NERVOUS SYSTEM - DRAFT - flores - anaphy - finals (1) PDF

Summary

This document covers the nervous system, including its functions, structural and functional classifications, and the different types of cells involved. It details the sensory, motor, and integrative functions, and also introduces different types of neurons and their roles. Key topics such as nerve impulses and synapses are addressed within the document.

Full Transcript

NERVOUS SYSTEM NERVOUS TISSUE: SUPPORT CELLS
FUNCTIONS OF THE NERVOUS SYSTEMS Support cells in the CNS are grouped together as
“neuroglia”
Sensory input—gathering information
General functions
To monitor changes occurring inside and
outside the body Support
Changes = stimuli Insulate
Protect neurons
Integration

To process and interpret sensory input and
decide if action is needed Astrocytes
Motor output - Abundant, star-shaped cells
- Brace neurons
A response to integrated stimuli - Form barrier between capillaries and
The response activates muscles or glands neurons
STRUCTURAL CLASSIFICATION OF THE - Control the chemical environment of the
NERVOUS SYSTEM brain

Central nervous system (CNS) Microglia

- Organs - Spiderlike phagocytes
Brain - Dispose of debris
Spinal cord
- Function
Integration; command center Ependymal cells
Interpret incoming sensory - Line cavities of the brain and spinal cord
information - Cilia assist with circulation of cerebrospinal
Issues outgoing instructions fluid
Peripheral nervous system (PNS)
- Nerves extending from the brain and spinal
cord
Spinal nerves—carry impulses to
and from the spinal cord Oligodendrocytes
Cranial nerves—carry impulses to
and from the brain - Wrap around nerve fibers in the central
- Functions nervous system
Serve as communication lines - Produce myelin sheaths
among sensory organs, the brain
and spinal cord, and glands or
muscles Satellite cells
FUNCTIONAL CLASSIFICATION OF THE - Protect neuron cell bodies
PERIPHERAL NERVOUS SYSTEM - Schwann cells
- Form myelin sheath in the peripheral
Sensory (afferent) division
nervous system
- Nerve fibers that carry information to the
central nervous system
NERVOUS TISSUE
Motor (efferent) division
: NEURONS
- Nerve fibers that carry impulses away from
the central nervous system Neurons = nerve cells
two subdivisions - Cells specialized to transmit messages
- Major regions of neurons
- Somatic nervous system = voluntary
Cell body—nucleus and metabolic
Consciously controls skeletal
center of the cell
muscles
Processes—fibers that extend from
- Autonomic nervous system = involuntary
the cell body
Automatically controls smooth and
cardiac muscles and glands Cell body
Further divided into the sympathetic
and parasympathetic nervous Nissl bodies
systems - Specialized rough endoplasmic reticulum
Neurofibrils
- Intermediate cytoskeleton
- Maintains cell shape
 Nucleus with large nucleolus Sensory (afferent) neurons
- Carry impulses from the sensory receptors
to the CNS
- Cutaneous sense organs
- Proprioceptors—detect stretch or tension
Motor (efferent) neurons
- Carry impulses from the central nervous
system to viscera, muscles, or glands

Processes outside the cell body
- Dendrites—conduct impulses toward the
cell body
Neurons may have hundreds of dendrites a. Free nerve endings (pain and temperature
- Axons—conduct impulses away from the receptors)
cell body b. Meissner’s corpuscle (touch receptor)
Neurons have only one axon arising from c. Lamellar corpuscle (deep pressure
the cell body at the axon hillock receptor)
d. Golgi tendon organ (proprioceptor)
Axons e. Muscle spindle (proprioceptor)
- End in axon terminals Interneurons (association neurons)
- Axon terminals contain vesicles with
neurotransmitters - Found in neural pathways in the central
- Axon terminals are separated from the next nervous system
neuron by a gap - Connect sensory and motor neurons
Synaptic cleft—gap between adjacent STRUCTURAL CLASSIFICATION OF NEURONS
neurons
Synapse—junction between nerve Multipolar neurons—many extensions from the
cell body

