Development of Human Behavior PDF

Summary

This document provides an overview of human behavior, focusing on developmental psychology concepts, genetics, and various aspects of the nervous system. It covers the development stages, genetic influences on the fetus, environmental impacts during gestation, and neuronal structure and communication. It also details different types of brain cells and their respective roles in supporting the neurons.

Full Transcript

Development
of Human
Behavior
Development of Human Behavior

Nature and Nurture

Developmental psychology is the branch of
psychology that studies the patterns of growth and
change that occur throughout life.

developmental psychologists today agree that both
nature and nurture interact to produce specific
developmental patterns and outcomes

Nurture – environmental causes of behavior
Nature – hereditary causes of behavior
Development of Human Behavior

Basics of Genetics
The one-cell entity established at conception
contains 23 pairs of chromosomes, rod-shaped
structures that contain all basic hereditary
information.
Genes
smaller units through which genetic information is transmitted
Composed of sequences of DNA (deoxyribonucleic acid)
equivalent of “software” that programs the future development of all
parts of the body’s hardware
Humans have 20,000 to 25,000 different genes
Development of Human Behavior
Earliest Development

Germinal Period – first two weeks
Zygote – egg becomes familiarized by the sperm, the resulting one-celled entity
Embryonic Period – lasts from week 2 through week 8
Embryo – develops through an intricate, programmed process of cell division,
developed a rudimentary beating heart, a brain, an intestinal tract, and a number
of other organs
Fetal Period – week 8 and continuing until birth
Fetus – movement become strong enough for the mother to sense them; the
major organs begin functioning
Development of Human Behavior
Genetic Influences on the Fetus

95 to 98 percent of all pregnancies – normal development
2 to 5 percent of cases – born with defects

Common Genetic And Chromosomal Difficulties.
Phenylketonuria (PKU) – cannot produce an enzyme that is required for normal
development; results in an accumulation of poisons that eventually cause
profound intellectual disabilities

Sickle-cell anemia – abnormally shaped red blood cells; results in pain,
yellowish eyes, stunted growth, and vision problems
 Development of Human Behavior
Genetic Influences on the Fetus

Common Genetic And Chromosomal Difficulties.

Tay-Sachs disease – usually die by age 3 or 4 because of the body’s inability to
break down fat
Down syndrome – zygote receives an extra chromosome at the moment of
conception; one of the causes of severe mental disabilities
Prenatal Environmental Influences
Mother’s nutrition Alcohol - fetal alcohol syndrome
Mother’s illness disorder (FASD), a condition
Mother’s use of drugs resulting in below-average
Nicotine intelligence, growth delays, and
facial deformities
Development of Human Behavior
The Structure of a Neuron

Dendrites are processes that extend outward
Soma or cell body of a neuron
Nucleus which is located within the soma,
contains genetic information, directs protein
synthesis, and supplies the energy
Axon is a process that extends far away from the
soma and carries an important signal called an
action potential to another neuron
Development of Human Behavior
The Structure of a Neuron

Myelin sheath an insulating substance covering
the axon of a neuron
Terminal Button forms synapses with spines, or
protrusions, on the dendrites of neuron at the end
of the axon
presynaptic terminal button – sending signal
postsynaptic membrane – receiving signal
Development of Human Behavior
The Structure of a Neuron

Synaptic Gap/Synaptic Cleft – exists between the
presynaptic terminal button and the postsynaptic
dendritic spine
Synaptic Vesicles – package together groups of
chemicals called neurotransmitters
Neurotransmitters - released from the presynaptic
terminal button, travel across the synaptic gap,
and activate ion channels on the postsynaptic
spine by binding to receptor sites
Development of Human Behavior
Types of Cells in the Brain

Sensory Neurons – neurons that help us receive
information about the world around us
Motor Neurons – allow us to initiate movement and
behavior, ultimately allowing us to interact with the world
around us
Interneurons - process the sensory input from our
environment into meaningful representations
Development of Human Behavior
Types of Cells in the Brain
Glial Cells- “glue of the nervous system”; provide
support for the neurons

Oligodendroglia – wrap their dendritic processes around the axons
of neurons many times to form the myelin sheath

Microglia and Astrocytes - digest debris of dead neurons, carry
nutritional support from blood vessels to the neurons, and help to
regulate the ionic composition of the extracellular fluid

Glial Cells play a vital role in neuronal support, they do not
participate in the communication between cells in the same
fashion as neurons do.
Development of Human Behavior
Types of Cells in the Brain

Three Main Categories Of Neurons

1. Unipolar neurons are structured in such a way that is ideal for
relaying information forward, so they have one neurite (axon)
and no dendrites
2. Bipolar neurons are involved in sensory perception such as
perception of light in the retina of the eye; one axon and one
dendrite which help acquire and pass sensory information to
various centers in the brain
3. Multipolar neurons have one axon and many dendrites which
allows them to communicate with other neurons.
Development of Human Behavior
Neuronal Communication

Neuron exists in a fluid environment – cytoplasm.
Electrical signal that passes through the neuron depends
on membrane potential
The electrical charge of the fluids is caused by charged
molecules (ions) dissolved in the fluid
The neuron membrane’s potential is held in a state of
readiness – resting potential.
Ions in high-concentration areas are ready to move to low-
concentration areas, and positive ions are ready to move
to areas with a negative charge
Development of Human Behavior
Neuronal Communication

Sodium (Na+) is at higher concentrations outside the cell
Potassium (K+) is more concentrated inside the cell
The inside of the cell is negatively charged providing force
for sodium to move into the cell
Development of Human Behavior
Neuronal Communication
From resting potential state, the neuron receives a signal
and its state changes abruptly
With this influx of positive ions, the internal charge of the
cell becomes more positive reaching a level called
threshold of excitation
Development of Human Behavior
Neuronal Communication

At the peak of the spike, the sodium gates close
and the potassium gates open.
As positively charged potassium ions leave, the
cell quickly begins repolarization.
It hyperpolarizes, becoming slightly more
negative than the resting potential, and then it
levels off, returning to the resting potential
Development of Human Behavior
Neuronal Communication

Positive spike constitutes the action potential: the
electrical signal that typically moves from the cell
body down the axon to the axon terminals
The electrical signal moves down the axon with the
impulses jumping in a leapfrog fashion between the
Nodes of Ranvier – natural gaps in the myelin
sheath.
Incoming signal from another neuron is either
sufficient or insufficient to reach the threshold of
excitation
Development of Human Behavior
Neuronal Communication

When the action potential arrives at the terminal
button, the synaptic vesicles release their
neurotransmitters into the synaptic cleft
The neurotransmitters travel across the synapse
and bind to receptors on the dendrites of the
adjacent neuron, and the process repeats itself in
the new neuron
Excess neurotransmitters in the synaptic cleft drift
away, are broken down into inactive fragments, or
are reabsorbed
Development of Human Behavior
Neuronal Communication
Reuptake involves the neurotransmitter being
pumped back into the neuron that released it, in
order to clear the synapse.
Clearing the synapse serves both to provide a clear
“on” and “off” state between signals and to regulate
the production of neurotransmitter
Neuronal communication is often referred to as an electrochemical event.
Movement of the action potential down the length of the axon is an
electrical event
movement of the neurotransmitter across the synaptic space represents
the chemical portion of the process
NEURON https://youtu.be/zADj0k0waFY