Nervous System (Ch 10 only)
Cell Types of Neural Tissue 1. Neurons
classified by structure Bipolar
two processes EX:eyes, ears, nose
Unipolar one process EX:ganglia
Multipolar many processes EX:most neurons of CNS
classified by function
Sensory neurons afferent (bringing impulse into the CNS) most are unipolar some are bipolar
Interneurons link neurons multipolar CNS only
Motor Neurons efferent (bringing impulse out from CNS) multipolar
carries impulses to effectors (thing receiving impulse) 2. Neuroglial cells
PNS Schwann cells
produce myelin found on peripheral myelinated neurons which speeds transmission (unrelated but axon diameter also speeds transmission)
Satellite cells support clusters of neuron cell bodies
CNS Astrocytes
scar tissue formation mop up excess ions, etc induce synapse formation connect neurons to blood vessels
Oligodendrocytes myelinating cell
Microglia Phagocytic cell
Ependyma ciliated line central canal of spinal cord and ventricles of brain
Divisions of the Nervous system
Sensory Division → picks up info then delivers to CNS Motor Division → carries info to muscles and glands
Somatic → carries info to skeletal muscle Autonomic → carries info to smooth muscle, cardiac muscle, and glands
Functions of Nervous System (SIM) 1. Sensory function → sensory receptors gather info for CNS 2. Integrative Function → sensory used to create sensations, memory, thoughts, and
decisions 3. Motor Function → decisions are acted upon/ impulses are carried to effectors
Neuron Structure
Myelination of Axons
White matter contains myelinated axons
Gray Matter contains unmyelinated structures: cell bodies/dendrites
Synaptic Transmission nerve impulses pass from neuron to neuron at synapses neurotransmitters are released when impulse reaches synaptic knob
Impulse Processing
1. Neuronal Pools → how interneurons are organized in CNS; groups of neurons that synapse with each other and work together to perform a common function
a. each pool receives input from other neurons and generate output to other neurons
2. Convergence → axons originating from different parts of NS leading to the same neuron exhibit
a. can amplify an impulse
b. facilitation → impulse from a single neuron in CNS may be amplified to activate enough motor units needed for muscle contraction
3. Divergence → impulses leaving a neuron pool Resting Membrane Potential
inside is negative relative to outside Na is on outside/ K is on inside
polarized membrane due to distribution of ions maintained Na+/K+ pump (diffusion = no energy needed)
Local Potential Changes
caused by various stimuli → temp. change, light, pressure, etc. environmental changes affect the membrane by opening a gated ion channel (Active
Transport)
hyperpolarized → membrane potential becomes more negative depolarized → membrane potential becomes less negative graded → local potentials are graded meaning the degree of change in resting potential is directly proportional to the intensity of the stimulation summation → can lead to threshold stimulus that starts an action potential Action Potential
at rest membrane is polarized threshold stimulus reached sodium channels open and membrane depolarizes potassium leaves cytoplasm and membrane repolarizes
(a=rest 70 mV b=reaching threshold 30 mV c=repolarization
All-or-None Response
if a neuron responds at all, it responds completely nerve impulse is conducted whenever a stimulus of threshold intensity or above is
applied to an axon all impulses carried on an axon are the same strength
Refractory Period 1. Absolute
time when threshold stimulus does not start another action potential 2. Relative
time when stronger stimulus can start another action potential Saltatory Conduction
action potentials occur only at nodes in myelinated neurons (appear to jump from node
to node) Synaptic Potentials
EPSP (excitatory postsynaptic potential) graded depolarizes membrane of postsynaptic neuron action potential of postsynaptic neuron becomes more likely
IPSP (inhibitory postsynaptic potential) graded hyperpolarizes membrane of postsynaptic neuron action potential of postsynaptic neuron becomes less likely
EPSP + IPSP = summation greater EPSP = greater action potential probability
Neurotransmitters
Green Boxes and Clinical Applications
1. Migraines Symptoms → pounding headache, waves of nausea, sometimes shimmering
images in peripheral field, and extreme sensitivity to light/sound Possible Causations → sudden exposure to bright light, eating particular
foods, lack of sleep, stress, high altitude, stormy weather, and excessive caffeine/ alcohol intake
70% of sufferers are women (hormonal) Results from changes in the diameters of blood vessels in the face head
and neck ii. Types
Classic
10 15% experience can last 4 6 hours begins with light in peripheral vision
Common lacks an aura can last 3 4 days
Familial Hemiplegic (rare) hereditary paralyzes one side of the body for a few hours to a few days may cause loss of unconsciousness
iii. Treatments Triptans → mimic serotonin Aspirin/Ibuprofen → usually enough Wild Rhubarb extract Antidepressants, anticonvulsants, and drugs to treat high blood pressure
2. Multiple Sclerosis (MS) i. myelin coating becomes inflamed and is eventually destroyed leaving hard scars
called scleroses scleroses block underlying neurons from transmitting messages muscles that stop receiving impulses, stop contracting, and then
