of Skeletal Muscles on the A. APPENDICULAR SKELETON
Body Consists of 126 BONES
S. Names of Skeletal Muscles Limbs (appendages)
T. Arrangement of Fascicles Pectoral (shoulder) girdle
U. Muscles of the Face Pelvic girdle - weight bearing, connected on the lower
V. Muscles of the Head extremities
W. Muscles of Mastication
X. Eye Muscles B. BONES OF THE SHOULDER GIRDLE
Y. Muscles of the Neck Composed of two bones
Z. Muscles of the Trunk ○ Clavicle - “collarbone”
III. The Muscular System (Upper and Lower Limb) ○ Scapula - “shoulder blade”
A. Prime Movers of the Arm These bones allow the upper limb to have exceptionally free
B. Muscles that Move the Forearm movement due to the following factors:
C. Muscles of the Scapula ○ Each shoulder girdle attaches to the axial skeleton at only
D. Muscles of the Rotator Cuff one point, the sternoclavicular joint.
E. Muscles that Move the Lower Limb ○ The loose attachment of the scapula allows it to slide
F. Muscles of the Hip Joint back and forth against the thorax as muscles act.
G. Muscles for Knee Movement ○ The glenoid cavity is shallow, and the shoulder joint is
H. Hamstring Group poorly reinforced by ligaments.
I. Sartorius The collarbone is the most commonly broken bone among
J. Quadriceps children.

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 ○ It usually occurs by falling on an outstretched arm. Acromioclavicular Joint - where the acromion connects
with the clavicle laterally.
Glenoid Cavity
➔ shallow socket that receives the head of the humerus.
Suprascapular Notch
➔ where nerves pass through.
Superior Angle and Subscapular Fossa - where
muscles of the chest are inserted into.
2 PROCESSES OF THE SCAPULA
Acromion Process
➔ enlarged lateral end of the spine
Coracoid Process - “beaklike”
➔ points laterally over the top of the shoulder
➔ anchors some muscles of the arms

C. BONES OF THE UPPER LIMB

The Arm
The arm is formed by a single bone
CLAVICLE Humerus
A slender bone that connect parts of the anterior thorax ➔ Head of humerus allows for rotation
The clavicle acts as a brace to hold the arm away from the 2 Tubercles of the Humerus
top of the thorax and prevent shoulder dislocation. Greater tubercle of the humerus
○ Medial (sternal) end - connected on the manubrium Lesser tubercle of the humerus
(head of the sternum)
○ Clavicular notch - where the medial end of the Anatomical Neck - a slight constriction immediately
clavicle sits on inferior to the head.
○ Lateral (acromial) end - directly connected to the Surgical neck (the line) - common site of fracture or
acromion; connected by the acromioclavicular joint. breakage of the humerus
Deltoid Tuberosity
➔ Just below the surgical neck
➔ Where deltoid muscles are attached
➔ Deltoid muscle is the largest arm muscle
◆ Site of intramuscular injection.
Capitulum & Trochlea - parts that are being connected to
the forearm.
Coronoid fossa - has a depression wherein the part of
the ulna is connected.
Radial groove
➔ runs obliquely down the posterior aspect of the shaft.
➔ where radial nerve passes on.

SCAPULA
Sometimes called the “wing” because they flare when we
move our arms posteriorly.
Each scapula has a flattened body with three borders:
superior, medial, lateral
It also has three angles: superior, inferior, lateral
Shoulder joint is poorly reinforced by LIGAMENTS.
Acromion
➔ where the lateral end of the clavicle is connected to.
➔ enlarged lateral end of the spine of the scapula

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 The Hand
The Forearm Carpals (8) - wrist
Has two bones: ○ Scaphoid bone - one of the biggest bones in the
Ulna carpal.
➔ the longer of the two forearm bones ○ Lunate
➔ located on the medial or little finger side of the ○ Triquetral
forearm. ○ Pisiform - smallest bone in the carpal.
○ The Olecranon process consists of the bone of the ○ Trapezium
proximal ulna from the base of the coronoid process ○ Trapezoid
proximally. ○ Capitate
○ Hamate
Metacarpals (5) - palm
Phalanges (14) - fingers
○ Distal - the thumb doesn’t have a distal phalange.
○ Middle
○ Proximal

D. BONES OF THE PELVIC GIRDLE

Radius
➔ located on the lateral or thumb side when the palm
of the hand is facing forward
➔ The head of the radius forms a joint with the
capitulum of the humerus.
○ Styloid Process
➔ Articulated on the wrist
○ Radial Tuberosity
➔ Articulated near the proximal radioulnar joint.
➔ Where tendons of the bicep muscles attaches,
Composed of two coxal bones (hip bones)
Radioulnar joint - where both proximally and distally the ○ Composed of three pairs of fused bones
radius and ulna articulate. Ilium
Interosseous Membrane - Connects the two bones. Ischium
Pubis
*Arms are among the most commonly broken bones, The total weight of the upper body rests on the pelvis
accounting for almost half of all adults’ broken bones. Protects several organs
○ Reproductive organs
○ Urinary bladder
○ Part of the large intestine

NOTE: pelvic girdle and pelvis have slightly different
meanings.
Pelvic girdle comprises the coxal bones and the
sacrum.
Pelvis comprises the coxal bones, sacrum and
coccyx.
Ilium
Connect posteriorly with the sacrum.
Large flaring bone that forms most of the hip bone
“Alae” – wing like portion of ilium
Sacroiliac joint - the one that joints the ilium and part of
the sacrum.

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Ischium (Sit down bone) F. BONES OF THE LOWER LIMB
Ischial tuberosity – receives body weight when in a
sitting position
Ischial spine – superior to the tuberosity.
Narrows the outlet of the pelvis

Pubis
The most anterior and inferior part.
Forms in the fusion of Rami of the pubis
Obturator foramen – opening that allows blood vessels
and nerves to pass into the anterior part of the thigh.
Pubic symphysis – pubic bones of each hip articulate
anterior to form a cartilaginous joint.

