Biopsychology: Structure of Neurons PDF

Summary

This document explains the structure of neurons and the process of generating action potentials. It covers topics such as intracellular and extracellular fluids, chemical and electrical gradients, and ion movement. The document also touches upon excitatory and inhibitory neurons.

Full Transcript

BIOPSYCHOLOGY: Generating Action Potentials:

Intracellular Fluid (ICF):
STRUCTURE OF NEURONS: The major ions in the ICF include Potassium
(K+), Phosphate (HPO4^2-), Proteins, and
A neuron is a special type of cell in the body Sodium (Na+).
that is responsible for sending and receiving
messages, which allows different parts of the Extracellular Fluid (ECF):
body to communicate with each other. The major ions in the ECF include Sodium
(Na+), Chloride (Cl-), Calcium (Ca2+), and
The cell body is the neuron's control center, Potassium (K+).
processing incoming signals and maintaining
the neuron's health. Electrochemical gradient is a combination of
a chemical gradient and an electrical gradient
Components of Cell body: that drives the movement of ions across
Nucleus contains the cell's genetic membranes.
material (DNA).
Cytoplasm includes various Chemical gradient is formed due to
organelles, such as mitochondria for energy differences in the concentration of ions
production and ribosomes for protein across the membrane, driving ions from
synthesis. higher to lower concentration.

The dendrites receive signals from other Electrical gradient is formed due to
neurons and conduct electrical messages to differences in electrical charge across the
the cell body. membrane, attracting ions to areas of
opposite charge.
The axon carries electrical impulses away
from the cell body to other neurons, muscles, Diffusion and Ion Movement:
or glands.
Diffusion is the movement of particles from
Components of Axon: an area of higher concentration to an area of
Axon hillock is the cone-shaped lower concentration, particularly involving
region where the axon joins the cell body and ions across the cell membrane.
is the site where action potentials are
initiated. Ion channels are proteins that create specific
Myelin sheath acts as an insulator, pathways for charged ions to pass through
increasing the speed of signal transmission the cell membrane.
along the axon.
Nodes of Ranvier are gaps in the Ion pumps is an active transport mechanisms
myelin sheath where ion channels are that move ions against their concentration
concentrated, allowing the action potential to gradients using ATP.
jump from node to node.
The Sodium-Potassium pump (Na+/K+
The axon terminals are the end points of the ATPase) moves 3 Na+ ions out of the cell and
axon where the neuron makes contact with 2 K+ ions into the cell, maintaining the
other cells and releases neurotransmitters concentration gradients of these ions.
into the synaptic cleft.

Component of Axon Terminal:
Synaptic vesicles contain
neurotransmitters that are released into the
synapse.
The Resting Potential: The all-or-nothing principle states that an
action potential either occurs fully or not at
The resting potential is the electrical all once the threshold is reached.
potential difference across the cell
membrane when the cell is not actively The refractory period is a time-based
sending signals. It is typically around -70 mV, property following an action potential, while
with the inside of the cell being negative propagation describes the movement of the
relative to the outside. action potential along the axon.

Permeability refers to the ability of the cell EXCITATORY AND INHIBITORY
membrane to allow certain substances to
pass through while blocking others. NEURONS:

The Action Potenial: Two main categories of Neurons:

An action potential is a rapid, temporary 1. Excitatory Neurons - they promote the
change in the membrane potential that firing of an action potential in the receiving
travels along the axon of a neuron. neuron.

During depolarization, the membrane Glutamate - most common excitatory
potential becomes less negative (more neurotransmitter in the central nervous
positive) as Na+ ions rush into the neuron. system.

The threshold for triggering an action 2. Inhibitory Neurons - decrease the
potential is around -55 mV. likelihood of postsynaptic neuron firing an
action potential.
During Na+ influx, the influx of Na+ ions
makes the inside of the neuron less negative GABA (gamma-aminobutyric acid) - primary
(more positive), moving the membrane inhibitory neurotransmitter in the brain.
potential towards zero and even beyond.
Key types of Excitatory Neurons:
Repolarization restores the negative resting
membrane potential by the efflux of K+ ions  Pyramidal Neurons: Found in cerebral
out of the cell. cortex, hippocampus, and amygdala;
involved in cognition, memory, and
Hyperpolarization is the process by which the motor control.
membrane potential becomes more negative  Granule Cells: Located in dentate gyrus
than the resting potential. of hippocampus and cerebellum;
involved in memory formation and
Refractory Periods: motor coordination.
 Spiny Stellate Cells: Found in visual
The absolute refractory period is the time cortex; involved in processing visual
immediately following an action potential information.
during which no stimulus can trigger another
action potential. Mechanism of action for Excitatory Neurons:

The relative refractory period is the phase 1. Release glutamate into the synaptic cleft.
following the absolute refractory period 2. Glutamate binds to AMPA and NMDA
during which a neuron can fire another receptors on the postsynaptic neuron.
action potential only in response to a 3. Ion channels open, allowing sodium (Na⁺)
stronger-than-usual stimulus. and calcium (Ca²⁺) ions to flow in.
4. This depolarizes the cell membrane,
moving it closer to the action potential
threshold.
Types of Glutamate Receptors: Mechanism of action for Inhibitory Neurons:

1. AMPA Receptor (a-amino-3-hydroxy-5- 1. Release GABA into the synaptic cleft.
methyl-4-isoxazolepropionic acid) - mediate 2. GABA binds to GABA_A receptors on the
fast synaptic transmission and allow sodium postsynaptic neuron.
ions to enter the neuron, leading to 3. Ion channels open, allowing chloride ions
depolarization. (Cl⁻) to enter the cell.
4. This hyperpolarizes the membrane, moving
AMPA is essential for synaptic plasticity, it further from the action potential threshold.
learning, and memory. They are usually
responsible for the immediate response of a GABA_A Receptors - these are ion channels
neuron to glutamate release. that allow chloride ions to enter the neuron,
leading to hyperpolarization and inhibition of
2. NMDA Receptor (N-methyl-D-aspartate) - neuronal activity.
require both glutamate binding and a
depolarized membrane to activate. GABA_A Receptors regulate neuronal
excitability, which helps reduce anxiety and
NMPA is crucial for synaptic plasticity and promote sleep.
long-term potentiation, which are important
for learning and memory. Some disorders associated with disruptions
in the balance between Excitation and
Key differences between AMPA and NMDA Inhibition:
receptors:
Epilepsy: Excessive neural activity due to
Activation: AMPA receptors are activated failure in inhibitory mechanisms.
solely by glutamate; NMDA receptors require Schizophrenia: Imbalances in excitatory and
glutamate and depolarization. inhibitory signaling affecting thought
Ion Permeability: AMPA receptors are processes.
primarily permeable to sodium (Na⁺); NMDA Anxiety Disorders: Deficits in inhibitory
receptors allow calcium (Ca²⁺) and sodium signaling contributing to heightened anxiety.
(Na⁺).
Role in Plasticity: NMDA receptors are more How do Excitatory and Inhibitory Neurons
significant for synaptic plasticity and long- work together in the brain?
term changes.
Timing: Excitatory neurons fire quickly;
Key types of Inhibitory Neurons: inhibitory neurons calm down later.
Different Targets: They hit different parts of
 GABAergic Neurons: Release GABA, neurons, shaping overall activity.
leading to hyperpolarization of Strength of Signals: Strong excitatory signals
postsynaptic neurons. can still make a neuron fire despite inhibitory
 Basket Cells: Control output of input.
excitatory pyramidal neurons. Learning and Adaptation: Balance can
 Parvalbumin-Positive Neurons: Provide change over time based on experience.
rapid inhibitory signals for timing control. Network Control: Create patterns of activity
 Chandelier Cells: Target axon initial important for brain functions.
segment of pyramidal neurons to inhibit
action potential initiation. SYNAPTIC TRANSMISSION:
 Purkinje Cells: Found in cerebellum;
modulate motor movements through Synapse - point where two cells, like neurons
GABA release. or a neuron and a muscle cell, communicate
with each other.
Communication at synapse is important Types of Synapses based on location:
because it is key to everything the nervous
system does, from moving muscles to 1. Axodendritic - between an axon and a
thinking. dendrite. Most common, usually exitatory.
2. Axosomatic - between an axon and a cell
2 Main Types of Synapses: body, often inhibitory.
3. Axoaxonic - between two axons, often
1. Electrical synapses - allow direct fast modulate neurotransmitter release.
communication between cells through gap 4. Axospinous - involves a dendritic spine,
junctions. important for learning and memory.
5. Dendrodendritic - between two dendrites.
Gap junctions - allow electrical signals to pass 6. Neuromuscular junction - specialized
directly from one cell to another. synapse between a motor neuron and a
muscle cell, built for fast communication to
Electrical synapses are useful for reflex ensure precise control of muscle contractions.
actions because they provide extremely fast
