UNRS 367 week 1 (1).pdf

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UNRS 367:
PATHOPHYSIOLOGY
KATIE MEYER MSN, RN, PHN, CCRN-K, NHDP-BC

ADAPTED FROM THE SLIDES FROM

LORI J. SILAO, PHD, RN, MN, NNP-BC
QUESTION FOR THOUGHT

What is pathophysiology and why is it important for clinical practice?
ANSWER:

Let’s Define It:
Physiology- the study of specific characteristics and functions of living organisms
Physis- Nature
Pathos- (Greek) suffering or disease

Therefore:
Pathophysiology is the study of disease or disorder of the human body
PATHOPHYSIOLOGY

Can we break these down?
 Homeostasis
 Disease
 Illness
 Epidemiology (endemic, epidemic, pandemic)
 Allostasis
QUESTION FOR THOUGHT:

How might disease interrupt homeostasis?
HOMEOSTASIS

Homeostasis and Systems Control

Homeostasis refers to stable operating conditions in the internal environment (in
the blood and interstitial fluid).

This is how the human body maintains a rather constant internal environment
despite changing external conditions

It is brought about by coordinated activities of cells, tissues, organs, and organ
systems
HOMEOSTASIS

Homeostasis requires three components:
1. Sensory receptor cells detect specific changes (stimuli) in the environment.

2. Integrators (brain and spinal cord) act to
direct impulses to the place where a response can be made.

3. Effectors (muscles and glands) perform the
appropriate response*

*Think GAS (General Adaptation Syndrome)
 A common homeostatic mechanism is negative feedback. It
works by detecting a change in the internal environment that
brings about a response that tends to return conditions to the
original state.

It is similar to the functioning of a thermostat in a
heating/cooling system. Some activity alters a condition in the
internal environment. The alteration triggers a response. The
response reverses the altered condition.

Think self-regulation!
 Again, the variable to be controlled must be
“sensed” to be regulated, examples:

1. When body temp. deviates from normal, negative
feedback restores homeostasis. The temp. (variable) is
“sensed” and the body responds by sweating.
 Another example:

High blood glucose levels (variable) is “sensed” and
the body responds by increased insulin production by
the pancreas, returning blood glucose levels to normal,
thus maintaining homeostasis.
 Another (less common) form of feedback for homeostatic
maintenance

In positive feedback, some activity alters the internal
environment. The alteration triggers a response. The response
intensifies the change in the internal condition. Positive
feedback mechanisms may intensify the original signal.
Only a few positive feedback examples operate in the body under normal
conditions:
1. Birth of a baby
2. Formation of a blood clot
 Contraction – oxytocin – nerve stimulus – hypothalamus – oxytocin -
contraction….repeat!

Injury – signals – platelets – more signals – rapid cascade – blood clot….repeat!

Can you find one more example?
 The study of the cause or reasons for phenomena (In this case, a disease)

A description of etiological process includes the identification of those causal
factors that provoke the disease
 Idiopathic: Iatrogenic:
The cause of the illness or disease is The cause of the illness or disease is
unknown from a medical treatment or
medical professional
 Infectious

Inherited Iatrogenic

Congenital Psychogenic

Metabolic Idiopathic

Degenerative Nutritional deficiency

Neoplastic Physical-agent

Immunologic

Psychosomatic: old school term, not used anymore,
carries a stigma.
 The development or evolution of disease
(think initial stimulus to the ultimate expression)

Varies with the causative agent and type of cell, tissue or organ
affected
 Time
Quantity
Location
Morphologic changes
 Time: the disease can be in its early or late stages OR the disease process may be
acute or chronic
Quantity: offering an amount of the infective agent; can be slight, moderate or marked
 Location: where in the body the invasion/illness is present
Morphologic Changes: the structural and associated functional alterations in
cells or tissues that are either characteristic of the disease or diagnostic of the
etiological process
 Primary: reducing susceptibility or exposure to disease or illness
Secondary: the early detection, screening and managing of a disease
Tertiary: includes rehabilitative and supportive care
1. What role does
stress play in the
development of
disease?
General Adaptation Syndrome

Spring 2015 23
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Spring 2015 24
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Cathecholamines
Norepinephrine:
Constricts blood vessels and raises blood pressure
Reduces gastric secretions
Increases night and far vision

Epinephrine:
Enhances myocardial contractility, increases heart rate, and increases cardiac output
Causes bronchodilation
Increases the release of glucose from the liver (glycogenolysis) and elevates blood
glucose levels
Adrenocortical Steroids:
Critical to maintenance of homeostasis
May synergize or antagonize effects of catecholamines
Examples: Cortisol and aldosterone

Cortisol:
Primary glucocorticoid
Affects protein metabolism
Promotes appetite and food-seeking behaviors
Suppress acute-phase response to
inflam. by decreasion overactivity.
Helps preserve glucose for brain cells.

Aldosterone
Primary mineralocorticoid
Secreted by adrenal cortex, binds to
kidneys distal/collecting ducts.
Promotes the reabsorption of Na & H20
Increases blood pressure Spring 2015
Immune Cytokines:
Secreted by macrophages during stress
response
Enhance immune system response
Prolonged stress can suppress immune functioning

Endorphins, Enkaphalin:
Small peptides, endogenous opioids produced within the CNS.
Release in response to stressors, certain foods (chocolate), laughter, massage,
accupunture.
Increase pain threshold (lowers pain).
Produces sedation as well as euphoria.
Growth Hormone (GH):
Released from the anterior pituitary
Increased secretion during strenuous exercise
Extreme stress leads to decrease in GH (i.e.chronic illness, children under severe abuse).