*During birth, the baby passes through the pelvic brim.
E. THE PELVIS
The Thigh
The thigh has one bone:
Femur - thigh bone
➔ longest, heaviest, and strongest long bone of the
human body.
➔ Its proximal end has a ball-like head, a neck, and a
greater trochanter and lesser trochanter, separated
anteriorly by the intertrochanteric line and posteriorly
by the intertrochanteric crest.
○ Lateral and Medial Condyle
➔ distal on the femur
ACETABULUM - Deep socket formed by the fusion of Ilium, ➔ articulate with the tibia
ischium and pubis. ➔ separated by the intercondylar fossa.
○ Accommodates the head of the femur. ○ Patella - knee cap
➔ Triangular bone located within a tendon that passes
False Pelvis over the knee.
➔ superior to the true pelvis ➔ Protects the anterior articular surface of the knee
➔ the area medial to the flaring portions of the ilia. joint.
True Pelvis ➔ Patellar surface - anteriorly on the distal femur;
➔ surrounded by bone forms a joint with the patella.
➔ lies inferior to the flaring parts of the ilia and the pelvic
brim.
Outlet
➔ the inferior opening of the pelvis measured between
the ischial spines.
Inlet
➔ superior opening between the right and left sides of
the pelvic brim.

Gender Differences of the Pelvis

The Leg
The leg has two bones
Tibia - shin bone; larger
○ Tibial Tuberosity
➔ a roughened area on the anterior tibial surface.
Female inlet is larger and more circular ○ Medial Malleolus
Female pelvis is shallower ➔ forms the inner bulge of the ankle.
Bone are lighter and thinner ○ Anterior Border
Female ilia flare more laterally ➔ unprotected by muscles which makes it easily felt
Female sacrum is shorter and less curved beneath the skin.
Female ischial spine are shorter and farther apart (bigger Fibula - long and thin
outlet) ○ Lateral Malleolus
Female pubic arch is more rounded. ➔ on the distal end

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 ➔ forms the outer part of the ankle.

Cartilaginous Joints (AMPHIARTHROSIS)
The Foot Bones connected by cartilage
The foot Examples:
○ Tarsal (7) - ankle ○ Pubic Symphysis
Body weight is carried mostly by the Calcaneus and ○ Intervertebral Joints
Talus.
Calcaneus - heel bone; largest tarsal
Talus - second largest tarsal; lies superior to the
calcaneus.
○ Metatarsals (5) - sole/instep
○ Phalanges (14) - toes

G. JOINTS
Articulations of bones
Functions of joints include:
○ Holds bones together
○ Provide flexibility
Ways joints are classified:
○ By their function
○ By their structure Synovial Joints
H. FUNCTIONAL CLASSIFICATION OF JOINTS Articulating bones are separated by a joint cavity
Synarthroses - immovable joints Synovial fluid is found in the joint cavity
Amphiarthroses - slightly moveable joints Reinforced by ligaments
Diarthroses - freely moveable joints All joints in the limbs are synovial joints.
Fibrous joints - generally immovable Bursae - small fluid-filled sacs that reduce friction
Cartilaginous Joints - Immovable or slightly moveable between moving parts in your body's joints.
Synovial Joints - Freely moveable Synovial Joints have 4 distinct features:
○ Articular Cartilage - covers the ends of the bones
forming the joints.
○ Articular Capsule - The joint surfaces are enclosed
by a sleeve of fibrous connective tissue lined with a
smooth synovial membrane.
○ Joint Cavity - The articular capsule encloses a
cavity called the joint cavity which contains a
lubricating synovial fluid.
○ Reinforcing Ligaments - The fibrous layer of the
capsule is usually reinforced with ligaments

6 types of Synovial Joints
Fibrous Joints (SYNARTHROSIS) Hinge Joint
Bones united by fibrous tissue - largely immovable. ○ Movement is like two boards joined together by a
Examples include sutures of the skull. hinge.
○ Movement in one direction;
Elbow, knees, fingers.

Ball and Socket Joint
○ When ball-shaped end of one bone fits into the
cup-shaped socket of another
○ Bones can move in many directions
Shoulder, hip

Pivot Joint
○ Allows for rotation around the length of a bone.

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 ○ Allows only for rotation Unlike nerves, however, muscles are also:
Head (side to side “no” action ○ Contractible (they can shorten in length)
Forearm joints (palms) supination/pronation ○ Extensible (they can extend or stretch)
○ Elastic (they can return to their original shape)
Saddle Joint
○ When the surfaces of both articulation bones are B. Three Types of Muscular Tissue
saddle-shaped Skeletal Muscle
○ Concave/Convex ➔ Fibers are HUGE, cigar shaped, multinucleate
○ Thumbs
○ Wide range of motion Smooth Muscle
➔ Spindle-shaped
Gliding Joint
➔ Surrounded by scant endomysium
○ Interaction of flat surfaces of articulating bones
➔ Contraction is SLOW and SUSTAINED.
○ Limited but complex movement
Wrist, ankle
Cardiac Muscle
➔ Cushioned by small amount of soft connective tissues
Condyloid Joint
(endomysium)
○ Oval-shaped articular surface of one bone fits into the
➔ Arranged in SPIRAL or figure 8-shaped bundles
oval-shaped depression of another
➔ Contact at a fairly steady rate (Pacemaker)
Mandible, knuckles

I. INFLAMMATORY CONDITIONS ASSOCIATED Location Function Appearance Control
WITH JOINTS
Bursitis SKELETAL Skeleton Movement, Striated, V
○ inflammation caused by a bursa usually caused by a blow heat, multi-nucleat
or friction. posture ed
Tendonitis (eccentric),
○ inflammation of tendon sheaths. fibers
Arthritis parallel
○ Inflammatory or degenerative diseases of joints.
➔ Over 100 different types CARDIAC Heart Pump Striated, one I
➔ The most widespread crippling disease in the United blood central
States continously nucleus
Clinical Forms of Arthritis VISCERAL G.I. tract, Peristalsis, No I
Osteoarthritis uterus, blood striations,
○ Most common chronic arthritis eye, pressure, one central
○ Probably related to normal aging processes blood pupil size, nucleus
Rheumatoid arthritis vessels erects hairs
○ An autoimmune disease – the immune system attacks
the joints
○ Symptoms begin with bilateral inflammation of certain
joints C. Skeletal Muscle Fibers
○ Often leads to deformities Skeletal muscle is the only organ of the muscular system
Gouty Arthritis ➔ Largest - 30 cm (1 foot in length)
○ ➔ Forms contour of body
Skeletal muscle is composed of skeletal muscle tissue and
II. THE MUSCULAR SYSTEM also contains nervous tissue, blood vessels and
connective tissue
MUSCLE
Half of the body’s weight is muscle tissue
Latin word “mus” - “Little mouse”
○ Skeletal muscle = 40% in males, 32% in females
○ Cardiac muscle = 10%
A. Functions of the Muscular System
Allow for movement, facial expressions, breathing,
1. Producing Movement - contraction of skeletal muscle
swallowing, writing, talking and singing, posture, heat
➔ Respond to change in external; environment
production
➔ Express emotion (smile and frown)
2. Maintaining Posture and Body Position
Connective Tissue Coverings
➔ Muscle adjust after the other - maintain posture
Fascia
3. Stabilizing Joints
➔ surrounds an individual skeletal muscle, separating it
➔ Skeletal muscle pulls on bone
from other muscles.
➔ Muscle tendon reinforces and stabilizes joints
➔ Tendon - fascia extending beyond the ends of the
4. Generate heat
muscle.
➔ Body heat - product of muscle activity (ATP)
➔ Aponeurosis - Fascia connecting to a muscle.
➔ Heat maintain normal body temperature
Like nervous tissue, muscles are excitable or
“irritable”
○ they have the ability to respond to a stimulus.