Myelin sheath—whitish, fatty material
covering axons
Schwann cells—produce myelin sheaths in - All motor and interneurons are multipolar
jelly roll-like fashion around axons (PNS) - Most common structure
Nodes of Ranvier—gaps in myelin sheath
along the axon Bipolar neurons—one axon and one dendrite
Oligodendrocytes—produce myelin
sheaths around axons of the CNS
NEURON CELL BOODY LOCATION
- Located in special sense organs such as
- Most neuron cell bodies are found in the
nose and eye
central nervous system - Rare in adults
Gray matter—cell bodies and
unmyelinated fibers Unipolar neurons—have a short single process
Nuclei—clusters of cell bodies leaving the cell body
within the white matter of the central
nervous system
Ganglia—collections of cell bodies
outside the central nervous system
Tracts—bundles of nerve fibers in
the CNS
Nerves—bundles of nerve fibers in
the PNS - Sensory neurons found in PNS ganglia
White matter—collections of
myelinated fibers (tracts)
Gray matter—collections of mostly
unmyelinated fibers and cell bodies
FUNCTIONAL CLASSIFICATION OF NEURONS
FUNCTIONAL PROPERTIES OF NEURONS Repolarization
Irritability - Ability to respond to stimuli - Potassium ions rush out of the neuron after
sodium ions rush in, which repolarizes the
Conductivity - Ability to transmit an impulse
membrane
NERVE IMPULSES - Repolarization involves restoring the inside
of the membrane to a negative charge and
Resting neuron the outer surface to a positive charge
- The plasma membrane at rest is polarized
- Fewer positive ions are inside the cell than Repolarization. Potassium ions diffuse out of the
outside the cell cell as the membrane permeability changes again,
restoring the negative charge on the inside of the
Resting membrane is polarized. In the resting state, membrane and the positive charge on the outside
the external face of the membrane is slightly surface. Repolarization occurs in the same direction
positive; its internal face is slightly negative. The as depolarization.
chief extracellular ion is sodium (Na+), whereas the
chief intracellular ion is potassium (K+). The Repolarization
membrane is relatively impermeable to both ions.
- Initial ionic conditions are restored using the
sodium-potassium pump.
Depolarization - This pump, using ATP, restores the original
- A stimulus depolarizes the neuron’s configuration
membrane - Three sodium ions are ejected from the cell
- The membrane is now permeable to sodium while two potassium ions are returned to the
as sodium channels open cell
- A depolarized membrane allows sodium
Initial ionic conditions restored. The ionic
(Na+) to flow inside the membrane
conditions of the resting state are restored later by
Stimulus initiates local depolarization. A stimulus the activity of the sodium-potassium pump. Three
changes the permeability of a local "patch" of the sodium ions are ejected for every two potassium
membrane, and sodium ions diffuse rapidly into the ions carried back into the cell.
cell. This changes the polarity of the membrane (the
TRANSMISSION OF A SIGNAL AT SYNAPSES
inside becomes more positive; the outside becomes
more negative) at that site. 1. When the action potential reaches the axon
terminal, the electrical charge opens
Action potential calcium channels
2. Calcium, in turn, causes the tiny vesicles
- The movement of ions initiates an action containing the neurotransmitter chemical to
potential in the neuron due to a stimulus fuse with the axonal membrane
- A graded potential (localized depolarization) 3. The entry of calcium into the axon terminal
exists where the inside of the membrane is causes pore like openings to form, releasing
more positive and the outside is less the transmitter
positive 4. The neurotransmitter molecules diffuse
across the synapse and bind to receptors
Depolarization and generation of an action on the membrane of the next neuron
potential. If the stimulus is strong enough, 5. If enough neurotransmitter is released,
depolarization causes membrane polarity to be graded potential will be generated
completely reversed and an action potential is 6. Eventually an action potential (nerve
initiated. impulse) will occur in the neuron beyond the
synapse
Propagation of the action potential 7. The electrical changes prompted by
neurotransmitter binding are brief
- If enough sodium enters the cell, the action
8. The neurotransmitter is quickly removed
potential (nerve impulse) starts and is
from the synapse
propagated over the entire axon
- Impulses travel faster when fibers have a THE REFLEX ARC
myelin sheath
Reflex—rapid, predictable, and involuntary
Propagation of the action potential. Depolarization response to a stimulus
of the first membrane patch causes permeability Occurs over pathways called reflex arcs
changes in the adjacent membrane, and the events
described in step are repeated. Thus, the action Reflex arc—direct route from a sensory neuron, to
potential propagates rapidly along the entire length an interneuron, to an effector
of the membrane.
Somatic reflexes REGIONS OF THE BRAIN: CEREBRUM
- Reflexes that stimulate the skeletal muscles Cerebral Hemispheres (Cerebrum)
- Example: pull your hand away from a hot
- Paired (left and right) superior parts of the
object
brain
Autonomic reflexes - Includes more than half of the brain mass
- The surface is made of ridges (gyri) and
- Regulate the activity of smooth muscles, the
grooves (sulci)
heart, and glands
- Example: Regulation of smooth muscles, Lobes of the cerebrum
heart and blood pressure, glands, digestive
- Fissures (deep grooves) divide the
system
cerebrum into lobes
Five elements of a reflex: - Surface lobes of the cerebrum
Frontal lobe
Sensory receptor–reacts to a stimulus
Parietal lobe
Sensory neuron–carries message to the
Occipital lobe
integration center
Temporal lobe
Integration center (CNS)–processes
information and directs motor output
Motor neuron–carries message to an
effector
Effector organ–is the muscle or gland to be
stimulated
Specialized areas of the cerebrum
Two-neuron reflex arcs
- Primary somatic sensory area
- Simplest type Receives impulses from the body’s
- Example: Patellar (knee-jerk) reflex sensory receptors
Three-neuron reflex arcs Located in parietal lobe
- Primary motor area
- Consists of five elements: receptor, Sends impulses to skeletal muscles
sensory neuron, interneuron, motor neuron, Located in frontal lobe
and effector - Broca’s area
- Example: Flexor (withdrawal) reflex Involved in our ability to speak

CENTRAL NERVOUS SYSTEM (CNS)
- CNS develops from the embryonic neural
tube
The neural tube becomes the brain
and spinal cord
The opening of the neural tube
becomes the ventricles
Four chambers within the brain Cerebral areas involved in special senses
Filled with cerebrospinal fluid
Gustatory area (taste)
Visual area
Auditory area
Olfactory area
Interpretation areas of the cerebrum

Speech/language region
REGIONS OF THE BRAIN
Language comprehension region
- Cerebral hemispheres (cerebrum) General interpretation area
- Diencephalon
Layers of the cerebrum
- Brain stem
- Cerebellum - Gray matter—outer layer in the cerebral
cortex composed mostly of neuron cell
bodies
- White matter—fiber tracts deep to the gray
matter
Corpus callosum connects
hemispheres
- Basal nuclei—islands of gray matter buried
within the white matter
REGIONS OF THE BRAIN: DIENCEPHALON Reticular Formation
- Sits on top of the brain stem - Diffuse mass of gray matter along the brain
- Enclosed by the cerebral hemispheres stem
- Made of three parts: - Involved in motor control of visceral organs
Thalamus - Reticular activating system (RAS) plays a
Hypothalamus role in awake/sleep cycles and
Epithalamus consciousness

Thalamus
- Surrounds the third ventricle
- The relay station for sensory impulses
- Transfers impulses to the correct part of the
cortex for localization and interpretation
Hypothalamus
- Under the thalamus
- Important autonomic nervous system center
Helps regulate body temperature
Controls water balance REGIONS OF THE BRAIN: CEREBELLUM
Regulates metabolism
- Two hemispheres with convoluted surfaces
- Houses the limbic center for emotions
- Provides involuntary coordination of body
- Regulates the nearby pituitary gland
movements
Produces two hormones of its own
PROTECTION OF THE CENTRAL NERVOUS
Epithalamus
SYTEM
- Forms the roof of the third ventricle
- Houses the pineal body (an endocrine
gland)
- Includes the choroid plexus—forms
cerebrospinal fluid
REGIONS OF THE BRAIN: BRAIN STEM
- Attaches to the spinal cord
- Parts of the brain stem Scalp and skin
Midbrain Skull and vertebral column
Pons Meninges
Medulla Oblongata Cerebrospinal fluid (CSF)
Blood-brain barrier

Midbrain MENINGES

- Mostly composed of tracts of nerve fibers Dura mater
- Has two bulging fiber tracts— cerebral - Tough outermost layer
peduncles - Double-layered external covering
- Has four rounded protrusions— corpora Periosteum—attached to inner
quadrigemina surface of the skull
Reflex centers for vision and hearing Meningeal layer—outer covering of
Pons the brain
- Folds inward in several areas
- The bulging center part of the brain stem Falx cerebri
- Mostly composed of fiber tracts Tentorium cerebelli
- Includes nuclei involved in the control of
breathing Arachnoid layer

