PSY 106 Midterm 1 Study Guide PDF

Summary

This document is a study guide for a midterm exam in PSY 106. It covers brain basics, cell biology, and neurons. Includes definitions of key terms and concepts. It's geared toward undergraduate-level study of the subject.

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PSY 106 Midterm 1 Study Guide
EXAM 1 is on 10/23/24 at 3:30 pm, in person in CHEM 1179

Week 1 (9/30-10/4)

Brain Basics, Cell Biology Basics, Neurons
➔ Define the term “biopsychology”
◆ Biopsychology is the biological approach to psychology that studies the
relationship between behavior and the brain
◆ “Behavioral neuroscience”
What is the physiological basis for emotions?
What changes in the brain when someone learns something new?
How do we recognize familiar faces?
➔ Differentiate between the central and peripheral nervous systems
◆ Central Nervous System (CNS)
Consists of the brain and spinal cord.
Processes and integrates sensory information; responsible for higher
brain functions (e.g., thinking, emotions).
Encased in the skull and vertebral column; protected by cerebrospinal
fluid and the blood-brain
barrier.
Limited ability to regenerate
after injury.
◆ Peripheral Nervous System (PNS)
Includes all nerves outside
the CNS, such as cranial
nerves and spinal nerves.
Connects the CNS to the rest
of the body; responsible for
transmitting sensory information to the CNS and motor commands from
the CNS to muscles.
Not protected by bony structures; more vulnerable to injury.
Greater capacity for regeneration after injury compared to the CNS.
➔ List the main animal species used in biopsychology research
◆ Rodents (usually rats or mice)
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◆ Non-human primates (macaques & marmosets)
◆ Aquatic vertebrates (fish & frogs)
◆ Squid
◆ Flies
◆ Worms
➔ List the major components of a typical cell
◆ Plasma membrane: A thin outer layer that controls what enters and exits the
cell; composed of a phospholipid bilayer
◆ Nucleus: The "control center" of the cell, containing most of the cell's DNA and
the nucleolus.
◆ Mitochondria: responsible for generating ATP
◆ Ribosomes: Responsible for protein synthesis
➔ Describe the key properties of the plasma membrane
◆ Composed of phospholipid bilayer
◆ Has two sets of phospholipid molecules, facing in opposite directions
Hydrophobic tails face inwards, hydrophilic tails face
◆ Selectively permeable
Some molecules can freely pass across the bilayer (like oxygen), but
many others need to use special hallways (called channels) or active
transporters
➔ Explain what ATP is and why it is important for a cell
◆ ATP (Adenosine Triphosphate): Primary energy carrier in cells.
Brain uses more energy than any other organ in the body
◆ Composed of adenine, ribose, and three phosphate groups.
◆ Energy is released when ATP is hydrolyzed to ADP and a phosphate group.
◆ Importance:
Powers cellular processes like muscle contraction, active transport, and
biochemical reactions.
Essential for metabolism, protein synthesis, and DNA replication.
➔ Describe the process through which DNA results in proteins
◆ Transcription:
Occurs in the nucleus.
DNA is transcribed into mRNA by RNA polymerase.
mRNA carries genetic information from DNA to the ribosomes.
◆ Translation:
Happens at the ribosome.
tRNA brings amino acids based on codons in mRNA.
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Ribosome links amino acids into a polypeptide chain.
Polypeptide folds into a functional protein.

➔ Define the terms cation, anion, monovalent, and divalent
◆ Cation: Positively charged ion (e.g., Na⁺).
◆ Anion: Negatively charged ion (e.g., Cl⁻).
◆ Monovalent: Ion with a charge of +1 or -1 (e.g., Na⁺, Cl⁻).
◆ Divalent: Ion with a charge of +2 or -2 (e.g., Ca²⁺, SO₄²⁻).
➔ Explain how we have come to learn about the brain and what it’s made out of
◆ Early observations:
Nissl stain (by Franz Nissl) stains the nucleus of cells and the rough ER
surrounding it- results in all cell bodies being darkened