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 D. Organization of Muscle Tissue

F. Structure and Organizational Levels of
Skeletal Muscle
MUSCLE (organ)

ENDOMYSIUM
Connective tissue sheath that encloses a muscle fiber
(cell).

PERIMYSIUM
Coarse fibrous membrane that wrap several sheath
muscle fibers. A muscle consists of hundreds to thousands of muscle
cells, plus connective tissue wrappings, blood vessels,
FASCICLE and nerve fibers.
bundle of fibers Covered externally by the epimysium.

EPIMYSIUM Fascicle (a portion of the muscle)
(Epi –upon,over, beside ; mys-muscle)
Tough “overcoat” of connective tissue that binds fascicle

APONEUROSIS
Epimysia blends into a strong, cord-like tendon which
attach muscle indirectly to bones, cartilages or connective
tissue coverings. A Fascicle is a discrete bundle of muscle cells, segregated
from the rest of the muscle by a connective tissue sheath.
TENDONS Surrounded by the perimysium.
Tough collagenic fibers - anchors to bone
Muscle Fiber (cell)
E. Skeletal Muscle Arrangement
A single muscle cell is a muscle fiber
○ Fibers are made up of myofibrils.
○ Myofibrils are made up of thick and thin filaments.
Sarcolemma - muscle cell membrane
Sarcoplasm - muscle cell cytoplasm
Myofibrils are striated
○ Striations due to arrangement of thick and thin
filaments A muscle fiber is an elongated multinucleate cell; it has a
Seen as alternating areas of light and dark bands banded (striated) appearance.
Sarcomere - The length of each myofibril that is divided Surrounded by endomysium.
into repeating units.
○ A sarcomere is the functional unit of skeletal
muscle

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Myofibril or Fibril (complex organelles composed of MYOSIN
bundles of myofilaments). ➔ protein molecule
➔ ATPase enzymes - general power of contraction

H. Sarcomere Structure
Sacromere exists from Z-line to Z-line
A-band is dark middle band
○ Overlapping think and thin filaments
Myofibrils are rodlike contractile elements that occupy I-Band - ends of A-Band, thin filaments only
most of the muscle cell volume. Z-line is in the middle if the I-Band
Composed of sarcomeres arranged end to end, they Myosin filaments are held to the z-line by titin proteins
appear banded, and bands of adjacent myofibrils are
aligned. I. Thick Filament Structure
Sarcomere (a segment of a myofibril)

A sarcomere is the contractile unit, composed of
myofilaments made up of contractile proteins.

Myofilament or Filament (extended macromolecular
structure)

Composed of many myosin molecules
○ Each myosin molecule has a tail region and 2 globular
heads (crossbridges)
Contractile myofilaments are two types-thick and thin. ➔ When they link is causes the CONTRACTION
Thick filaments contain bundled myosin molecules; thin J. Thin Filament Structure
filaments contain actin molecules (plus other proteins).
The sliding of the thin filaments past the thick filaments
produces muscle shortening.
Elastic filaments maintain the organization of the A band
and provide elastic recoil when muscle contraction ends.

G. Sarcomere Arrangement

Composed of actin protein
○ 2 strands of globular actin molecules twisted into a
helix
○ Actin filaments have binding sites for myosin cross
bridges
○ Tropomyosin protein spirals around actin helix
Troponin protein (3 subunits) is attached to actin and holds
tropomyosin in place
○ Call this the troponin-tropomyosin complex
Alternating light (I) and dark (A) bands give the muscle
cell as a whole its STRIPED appearance.
The banding pattern reveals the working structure of the
myofibrils.
Thick filaments - myosin filaments
Thin Filaments - contractile protein “actin”

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 K. Physiology of Skeletal Muscle SKELETAL MUSCLE CONTRACTION
Contraction: Neurotransmitter Release When a nerve impulse reaches a neuromuscular junction,
acetylcholine (ACH) is released. Upon binding to
sarcolemma receptors, ACh causes a change in
sarcolemma permeability leading to a change in
membrane potential.

STEPS:
1. Action potential arrives at axon terminal of motor
neuron
2. Voltage-gated Ca2+ channels open. Ca2+ enters the
axon terminal moving down its electrochemical
gradient,
3. Ca2+ entry causes ACh to neurotransmitters to be
released by exocytosis.
4. ACh diffuses across the synaptic cleft and binds to its
receptors on the sarcolemma.
5. ACh binding opens ion channels in the receptors that
allow simultaneous passage of Na+ into the muscle
fiber and K+ out of the muscle fiber. More Na+ ions
enter than L+ ions exit, which produces a local
Motor impulse is initiated in the brain change in the end plate potential.
Travels through the brain and spinal cord to a motor nerve 6. ACh effects are terminated by its breakdown in the
ending synaptic cleft by acetylcholinersterase and diffusion
Motor nerve endings (axons) depolarize away from the junction.
Calcium enters the axonal endings
Calcium causes the release of acetylcholine into the L. Sliding Filament Theory
neuromuscular junction (synaptic cleft) A sarcomere is the functional unit of skeletal muscle
When a skeletal muscle contracts, sarcomeres shorten
MOTOR NEURON The sliding filament model of contraction states that during
Nerve cell that innervates skeletal muscle tissue contraction the thin filaments slide past the thick ones so
that the actin and myosin filaments overlap to a greater
DENDRITE degree
➔ Receives information

AXON
➔ Transmits information
➔ Has vesicles containing neurotransmitters that will
stimulate or inhibit muscle contraction.

NEUROMUSCULAR JUNCTION
➔ site where branch of motor neuron (motor nerve
ending) comes in contact with sarcolemma of skeletal
muscle fiber.