Medulla oblongata - Middle layer
- Web-like extensions span the subarachnoid
- The lowest part of the brain stem space
- Merges into the spinal cord - Arachnoid villi reabsorb cerebrospinal fluid
- Includes important fiber tracts
- Contains important control centers Pia mater
Heart rate control - Internal layer
Blood pressure regulation - Clings to the surface of the brain
Breathing
Swallowing
Vomiting
CEREBROSPINAL FLUID (CFS) Cerebrovascular Accident (CVA) or Stroke
- Similar to blood plasma composition - Result from a ruptured blood vessel
- Formed by the choroid plexus supplying a region of the brain
- Choroid plexuses–capillaries in the - Brain tissue supplied with oxygen from that
ventricles of the brain blood source dies
- Forms a watery cushion to protect the brain - Loss of some functions or death may result
- Circulated in arachnoid space, ventricles, Hemiplegia–One-sided paralysis
and central canal of the spinal cord Aphasis–Damage to speech center
in left hemisphere
Cerebrospinal Fluid (CSF) Pathway of Flow
- Transischemia-attack (TIA)–temporary
1. CSF is produced by the choroid plexus of brain ischemia -(restriction of blood flow)
each ventricle. Warning signs for more serious
2. CSF flows through the ventricles and into CVAs
the subarachnoid space via the median and
Alzheimer’s Disease
lateral apertures. Some CSF flows through
the central canal of the spinal cord. - Progressive degenerative brain disease
3. CSF flows through the subarachnoid space. - Mostly seen in the elderly, but may begin in
4. CSF is absorbed into the dural venous middle age
sinuses via the arachnoid villi. - Structural changes in the brain include
abnormal protein deposits and twisted fibers
within neurons
- Victims experience memory loss, irritability,
confusion, and ultimately, hallucinations and
death

Hydrocephalus in a Newborn
Hydrocephalus SPINAL CORD
- CSF accumulates and exerts pressure on - Extends from the foramen magnum of the
the brain if not allowed to drain skull to the first or second lumbar vertebra
- Possible in an infant because the skull - Provides a two-way conduction pathway
bones have not yet fused from the brain to and from the brain
- In adults, this situation results in brain - 31 pairs of spinal nerves arise from the
damage spinal cord
BLOOD-BRAIN BARRIER - Cauda equina is a collection of spinal
nerves at the inferior end
- Includes the least permeable capillaries of
the body
- Excludes many potentially harmful
substances
- Useless as a barrier against some
substances
Fats and fat soluble molecules
Respiratory gases
Alcohol
Nicotine
Anesthesia SPINAL CORD ANATOMY

TRAUMATIC BRAIN INJURIES - Internal gray matter is mostly cell bodies
Concussion Dorsal (posterior) horns
Slight brain injury Anterior (ventral) horns
No permanent brain damages Gray matter surrounds the central
canal
Contusion - Central canal is filled with cerebrospinal
- Nervous tissue destruction occurs fluid
- Nervous tissue does not regenerate - Exterior white mater—conduction tracts
Dorsal, lateral, ventral columns
Cerebral edema
- Swelling from the inflammatory response
- May compress and kill brain tissue
-
 - Meninges cover the spinal cord - And – Abducens
- Spinal nerves leave at the level of each - Feel – Facial
vertebrae - Very – Vestibulocochlear
- Dorsal root - Green – Glossopharyngeal
Associated with the dorsal root - Vegetables – Vagus
ganglia—collections of cell bodies - A – Accessory
outside the central nervous system- - H – Hypoglossal
- Ventral root
PNS: CRANIAL NERVES
Contains axons
- I Olfactory nerve—sensory for smell
- II Optic nerve—sensory for vision
- III Oculomotor nerve—motor fibers to eye
muscles
- IV Trochlear—motor fiber to one eye muscle
- V Trigeminal nerve—sensory for the face;
motor fibers to chewing muscles
- VI Abducens nerve—motor fibers to eye
muscles
- VII Facial nerve—sensory for taste; motor
fibers to the face
- VIII Vestibulocochlear nerve—sensory for
balance and hearing
- IX Glossopharyngeal nerve—sensory for
taste; motor fibers to the pharynx

- X Vagus nerves—sensory and motor fibers
PERIPHERAL NERVOUS SYSTEM (PNS) for pharynx, larynx, and viscera
- Nerves and ganglia outside the central - XI Accessory nerve—motor fibers to neck
nervous system and upper back
- Nerve = bundle of neuron fibers - XII Hypoglossal nerve—motor fibers to
- Neuron fibers are bundled by connective tongue
tissue PNS: SPINAL NERVES
PNS: STRUCTURE OF A NERVE - There is a pair of spinal nerves at the level
- Endoneurium surrounds each fiber of each vertebrae for a total of 31 pairs
- Groups of fibers are bound into fascicles by - Formed by the combination of the ventral
perineurium and dorsal roots of the spinal cord
- Fascicles are bound together by - Named for the region from which they arise
epineurium
PNS: CLASSIFICATION OF NERVES
Mixed nerves
- Both sensory and motor fibers
Sensory (afferent) nerves
- Carry impulses toward the CNS
Motor (efferent) nerves
- Carry impulses away from the CNS
PNS: CRANIAL NERVES
- Twelve pairs of nerves that mostly serve the
head and neck
- Only the pair of vagus nerves extend to PNS: ANATOMY OF SPINAL NERVES
thoracic and abdominal cavities
- Spinal nerves divide soon after leaving the
- Most are mixed nerves, but three are
spinal cord
sensory only
- Ramus—branch of a spinal nerve; contains
PNS: CRANIAL NERVES DEVICE both motor and sensory fibers
Dorsal rami—serve the skin and
- Oh – Olfactory muscles of the posterior trunk
- Oh – Optic Ventral rami—form a complex of
- Oh – Oculomotor networks (plexus) for the anterior
- To – Trochlear
- Touch – Trigeminal
PNS: SPINAL NERVE PLEXUSES
- Plexus–networks of nerves serving motor
and sensory needs of the limbs
- Form from ventral rami of spinal nerves in
the cervical, lumbar, and sacral regions
- Four plexuses:
Cervical
Brachial
Lumbar
Sacral
Cervical Plexus
- Originates from ventral rami in C1 – C5
- Important nerve is the phrenic nerve
- Areas served:
Diaphragm PNS: ANATOMY OF THE PARASYMPATHETIC
Shoulder and neck DIVISION

