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NCM 212 - OXYGENATION CONCEPT

OXYGENATION CONCEPT

NCM 212 Care of clients with problems in COURSE OUTLINE
oxygenation, fluid & electrolytes, infectious, Unit 1: ALTERATION IN GAS EXCHANGE
inflammatory & immunologic response, cellular Review of anatomy and physiology
aberrations, acute and chronic respiratory system
Assessment of respiratory status
PRELIM PERIOD Common diagnostic tests
Respiratory modality of care
CARE OF CLIENTS WITH PROBLEMS WITH
Disturbances:
OXYGENATION
○ Respiratory tract infections
Alterations in Respiratory, Cardiovascular
Rhinitis
and Hematologic System (37.5 Hours)
Pneumonia
Pulmonary tuberculosis
COURSE DESCRIPTION Influenza
This course deals with concepts, ○ Obstructive lung disease
principles, theories, and techniques of Chronic obstructive
nursing care management of at-risk and pulmonary disease
sick adults clients, in any setting with Emphysema
problems with oxygenation Chronic bronchitis
The learners are expected to provide Bronchiectasis –
nursing care to at-risk and sick adult bronchial
clients utilizing the nursing process Asthma
○ Restrictive lung disease
Chest trauma
LEARNING OBJECTIVES Pneumothorax
At the end of 37.5 hours students will be able to: Atelectasis
1. Describe the interaction between the ○ Pulmonary vascular disease
respiratory, cardiovascular, and Pulmonary embolism
hematologic systems in the delivery of Cor pulmonale
adequate oxygenation in the body; Unit 2: ALTERATION IN CARDIAC
2. demonstrate knowledge in assessing the PERFORMANCE
respiratory, cardiovascular, and Review of anatomy and physiology of
hematologic status of a client at risk or cardiovascular system
with problems in oxygenation; Assessment of Cardiovascular status
3. distinguish appropriate nursing actions to Common diagnostic tests
common diagnostic tests and procedures Disturbances
used to diagnose respiratory, ○ Coronary Artery Disease
cardiovascular, and hematologic Angina Pectoris
disorders; Acute Coronary Syndromes
4. Outline the pathophysiology of the given Myocardial Infarction
condition involved in the alteration of ○ Heart Failure
oxygenation ○ Valvular Heart Defects
5. Determine the appropriate medical, ○ Inflammatory Cardiac disease
pharmacologic, and possible surgical Rheumatic heart disease
management of a client with respiratory, Infective Endocarditis
cardiovascular, and hematologic disorders ○ Congenital Heart Defects
6. Formulate a nursing plan of care for a
given condition involved in the alteration Unit 3: ALTERATION IN VASCULAR INTEGRITY
or problem in oxygenation Review of anatomy and physiology of
vascular system

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 NCM 212 - OXYGENATION CONCEPT

