function of nervous system
detects physical change that can affect the body |
works with endocrine system to respond to change |
excitable characteristics of nervous tissue aids these functions |
generation of nerve impulses - action potentials |
cells of nervous system
neurons |
form processing networks "wiring" within brain and spinal cord, functional unit of the nervous system excitable cells that conduct nerve impulses. bring all regions of the body under the CNS control |
glia |
(protect, nutrients, insulating) smaller and more than neurons. the "glue" that maintains neuronal networks. ability to divide. |
regions of neurons
dendrites (receiving end) |
conduct nerve signals toward the cell body |
cell body (aka soma) |
contains organelles (lysosome, mitochondria, nissl bodies) respond to stimuli |
axon |
conducts nerve impulses away from cell body toward other neuron or effector cell. |
axon hillock (axon) |
axon joins cell body. determines if action potential happens (-55v) |
synaptic knob/button (axon) |
carry info of stimulus as electrical impulse |
cytoskeleton |
“railway” allowing rapid transport of small organelles to/from far ends of neuron. Motor molecules shuttle vesicles with NT between soma and terminal buttons. process= axonal transport |
receiving and conducting nerve signals
input zone |
dendrites, cell body |
summation zone |
axon hillock |
conduction zone |
axon |
output zone |
axon terminal, knobs |
neuronal regeneration
in CNS |
little to no regeneration possible |
in PNS |
repair possible if cell body not damaged and if shwann cells still capable of producing myelin |
types of channels
leak channels |
randomly open and close, there are more K+ leak channels than Na+. found in dendrites and cell bodies |
ligand (gated) |
open and close in response to binding with a ligand (specific chemical). found in dendrites and cell bodies. |
voltage (gated) |
opens in response to changes in membrane potential (voltage) charge in mVolts. found in initial segment of axon, a long axon and axon terminals |
Repolarization channels 2 states
movement of K+ is responsible for repolarization |
voltage-gated potassium channels have 2 states |
resting state |
channels closed; no K+ movement |
activated state |
channels open; K+ flows doen concentration gradients |
local potential
excitation of a neuron |
when a stimulus triggers opening of NA+ ligand-gated channels. Excess positive ions outside the plasma membrane decreases, the membrane potential becomes more positive (moves toward zero) depolarization |
inhibition of a neuron |
when a stimulus triggers opening of K+ ligand-gated channels as K+ diffuses out of cell, excess of positive ions outside plasma membrane increases membrane potential hyperpolarization |
propagation of AP conduction speed
axons with larger diameter have faster conduction speeds |
myelinated axons get signal to axon terminal faster |
saltatory conduction |
myelin sheath increases efficiency and speed of signal conduction; AP only depolarize nodes of Ranvier and "jump over" internodes |
continuous conduction |
every section of unmyelinated membrane from trigger zone to axon terminal must propagate AP; slow conduction speed |
local anesthetic drugs
cause temporary numbness to a specific region of the body |
block voltage gated Na+ channels of neurons in treated area; prohibits depolarization |
causes APs relaying pain to not be transmitted to CNS |
cause temporary paralysis |
neurotransmitters (NT) classifications
function (post synaptic receptor) |
2 main classifications: excitatory or EPSPs and inhibitory IPSPs; or whether receptor directly opens a channel, ionotropic or indirectly, metabotropic. |
structure (mechanisms, NTs cause a change) |
2 main classes: small and large- molecules transmitters; because the functions of specific NTs vary by location thayre usually classified by chemical structure. |
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3 fundamental steps
1. sensory function detects internal and external stimuli |
2. interpretation is made (analysis) |
3. motor response occurs (reaction) |
type of effector regulated
somatic nervous system (SNS) |
info to the somatic effectors, skeletal muscles |
autonomic nervous system (ANS) |
info to autonomic or visceral effectors, smooth muscle, glands, adipose tissue, other involuntary tissue. |
enteric nervous system (ENS) |
info to digestive system effectors |
efferent pathways of ANS
sympathetic division |
pathways exiting the middle of the spinal cord, trigger fight or flight response |
parasympathetic division |
pathways exiting brain or lower portions of the spinal cord, triggers rest and repair response. |
functional classification
Sensory or afferent neurons |
conveys impulse into CNS through cranial or spinal nerves |
Motor or efferent neurons |
convey impulses away from CNS to effectors |
Interneurons/Association neurons |
located between sensory and motor neurons and process sensory info. elicit motor response |
white vs gray matter
white matter |
gray matter |
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composed of cell bodies and unmyelinated fibres |
CNS: myelinated tracts |
CNS: referred to as nuclei (not nucleus) |
PNS: myelinated nerves |
PNS: referred to as ganglia |
changes resting potential (RMP)
depolarization |
Na+ channels open. Allows positively charged Na+ to flow into cell Membrane potential becomes more positive |
repolarization |
K+ channels open. Allows positively charged K+ to flow out of cell. Cell becomes more negative, returning to RMP |
hyperpolarization |
– cell becomes more negative than its normal RMP due to loss of K+ |
3 general phases AP
depolarization phase |
membrane potential rises toward zero, then becomes positive briefly |
repolarization phase |
membrane potential returns to a negative value |
hyperpolarization phase |
membrane potential temporarily becomes more negative than resting membrane potential |
mechanisms that produce AP
1. Stimulus applied to neuron, triggers ligand-gated Na+ channels to open; Na+ diffuses rapidly into cell = local depolarization |