Brachial Plexus - Preganglionic neurons originate from the
craniosacral regions:
- Originates from ventral The cranial nerves III, VII, IX, and X
rami in C5 – C8 and T1 S2 through S4 regions of the spinal
- Important nerves: cord
Axillary - Due to site of preganglionic neuron
Radial origination, the parasympathetic division is
Median also known as the craniosacral division
Musculocutaneous - Terminal ganglia are at the effector organs
Ulnar - Neurotransmitter: acetylcholine
- Areas served: shoulder, arm, forearm, and
hand
Lumbar Plexus
- Originates from ventral rami in L1 through
L4
- Important nerves:
Femoral
Obturator
- Areas served:
Lower abdomen
Anterior and
medial thighs
Sacral Plexus
- Originates from ventral rami
in L4 – L5 and S1 – S4
- Important nerves: - Preganglionic neurons originate from T1
Sciatic through L2
Superior and inferior gluteal - Ganglia are at the sympathetic trunk (near
- Areas served: the spinal cord)
Lower trunk and posterior thigh - Short pre-ganglionic neuron and long
Lateral and posterior leg and foot post-ganglionic neuron transmit impulse
Gluteal muscles of hip are from CNS to the effector
- Neurotransmitters: norepinephrine and
PNS: AUTONOMIC NERVOUS SYSTEM
epinephrine (effector organs)
- Motor subdivision of the PNS
PNS: AUTONOMIC FUNCTIONING
Consists only of motor nerves
- Also known as the involuntary nervous Sympathetic— “fight or flight”
system
Regulates activities of cardiac and - Response to unusual stimulus
smooth muscles and glands - Takes over to increase activities
- Two subdivisions - Remember as the “E” division
Sympathetic division Exercise, excitement, emergency,
and embarrassment
Parasympathetic division
PNS: DIFFERENCES BETWEEN SOMATIC AND
AUTONOMIC NERVOUS SYSTEMS
 Lacrimal apparatus
Parasympathetic— “housekeeping” activites
- Conserves energy
- Maintains daily necessary body functions
- Remember as the “D” division
digestion, defecation, and diuresis

EXTERNAL AND ACCESSORY STRUCTURES
Eyelids
- Meet at the medial and lateral commissure
(canthus)
Eyelashes
- Tarsal glands produce an oily secretion that
lubricates the eye
DEVELOPMENT ASPECTS OF THE NERVOUS - Ciliary glands are located between the
SYSTEM eyelashes
- The nervous system is formed during the Conjunctiva
first month of embryonic development
- Membrane that lines the eyelids and eyeball
- Any maternal infection can have extremely
- Connects with the transparent cornea
harmful effects
- Secretes mucus to lubricate the eye and
- The hypothalamus is one of the last areas
keep it moist
of the brain to develop
- No more neurons are formed after birth, but Lacrimal apparatus = lacrimal gland + ducts
growth and maturation continue for several
years Lacrimal gland—produces lacrimal fluid (tears);
- The brain reaches maximum weight as a situated on lateral end of each eye
young adult - Tears drain across the eye into the lacrimal
canaliculi, then the lacrimal sac, and into the
nasolacrimal duct, which empties into the
nasal cavity
- Tears contain:
Dilute salt solution
Mucus
Antibodies
Lysozyme (enzyme that destroys
bacteria)
- Function of tears
Cleanse, protect, moisten, lubricate
SPECIAL SENSES the eye

Special senses include:
- Smell
- Taste
- Sight
- Hearing
- Equilibrium
- Special sense receptors
- Large, complex sensory organs
- Localized clusters of receptors
- Extrinsic eye muscles
PART 1: THE EYE AND VISION Six muscles attach to the outer
- 70 percent of all sensory receptors are in surface of the eye
the eyes Produce gross eye movements
- Each eye has over 1 million nerve fibers
carrying information to the brain
- Accessory structures include the:
Extrinsic eye muscles
Eyelids
Conjunctiva
 1. Outer pigmented layer absorbs
light and prevents it from scattering
2. Inner neural layer contains
receptor cells (photoreceptors)
Rods
Cones
- Electrical signals pass from photoreceptors
via a two- neuron chain:
Bipolar neurons
Ganglion cells
- Signals leave the retina toward the brain
through the optic nerve
- Optic disc (blind spot) is where the optic
nerve leaves the eyeball
Cannot see images focused on the
optic disc
- Rods
Most are found toward the edges of
the retina
INTERNAL STRUCTURES: THE EYEBALL Allow vision in dim light and
- Three layers, or tunics, form the wall of the peripheral vision
eyeball All perception is in gray tones
Fibrous layer: outside layer
Vascular layer: middle layer
Sensory layer: inside layer
- Humors are fluids that fill the interior of the
eyeball
- Lens divides the eye into two chambers

- Cones
Allow for detailed color vision
Densest in the center of the retina
Fovea centralis–lateral to blind spot
✓ Area of the retina with only
cones
Fibrous layer = sclera + cornea ✓ Visual acuity (sharpest
vision) is here
- Sclera No photoreceptor cells are at the
White connective tissue layer optic disc, or blind spot
Seen anteriorly as the ―” white of - Cone sensitivity
the eye” Three types of cones
- Cornea Each cone type is sensitive to
Transparent, central anterior portion different wavelengths of visible light
Allows for light to pass through
Repairs itself easily Lens
The only human tissue that can be - Flexible, biconvex crystal-like structure
transplanted without fear of rejection - Held in place by a suspensory ligament
Vascular layer attached to the ciliary body
- Lens divides the eye into two chambers
- Choroid is a blood-rich nutritive layer that 1. Anterior (aqueous) segment
contains a pigment (prevents light from Anterior to the lens
scattering) Contains aqueous humor, a
Choroid is modified anteriorly into clear, watery fluid
two smooth muscle structures 2. Posterior (vitreous) segment
- Ciliary body Posterior to the lens
- Iris—regulates amount of light entering eye Contains vitreous humor, a
Pigmented layer that gives eye color gel-like substance
- Pupil—rounded opening
Aqueous humor
Sensory layer
- Watery fluid found between lens and cornea
- Retina contains two layers - Similar to blood plasma
- Helps maintain intraocular pressure
 - Provides nutrients for the lens and cornea Astigmatism
- Reabsorbed into venous blood through the
- Images are blurry
scleral venous sinus, or canal of Schlemm
- Results from light focusing as lines, not
Vitreous humor points, on the retina because of unequal
curvatures of the cornea or lens
- Gel-like substance posterior to the lens
- Prevents the eye from collapsing PHYSIOLOGY OF VISION
- Helps maintain intraocular pressure
Eye reflexes
Ophthalmoscope
- Convergence: reflexive movement of the
- Instrument used to illuminate the interior of eyes medially when we focus on a close
the eyeball and fundus (posterior wall) object
- Can detect diabetes, arteriosclerosis, - Photopupillary reflex: bright light causes
degeneration of the optic nerve and retina pupils to constrict
- Accommodation pupillary reflex: viewing
close objects causes pupils to constrict
PHYSIOLOGY OF VISION PART II: THE EAR: HEARING AND BALANCE
- Pathway of light through the eye and light - Ear houses two senses:
refraction
Hearing
- Light must be focused to a point on the
Equilibrium (balance)
retina for optimal vision
- Receptors are mechanoreceptors
- Light is bent, or refracted, by the cornea,
- Different organs house receptors for each
aqueous humor, lens, and vitreous humor
sense
- The eye is set for distant vision (over 20 feet
- The ear is divided into three areas:
away)
External (outer) ear
- Accommodation—the lens must change
Middle ear
shape to focus on closer objects (less than
20 feet away) Internal (inner) ear
- Pathway of light through the eye and light
refraction (continued)
Image formed on the retina is a real
image
Real images are:
✓ Reversed from left to right
✓ Upside down
✓ Smaller than the object
Summary of the pathway of impulses from the
retina to the point of visual interpretation
1. Optic nerve
2. Optic chiasma
3. Optic tract
4. Thalamus
5. Optic radiation
6. Optic cortex in occipital lobe of brain ANATOMY OF THE EAR
External (outer) ear