Prolactin:
Released from the anterior pituitary
Secreted in response to stress, sexual activity, suckling (men included), breastfeeding.

Oxytocin:
Secreted from anterior pituitary
Childbirth, lactation, sexual behavior.
Promotes bonding and social attachment.
HOMEOSTASIS VERSUS ALLOSTASIS
CELLS

What do you remember about what cells do?
Draw a cell and any of the components you
remember about a cell.
 What are the major cellular structures and their functions?

Plasma Membrane
Cytoskeleton
Nucleus
Endoplasmic Reticulum
Golgi Apparatus
Lysosomes & Peroxisomes
Mitochondria
CELLULAR STRUCTURE AND FUNCTION REVIEW
 According to the accepted current theory, known as the fluid mosaic
model, the plasma membrane is composed of a double layer (bilayer) of
lipids, oily substances found in all cells. Most of the lipids in the bilayer can
be more precisely described as phospholipids.

Phospholipids are characteristically hydrophilic ("water-loving") at their
phosphate ends and hydrophobic ("water-fearing") along their lipid tail
regions.

Plasma Membrane’s Functions
Transport nutrients and waste products
Generate membrane potentials
Cell recognition and communication
Growth regulation
Sensor of signals that enable cell to respond and adapt to
changes in environment.
 The cytoskeleton provides both the supporting structure of the
cell and the vehicle for internal transport processes.

It is a network of long protein filaments, mainly microtubules,
actin filaments and intermediate filaments, coupled by smaller
proteins, such as motor proteins.

Motor proteins are molecular machines that convert chemical
energy derived from the hydrolysis of ATP (Adenosine
TriPhosphate) into mechanical work, generating forces and
motion of the filaments relative to each other in this complex
fluid.
 The cell nucleus is one of the largest organelles found in cells and
also plays an important biological role.

It composes about 10% of the total volume of the cell and is found
near the center of eukaryotic cells.

Its importance lies in its function as a storage site for DNA, our
genetic material.

The cell nucleus is composed of two membranes that form a
porous nuclear envelope, which allows only select molecules in
and out of the cell.
 The DNA that is found in the cell nucleus is packaged into
structures called chromosomes.

Chromosomes contain DNA and proteins and carry all the
genetic information of an organism.

The nucleus gains support from intermediate filaments that
both form the surrounding nuclear lamina and makes direct
contact with the endoplasmic reticulum.

The nucleus is also the site of DNA and RNA synthesis.
Spring 2015
 The endoplasmic reticulum plays a role in both the transport of large
molecules in the cytoplasm and protein synthesis.

The ER is divided into two different parts: The rough and the smooth
ER. The two, together, make up over half of a cell membrane and extend
through the cytoplasm to the nuclear membrane.

Central role in synthesis of membrane components.

Rough and smooth types.
Rough: coated with ribosomes, complexes of protein, and RNA
Smooth: lacks ribosomes; involved with lipid metabolism
 The Golgi apparatus is a part of the membrane system within the cell
as well and works closely with the endoplasmic reticulum.

The Golgi Apparatus modifies proteins and brings them to the cell surface
where they can be secreted.

Secretions
hormones, enzymes, antibodies and other molecules.
 Lysosomes are membrane bound vesicles whose purpose
is to help with the digestion of molecules.

They are able to do this because of their acidic interior
which contains digestive enzymes.

They also make sugars, amino acids, and bases which help
create the foundation of the very macromolecules they
digest
 Like Lysosomes, these are membrane
bound sacks of enzymes
Particularly important in liver and
kidney cells
Detoxify substances such as alcohol
 Known as the cell’s “powerhouse”

Mitochondrial proteins are responsible for cell respiration and the synthesis
of ATP that provides cellular energy.

Enzymes in the cell catalyze chemical reactions. Storage vesicles contain and
release hormones and neurotransmitters.

They act on receptors and control ion channels. In this way cells can
communicate with each other and order proteins in the cell to work in
concert with the entire organism.

Programmed cell death called apoptosis
 Cell energy or metabolism, is the process by which individual cells
process nutrient molecules.

Metabolism has two distinct divisions:
catabolism, refers to the energy-releasing breakdown of nutrient sources such as glucose to
provide ATP to the cell,

anabolism, refers to energy-using metabolic processes or pathways that result in the
synthesis of complex molecules such as fats.

Both these processes require long, and complex series of enzymatic steps.
 Once inside the cell, glucose is broken down to make adenosine
triphosphate (ATP), a form of energy, via two different pathways.

The first pathway, glycolysis, requires no oxygen and is referred to as
anaerobic metabolism.

Each reaction is designed to produce some hydrogen ions that can
then be used to make energy packets (ATP). In prokaryotes, glycolysis
is the only method used for converting energy.

The second pathway, called the Krebs cycle, or citric acid cycle, occurs
inside the mitochondria and is capable of generating enough ATP to
run all the cell functions.
 How are substances transported across the cell membrane?