Introductory Biology II: Nervous System

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Nervous System pt 1 & 2
Candice Young
Fichas por Candice Young, actualizado hace más de 1 año
Candice Young
Creado por Candice Young hace más de 7 años
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3 meninges (in Humans) protective tissue that protect CNS; 3 layers include Dura Mater (outer), Arachnoid Mater (middle), and Pia Mater (inner)
Cerebrospinal Fluid fluid-filled container that the brain floats in; NOT directly connected to blood
(in mammals) CNS includes: brain and spinal cord
(in mammals) PNS includes: neurons that communicate between CNS and periphery
afferent incoming to the brain
efferent outgoing from the brain
Cerebral Cortex features sulci (folds) & gyri (smooth regions inbetween), both in a left and right hemisphere
Spinal Nerves a part of the PERIPHERAL nervous system, carry signals between spinal cord and body
Dorsal Roots where sensory information comes into the spinal nerves
Dorsal Root Ganglia cell bodies of sensory neurons located here (in PNS)
Ventral Roots motor information leaves from here (in CNS)
Congregations of neural cell bodies Ganglia
Nuclei Many ganglia within the brain
Nissl Stain stains neurons, shows white vs grey matter in visual cortex
White Matter long bits of axon communication tracts between neurons
Grey Matter contains the cell bodies, dendrites, and axon terminals of neurons
"The Neuron Doctrine" The idea that the brain is composed of individual cells
Glial Cells cells that surround neurons in the CNS
Glial Cell Functions provide support and protection to neurons, remove waste, supply nutrients, lay down axon tracts & provide charge
Soma cell body of neuron
Dendrite branched part of neuron
Myelin type of glial outgrowth that wraps around axons; helps speed up conduction and avoid degradation of signal
Direction of information flow along neuron bodies FROM the dendrites, along the axon, and TO the axon terminals
Conductance Measure of an ion's ability to cross the membrane, can change by opening or closing ion channels
How mV is measured: difference in charge "between the inside and the outside"
Concentration Differences Influences ions to diffuse down concentration gradient through open channels
Electrical potential difference Negative charged ions along inside and positive ions on outside --> attracts and repels ions across a membrane
Ion Pumps Na+/K+ ATPase pumps Na+/K+ against their concentration/electrical gradient through this
Concentration of Na+ higher concentrations OUTSIDE the cell
Concentration of K+ higher concentrations INSIDE the cell
At "rest" the membrane is permeable to this ion K+
Resting Membrane Potential a -70 mV charge produced by K+ leaving neurons through leak channels at rest & involvement of Na+/K+ ATPase
Voltage Gated Channels Receptors that change conformation in response to cell depolarization/change in membrane potential
Graded potentials a small change in voltage, will decay along cell fibre if only passively conducted
Action Potential conformational change of voltage gated channel proteins releases Na+ into cell; activation gate opens after depolarization (-55mV) and then inactivation gate closes (at about +30mV); is the signal traveling across synapses!
Threshold Potential the critical level to which a membrane potential must be depolarized in order to initiate an action potential
Absolute Refractory period period where it is impossible to start a second action potential, since a "reset" must first occur (activation gates close and inactivation gates open)
Relative Refractory period after absolute refractory period, possible to generate AP but large stimulus needed
hyper-polarization brief period before neuron reaches resting membrane potential once again, more polarized than at rest
Direction of travel of Action Potential From axon hillock to terminal boutons
Unmyelinated Axons Signal will degrade across these unless the axon diameter is large enough
Types of glial cells that provide myelination for axons Oligodendrocytes and Schwann cells
Nodes of Ranvier gaps in myelin where voltage gated channels are located
Myelin is composed of this bilayers of phospholipids in glial cells
Saltatory Conduction propagation of action potentials along myelinated axons from one node to the next; can be considered "jumping"
Synapses points of contact between nerve/nerve cells or nerve/muscle cells
Electrical Synapses gap junctions between plasma membranes of adjacent cells, bidirectional, instantaneous and direct transmission
Chemical synapses synaptic clefts between pre- and post-synaptic neurons, neurotransmitter chemical released, unidirectional, delayed and excitatory/inhibitory transmission, humans mostly have this
Activation of Chemical Synapses (step by step)
Neurotransmitters chemicals that are released by one neuron and interact with a receptor on the synaptic partner
Acetylcholine (ACh) main neurotransmitter at neuromuscular junctions, acts at nAChR and mAChR ion channel receptors
Nicotine an agonist at nAChRs
Muscarine an agonist at mAChRs
Atropine an antagonist at mAChRs
GABA-A receptor ligand gated ion channel, when ligand bonds it conducts Cl- through its pore which hyper-polarizes the neuron and inhibits an action potential *Picrotoxin blocks channel, can lead to convulsions*
D1 receptors Metabotropic receptor that responds to bonding of dopamine --> G protein activates --> bonds to adenylyl cyclase (using ATP) --> produces cAMP--> downstream effects
mAChRs 5 subtypes of metabotropic receptors, inhibit cAMP and activate GTFs
Photoreceptors cells in the eye that respond to light by change in voltage
Rods responsible for vision at low light levels
Cones responsible for vision at higher light levels, capable of color vision and responsible for high spatial acuity
Rhodopsin membrane proteins that respond to different wavelengths of light
Vitreous Humour gel space in between the lens (front) and the retina (back)
Bipolar cells transmit signals from photoreceptor cells to ganglion cells *amacrine and horizontal cells help integrate the information*
Retinal Ganglion Cells neurons in the inner surface of the retina; receive visual information from photoreceptors and then fire action potentials
Optic Nerve composed of retinal ganglion and glial cells; transmits all visual information from retina to the brain; FORM the optic nerve
fovea small pit packed with cones, responsible for sharp central vision
Optic Chiasm where the "crossing over" of information occurs when being transmitted to the visual cortex
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