communication. Enzymatic degradation - breakdown of
complex molecules into simpler ones through
The key feature of electrical synapses the action of enzymes in the synaptic cleft.
regarding signal direction, they are both
bidirectional, allowing signals to travel both If there are issues with neurotransmitter
ways. release, it can lead to disorders, emphasizing
the importance of synapses in health and
2. Chemical synapses - more complex and disease.
versatile than electrical synapses.
NEUROTRANSMITTER SYSTEMS:
Chemical synapses involve communication
using chemicals called neurotransmitters.
Neurotransmitter systems are crucial for
brain function.
After neurotransmitters bind to receptors on
the next neuron, they can either excite or
Immunocytochemistry - a technique used to
calm the receiving neuron.
visualize the location of specific proteins or
antigens in cell.
Neurotransmitter recycling - allows
neurotransmitters to be broken down or
In Situ Hybridization - method used to detect
taken back into the first neuron for reuse.
specific mRNA responsible for synthesizing
neurotransmitters.
Binding of neurotransmitters affect the
receiving neuron by leading to a new
Studying Neurotransmitter release:
electrical signal in the receiving neuron,
continuing the communication chain.
 Vitro method - a method commonly
used by stimulating brain slices.
Action potentials trigger the release of
 Optogenetics - a recent advancements
neurotransmitters at chemical synapses.
to activate specific synapses with light.
Synaptic plasticity - process where repeated
Synaptic mimicry - methods to replicate
use of certain synapses strengthens them,
synaptic transmission in a controlled
making it easier to trigger an action potential
environment.
in the future and essential for learning and
memory.
Microiontophoresis - technique used to test if
neurotransmitter candidate evokes a
postsynaptic response.
Studying Receptors:  Endocannabinoids - a class of lipid
molecules that are produced on demand
 Neuropharmacological Analysis - and act in a retrograde manner from
examining how drugs affect postsynaptic to presynaptic neurons.
neurotransmitter receptors.
Gaseous Neurotransmitters:
 Ligand-Binding Methods- techniques to Nitric Oxide (NO) - regulates blood
study the binding of neurotransmitters flow and acts as a retrograde messenger in
to their receptors. the brain.
Carbon Monoxide (CO)
Three categories of neurotransmitters based Hydrogen Sulfide (H2S)
on their chemical structures:
Cholinergic Neurons:
1. Amino Acids Uses acetylcholine (ACh) as their
a) Glutamate - excitatory neurotransmitter that facilitates
b) GABA - inhibitory communication between motor neurons and
2. Amines muscle cells.
a) Dopamine
b) Norepinephrine Choline Acetyltransferase (CHAT) is the
c) Serotonin enzyme synthesizes acetylcholine.
3. Peptides
a) Endorphins Catecholaminergic Neurons:
b) Oxytocin Catecholamines are derived from the
amino acid tyrosine release dopamine (DA),
Amine neurotransmitters regulate mood, norepinephrine (NE) and epinephrine
movement, and attention. (adrenaline), involved in mood regulation,
attention and the fight or fight response.
G-Protein Coupled Receptors (GPCRs) -
initiate slower but more sustained cellular Serotonergic Neurons:
responses through second messenger Neurons that releases serotonin, play
cascades. a role in mood, appetite and sleep.

Evolutionary significance of Selective Serotonin Reuptake Inhibitors
neurotransmitters: (SSRIs) - prevent serotonin from being
reabsorbed into the presynaptic neuron,
 Tied to basic building blocks of life prolonging its action.
(amino acids)
 Used for multiple functions, including Amino Acidergic Neurons:
neurotransmission Glutamate
 Most neurotransmitters are amino acids, GABA
derivatives (amines), or peptides Glycine
 Acetylcholine is synthesized from acetyl
CoA and choline The significance of the balance between
excitatory and inhibitory neurotransmitters
Dale’s Principle - posited by Sir Henry Dale is critical for normal brain function and
that each neuron releases a single type of preventing conditions like seizures.
neurotransmitter.
Dual Roles of Neurotransmitters:
Other Neurotransmitter Candidates:
 Function in neural communication.
 Adenosine Triphosphate (ATP) - widely  Involved in other physiological processes
recognized for its role in cellular throughout the body.
metabolism