2. If magnitude of local depolarization surpasses a limit threshold potential (-55v) voltage-gated Na+ channels activated |
3. More Na+ enters cell = further depolarization |
4. Action potential is an ALL-OR-NONE response |
5. Voltage-gated Na+ channels stay open for ~1 ms |
6. More Na+ rushes into cell, membrane rapidly moves toward 0mV |
7. continues in a positive direction to peak around +30v; an excess of positive ions inside the membrane |
8. after action potential peaks, membrane potential begins to move back toward the resting membrane potential. |
9. Na+ stop flowing into axon, K+ begins exiting axon as repolarization begins |
10. as neuron's plasma membrane returns to RMP, there is a brief period of hyperpolarization; membrane potential more negative than RMP before K+ channels return to resting state |
11. Na+ channels return to resting state |
12. RMP is restored by Na+- K+ pumps |
summation
summation |
where all input from several postsynaptic potentials are added together ( excitatory postsynaptic potential and inhibitory postsynaptic potential) to affect membrane potential at trigger zone |
2 types |
temporal summation |
NT releases repeatedly from axon terminal of a single presynaptic neuron |
spatial summation |
involves simultaneous release of NT's from axon terminals of many presynaptic neuron. |
synaptic transmission sequence of events
1 AP reaches synaptic knob, causes Calcium Voltage gated channels to ope Ca 2+ diffuses into knob |
2 increase Ca2+ triggers release of NT by exocytosis |
3 neurotransmitters diffuse across synaptic cleft and bind to receptors, causing ion channels to open |
4 opening of ion channels produces a local potential possibly an action potential is threshold is reached |
5 the NT's action is quickly terminated |
large molecule NTs
neuropeptides |
act as neuromodulator: released with other NTs and modifies their effects |
example |
Endorphins, substance P |
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peripheral nervous system
nervous tissue in outer regions of the body |
cranial nerves- originate in brain communicate with peripheral nerve |
spinal nerves - originate in spinal cord |
central nervous system
structural and functional centre |
brain and spinal cord |
brings in incoming sensory info then evaluates info, creates outgoing response |
pathways divisions
afferent division |
carry toward, all incomoing sensory and afferent pathways. |
efferent |
carry away, all outgoing motor or efferent pathways |
Glia
astrocyte (CNS) |
(tight junctions =blood-brain barrier) Connect neurons and capillaries of the brain. transfers nutrients |
microglia (CNS) |
(macrophages) In inflamed brain tissue, they enlarge, move and carry on phagocytosis |
Ependymal cells (CNS) |
Produce or aid in circulation of fluid (help make CSF) |
oligo dendrocytes (CNS) |
Hold nerve fibers together and produce myelin sheath (wraps itself around neuron) |
shwann cells (PNS) |
Hold nerve fibers together and produce myelin sheath (wraps itself around neuron) |
nerves and tracts
NERVES layers of nerves |
bundles of peripheral neurons held together by layers of C.T |
epineurium |
surrounds complete nerve (superficial) |
perineurium |
surrounds bundles of nerve fibres (fascicles) |
endoneurium |
surrounds each neuron (deep) |
in CNS |
bundles of neurons are called tracts or fasciculi not nerves |
remember
(-) inside cells k+, (+) outside cells Na+ |
2 types of electrical signals
local potentials |
short distance, shift away from RMP in a specific region of the plasma membrane. (strength of potential decreases with distance) |
action potentials |
long distance (axon length), only travel from axon hillock to axon terminal only generated in trigger zone (axon hillock, initial segment of axon) |
depolarization channels 3 states AP
Na+ movement is responsible for depolarization |
voltage gated Na+ channels have an activation gate and inactivation gate with 3 states |
resting state |
inactivation gate open and activation gate closed; no Na+ movement |
activated state |
activation and inactivation gates open when an action potential is initiated; due to voltage change |
inactivation state |
inactivation gate closed and activation gate open; no Na+ movement; once action potential is over channel returns to resting state |
refractory period
period after AP when a neurons cannot be stimulated to generate another AP |
propagation of AP sequence
1 the plasma membrane depolarizes to threshold at trigger zone due to local potential |
2 as Na+ channels activate, an AP is triggered and spreads down the axon |
3 the next section of plasma membrane depolarizes to threshold and fires an AP as the previous section of plasma membrane repolarizes |
4 the current continues to move down the axon, and the process repeats |
neuronal synapses
synapses |
where signals are transmitted one neuron (sender presynaptic) to another neuron/muscle (receiver- postsynaptic) |
two kinds |
1 electrical synapses |
cells joined end to end (gap junctions); cardiac muscles cells, smooth muscle cells, parts of brain |
2 chemical synapses |
presynaptic cells release chemical transmitters across a tiny gap to postsynaptic cell, possibly including an AP there |
synaptic knob |
tiny bulge at end of a terminal branch of presynaptic neuron's axon that contains vesicles housing NTs |
synaptic cleft |
space between a synaptic knob and the plasma membrane of a postsynaptic neuron |
PLasma membrane of presynaptic neuron has protein molecules that work as receptors fpr neurotransmitters (NTs) |
Ionotropic receptors |
direct; ion channels |
Metabotropic receptors |
indirect; proteins that bind NT and signals ion flow elsewhere. |
small molecule NTs
acetylcholine |
Excitatory and Inhibitory roles; deactivated by acetylcholinesterase |
amines |
Monoamines and catecholamines ; ex dopamine, epinephrine, norepinephrine |
amino acids |
Common neurotransmitters in CNS; ex Glutamate, Glycine, Aspartate, Gabba aminobutyric acid |
other small molecule transmitters |
Nitric Oxide, Carbon monoxide |
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