NEUROMUSCULAR JUNCTION
Motor end-plate
➔ Sarcolemma of muscle fiber directly beneath motor THE SLIDING-FILAMENT MECHANISM
nerve ending
➔ Contains an abundance of mitochondria and nuclei)
Acetylcholine (Ach) is the neurotransmitter released by
motor neurons
➔ Chemical substance released from vesicles in the
motor nerve ending (axonal ending
When stimulated by a nerve impulse, Acetylcholine is
released, travels across the synaptic cleft and binds
receptors on the motor end plate
Stimulates contraction
The “sliding” of actin on myosin (thick filaments on thin
filaments) can be broken down into a 4 step process

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 MUSCLE RELAXATION MECHANISM
Acetylcholinesterase present in the NMJ destroys ACh
(preventing continual stimulation)
Calcium ions are transported from the sarcoplasm back
into the SR.
Linkages between myosin and actin are broken Requires
ATP binding

THEN: The muscle fiber relaxes

With exposure of the myosin binding sites on actin (the thin ENERGY FOR CONTRACTION
filaments)—in the presence of Ca2+ and ATP—the thick and Muscle cells require huge amounts of ATP energy to
thin filaments “slide” on one another and the sarcomere is power contraction
shortened The cells have only a very small store of ATP.
Three pathways supply ATP to power muscle contraction
M. Physiology of Skeletal Muscle
Contraction:Power Stroke
Calcium binds troponin (which is attached to tropomyosin
Moves tropomyosin from the myosin binding sites on actin
Myosin crossbridges (heads) bind to actin
○ ATP hydrolysis supplies energy
Actin is pulled inward towards the center of the sarcomere
= POWER STROKE
Sarcomeres shorten as muscle contracts

ENERGY FOR CONTRACTION
ATP initially supplied from cellular respiration.
If ATP is abundant, it is converted to creatine phosphate
and stored in skeletal muscles.
When ATP is low, creatine phosphate supplies phosphate
to ADP making ATP.
CP & ATP stores only good for about a 10 second
maximal contraction.
ATP must then come from cellular respiration or glycolysis.

N. Physiology of Skeletal Muscle
Contraction: Depolorization
After ACh binds to the ACh receptors, its effects are
quickly terminated by acetylcholinesterase , an enzyme
located in the synaptic cleft.
Acetylcholinesterase breaks down ACh to its building
blocks, acetic acid and choline
This removal of ACh prevents continued (and most likely
undesirable) muscle fiber contraction in the absence of
additional nervous system stimulation

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 Exercise and Skeletal Muscles
Intense, strenuous exercise
Muscles exceed capacity of respiratory and cardiovascular
systems to deliver oxygen for contraction.
ATP supplied anaerobically through glycolysis
Pyruvate is converted to lactic acid
Lactic acid builds up in muscles
Causes muscles to fatigue

OXYGEN DEBT

Oxygen & Muscle Contraction
Myoglobin of muscle (similar to hemoglobin) binds to and
stores oxygen
Supplies O2 needed to make ATP for contraction

Exercise and Skeletal Muscles
Prolonged, moderate exercise
ATP supplied through cellular respiration Amount of oxygen needed by liver cells to use the
Once glycogen stores are depleted in muscle, glucose and accumulated lactic acid to produce glucose
fatty acid deliveries from blood are used as fuel source ○ Oxygen not available
○ Glycolysis continues
Exercise and Contraction ○ Pyruvic acid converted to lactic acid
In intense strenuous activity, oxygen can be depleted. ○ Liver converts lactic acid to glucose
Why? Also the amount of oxygen needed to replace O2 levels in
○ Contraction of skeletal muscles decreases blood skeletal muscle to pre-exercise levels.
delivery to muscles Nutrient and O2 levels in
contracting muscles decrease HEAT PRODUCTION
Cellular respiration is only about 40% efficient.
About 60% of the energy found in a glucose is lost as heat
during cellular respiration.
Muscle contraction generates heat because muscles use
large amounts of nutrients to make ATP, generating large
amounts of heat.
Heat is used to maintain body temperature.

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 O. Lever Systems: Bone-Muscle
Relationships
The operation of most skeletal muscles involves
leverage—using a lever to move some object.
○ LEVER
➔ a rigid bar that moves on a fixed point called the
FULCRUM.
Effort
○ The applied force;
○ is used to move a resistance or load.
JOINTS – acts as Fulcrums
BONES - acts as Levers

Lever Systems: Second Class
FULCRUM-LOAD-EFFORT
Example: Wheelbarrow

Each BONE is a LEVER
○ a rigid, moving structure
Each JOINT a FULCRUM
○ a fixed point

Muscles provide applied force (AF) required to overcome
resistance (R)

FUNCTIONS
To change: In the body, a second class leverage is exerted when
Direction of an AF. you stand on tip-toe.
Distance & speed of movement produced by an AF. ○ Effort = exerted by calf muscles pulling upward on
Effective strength of an AF. the heel.
○ Fulcrum - joints of the ball of the foot.
THREE CLASSES OF LEVER SYSTEM ○ Load = weight of the body
➔ depend on the relationship between applied force,
fulcrum, and resistance.
first class, second class, third class

Lever Systems: First Class
LOAD-FULCRUM-EFFORT
Example: Scissors

Lever Systems: Third Class
LOAD-EFFORT-FULCRUM
Example: tweezers or forceps.

In the body, a first class system raises your head off
your chest.
The posterior neck muscles = effort
the atlanto-occipital joint = fulcrum
the facial skeleton = weight to be lifted/load.

In the body, flexing the forearm by the biceps brachii
muscles exemplifies third-class leverage.
○ Effort = exerted on the proximal of the forearm
○ Fulcrum = elbow joint
○ Load = hand and the distal end of the forearm

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 P. Muscle Attachments
Point of Attachment
ORIGIN
➔ Point of attachment does not move (immovable)
➔ Origin bone is the more stationary of the two bones at
a joint when contraction occurs
INSERTION
➔ Moves during contraction
➔ Insertion bone towards the origin bone

*REMEMBER!*
The terms origin and insertion provide useful points of
reference. Many muscles have multiple points of origin
and insertion. Understanding the functional relationship
of these attachment points during muscle contraction INVERSION AND EVERSION
helps in deducing muscle actions” Special movement of the foot
○ Inversion - turn the sole medially
○ Eversion - turn the sole laterally
Q. Basic Body Movement
DORSIFLEXION AND PLANTAR FLEXION
UP and DOWN movement of the foot
○ Dorsiflexion – Lifting foot so that superior surface
approaches the shin (walking on heels)
Hands – extension of hands at the wrist
○ Plantar Flexion - depressing the foot (pointing the
toes)
Hands – flexion of the hands.

