INTEGUMENTARY SYSTEM
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Transcript INTEGUMENTARY SYSTEM
MUSCULAR SYSTEM
Bio 221
REVIEW OF MUSCLE
TISSUE
Muscle tissue contracts in response to
stimulation
3 types of muscle tissue:
- Skeletal
- Cardiac
- Smooth
REVIEW OF MUSCLE TISSUE
continued
Skeletal Muscle
Characteristics:
- Cylindrical cells
- Striated
- Multiple, peripheral
nuclei
- Voluntary
- Attached to skeleton
REVIEW OF MUSCLE
TISSUE continued
Cardiac Muscle
Characteristics:
- Branching cells
- Striated
- One or two central
nuclei
- Involuntary
- Heart
REVIEW OF MUSCLE
TISSUE continued
Smooth Muscle
Characteristics:
-
Spindle-shaped cells
Non-striated
Single, central nucleus
Involuntary
Located in the walls of
hollow organs
FUNCTIONS OF SKELETAL
MUSCLE
Produces voluntary movement
- Locomotion
- Manipulation
- Assists in breathing, eating, speech, support
of organs
- With nervous system, generates reflexes
- Provides facial expressions
Stabilizes joints
Maintains posture
Produces body heat
CHARACTERISTICS OF SKELETAL
MUSCLE
Makes up “flesh” of body (~40% by
weight)
Most “meat” is skeletal muscle
Muscles are organs
- Fibers (muscle cells)
- Motor neurons
- Blood vessels
- Connective tissue
ARRANGEMENT OF SKELETAL
MUSCLE
Connective tissue coverings provide
strength & support
- Endomysium: Around each muscle fiber
- Perimysium: Around fascicles (bundles
of cells)
- Epimysium: Around entire muscle
(bundles of fascicles)
- Fascia: connective tissue around &
between muscles
ATTACHMENTS OF SKELETAL
MUSCLE
Connective tissue attachments join
muscles to bones, to cartilages, or to CT
coverings of other muscles
- Tendons - cordlike bundles of
collagen fibers
- Aponeuroses (sing. -sis) - sheetlike
arrangements of collagen fibers
Skeletal Muscles Cells are Different
Fibers (skeletal muscle cells):
- Long, cylindrical, multinucleate
Sarcolemma: cell membrane
Sarcoplasm: cytoplasm
Numerous mitochondria
Sarcoplasmic Reticulum (SR): Smooth
E.R., stores Ca2+
MICROSCOPIC ANATOMY
OF A MUSCLE CELL
Myofibrils are Contractile
Organelles
Myofibrils
- Contractile organelles
- Lie parallel to one another
- Run entire length of cell
- Composed of Myofilaments
(Protein)
*Actin – Thin myofilament
*Myosin – Thick myofilament
Myofilaments
Thick myofilament
- Myosin heads free, project out from ends
- Myosin tails attached, central
- Myosin heads can attach to actin, forming
crossbridges
Myofilaments
Thin myofilament
- Actin & regulatory proteins
* Tropomyosin
Covers sections of actin
* Troponin
Attaches to actin & tropomyosin
Binding site for Ca2+
Myofibrils are composed of
Sarcomeres
Sarcomeres:
- Contractile units of myofibrils
- Source of fiber’s striations
- Banding caused by arrangement of
myofilaments (Actin & Myosin)
Thin & Thick Myofilaments
Sarcomere Anatomy
A (Dark) bands: correspond to length of
myosin filaments
I (Light) bands: actin (no myosin)
Z line: anchor for actin; separates
sarcomeres
H zone: center of A band; no actin
M line: Narrow region at center of H zone;
anchor for myosin
Stimulation of Fibers
Fibers must be stimulated to contract
Motor Neurons deliver the stimulus
Point of communication between a motor
neuron and a fiber = Neuromuscular
Junction (NMJ)
Fibers & Motors Neurons do not touch
Neurotransmitter molecules directly
stimulate muscle fibers
Structure of Neuromuscular
Junction (NMJ)
Axon Terminal – end of motor neuron
Synaptic Cleft (Gap) – space between
axon terminal & sarcolemma
Motor End Plate:
*Sarcolemma at NMJ
*Invaginated
*High SA (surface area)
*ACh (neurotransmitter) Receptors
STEPS IN CONTRACTION
Sliding Filament Theory
Nerve Impulse arrives at axon terminal
Exocytosis of synaptic vesicles
Neurotransmitter Acetylcholine (ACh)
diffuses across cleft
ACh binds to receptors on sarcolemma
Prior to contraction, sarcolemma must be
polarized (+ outside/- within)
Sarcolemma now permeable to Na+ and K+
(depolarizes)
STEPS IN CONTRACTION
Sliding Filament Theory
Na+ diffuses into fiber
SR release Ca2+ into sarcoplasm
Ca2+ binds to troponin on actin
Tropomyosin on actin moves, exposing
binding site