experience atrophy ii. Symptoms → begins as blurred vision, numb legs/arms
following symptoms vary depending on what neurons are affected 70% first notice symptoms in ages 20 40 eventually become paralyzed women are twice as more likely to develop this; caucasians are more
often affected than other races more common in temperate zones of Europe, SA, and NA
iii. Diagnosis → MRI scans (track development of lesions) hypothesized that certain infections in certain individuals stimulate T cells
(a type of white blood cell) in the periphery cross blood brain barrier and attack cells producing myelin
virus may lie behind misplaced immune attack that is MS iv. Treatments
drugs to treat urinary problems antidepressants short term steroids are used to shorten the length of acute disabling
relapses 3 main long term drugs
Beta interferon an immune system biochemical adapted as a drug decreases # of attacks by ⅓ + can slow progression may cause flulike symptoms
Glatiramer Acetate 4 linked amino acids (found in myelin basic protein) fools Tcells into attacking this and dampening
inflammation may protect axons can slow relapse rate
Mitoxantrone antiinflammatory drug halts immune system’s attack on CNS myelin can slow relapse rate
3. Normal Myelin development i. myelin beings formation during 14th week of prenatal development ii. by birth, many axons are not completely myelinated iii. when child starts walking, all myelinated axons begin to develop sheaths iv. continues into adolescence
TaySachs Disease excess myelin seriously impairs NS hereditary defect in a lysosomal enzyme causing neurons to be
buried in fat symptoms → gradual loss of sight, hearing, and muscle function
starts around 6 months old; death by 4 years 4. Neuromas
when peripheral nerve is severed, it is very important the two cut ends be connected asap
so that sprouts of the axon can more easily reach the tubes formed by the basement membranes and connective tissues on the distal side of the gap
gaps > 3mm are prone to neuromas
composed of sensory axons and is painfully sensitive to pressure can complicate a patient’s recovery following limb amputation
5. Factors Affecting Impulse Conduction a # of substances alter axon membrane permeability EXAMPLE 1 → calcium ions are required to close sodium channels in axon
membranes during an action potential Calcium deficiency → Tetanus/Tetany
spontaneous impulses that travel through skeletal fibers and cause spasms
can be caused by maternal Calcium taken in pregnancy/ decreased vitamin D/ prolonged diarrhea
EXAMPLE 2 → potassium ions Potassium increase → Convulsions
can cause the resting potential of nerve fibers to be less negative (partially depolarized)
threshold is reached with less intense stimulus than usual as a result of very excitable fibers
Potassium decrease → muscle paralysis resting potentials of nerves may become so negative that action
potentials are not generated EXAMPLE 3 → anesthetic drugs
Procaine → decreases permeability of sodium ions in the tissue fluids surrounding an axon prevents nerve impulses from passing through
blocks touch and pain 6. Opiates in the Human Body
Opiate drugs → morphine, heroin, codeine, and opium potent painkillers derived from poppy plant easier to tolerate pain and mood elevation
Endorphins body’s natural opiates peptides resemble opiate drug; influence perception of pain + mood discovered in 1971 at Stanford University and the John Hopkins School of
medicine exposed mammalian brain tissue to morphine (which was
radioactively labeled) bound to receptors on membrane of nerve cells that transmit pain
why would it bound to those places unless there was already a natural signal?
explained why some people who are addicted to opiate drugs experience withdrawal pain
body stops producing endorphins because of the perceived excess of endorphins in the body
7. Drug Addiction Timeline → 3,500 yr. old egyptians used opium, 1600’s Chinese relied on opium,
Japan and Europe discovered addictive nature of nicotine, during American civil war morphine was used as painkiller and cocaine was later introduced to relieve veterans addicted to morphine, 1960s LSD was used for psychotherapy, and PCP was an anesthesia before being used in the 1980s
Role of Receptors when drug alters activity of a neurotransmitter on postsynaptic neuron, it
halts/enhances synaptic transmission Antagonist → drug that blocks neurotransmitter from binding Agonist → drug that activates a receptor, triggering action
potential/ helps a neurotransmitter bind many addictive substances bind to the receptor for Dopamine in a region
called nucleus accumbens with repeated use, # of receptors it targets can decline (tolerance) EXAMPLE 1 → Amphetamine
enhances norepinephrine → controls arousal, dreaming, and mood
EXAMPLE 2 → Cocaine blocks reuptake of norepinephrine + binds to molecules that
transport dopamine EXAMPLE 3 → Valium
GABA agonist
causes relaxation and inhibits seizures + anxiety by helping GABA → an inhibitory neurotransmitter used in ⅓ of the brain synapses
Nicotine binds postsynaptic receptors that normally bind the neurotransmitter ACH alters receptor so that positive ions enter the cell triggering dopamine
release heavy smoker = stimulation of excess receptors to accumulate and soon
become nonfunctional (tolerance)