Assessment findings BASIC CONCEPT OF OXYGENATION
Common diagnostic tests Delivery of oxygen to the body tissues and cells.
Peripheral vascular disease Process of providing adequate oxygen for the body
Arterial disorder which is essential for cells' survival. The adequacy
○ Hypertension of the Oxygen in the body is brought about by the
○ Aneurysm (AAA) interplay of 3 BODY SYSTEMS:
○ Thromboangiitis obliterans 1. Respiratory - Gas Exchange (Diffusion,
○ Arteriosclerosis obliterans Perfusion, Ventilation)
○ Raynaud’s disease 2. Hematologic
Venous Disorder transport of oxygenated blood
○ Thrombosis/Thrombophlebitis 97% of oxygen needs are
Superficial transported by RBC, only 3% is
DVT arterial mixture
Venous Thromboembolism 3. Cardiovascular system - Pumping action
○ Varicose Veins
Did you know?
On average, a person can live
Unit 4: ALTERATION IN OXYGEN CARRYING
without food for 3 weeks
CAPACITY OF THE BLOOD
without water for 3 days
Review of anatomy and physiology
without oxygen for 3 minutes
hematologic system
Assessment of hematologic system
Why is it that a person may have brain death
Common diagnostic tests
without oxygen in a matter of 3-6 minutes.
Rbc disturbances
- the brain is very sensitive, if oxygen is not
○ Anemia
provided it can cause brain death
Iron deficiency anemia
Megaloblastic anemia
Aplastic anemia Self-Learning Activities
Sickle cell anemia 1. Answer the pretest in the quipper
Thalassemia 2. View the video on the review of the
○ Polycythemia vera anatomy and physiology of the respiratory
Hemophilia system. Review your notes on the
respiratory system
3. Read in advance about respiratory
REFERENCES assessment and diagnostic tests for
Bickley, L. S. (2017). Bates’ guide to respiratory disease, particularly on the
physical examination and history taking nursing responsibilities on the following
(11th ed.). Philadelphia, PA: Wolters diagnostic test: CXR, Mantoux test,
Kluwer Health Lippincott Williams & sputum exam, bronchoscopy, lung scan,
Wilkins PFT, pulmonary angiography, MRI, pulse
Brunner, S. (2018). Textbook of oximetry, thoracentesis, ABG
Medical-Surgical Nursing 14th edition.
Philadelphia. Wolters and Kluwers
Jameson,L et.al. (2018). Harrison’s ADDITIONAL NOTES:
Principles of Internal Medicine 20th Anatomy and physiology of the respiratory …
Edition. New York.McGraw Hill Control Of Respiration (regulation of breath…
Grossman,s.et.al. (2020). Porth’s Basics of VQ Matching
Pathophysiology concepts of altered Sounds of Breathing Patterns (Cheyne Sto…
health states 5th edition. Philadelphia.
Adventitious Breath Sounds: Stridor, Whee…
Wolters Kluwers Lippincott Williams and
Wilkins. Oxygen Hemoglobin Dissociation Curve (wi…
Oxygen-hemoglobin dissociation curve | Osmosis

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THE RESPIRATORY SYSTEM OVERVIEW RESPIRATORY DIVISION BY FUNCTION
Main Function of Respiratory System
By structure By Function
Primary
○ Gas exchange – to bring oxygen Upper RT Conducting
(O2) into the body and carry carbon - nose to - nose to terminal
dioxide (CO2) out of it trachea bronchioles
Secondary Lower RT Respiratory zone
○ voice production, body temperature - bronchi to - respi. bronchiole
regulation, acid-base balance alveoli to alveoli sac
regulation, and the sense of smell

DIVISION BY FUNCTION
UPPER RT/ CONDUCTING AIRWAYS
transport of gases to the lower airways
protection of the lower airways from foreign
matter
warming, filtration & humidification of
inspired air

Important Structures
Epiglottis
○ a valve flap; covers the opening to
the larynx during swallowing
○ an elastic cartilaginous leaf-shaped
flap covering the opening of the
Additional Notes: larynx
The main function of the Respiratory System is ○ Protect the lower airways from
Gas exchange through the process of aspiration during swallowing
Ventilation (breathing) Larynx (voice box)
Entry of the air from the atmospheric to ○ 9 cartilages
the nose until the alveoli. ○ a hollow tube that lets air pass from
The process of drawing air into the lungs the throat (pharynx) to the trachea
and blowing it back out again on the way to the lungs.
Respiration Trachea (windpipe)
○ the process of exchanging oxygen ○ 16-20 cartilages; C-shape
and carbon dioxide Carina - an area where the trachea divides
Two phases into two main bronchi
○ Inhalation (inspired)
○ Exhalation (expired)
Diffusion
The movement of the gases (oxygen)
from alveoli to the pulmonary capillaries
Either mix with the blood (called arterial
oxygen) or bind with hemoglobin
(oxyhemoglobin) through the process of
diffusion
○ the amount of oxygen that would
bind with hemoglobin is called
oxygen saturation
Movement of molecules from higher
concentration to lower concentration