Myosin heads attach to actin, form crossbridges & pivot
STEPS IN CONTRACTION
Sliding Filament Theory
Actin slides towards center of
sarcomere
ATP provides energy to release & recock myosin heads
Relaxation occurs from:
- Cholinesterase breaks down ACh at
NMJ
- Ca2+ actively pumped back into SR
ACTIVITY OF SINGLE
FIBERS (CELLS)
“All-or-None” Law: At threshold, a fiber
will contract to its maximum extent
- No “partial” contractions of individual
fibers
- Increasing stimulus strength has no
additional effect
Single nerve impulse produces one
contraction
ACTIVITY OF MOTOR UNITS
A muscle is composed of motor units
Motor Unit: a motor neuron + all the
fibers it controls
Number of fibers varies (2-2000)
Each motor unit responds independently
All muscle cells in a motor unit respond
maximally, or they don’t respond at all
ACTIVITY OF MOTOR
UNITS
Strength of contraction is determined by
number of motor units stimulated
Recruitment: Process of increasing the
number of motor units responding
Strength increases as number of motor
units increases
ACTIVITY OF WHOLE
MUSCLES
Skeletal muscles are capable of Graded
Responses
Different degrees of shortening occur by:
- Changing the number of motor units
activated
- Changing frequency of stimulation
Different Types of Muscle Fibers
Red Slow (Slow Oxidative)
White Fast (Fast Glycolytic)
Intermediate (Fast Oxidative-Glycolytic)
Types of Muscle Fibers
Red Slow
-
Fewer myofibrils, weaker
Lots of myoglobin, mitochondria, capillaries
Needs oxygen to make ATP
Contracts slowly; fatigues slowly
Endurance
Types of Muscle Fibers
Types of Muscle Fibers
White Fast
- Most myofibrils, strongest
- Low myoglobin, fewer mitochondria &
capillaries
- Makes ATP without oxygen
- High glycogen stores
- Contracts rapidly, fatigues rapidly
- Short-term powerful movements
- May hypertrophy in response to training
Types of Muscle Fibers
Intermediate
-
Intermediate diameter/number of myofibrils
Lots of myoglobin, mitochondria, capillaries
Can make some ATP without oxygen
Contracts rapidly, moderately resistant to
fatigue
- Walking, jogging, biking over short to
moderate distances
EFFECTS OF EXERCISE
Skeletal muscle cells do not undergo
mitosis
Exercise does not increase the number of
skeletal muscle cells
Hypertrophy: Enlargement of muscle
cells due to exercise
- The number of actin and myosin
myofilaments increases
- Mitochondria increase
- Blood supply increases
EFFECTS OF LACK OF
EXERCISE
Atrophy: Decrease in the size of muscle
cells due to lack of use
- The number of actin and myosin
myofilaments decreases
- Mitochondria decrease
- Blood supply decreases
BODY MOVEMENTS
Produced by contraction of skeletal muscle
Shortening of a skeletal muscle resulting in
movement of attachments
Movement depends on joint, attachments
Skeletal muscles have at least two
attachments
- One attachment is relatively immobile
- The other attachment is more mobile
BODY MOVEMENTS :
MUSCLE ATTACHMENTS
Origin: Less movable attachment
Insertion: More movable attachment
Action: What the muscle “does”
- Moves insertion toward origin
- The “movement” produced
Types of Ordinary Body
Movements
Flexion – decreases angle between bones
Extension – increases angle between bones
Rotation – movement around an axis
Abduction – moves appendage away from
midline
Adduction – moves appendage toward midline
Circumduction – moves appendage in a circle
around joint
Copyright © 2003 Pearson Education, Inc. publishing as Benjamin Cummings
Slide 6.32
Body Movements
Figure 6.13
Copyright © 2003 Pearson Education, Inc. publishing as Benjamin Cummings
Slide 6.33
BODY MOVEMENTS:
MUSCLE GROUPS
Prime mover: Muscle primarily
responsible for an action
Antagonist: Muscle(s) that resist prime
mover, or move opposite to it
Synergist: Muscle(s) that assist(s) prime
mover
NAMING SKELETAL
MUSCLES: CRITERIA
Muscle attachments: Origin and/or insertion
(e.g. sternocleidomastoid)
Muscle action (Adductor magnus)
Direction of muscle fibers (Rectus abdominis)
Location of muscle (Temporalis)
Size of muscle (Gluteus maximus)
Number of origins/heads (Biceps brachii)
Shape of muscle (Deltoid)