Golgi stain (by Camillo Golgi) darkens entire cells with silver, but only a
small percentage of them, at random

◆ Microscopy:
Led to the neuron doctrine (Ramón y Cajal).
○ The brain is made up of individual neurons that connect to one
another with long projections
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◆ Modern techniques:
Neuroimaging (e.g., MRI, fMRI, PET scans): Non-invasive brain imaging.
Electrophysiology: Measures electrical activity in neurons.
Molecular biology: Studies the brain at the genetic and protein level.
◆ Brain composition: Neurons, glial cells, and other structures for information
processing and bodily regulation.
➔ Describe what makes a neuron different from other cell types
◆ Excitability: Can generate and propagate electrical impulses (action potentials).
◆ Synaptic transmission: Communicates via neurotransmitter release at synapses.
◆ Unique structure:
Dendrites (receive signals), axon (transmit signals), soma (cell body).
◆ Polarity: Signals flow in one direction—from dendrites to axon terminal.
➔ Label the parts of a typical neuron
◆ Dendrites: Receive signals from other neurons.
◆ Cell body (soma): Contains nucleus and organelles; integrates signals.
◆ Axon: Transmits electrical impulses away from the soma.
◆ Axon hillock: Where the axon connects to the soma; action potentials initiated.
◆ Myelin sheath: Insulates axon, speeding up signal transmission.
◆ Nodes of Ranvier: Gaps in the myelin sheath where action potentials are
regenerated.
◆ Axon terminal: Releases neurotransmitters to communicate with other neurons.
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Week 2 (10/7-10/13)

Glia; Membranes & Potentials; The Action Potential
➔ Compare and contrast various glia types and their functions
◆ Astrocytes
Location: Central Nervous System (CNS)
Functions:
○ Structural support: Astrocytes provide physical scaffolding for
neurons and maintain the structural integrity of the brain.
○ Nutrient supply: They regulate the blood-brain barrier and help
deliver nutrients from the bloodstream to neurons.
○ Waste removal: Astrocytes participate in clearing excess
neurotransmitters and metabolic waste.
○ Ion balance: They regulate the extracellular environment by
maintaining ion balance, particularly potassium (K+), around
neurons.
○ Neurotransmitter recycling: Astrocytes uptake and recycle
neurotransmitters like glutamate and GABA, preventing
excitotoxicity.
○ Modulation of synaptic activity: They release gliotransmitters that
modulate neuronal signaling.
◆ Microglia
Location: CNS
Functions:
○ Immune defense: Microglia act as the primary immune cells of the
CNS. They respond to infection, injury, or disease by removing
pathogens and dead cells through phagocytosis.
○ Synaptic pruning: During development and in response to injury,
microglia help refine neural circuits by eliminating unnecessary
synapses.
○ Inflammatory response: Microglia produce inflammatory
cytokines and other signaling molecules to recruit immune cells
when needed, but chronic activation can contribute to
neuroinflammation in diseases like Alzheimer's.
◆ Oligodendrocytes
Location: CNS
Functions:
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○ Myelination: Oligodendrocytes form the myelin sheath around
axons in the CNS. This sheath increases the speed of action
potentials by facilitating saltatory conduction.
○ Support: They supply metabolic support to neurons, particularly
to the long axons that they myelinate.
◆ Schwann Cells
Location: Peripheral Nervous System (PNS)
Functions:
○ Myelination: Similar to oligodendrocytes, Schwann cells produce
the myelin sheath in the PNS, which helps in the rapid
transmission of electrical signals along peripheral nerves.
○ Axonal regeneration: In the event of injury in the PNS, Schwann
cells play an essential role in guiding axonal regrowth and repair.
➔ Describe the important ions inside and outside of the neuron and compare their
concentration gradients