A CLOSER LOOK - Auricle (pinna)
- External acoustic meatus (auditory canal)
Emmetropia – eye focuses images Narrow chamber in the temporal
correctly on the retina bone
Lined with skin and ceruminous
Myopia (nearsightedness) (earwax) glands
- Distant objects appear blurry Ends at the tympanic membrane
- Light from those objects fails to reach the (eardrum)
retina and are focused in front of it - External ear is involved only in collecting
- Results from an eyeball that is too long sound waves

Hyperopia (farsightedness) Middle ear cavity (tympanic cavity)

- Near objects are blurry, whereas distant - Air-filled, mucosa-lined cavity within the
objects are clear temporal bone
- Distant objects are focused behind the - Involved only in the sense of hearing
retina - Located between tympanic membrane and
- Results from an eyeball that is too short or oval window and round window
from a ―”lazy lens” - Pharyngotympanic tube (auditory tube)
 Links middle ear cavity with the - Hair cells are stimulated, and the impulse
throat travels the vestibular nerve to the
Equalizes pressure in the middle ear cerebellum
cavity so the eardrum can vibrate
HEARING
- Three bones (ossicles) span the cavity
Malleus (hammer) Spiral organ of Corti
Incus (anvil)
- Located within the cochlear duct
Stapes (stirrup)
- Receptors = hair cells on the basilar
- Function
membrane
Transmit vibrations from tympanic
- Gel-like tectorial membrane is capable of
membrane to the fluids of the inner
bending hair cells
ear
- Cochlear nerve attached to hair cells
transmits nerve impulses to auditory cortex
on temporal lobe
Vibrations travel from the hammer →
anvil → stirrup → oval window of
inner ear

- Internal (inner) ear
Includes sense organs for hearing
and balance
Bony labyrinth (osseous labyrinth)
consists of:
✓ Cochlea
✓ Vestibule
✓ Semicircular canals
Bony labyrinth is filled with perilymph
Membranous labyrinth is suspended
in perilymph and contains
endolymph
EQUILIBRIUM Pathway of vibrations from sound waves

- Equilibrium receptors of the inner ear are - Move by the ossicles from the eardrum to
called the vestibular apparatus the oval window
- Vestibular apparatus has two functional - Sound is amplified by the ossicles
parts - Pressure waves cause vibrations in the
Static equilibrium basilar membrane in the spiral organ of
Dynamic equilibrium Corti
- Hair cells of the tectorial membrane are
STATIC EQUILIBRIUM bent when the basilar membrane vibrates
Maculae—receptors in the vestibule against it
- An action potential starts in the cochlear
- Report on the position of the head nerve (cranial nerve VIII), and the impulse
- Help us keep our head erect travels to the temporal lobe
- Send information via the vestibular nerve - High-pitched sounds disturb the short, stiff
(division of cranial nerve VIII) to the fibers of the basilar membrane
cerebellum of the brain Receptor cells close to the oval
window are stimulated
Anatomy of the maculae
- Low-pitched sounds disturb the long, floppy
- Hair cells are embedded in the fibers of the basilar membrane
otolithic membrane Specific hair cells further along the
- (tiny stones) float in a gel around cochlea are affected
hair cells
PART III: CHEMICAL SENSES: SMELL
- Movements cause otoliths to roll
AND TASTE
and bend hair cells
- Chemoreceptors
DYNAMIC EQUILIBRIUM
Stimulated by chemicals in solution
Crista ampullaris Taste has five types of receptors
Smell can differentiate a wider range
- Responds to angular or rotational
of chemicals
movements of the head
Both senses complement each other
- Located in the ampulla of each semicircular
and respond to many of the same
canal
stimuli
- Tuft of hair cells covered with cupula
(gelatinous cap) OLFACTORY RECEPTORS AND THE SENSE OF
- If the head moves, the cupula drags against SMELL
the endolymph
 - Olfactory receptors are in roof of nasal Five basic taste sensations
cavity
- Sweet receptors respond to sugars,
Olfactory receptor cells (neurons)
saccharine, some amino acids
with long cilia known as olfactory
- Sour receptors respond to H+ ions or acids
hairs detect chemicals
- Bitter receptors respond to alkaloids
Chemicals must be dissolved in
- Salty receptors respond to metal ions
mucus for detection by
- Umami receptors respond to the amino acid
chemoreceptors called olfactory
glutamate or the beefy taste of meat
receptors
- Impulses are transmitted via the olfactory
filaments to the olfactory nerve (cranial
nerve I)
- Smells are interpreted in the olfactory cortex

PART VI: DEVELOPMENTAL ASPECTS OF THE
SPECIAL SENSES
- Special sense organs are formed early in
embryonic development
- - Maternal infections during the first 5 or 6
weeks of pregnancy may cause visual
abnormalities as well as sensorineural
deafness in the developing child
- Vision requires the most learning
- The infant has poor visual acuity (is
farsighted)
- and lacks color vision and depth perception
TASTE BUDS AND THE SENSE OF TASTE at
Taste buds house the receptor organs birth
- The eye continues to grow and mature until
- Locations of taste buds age
Most are on the tongue 8 or 9
Soft palate
Age-related eye issues
Superior part of the pharynx
Cheeks - Presbyopia—―old vision‖ results from
- The tongue is covered with projections decreasing lens elasticity that accompanies
called papillae that contain taste buds aging
Vallate (circumvallate) papillae Causes difficulty to focus for close
Fungiform papillae vision
Filiform papillae - Lacrimal glands become less active
- Gustatory cells are the taste receptors - Lens becomes discolored
Possess gustatory hairs (long - Dilator muscles of iris become less efficient,
microvilli) causing pupils to remain constricted
Gustatory hairs protrude through a - The newborn infant can hear sounds, but
taste pore initial
Hairs are stimulated by chemicals responses are reflexive
dissolved in saliva - By the toddler stage, the child is listening
critically and beginning to imitate sounds as
language development begins
Age-related ear problems
- Presbycusis—type of sensorineural
deafness that may result from otosclerosis
- Otosclerosis—ear ossicles fuse
- Congenital ear problems usually result from
missing pinnas and closed or missing
external acoustic meatuses