SUPINATION
Turning backward
Forearm rotates laterally so that palm face anteriorly.

PRONATION
Turning forward
FLEXION Forearm rotates medially so that palm face posteriorly.
Decrease the angle of the joint and bring two bones
together. SUPINATION
“Hinge joint” - bending The saddle joint between the metacarpal 1 and the carpal
allows opposition of the thumb.
EXTENSION
Movement to increase the angle or distance between two
bones R. Interaction of Skeletal Muscle in the
body
ABDUCTION Muscle groups produce an opposite movement on the
Moving a limb away (from midline) ;fingers and toes opposite side of the joint
spread apart Produces smooth, smooth, and coordinated movement.

ADDUCTION PRIME MOVERS:
Moving of a limb toward the midline. ○ Responsible for the causing a particular movement

ROTATION ANTAGONIST:
○ Muscle that oppose or reverse the movement
Movement of a bone around its longitudinal axis Example:
○ STRETCHED AND RELAXED- When prime mover is
ball and socket joint, movement of atlas around the dens
active.
CIRCUMDUCTION
SYNERGIST:
Combination of flexion, extension, abduction adduction
○ Help prime mover by producing the same movement
Example: ball and socket joint (shoulder); Proximal end is
or by reducing movement
stationary and its distal end moving is circle.
○ Example: Finger flexor muscle of both wrist and the
finger joint

FIXATOR:
○ Specializes synergist

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 ○ Stabilize the origin of a prime mover so all the tension 2. CONVERGENT
can be used to move to move the insertion bone Fascicles converge toward a single insertion tendo
○ Example: Pectoralis major
S. Names of Skeletal Muscle
3. PARALLEL
DIRECTION OF THE MUSCLE FIBER Length of the fascicles run parallel to the long axis of the
➔ Reference to imaginary line (Midline or Long axis) muscle
RECTUS – straight, muscle fiber runs parallel to the ○ Example: Sartorius muscle
imaginary line
○ Example: rectus femoris (straight muscle of the thigh 4. PENNATE
/femur) Short fascicle attached obliquely to the central TENDON.
OBLIQUE – muscle runs obliquely (slant) ○ Example: Extensor digitorum (leg muscle)
○ Fascicle insert into only one side of the tendon and
RELATIVE SIZE OF THE MUSCLE muscle
MAXIMUS – Largest (Gluteus maximus)
MINIMUS – Smallest 5. BIPENNATE
LONGUS - Long Fascicle insert into OPPOSITE site or from several
different sides.
NUMBER OF ORIGIN
BIceps – TWO origins 6. FUSIFORM
○ Example; Biceps muscle of arm has two heads Spindle-shaped muscle with an EXPANDED belly
TRIceps – THREE Origin (midsection)
QUADriceps – FOUR Origin ○ Example: Biceps brachii

LOCATION OF THE MUSCLES ORIGIN AND INSERTION U. Muscles of the Face
Example: STERNOCLEIDOMASTOID MUSCLE 1. Frontalis
○ Origin: STERNUM and CLAVICLE(Cleido) 2. Corrugator
○ Insertion: Mastoid process 3. Procerus
4. Depressor supercilli
SHAPE OF THE MUSCLE 5. Orbicularis oculi (superior lateral)
Deltoid - Triangular 6. Orbicularis oculi (lateral)
○ Example: Deltoid muscle 7. Nasalis
8. Levator labii superioris alaeque nasi
ACTION OF THE MUSCLE 9. Levator labii superioris
ACTION – Flexor, Extensor and Adductor. 10. Zygomaticus minor
○ Example: Adductor muscle of the thigh – 11. Zygomaticus major
ADDUCTION 12. Orbicularis oris
○ Extensor muscle of the wrist - EXTENSOR 13. Buccinator
14. Risorius
T. Arrangement of Fascicles 15. Masseter
16. Depressor anguli oris
17. Depressor labii inferioris
18. Platysma
19. Mentalis

1. CIRCULAR
Arrange in concerntric rings
Usually found surrounding external body opening which
closes by contraction.
○ Example: Orbicularis muscle surrounding the eyes
and mouth.

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 Orbicularis oculi (Superficial muscle of expression)
Thin, flat sphincter muscle of eyelid; surrounds the rim of
the orbit.

ORIGIN Frontal bone,

maxilla

medial palpebral ligament

lacrimal bone

INSERTION Lateral palpebral raphe

V. Muscles of the Head superior and inferior tarsi medial

Occipitofrontalis (Epicranius) ACTION Blinks and closes eyelids
Bipartite muscle consisting of the frontal and occipital
bellies connected by the epicranial aponeurosis. NERVE Facial Nerve
Muscle of the Scalp SUPPLY
Covers forehead and dome of the skull; no bony
attachment.
Orbicularis oris
ANTERIOR SCALP: FRONTALIS (FRONTAL BELLY) Encircles the mouth, muscle of facial expression.
Kissing and whistling muscle
ORIGIN INSERTION ACTION NERVE
SUPPLY
ORIGIN Mandible and maxilla
Epicranial Skin of Raises the Facial nerve
aponeurosis eyebrow and eyebrow, INSERTION Sphincter-like muscle at the angle of the
root of nose wrinkles mouth
forehead
horizontally ACTION superficial = closes, protrudes lips;

deep = presses lip against teeth

POSTERIOR (SCALP) BELLY: OCCIPITALIS NERVE Facial Nerve
➔ Overlies posterior occiput; by pulling on the epicranial SUPPLY
aponeurosis, fixes origin of frontal belly.
W. Muscle of Mastication
ORIGIN INSERTION ACTION NERVE Temporalis
SUPPLY
Fan-shaped muscle that covers parts of the temporal,
frontal, and parietal bones
Occipital bone Galea Pulls scalp Facial nerve
and temporal aponeuronica posteriorly
bone ORIGIN Temporal fossa