◆ Sodium ions (Na⁺):
Outside the neuron: High concentration.
Inside the neuron: Low concentration.
Concentration gradient pushes Na⁺ into the neuron, but Na⁺ channels
remain closed during resting potential, preventing influx.
○ STRONG inward driving force
◆ Potassium ions (K⁺):
Outside the neuron: Low concentration.
Inside the neuron: High concentration.
Concentration gradient pushes K⁺ out of the neuron, but the selective
permeability of the neuron membrane allows some K⁺ to leak out,
maintaining resting potential.
○ WEAK outward driving force
◆ Chloride ions (Cl⁻):
Outside the neuron: High concentration.
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Inside the neuron: Low concentration.
Cl⁻ concentration gradient pulls it into the cell, but it typically remains
balanced due to electrostatic forces and chloride channels.
○ Little to no driving force
◆ Calcium ions (Ca²⁺):
Outside the neuron: High concentration.
Inside the neuron: Very low concentration.
Ca²⁺ enters the neuron during synaptic transmission, triggering
neurotransmitter release, but it is actively pumped out afterward to
maintain low intracellular levels.
○ STRONG inward driving force
➔ Explain how diffusional and electrostatic forces act upon ions
◆ Diffusional (concentration) forces:
Moving ions fro regions of high concentration to regions of low
concentration
○ A difference in concentration between regions is called a
concentration gradient
For example:
○ Sodium ions (Na⁺) are more concentrated outside the neuron, so
diffusional forces push Na⁺ into the neuron.
○ Potassium ions (K⁺) are more concentrated inside the neuron, so
diffusional forces push K⁺ out of the neuron.
Diffusional forces occur due to the random movement of particles and
are independent of the ions' electrical charge.
◆ Electrostatic forces:
Moving ions based on electrical charge
○ Opposite charges attract (e.g., positive ions are drawn to
negatively charged areas).
○ Like charges repel (e.g., two positive ions will push away from
each other).
A difference in charge is called electric potential, or voltage
➔ Describe how ions can cross the phospholipid bilayer
◆ Ion channels:
Ion channels are proteins embedded in the phospholipid bilayer that
provide a passageway for ions to move across the membrane.
Channels are selective for specific ions (e.g., Na⁺, K⁺, Cl⁻) and can be
either open or gated (closed until a stimulus opens them).
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○ Leak channels: Always open, allowing specific ions (e.g., K⁺) to
move down their concentration gradient.
○ Voltage-gated channels: Open or close in response to changes in
membrane potential (e.g., Na⁺ channels open during an action
potential).
➔ Define resting membrane potential, threshold potential, and action potential
◆ The resting membrane potential is the electrical charge difference across the
neuron's membrane when it is not actively sending a signal (i.e., at rest).
Typically around -65 mV, the inside of the neuron is more negative
compared to the outside.
◆ The threshold potential is the critical level of membrane depolarization that
must be reached for an action potential to be triggered.
Usually around -55 mV, if the neuron’s membrane potential reaches this
value, voltage-gated sodium channels open, allowing Na⁺ to rush into
the cell.
◆ The action potential, also called a “spike”, is a rapid and dramatic redistribution
of charge across the membrane
This is an essential element of communication between neurons
Allows for the transmission of information across very long distances
➔ Explain the concept of an equilibrium potential for an ion
◆ The equilibrium potential for an ion is the membrane potential at which there is
no net movement of that ion across the membrane. At this point, the ion’s
concentration gradient (diffusion) and electrostatic forces (charge) are balanced.
◆ Each ion has its own equilibrium potential, calculated using the Nernst equation.
For example:
○ Potassium (K⁺) has an equilibrium potential of about -80 mV.
○ Sodium (Na⁺) has an equilibrium potential of around +60 mV.
➔ Describe the phases of an action potential and what sodium and potassium ions are
doing during them
◆ States:
Resting state:
○ Membrane potential: ~65 mV.
○ Na⁺ and K⁺ channels are closed, and the sodium-potassium pump
maintains the resting potential.
Depolarization:
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○ Na⁺ channels open, and Na⁺ rushes into the neuron, making the
inside more positive. Membrane potential gets closer to 0
(becomes equal to outside of cell)
○ Membrane potential rapidly rises toward +30 mV.
Repolarization:
○ Na⁺ channels close, and K⁺ channels open.
○ K⁺ flows out of the neuron, restoring the negative charge inside.
Hyperpolarization:
○ K⁺ channels remain open briefly, causing the membrane to
become more negative than the resting potential. Membrane
potential gets farther from zero.
Return to resting potential:
○ K⁺ channels close, and the sodium-potassium pump restores the
resting state by moving Na⁺ out and K⁺ in.
◆ Phases:
Rising Phase: Voltage-gated Na⁺ channels are now able to open up, and
since Na⁺ is under strong diffusional and electrostatic forces, Na⁺ ions
rapidly rush into the neuron, depolarizing it further (making it less
negative)
Overshoot: Sodium’s equilibrium potential is very positive (around 60
mV): Na⁺ ions will enter the cell for as long as sodium channels are open
Falling Phase: With Na⁺ no longer entering the cell and K⁺ now rushing
out, the action potential is in the falling phase (repolarization)
Undershoot: Voltage gated K⁺ channels remain open, allowing K⁺ to
continue flowing outward in an attempt to reach the K⁺ equilibrium
potential of -80 mV
➔ Compare the absolute and relative refractory periods and what causes them
◆ Absolute Refractory Period:
No second action potential can be initiated, regardless of stimulus
strength.
Duration: During depolarization and most of repolarization.
Cause: Inactivation of Na⁺ channels prevents reopening until the
membrane potential returns to a certain level.
◆ Relative Refractory Period:
A second action potential can be initiated, but only with a
stronger-than-normal stimulus.
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Duration: After the absolute refractory period, during the latter part of
repolarization and undershoot.
Cause: Open K⁺ channels lead to hyperpolarization, requiring a stronger
stimulus to reach the threshold.
➔ Explain how the sodium-potassium pump functions to maintain potassium and
sodium distributions
◆ The sodium potassium pump has to continually work to get things back to
normal
The pumps take 3 molecules of sodium from the inside and push them
outside, and take 2 molecules of potassium from the outside and push
them in
○ The process uses a lot of ATP since it is working against the
concentration gradient