- Impulses are carried to the gustatory
- Taste and smell are most acute at birth and
complex by several cranial nerves because
decrease in sensitivity after age 40 as the
taste buds are found in different areas
number of olfactory and gustatory receptors
Facial nerve (cranial nerve VII)
decreases
Glossopharyngeal nerve (cranial
nerve IX)
Vagus nerve (cranial nerve X)
- Taste buds are replaced frequently
by basal cells
THE SKELETAL SYSTEM - Example:
Carpals
Parts of the skeletal system
Tarsals
Bones (skeleton)
Flat bones
Joints
Cartilages - Thin, flattened, and usually curved
Ligaments - Two thin layers of compact bone surround a
layer of spongy bone
Two subdivisions of the skeleton - Example:
Axial skeleton Skull
Appendicular skeleton Ribs
Sternum
FUNCTIONS OF BONES
Irregular bones
- Support the body
- Protect soft organs - Irregular shape
Skull and vertebrae for brain and - Do not fit into other bone classification
spinal cord categories
Rib cage for thoracic cavity organs - Example:
- Allow movement due to attached skeletal Vertebrae
muscles Hip bones
- Store minerals and fats
ANATOMY OF A LONG BONE
Calcium and phosphorus
Fat in the internal marrow cavity Diaphysis
- Blood cell formation (hematopoiesis)
- Shaft
BONES OF THE HUMAN BODY - Composed of compact bone

- The adult skeleton has 206 bones Epiphysis
- Two basic types of bone tissue
- Ends of the bone
Compact bone
- Composed mostly of spongy bone
-Homogeneous
Spongy bone Periosteum
- Small needle-like pieces of bone
- Outside covering of the diaphysis
- Many open spaces
- Fibrous connective tissue membrane
Perforating (Sharpey’s) fibers
- Secure periosteum to underlying bone
CLASSIFICATION OF BONES ON THE BASIS
Arteries
OF SHAPE
- Supply bone cells with nutrients
Bones are classified as:
Articular cartilage
Long
Short - Covers the external
Flat surface of the
Irregular epiphyses
- Made of hyaline
Cartilage
CLASSIFICATION OF BONES - Decreases friction at joint surfaces

Long bones
- Typically longer than they are wide
- Shaft with heads situated at both ends
- Contain mostly compact bone
- All of the bones of the limbs (except wrist,
- ankle, and kneecap bones)
- Example:
Femur Epiphyseal plate
Humerus
Flat plate of hyaline cartilage seen in young,
Short bones growing bone
- Generally cube-shaped Epiphyseal line
- Contain mostly spongy bone
- Includes bones of the wrist and ankle Remnant of the epiphyseal plate
- Sesamoid bones are a type of short bone Seen in adult bones
which form within tendons (patella) Marrow (medullary) cavity
 Cavity inside of the shaft - During development, much of this cartilage
Contains yellow marrow (mostly fat) in is replaced by bone
adults - Cartilage remains in isolated areas
Contains red marrow for blood cell Bridge of the nose
formation in infants Parts of ribs
In adults, red marrow is situated in cavities Joints
of spongy bone and epiphyses of some long
BONE GROWTH (OSSIFICATION)
bones
Epiphyseal plates allow for lengthwise growth
BONE MARKINGS
of long bones during childhood
- Surface features of bones
- New cartilage is continuously formed
Sites of attachments for muscles,
- Older cartilage becomes ossified
tendons, and ligaments
Cartilage is broken down
Passages for nerves and blood
Enclosed cartilage is digested away,
vessels
opening up a medullary cavity
- Categories of bone markings
Bone replaces cartilage through the
Projections or processes—grow out
action of osteoblasts
from the bone surface
Terms often begin with “T” Bones are remodeled and lengthened until
Depressions or cavities— growth stops
indentations
Terms often begin with “F” - Bones are remodeled in response to two
factors
MICROSCOPIC ANATOMY OF COMPACT BONE Blood calcium levels
Osteon (Haversian system) Pull of gravity and muscles on the
skeleton
- A unit of bone containing central canal and
matrix rings Bones grow in width (called appositional
growth)
Central (Haversian) canal
- Opening in the center of an osteon
- Carries blood vessels and nerves
Perforating (Volkmann’s) canal
- Canal perpendicular to the central canal
- Carries blood vessels and nerves

MICROSCOPIC ANATOMY OF BONE
Lacunae
- Cavities containing bone cells (osteocytes)
- Arranged in concentric rings called lamellae
Lamellae
- Rings around the central canal
- Sites of lacunae

Canaliculi TYPES OF BONE CELLS

- Tiny canals - Osteocytes—mature bone cells
- Radiate from the central canal to lacunae - Osteoblasts—bone-forming cells
- Form a transport system connecting all - Osteoclasts—giant bone-destroying cells
bone cells to a nutrient supply Break down bone matrix for
remodeling and release of calcium in
FORMATION OF THE HUMAN SKELETON response to parathyroid hormone
- Bone remodeling is performed by both
- In embryos, the skeleton is primarily hyaline
osteoblasts and osteoclasts
cartilage
BONE FRACTURES THE SKULL
Fracture—break in a bone - Two sets of bones
Cranium
Types of bone fractures
Facial bones
- Closed (simple) fracture—break that does - Bones are joined by sutures
not penetrate the skin - Only the mandible is attached by a freely
- Open (compound) fracture—broken bone movable joint
penetrates through the skin
Bone fractures are treated by reduction and
immobilization
COMMON TYPES OF FRACTURES
- Comminuted—bone breaks into many
fragments
- Compression—bone is crushed
- Depressed—broken bone portion is
pressed inward
-
- Impacted—broken bone ends are forced
into each other
- Spiral—ragged break occurs when
excessive twisting forces are applied to a
bone
- Greenstick—bone breaks incompletely
REPAIR OF BONE FRACTURES
- Hematoma (blood-filled swelling) is formed
- Break is splinted by fibrocartilage to form a
callus
- Fibrocartilage callus is replaced by a bony
callus
- Bony callus is remodeled to form a
permanent patch