Temporal fascia

INSERTION Coronoid process

anterior ramus of mandible

ACTION Closes Jaw

Elevates and retracts the mandible against
maxilla with great force

NERVE Trigeminal Nerve
SUPPLY

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Masseter Levator labii Superioris
Powerful muscle that covers lateral aspect of the Thin muscle between orbicularis oris and inferior eye
mandibular ramus. margin
Superficial muscle of mastication
ORIGIN Zygomatic bone and infraorbital margin of
maxilla
ORIGIN Temporal bone
INSERTION Skin and muscle of upper lip
INSERTION Ramus of mandible
ACTION Opens lips; raises and furrows upper lip
ACTION Raises the mandible against the maxilla with
great force NERVE Facial Nerve
SUPPLY
NERVE Trigeminal nerve
SUPPLY (Cranial Nerve V)
Depressor labii inferioris
Small muscle running from mandible to lower lip

Buccinator ORIGIN Body of the mandible lateral to its midline
Thin, horizontal cheek muscle; principal muscle of the
cheek; deep to masseter INSERTION Skin and muscle of the lower lip

ORIGIN molar region of maxilla and mandible ACTION raws lower lip inferiorly (pout)

NERVE Facial Nerve
INSERTION Orbicularis Oris SUPPLY

ACTION Compresses cheek (as in whistling and Depressor anguii oris
sucking,draws corner of mouth laterally Small muscle running from mandible to lower lip
ORIGIN Body of mandible below incisors

NERVE Facial Nerve INSERTION Skin and muscle at angle of mouth below
SUPPLY insertion of zygomaticus

Zygomaticus ACTION Draws corners of mouth down and laterally
Muscle pair extending diagonally from cheekbone to (a”tragedy mask” grimace); zygomaticus
corner of mouth antagonist)

ORIGIN Zygomatic Bone NERVE Facial Nerve
SUPPLY
INSERTION Skin and muscle at the corner of the mouth

ACTION Raises lateral corners of mouth upward X. Eye Muscles
(smiling muscle) ‘ Superior rectus
Upgaze, upward; with some contribution – inferior oblique
NERVE Facial Nerve Rotate medially
SUPPLY
Lateral rectus
Outward, toward the ear
Risorius
Slender muscle inferior and lateral to zygomaticus Superior oblique
Rotate medially
ORIGIN Lateral Fascia associated with masseter
muscle Inferior rectus
Down gaze, downward; with some contribution – superior
INSERTION Skin at angle of mouth oblique
Rotate laterally
ACTION Draws corner of lip laterally; tenses lips;
synergist of zygomaticus Medial rectus
Inward, toward the nose
NERVE Facial Nerve
SUPPLY Inferior oblique
Rotate laterally

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 Y. Muscles of the Neck SPLENIUS CAPITIS
Muscles that moves the head and shoulder girdle
➔ Intrinsic muscle of the spine
PLATYSMA ➔ Classified with posterior triangle of the neck
➔ Vertebral column and head movements
➔ Unpaired, thin, sheetlike superficial neck muscle; not
strictly a head muscle, but plays a role in facial expression
➔ A single sheet-like muscle that covers the anterolateral ORIGIN Lower half of ligamentum nuchae and
neck spinous process of 7th cervical vertebra –
3rd or 4th thoracic vertebra

ORIGIN fascia of chest (over pectoral muscles and INSERTION Mastoid process of temporal bone and
deltoid) occipital bone

ACTION ○ Supports head erection
INSERTION Lower margin of mandible, and skin and ○ Draws head directly backwards
muscle at corner of mouth ○ Draws head to one side
○ Slight rotation, turning face to same side
ACTION Tenses skin of neck (as during shaving);
helps depress mandible; pulls lower lip back NERVE Cervical spinal nerve
and down, producing downward sag of SUPPLY
mouth; “Sad Clown Face”

NERVE Facial Nerve Z. Muscles of the Trunk
SUPPLY ➔ Muscles that moves the:
Vertebral column (Posterior anti-gravity muscle)
Anterior Thorax (ribs, head and arms)
STERNOCLEIDOMASTOID Abdominal wall – moves the vertebral column

➔ Neck muscle classified with lateral cervical muscles ANTERIOR MUSCLES
➔ Arises from two heads, responsible for movements of the
vertebral column and head. Pectoralis Major
Anterior shoulder joint muscles forming the shoulder girdle
Fan-shaped
ORIGIN Sternum and clavicle
Three heads:
○ Clavicular
○ Sternocostal
INSERTION Lateral surface of the mastoid process;
○ Abdominal
nuchal line of occipital bone
Pectoralis Major
ACTION Draws head towards shoulder of same side,
rotates head to opposite side, flexes cervical ORIGIN Sternum, clavicle and first to sixth ribs
part, assist in elevating the thorax

INSERTION Proximal humerus
NERVE Accessory nerve (cranial nerve XI) and
SUPPLY branches of cervical spinal nerves C2 and C3 ACTION Adducts and flexes the humerus
(ventral rami)
Intercostal Muscles
SCALENES
Located more laterally than anteriorly on neck; deep to External intercostals
platysma and sternocleidomastoid. Muscles of thorax from tubercles of the ribs behind to the
cartilages of the ribs in front.
Fibers are directly obliquely downwards and laterally on
ORIGIN Transverse processes of cervical vertebrae
the back of the thorax, and downward, forward and medial
ward to the front
INSERTION anterolaterally on first two rib
ORIGIN lower border of ribs 1-11
ACTION Elevate first two ribs (aid in inspiration); flex
and rotate neck
INSERTION Upper border of ribs below 2- 12
NERVE Cervical spinal nerve
SUPPLY ACTION Elevates the ribs, aiding in normal inspiration
(Inhalation)

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Internal intercostals Rectus abdominis
Muscles of the thorax, from sternum to vertebral column. Most SUPERFICIAL muscle of the abdomen
Fibers are directed obliquely and pass in a direction Long, flat, paired strap-like muscle of the abdomen
opposite of the external intercostals Extends the length of front of abdomen (From the pubis to
the rib cage enclosed in a aponeurosis)
FLEX the vertebral column
ORIGIN Superior border of 2nd – 12th rib
Separated by the linea alba
“abdominal muscle” or “abs”
Compress the abdominal content during defecation and
INSERTION inferior border of the ribs above 1-11 childbirth / Forceful breathing
ACTION Depresses the ribs, aids in forced expiration ORIGIN Crest of the pubis and pubic tubercle; front of
pubis symphysis
Diaphragm
Muscles of the thorax INSERTION Crest of the pubis and pubic tubercle; front of
Dome-shaped, musculofibrous septum pubis symphysis
Separate thoracic & abdominal cavities
Principal muscle of inspiration ACTION Flexes vertebral column
Tenses abdominal wall
Compresses abdominal viscera
ORIGIN Xiphoid process, cartilages of ribs 7-12,
anterior surface of the lumbar vertebrae, Internal Oblique
crura of the upper two (left crus) and three Paired muscle deep to the external obliques.
(right crus) lumbar vertebrae Fibers run at right angle to those of the external oblique.
Thinner and smaller than external oblique
ARISES from the iliac crest and INSERT into the last three
INSERTION Central tendon that blends with the anterior ribs.
longitudinal ligament of the vertebral column
ORIGIN Lateral half of the inguinal ligament, middle
ACTION Expands the thoracic cavity Compresses the lip of the iliac crest; and lumbodorsal for
abdominal cavity thoracolumbar fascia