Week 3 (10/14-10/20)

Synaptic Transmission & Neurotransmitters
➔ Describe where action potentials originate and how they travel down the axon
◆ Action potentials originate at the axon hillock
(trigger zone).
◆ The action potential is propagated down the axon
toward the axon terminals
◆ They travel down the axon by depolarizing sections
of the membrane in a wave-like manner, where
sodium (Na+) ions enter and potassium (K+) ions
exit.
➔ Explain what myelin is and how it results in saltatory conduction
◆ Myelin is a fatty substance that insulates axons, produced by Schwann cells
(PNS) or oligodendrocytes (CNS).
◆ Myelinated axons conduct action potentials faster
through saltatory conduction, where the signal jumps
between Nodes of Ranvier.
V-gated sodium channels are only at the
nodes
◆ Saltatory conduction: leaping conduction
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➔ Compare and contrast electrical and chemical synapses
◆ Electrical synapses: Direct ion flow between cells via gap junctions; fast but less
flexible; simpler than chemical synapses
More common in invertebrates
◆ Chemical synapses: Use neurotransmitters to transfer signals across a synaptic
cleft; slower but highly adaptable.
Acts on specific receptors on the receiving cell’s surface
➔ Identify the proteins and ions that are required for neurotransmitter release
2+
◆ Calcium ions (𝐶𝑎 ) trigger vesicle fusion.
◆ SNARE proteins (syntaxin, SNAP-25, synaptobrevin) are essential for vesicle
docking and neurotransmitter release.
Found on the membrane of the vesicles and on the neuronal membrane
itself
➔ Describe the sequence of events that results in the release of neurotransmitter
◆ Action potential reaches the axon terminal.
2+
◆ Voltage-gated 𝐶𝑎 channels open, allowing calcium to enter.
◆ Synaptic vesicles fuse with the membrane, releasing neurotransmitters.
◆ Neurotransmitters diffuse across the synapse and bind to receptors.
➔ Define “ligand” and “receptor”
◆ Ligand: A molecule that binds to a receptor (e.g., neurotransmitter).
◆ Receptor: A protein on the cell surface that ligands bind to, initiating a response
➔ Compare and contrast ionotropic and metabotropic receptors
◆ Ionotropic receptors: receptor is an ion channel, ions rapidly flow through with
open (depending on driving force); can also call these “transmitter-gated ion
channels
Ligand-gated ion channels, fast-acting, direct effects on ion flow.
◆ Metabotropic receptors: ligand induces change in shape that leads to
intracellular cascade of events
Many different effects, depending on protein complex
Receptor is connected to multiple pathways inside the cell
G-protein-coupled receptors, slower, indirect, activate secondary
messenger pathways (chain reaction from single transmitter)
➔ Explain how excitatory and inhibitory postsynaptic potentials are generated
◆ EPSPs: Generated by depolarization (e.g., Na+ influx),
making action potentials more likely.
◆ IPSPs: Generated by hyperpolarization (e.g., Cl- influx),
making action potentials less likely.
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➔ Compare and contrast spatial and temporal summation of postsynaptic potentials
◆ Spatial summation: Multiple signals from different synapses combine at the
postsynaptic neuron.
◆ Temporal summation: Rapid, successive signals from the same synapse combine
over time.