THE AXIAL SKELETON
- Forms the longitudinal axis of the body
- Divided into three parts
Skull
Vertebral column
Bony thorax
 - Primary curvatures are the spinal curvatures
of the thoracic and sacral regions
PARANASAL SINUSES
Present from birth
- Hollow portions of bones surrounding the Form a C-shaped curvature as in
nasal cavity newborns
- Functions of paranasal sinuses - Secondary curvatures are the spinal
Lighten the skull curvatures of the cervical and lumbar
Give resonance and amplification to regions
voice Develop after birth
Form an S-shaped curvature as in
adults
THE HYOID BONE A TYPICAL VERTEBRAE
- The only bone that does not articulate with Body
another bone
Vertebral arch
- Serves as a moveable base for the tongue
- Pedicle
- Aids in swallowing and speech
- Lamina
Vertebral foramen
Transverse processes
THE FETAL SKULL
Spinous process
- The fetal skull is large compared to the Superior and inferior articular
infant’s total body length processes
Fetal skull is 1/4 body length
SACRUM AND COCCYX
compared to adult skull which is 1/8
body length Sacrum
- Fontanels—fibrous membranes connecting
- Formed by the fusion
the cranial bones
of five vertebrae
Allow skull compression during birth
Allow the brain to grow during later Coccyx
pregnancy and infancy
- Formed from the fusion of
Convert to bone within 24 months
after birth three to five vertebrae
- “Tailbone,” or remnant of a tail that other
vertebrates have
THE BONY THORAX
- Forms a cage to protect major organs
- Consists of three parts
Sternum
THE VERTEBRAL COLUMN Ribs
-True ribs (pairs 1–7)
- Each vertebrae is given a name according - False ribs (pairs 8–12)
to its location - Floating ribs (pairs 11–12)
- There are 24 single vertebral bones - Thoracic vertebrae
separated by intervertebral discs
Seven cervical vertebrae are in the THE APPENDICULAR SKELETON
neck
- Composed of 126 bones
Twelve thoracic vertebrae are in the
Limbs (appendages)
chest region
Pectoral girdle
Five lumbar vertebrae are
Pelvic girdle
associated with the lower back
Nine vertebrae fuse to form two THE PECTORAL (SHOULDER) GIRDLE
composite bones(Sacrum and
Coccyx) - Composed of two bones
Clavicle—collarbone
-Articulates with the sternum
medially and with the scapula
laterally
Scapula—shoulder blade
- Articulates with the clavicle at the
acromioclavicular joint
- Articulates with the arm bone at the
glenoid cavity
- These bones allow the upper limb to have
exceptionally free movement
 BONES OF THE PELVIC GIRDLE
BONES OF THE UPPER LIMB - Formed by two coxal (ossa coxae) bones
- Composed of three pairs of fused bones
- Humerus
Ilium
Forms the arm
Ischium
Single bone
Pubis
Proximal end articulation
- Pelvic girdle = 2 coxal bones, sacrum
-Head articulates with the glenoid
- Bony pelvis = 2 coxal bones, sacrum,
cavity of the scapula
coccyx
- Distal end articulation
- The total weight of the upper body rests on
Trochlea and capitulum articulate
the
with the bones of the forearm Pelvis
- It protects several organs
Reproductive organs
Urinary bladder
Part of the large intestine

The forearm has two bones
- Ulna—medial bone in
anatomical position
Proximal end articulation
Coronoid process and
olecranon articulate with the
humerus
- Radius—lateral bone in
anatomical position
Proximal end articulation
Head articulates with the
capitulum of the humerus
BONES OF THE UPPER LIMBS
Hand
- Carpals—wrist
Eight bones arranged in two rows of
four bones in
each hand GENDER DIFFERENCES OF THE PELVIS
Metacarpals—palm - The female inlet is larger and more circular
- Five per hand - The female pelvis as a whole is shallower,
and the bones are lighter and thinner
Phalanges—fingers and - The female ilia flare more laterally
thumb - The female sacrum is shorter and less
curved
- Fourteen phalanges
- The female ischial spines are shorter and
in each hand
farther apart; thus the outlet is larger
- In each finger, there
- The female pubic arch is more rounded
are three bones
because the angle of the pubic arch is
- In the thumb, there are only two bones
greater
BONES OF THE LOWER LIMB
Femur—thigh bone STRUCTURAL CLASSIFICATION OF JOINTS
- The heaviest, strongest bone in the body Fibrous joints - Generally immovable
- Proximal end articulation
Cartilaginous joints - Immovable or slightly
Head articulates with the
moveable
acetabulum of the coxal (hip) bone
Synovial joints - Freely moveable
Distal end articulation
FIBROUS JOINTS
- Lateral and medial condyles articulate with
the tibia in the lower leg - Bones united by collagenic fibers
- Types
The lower leg has two bones
Sutures – Immobile
- Tibia—Shinbone; larger and medially Syndesmoses - Allows more
oriented movement than sutures but still
Proximal end articulation immobile
Medial and lateral condyles Example: Distal end of tibia and
articulate with the femur to form the fibula
knee joint Gomphosis – Immobile
- Fibula—Thin and sticklike; lateral to the
CARTILAGINOUS JOINTS
tibia
Has no role in forming the knee joint - Bones connected by cartilage
- Types
The foot
Synchrondrosis – Immobile
- Tarsals—seven Symphysis - Slightly movable
bones Example: Pubic symphysis,
Two largest tarsals intervertebral joints
- Calcaneus (heel bone)
SYNOVIAL JOINTS
- Talus
- Metatarsals—five - Articulating bones are separated by a joint
bones form the sole of the cavity
- foot - Synovial fluid is found in the joint cavity
- Phalanges—fourteen
bones form the toes

ARCHES OF THE FOOT
- Bones of the foot are
arranged to form three FEATURES OF SYNOVIAL JOINTS
strong arches
Two longitudinal - Articular cartilage (hyaline cartilage) covers
One transverse the ends of bones
- Articular capsule encloses joint surfaces
and
lined with synovial membrane
- Joint cavity is filled with synovial fluid
JOINTS - Reinforcing ligaments
- Articulations of bones STRUCTURES ASSOCIATED WITH THE
- Functions of joints SYNOVIAL JOINT
Hold bones together
- Bursae—flattened fibrous sacs
Allow for mobility
Lined with synovial membranes
- Two ways joints are classified
Filled with synovial fluid
Functionally
Not actually part of the joint
Structurally
- Tendon sheath
FUNCTIONAL CLASSIFICATION OF JOINTS Elongated bursa that wraps around
a tendon
Synarthroses - Immovable joints
Amphiarthroses - Slightly moveable joints
Diarthroses - Freely moveable joints
INFLAMMATORY CONDITIONS - 8 or 9 years old—skull is near adult size and
proportion
ASSOCIATED WITH JOINTS
- Between ages 6 and 11, the face grows out
- Bursitis—inflammation of a bursa usually from the skull
caused by a blow or friction
- Tendonitis—inflammation of tendon
sheaths
- Arthritis—inflammatory or degenerative
diseases of joints
Over 100 different types Curvatures of the spine
The most widespread crippling
disease in the United States - Primary curvatures are present at birth and
Initial symptoms: pain, stiffness, are convex posteriorly
swelling of the joint - Secondary curvatures are associated with a
child’s later development and are convex
CLINICAL FORMS OF ARTHRITIS anteriorly
- Abnormal spinal curvatures (scoliosis and
Osteoarthritis
lordosis) are often congenital
- Most common chronic arthritis
Osteoporosis
- Probably related to normal aging processes
- Bone-thinning disease afflicting
Rheumatoid arthritis
50 percent of women over age 65
- An autoimmune disease—the immune 20 percent of men over age 70
system attacks the joints - Disease makes bones fragile and bones
- Symptoms begin with bilateral inflammation can easily fracture
of certain joints - Vertebral collapse results in kyphosis (also
- Often leads to deformities known as dowager’s hump)
- Estrogen aids in health and normal density
Gouty arthritis of a female skeleton
- Inflammation of joints is caused by a
deposition of uric acid crystals from the
blood
- Can usually be controlled with diet
- More common in men
DEVELOPMENTAL ASPECTS OF THE
SKELETAL SYSTEM
- At birth, the skull bones are incomplete
- Bones are joined by fibrous membranes
called fontanels
- Fontanels are completely replaced with
bone within two years after birth