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Additional notes:
Specific structures that protect the lower airways
Cilia of the nose
○ Has sweeping movement called
mucus ciliary clearance that has
rhythmic sweeping off foreign
body inside to swallow to detoxify
by the gastric acid or sweep out.
Mucus
○ production of mucus produced by
the goblet cells. Submucosal
glands, found in the airways,
mouth, and gastrointestinal
tract, also produce and release
mucin and mucus. Ciliated cells
use their tiny projections to move
mucus throughout the body. The
cilia move in a way that creates a
unified pulse, pushing mucus
along in waves
Warming, filtration & humidification
○ can help protect because the
oxygen has a drying effect

Cartilage
a strong, flexible connective tissue that
protects joints and bones. It acts as a
shock absorber throughout the body.
Cartilage at the end of the bones reduces
friction and prevents them from rubbing
together when using the joints
It keeps the airway open so that it won’t
collapse.
○ Bronchiectasis
damage of cartilage that
can cause chronic
respiratory disease
Pharynx, larynx, and trachea contains
cartilage

What keeps the Bronchioles open?
Bronchioles do not have cartilages to
LOWER RT/RESPIRATORY ZONE keep them open just smooth muscles, so
Gas exchange the Alveolar pressure, which is the air
○ the diffusion of O2 into the that passes through those branches and
bloodstream and the diffusion of to the alveoli that keeps the airflow patent
CO2 out of the bloodstream In cases of pneumonia, or edema, there is
no passage of air to the bronchioles that
causes bronchoconstriction

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MAIN ORGAN OF RESPIRATION
Additional Notes:
LUNGS
Alveoli also called Pneumocytes
The main organ of respiration
the alveolocapillary membrane is affected
Soft, spongy, cone-shaped organs;
if there is fibrosis, wherein the problem is
Divided into lobes:
in the diffusion gases and not in the
○ Left - 2 lobes
passage of air
○ Right - 3 lobes
Surfactant
Broncho pulmonary segment is supplied by
○ lines the alveoli to lower surface
tertiary bronchioles
tension, thereby preventing
○ if only one pulmonary segment is
atelectasis during breathing
affected by a disease, it is the only
○ Atelactasis
one that will be removed, not the
complete or partial
entire lobe
collapse of the lung or just
Alveoli/Air sac
a lobe of the lung
○ By structure, it is the basic unit
○ If you are a premature baby, you
where gas exchange happens.
are prone into acute respiratory
○ By functional unit, it starts with
distress because of the decrease
respiratory bronchioles to alveoli to
of surfactant, which means the
alveoli sac.
surface pressure tension is
○ lungs are composed of 300 million
increased.
alveoli, arranged in clusters of 15-20
○ Surfactant is a mixture of lipids,
mostly phospholipids, and proteins
Types of Alveolar Cells
that allows for breathing with
minimal effort
○ Type I Alveolar cells - 95%
small portion of the lungs; LUNG MEMBRANE
very thin; but very important Pleura - the lung covering
to promote gas exchange ○ Visceral pleura - covers the lungs
very close together with ○ Parietal pleura - lines the thorax
pulmonary capillaries - ○ Pleural space - space between
alveolocapillary membrane visceral and parietal pleura.
○ Type II AC - 5% Contains a small amount of fluid
metabolically active; called pleural fluid
secrete/ production of Pleural fluid - 5-15 ml
surfactant ○ Lubricates the lungs and thorax
○ Type III AC - macrophages which ○ the pleural space will create a
ingest foreign matter cohesion that helps the visceral and
parietal membranes stick together
○ if the fluid is more than 5-15 ml, it
will push the lungs that will cause
the lungs to collapse called pleural
effusion
○ The negative pressure between the
space should be maintained, in
cases of inflammation or injury it can
cause the escape of the pressure
that can cause lung collapse
Mediastenum space
○ space between right and left lung
where heart and aorta are located

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 NCM 212 - OXYGENATION CONCEPT