➔ Describe the synthesis, effects, and clearance methods of a few key
neurotransmitters

Neurotransmitter Where does it What does it Where does it Function in the
come from? bind to? go nervous system
afterwards?

Glutamate Synthesized in Ionotropic Reuptake by Primary excitatory
neurons from receptors: glial cells neurotransmitter in
glutamine via NMDA, AMPA, (astrocytes) or the CNS, involved in
the enzyme kainate glutamate learning, memory,
glutaminase. receptors transporters and synaptic
(excitatory). plasticity.
Metabotropic
receptors:
mGluR
(metabotropic
glutamate
receptors).

GABA Synthesized Ionotropic Reuptake by Primary inhibitory
from receptors: presynaptic neurotransmitter in
glutamate by GABA-A neurons or the CNS, involved in
the enzyme receptors glial cells via reducing neural
glutamic acid (chloride GABA excitability,
decarboxylase channels, transporters regulating muscle
(GAD) in inhibitory). (GAT), then tone, and preventing
neurons. degraded by overstimulation.
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GABA
transaminase.

Acetylcholine (ACH) Synthesized in Ionotropic Broken down Involved in muscle
neurons from receptors: in the synaptic contraction (PNS),
choline and Nicotinic cleft by autonomic nervous
acetyl-CoA by acetylcholine acetylcholinest system functions,
the enzyme receptors erase (AChE) attention, learning,
choline (nAChRs). into choline and memory (CNS).
acetyltransfera Metabotropic and acetate;
se (ChAT). receptors: choline is
Muscarinic taken back up
acetylcholine into the neuron
receptors for reuse.
(mAChRs).

Dopamine Synthesized in Metabotropic Reuptake by Regulates reward
neurons from receptors: presynaptic and motivation,
tyrosine via D1-like neurons via motor control, and
tyrosine (excitatory) dopamine mood. Dysregulation
hydroxylase and D2-like transporters is implicated in
and DOPA (inhibitory) (DAT); broken Parkinson’s disease
decarboxylase. dopamine down by and schizophrenia.
receptors. monoamine
oxidase (MAO)
and
catechol-O-me
thyltransferase
(COMT).

Serotonin Synthesized Ionotropic Reuptake by Regulates mood,
from receptors: presynaptic sleep, appetite, and
tryptophan by 5-HT3 neurons via pain perception.
tryptophan receptors. serotonin Imbalances are
hydroxylase Metabotropic transporters linked to depression
and aromatic receptors: (SERT); and anxiety
L-amino acid Several 5-HT degraded by disorders.
decarboxylase. receptor monoamine
subtypes (e.g., oxidase (MAO).
5-HT1A,
5-HT2A).
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Week 4 (10/21-10/27)

Recap and Review
➔