MUSCLES OF THE ABDOMINAL WALL INSERTION Pubis, inferior border of the lower 3 or 4 ribs
External oblique (9, 10-12), linea alba; aponeurosis fus
Rectus abdominis
Internal oblique ACTION Bilaterally: compresses the abdominal
Transverse abdominis viscera; flexes the spine
Unilaterally: laterally flexes and rotates
★ Reinforces body trunk – contain and protect the spine to same side
abdominal contents
★ Muscle fibers forms a pair that runs in different direction
★ Exceptionally strong for its THICKNESS Transverse Abdominis
Arises from the lower ribs and iliac crest into the pubis
External Oblique “transverse” direction of the fibers
Situated at the lateral and anterior part of the abdomen Most internal of flat muscles
Fibers run downward and medially from the last eight ribs Located deep to the internal oblique
and insert in the ilium Fibers run horizontally across the abdomen
Largest and most superficial of the three flat muscles Muscle compresses the abdominal content.
FLEXES the vertebral column, ROTATES the trunk and
bend it LATERALLY ORIGIN Lateral third of the inguinal ligament, inner lip
of iliac crest, inner surface of the cartilages of
ORIGIN Sternum, external surfaces and inferior the lower 6 ribs, lumbodorsal (thoracolumbar)
border of lower eight ribs (5-12) fascia and interdigitating with diaphragm

INSERTION Pubis, line alba via an aponeurosis and the INSERTION Ends in an aponeurosis; upper ¾ forms the
iliac crest back of the rectus sheath and insert on the
linea alba; the lower 4 th forms the front of
ACTION Bilaterally: compresses the abdomen and the rectus sheath and attaches to the pubis
flexes the spine
Unilaterally: laterally flexes the trunk to ACTION Compresses abdominal visceral tenses
same side; rotate trunk to opposite side abdominal wall

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 POSTERIOR MUSCLES
ORIGIN Iliac crest, lumbar fascia
Trapezius
Most superficial muscle of posterior thorax; flat and
triangular in shape; upper fibers run inferiorly to scapula; INSERTION Transverse process of upper lumbar
middle fibers run horizontally to scapula; lower fibers run vertebrae
superiorly to scapula
ACTION Flexes spine laterally; extend spine
ORIGIN Occipital bone, and all cervical and thoracic
vertebrae
III. THE MUSCULAR SYSTEM (UPPER AND
LOWER LIMB)
INSERTION Lateral third of clavicle, acromion and
scapular spine of scapula A. Prime Movers of the Arm
Pectoralis major
ACTION Raises, retracts and rotates scapula Latissimus Dorsi
Deltoid Muscles of the Humerus
NERVE Accessory nerve (cranial nerve XI); C3 and Biceps Brachii
SUPPLY C4 Brachialis
Brachioradialis
Triceps Brachii
Latissimus Dorsi
Two large flat muscle that covers the lower back Deltoid
Two large flat muscle covering the lumbar region and “delta” – triangular
lower half of the thoracic region Thick, multipennate muscle forming rounded shoulder
Function include joining the upper limb with the axial muscle mass
skeleton and facilitate motion of upper limb (example: Common site for intramuscular injection
swimming striking a blow)
ORIGIN Lower spine and iliac crest ORIGIN Lateral third of the clavicle; acromion;
scapular spine

INSERTION Proximal humerus
INSERTION Deltoid tuberosity of the lateral side of the
ACTION Extend and adducts the humerus body of the humerus

Erectore Spinae ACTION Prime mover of arm abduction when all its
Group of prime movers of back fibers contract simultaneously
Paired muscle – deep muscle
Composite muscle Antagonist of pectoralis major and latissimus
○ Longissimus dorsi which adduct the arm.
○ Iliocostalis
○ Spinalis Synergist of pectoralis major
Power back extensor (“erectors”) – provides resistance of
bending over the waist. ✔Anterior fibers are active - act powerfully in
Common cause of lower back pain flexing and rotating humerus medially.

ORIGIN Lower spine and iliac crest Ribs 2-3 and ✔ Posterior fibers are active - extension and
vertebrae lateral rotation of arm

Flexion and medial rotation of humerus
INSERTION Ribs, thoracic and cervical vertebrae
Abduction of the humerus
ACTION Raises, retracts and rotates scapula
Extension and lateral rotation of the humerus
NERVE Extend and laterally flexes spine
SUPPLY Nerve Axillary nerve (C5 and C6)
Supply
Quadratus Lumborum
Forms part of the posterior abdominal wall Biceps Brachii
Separately, each muscle FLEXES the spine LATERALLY. Two-headed fusiform muscle
Collectively, EXTEND the lumbar spine. Bellies unite at insertion point is approached
Arises from the iliac crest and insert into the upper lumbar Tendon of long head helps stabilize shoulder join
vertebrae. Anterior flexor muscles of the elbow joint (powerful prime
mover for flexion of forearm)

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 Bulges when the elbow flexes
Long head and short head Triceps Brachii
The only muscle fleshing out of the posterior humerus
Large upper limb muscle, posterior muscle of the elbow
ORIGIN Short head: coracoid process
joint
Situated at the back of the arm, extends the entire length
Long head: supraglenoid tubercle and lip of
of the dorsal surface of humerus
glenoid cavity.
Powerful prime mover of elbow EXTENSION
(ANTAGONIST of Biceps Brachii)
Three head:
INSERTION Deltoid tuberosity of the lateral side of the ○ Lateral head
body of the humerus ○ Long head
○ Medical head
Proximal radius “BOXERS” MUSCLE
ACTION Flexion and medial rotation of humerus
ORIGIN Long head: infraglenoid tubercle of scapula
Abduction of the humerus
Lateral head: posterior shaft of humerus
Extension and lateral rotation of the humerus
Medial head: posterior humeral shaft distal to
Nerve Musculocutaneous nerve (C5 and C6 radial groove
Supply