SKELETAL CHANGES THROUGHOUT LIFE
Fetus
- Long bones are formed of hyaline cartilage
- Flat bones begin as fibrous membranes
- Flat and long bone models are converted to
bone
Birth
- Fontanels remain until around age 2
Adolescence
- Epiphyseal plates become ossified and long
bone growth ends
Size of cranium in relationship to body
- 2 years old—skull is larger in proportion to
the body compared to that of an adult
THE MUSCULAR SYSTEM Endomysium—encloses a single
muscle fiber
- Muscles are responsible for all
Perimysium—wraps around a
types of body movement
fascicle (bundle) of muscle fibers
- Three basic muscle types are
Epimysium—covers the entire
found in the body
skeletal muscle
Skeletal muscle
Fascia—on the outside of the
Cardiac muscle
epimysium
Smooth muscle
SKELETAL MUSCLE ATTACHMENTS
CHARACTERISTICS OF MUSCLES
- Epimysium blends into a connective tissue
- Skeletal and smooth muscle cells are
attachment
elongated (muscle cell = muscle fiber)
Tendons—cord-like structures
- Contraction and shortening of muscles is
- Mostly collagen fibers
due to the movement of microfilaments
- Often cross a joint due to
- All muscles share some terminology
toughness and small size
Prefixes myo and mys refer to
Aponeuroses—sheet-like structures
“muscle”
-Attach muscles indirectly to bones,
Prefix sarco refers to “flesh”
cartilages, or connective tissue
coverings
- Sites of muscle attachment
Bones
Cartilages
Connective tissue coverings
SMOOTH MUSCLE CHARACTERISTICS
COMPARISON OF SKELETAL, CARDIAC, AND
SMOOTH MUSCLES - Lacks striations
- Spindle-shaped cells
- Single nucleus
- Involuntary—no conscious control
- Found mainly in the walls of hollow organs
CARDIAC MUSCLE CHARACTERISTICS
- Striations
- Usually has a single nucleus
- Branching cells
- Joined to another muscle
cell at an intercalated disc
- Involuntary
- Found only in the walls of the heart
SKELETAL MUSCLE FUNCTION
- Produce movement
- Maintain posture
- Stabilize joints
- Generate heat
MICROSCOPIC ANATOMY OF SKELETAL
MUSCLE
- Sarcolemma—specialized plasma
membrane
SKELETAL MUSCLE CHARACTERISTICS - Myofibrils—long organelles inside muscle
cell
- Most are attached by tendons to bones
- Sarcoplasmic reticulum—specialized
- Cells are multinucleate
smooth endoplasmic reticulum
- Striated—have visible banding
- Voluntary—subject to conscious control
CONNECTIVE TISSUE WRAPPING OF
SKELETAL MUSCLE
- Cells are surrounded and bundled by
connective tissue

- Myofibrils are aligned to give distinct bands
 I band = light band THE NERVE STIMULUS AND ACTION
-Contains only thin filaments POTENTIAL
A band = dark band
- Skeletal muscles must be stimulated by a
-Contains the entire length of
motor neuron (nerve cell) to contract
the thick filaments
- Motor unit—one motor neuron and all the
skeletal muscle cells stimulated by that
neuron

- Sarcomere—contractile unit of a muscle
fiber
- Organization of the sarcomere
- Myofilaments
Thick filaments = myosin filaments
Thin filaments = actin filaments
Thick filaments = myosin filaments
Neuromuscular junction
- Composed of the protein myosin
- Association site of axon terminal of the
- Has ATPase enzymes
motor neuron and muscle
- Myosin filaments have heads (extensions,
or cross bridges)
- Myosin and actin overlap somewhat
Thin filaments = actin filaments
- Composed of the protein actin
- Anchored to the Z disc
Synaptic cleft
- Gap between nerve and muscle
- Nerve and muscle do not make contact
- Area between nerve and muscle is filled
with interstitial fluid
- At rest, within the A band there is a zone
that lacks actin filaments Action potential reaches the axon terminal of
Called either the H zone or bare the motor neuron
zone
- Sarcoplasmic reticulum (SR) Calcium channels open and calcium ions enter
the axon terminal
Stores and releases calcium
Surrounds the myofibril TRANSMISSION OF NERVE IMPULSE TO
MUSCLE
- Calcium ion entry causes some synaptic
vesicles to release their contents
(acetylcholine, a neurotransmitter) by
exocytosis
- Neurotransmitter—chemical released by
nerve upon arrival of nerve impulse in the
axon terminal
STIMULATION AND CONTRACTION OF SINGLE - The neurotransmitter for skeletal muscle is
SKELETAL MUSCLE CELLS acetylcholine (ACh)
- Acetylcholine attaches to receptors on the
- Excitability (also called responsiveness or
sarcolemma of the muscle cell
irritability)—ability to receive and respond to
a stimulus - In response to the binding of ACh to a
- Contractility—ability to shorten when an receptor, the sarcolemma becomes
adequate stimulus is received permeable
to sodium (Na+)
- Extensibility—ability of muscle cells to be
- Sodium rushes into the cell generating an
stretched
action potential and potassium leaves the
- Elasticity—ability to recoil and resume
cell
resting length after stretching
- Once started, muscle contraction cannot be
Stopped
 TYPES OF GRADES RESPONSES
Twitch
- Single, brief contraction
- Not a normal muscle function

Summing of contractions
- One contraction is
immediately followed by another
- The muscle does not completely return to a
resting state due to more frequent
stimulations
- The effects are added
Unfused (incomplete) tetanus
- Some relaxation occurs between
contractions but nerve stimuli arrive
THE SLIDING FILAMENT THEORY OF MUSCLE at an even faster rate than during summing
CONTRACTION of contractions
- Unless the muscle contraction is smooth
- Activation by nerve causes myosin heads
and sustained, it is said to be in unfused
(cross bridges) to attach to binding