INSERTION Olecranon process of the ulna
Brachialis
Strong muscle that is immediately deep to biceps brachii ACTION Powerful forearm extensor (prime mover,
on distal humerus particularly medial head)
Flexor muscle of the elbow
Covers front of the elbow joint and lower half of the Antagonist of forearm flexors; long and
humerus lateral heads mainly active in extending the
forearm against resistance
ORIGIN Front of distal humerus; embraces insertion
of deltoid muscle Long head tendon may help stabilize
shoulder joint and assist in arm adduction

INSERTION Coronoid process of ulna and capsule of
elbow joint. B. Muscles that Moves the Forearm

ACTION A major forearm flexor (lifts ulna as biceps Pronator teres
lifts the radius) pronation = turning palm posteriorly, or down teres = round
Two-headed muscle; seen in superficial view between
Nerve Musculocutaneous nerve proximal margins of brachioradialis and flexor carpi
Supply radialis
Forms medial boundary of cubital fossa.
Brachioradialis
Superficial muscle of lateral forearm; forms lateral Pronator teres
boundary of cubital fossa; extends from distal humerus to
distal forearm ORIGIN medial epicondyle of humerus; coronoid
process of ulna
ORIGIN Lateral supracondylar ridge at distal end of
humerus
INSERTION Common tendon into lateral radius, midshaft

INSERTION Base of radial styloid process ACTION Pronates forearm; weak flexor of elbow

ACTION Synergist in flexing forearm

Acts to best advantage when forearm is
partially flexed and semi pronated

Stabilizes elbow during rapid flexion and
extension

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Flexor carpi radialis
flex = decrease angle between two bones carpi = wrist Flexor Digitorum Superficialis
radi = radius digit = finger, toe superficial = close to surface)
Runs diagonally across forearm; midway, its fleshy belly is Two-headed muscle; more deeply placed (therefore,
replaced by a flat tendon that becomes cordlike at wrist actually forms an intermediate layer)
Overlain by muscles above but visible at distal end of
forearm
Flexor carpi radialis

ORIGIN medial epicondyle of humerus Flexor Digitorum Superficialis

ORIGIN medial epicondyle of humerus, coronoid
INSERTION Base of second and third metacarpals; process of ulna; shaft of radius
insertion tendon easily seen and provides
guide to position of radial artery at wrist
(pulse taking) INSERTION four tendons into middle phalanges of fingers
2–5
ACTION Powerful flexor of wrist; abducts hand; weak
synergist of elbow flexion ACTION Flexes wrist and middle phalanges of fingers
2–5
Nerve Median Nerve
Supply Nerve Median nerve (C7, C8, and T1)
Supply
Palmaris longus
Palma = palm Longus = long
Small fleshy muscle with a long insertion tendon; often Flexor pollicis longus
absent; may be used as guide to find median nerve that “flek·sr paa·luh·sis laang·guhs”
lies lateral to it at wrist pollix = thumb
Partly covered by flexor digitorum superficialis; parallels
flexor digitorum profundus laterally
Palmaris longus

ORIGIN medial epicondyle of humerus Flexor pollicis longus

ORIGIN anterior surface of radius and interosseous
INSERTION palmar aponeurosis; (fascia of palm) membrane

ACTION Tenses skin and fascia of palm during hand
movements; weak wrist flexor; weak INSERTION distal phalanx of thumb
synergist for elbow flexion
ACTION Flexes distal phalanx of thumb
Nerve Median Nerve
Supply
Flexor digitorum profundus
Flexor carpi ulnaris profound = deep
Most medial muscle of this group Extensive origin; overlain entirely by flexor digitorum
Two-headed superficialis
Ulnar nerve lies lateral to its tendon
Flexor digitorum profundus
Flexor carpi ulnaris
ORIGIN coronoid process, anteromedial surface of
ORIGIN Medial epicondyle of humerus; olecranon ulna, and interosseous membrane
and posterior surface of ulna.

INSERTION four tendons into distal phalange
INSERTION Pisiform and hamate bones and base of fifth
metacarpal ACTION Flexes distal interphalangeal joints; slow
acting flexor of any or all fingers; helps flex
ACTION Flexes wrist and abducts hands wrist

Nerve Ulnar nerve (C7 and C8)
Supply

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Pronator quadratus Extensor carpi digitorum
quad = square, four-sided Lies medial to extensor carpi radialis brevis
Deepest muscle of distal forearm; passes downward and Detached portion of this muscle, called extensor digiti
laterally minimi, extends little finger
Only muscle that arises solely from ulna and inserts solely
into radius
Extensor carpi digitorum

Pronator quadratus ORIGIN Distal humerus

ORIGIN distal portion of anterior ulnar shaft
INSERTION Distal phalanges of second to fifth fingers

INSERTION distal surface of anterior radius ACTION Extend fingers

ACTION Prime mover of forearm pronation; acts with
pronator teres; also helps hold ulna and Extensor carpi ulnaris
radius together Most medial of superficial posterior muscles; long, slender
muscle

Extensor carpi radialis longus Extensor carpi ulnaris
extend = increase angle between two bones
Parallels brachioradialis on lateral forearm. ORIGIN Lateral epicondyle of humerus and posterior
border of ulna

Extensor carpi radialis longus
INSERTION Base of fifth metacarpal
ORIGIN Lateral supracondylar ridge of humerus
ACTION Extends wrist in conjunction with extensor
carpi radialis and adducts wrist in conjunction
INSERTION Base of second metacarpal with flexor carpi ulnaris

ACTION Extends wrist in conjunction with extensor
carpi ulnaris and abducts wrist in conjunction Rhomboids
with flexor carpi radialis
Rhomboids
Extensor carpi radialis brevis
brevis = short ORIGIN Spinous processes of C7 and T1 (minor) and
Shorter than extensor carpi radialis longus and lies deep spinous processes of T2–T5 (major)
to it

INSERTION Medial border of scapula
Extensor carpi radialis brevis
ACTION Stabilize scapula; act together (and with
ORIGIN lateral epicondyle of humerus middle trapezius fibers) to retract (adduct)
scapula

INSERTION base of third metacarpal Assist trapezius in downward rotation of
scapula
ACTION Extends and abducts wrist; acts
synergistically with extensor carpi radialis Adduction of scapula
longus to steady wrist during finger flexion