MUSCLES OF RESPIRATION
MUSCLES OF INSPIRATION
Additional Notes:
Mediastenum space
During inspiration, the lungs inflate → need energy
○ located in between right and left
Principal organ
lung where the heart and aorta are
Diaphragm
located, That’s why if there is a
○ largest organ muscle
condition that affects the lungs, it
○ domes descend, increasing
will also affect the heart, the
longitudinal dimension of chest and
pumping action is affected which
chest and elevating lower ribs
is called Mediastinal shifting. It
○ innervated by the phrenic nerve
cannot only cause hypoxia (low
roots, which arise mainly from C4
oxygen in tissue) but also
but also from C3 & C5
hypovolemia (body loss of fluid).
- any injury affecting the C3
○ Mediastinal shift is the deviation of
and C4 can cause respiratory
the mediastinal structures towards
problems
one side of the chest cavity.
External intercostal muscles
○ (elevate ribs) helps the diaphragm
during (aids) inspiration
Parasternal intercartilaginous muscles
(elevate ribs)

Accessory Organ
sternocleidomastoid, scalenes, serratus,
pectoralis – contribute less during normal
breathing periods and more during active
breathing periods for deep forceful
inspiration,
○ e.g., during exercise and forced
breathing maneuvers.

MUSCLES OF EXPIRATION

During expiration, the lungs passively recoil to their
original size that does not need energy
during obstructive lung disease, the one that
is affected is the elastic recoil, especially
emphysema also called pink puffers. The
elastic recoil is gone which means they
need to spend energy just to breathe out

Quiet breathing
expiration results from passive recoil of
lungs.
Active breathing
Internal intercostal muscles and abdominal
muscles
○ used to increase expiratory effort, in
incases of emphysema
○ the use of this muscle means the
patient is in respiratory distress

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LUNG VOLUMES AND LUNG CAPACITIES maximal inhalation
Gives the mechanics of air passages. It is very Lung volume reflects the mechanics of ventilation
important to identify the disease if restrictive or and an important calculation of lung function
obstructive

LUNG VOLUMES
The amount of air exchanged during ventilation
4 components of Lung Volume

Tidal volume (TV)
○ the amount of air volume that moves
in or out of the lungs during quiet
respiration
○ 500 mL in a healthy adult
○ used by the nurses during identifying
if the patient needs a mechanical
ventilator. They will look at the
minute volume (not the TV) to
calculate, by multiplying RR and the
usual 500 mL. It serves as a basis if
the patient sustains their respiration.
Inspiratory reserve volume (IRV)
○ amount of air a person can inhale
forcefully after normal tidal volume
inspiration or normal exhalation
Expiratory reserve volume (ERV)
○ extra volume of air that can be
expired with a maximum effort
beyond the level reached at the end
of a normal, quiet expiration
Residual volume (RV)
○ the amount of air that remains in a
person's lungs after fully exhaling

LUNG CAPACITY
Consist of two or more lung volumes
4 components: TLC, IC, FRC, and VC

Total Lung Capacity (TLC)
○ All air that comes in and out during
ventilation (breathing)
○ maximal volume of gas in the lungs
after a maximal inhalation
Inspiratory Capacity (IC)
○ maximum volume of air that can be
inhaled following a resting state
Functional residual capacity (FRC)
○ is the volume remaining in the lungs
after a normal, passive exhalation
Vital Capacity
○ total amount of air exhaled after

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VENTILATION PERFUSION RATIO
Additional notes:
For the body to have an adequate oxygenation, the
Ventilation (breathing)
ratio of ventilation and perfusion should be normal
flow of gas in and out of the lungs
in every ventilation there is perfusion. Once
we inhale air, there should be blood flow
Perfusion
Unequal ratio can cause hypoxia (low O2 in
refers to the blood flow to tissues and
the tissue) & hypoxemia (low O2 in blood)
organs. Alveoli are perfused by capillaries
so the diffusion of oxygen and carbon
1. Normal Ratio - 1:1 VQ ratio (4:5 or 0:8)
dioxide can take place.
4 L of oxygen every inhalation to the
alveolar unit with corresponding 5 L of blood
that flow in the pulmonary for adequate
oxygenation.

2. Low ventilation - Perfusion ratio: Shunt

blood will bypass alveoli without gas
exchange (pneumonia, atelectasis)
During ventilation (breathe in), there is no
air in some alveolar units, but there is no
problem in perfusion or in the blood flow.
One common reason is the inflammatory
process such as pneumonia, atelectasis,
and pleural effusion that causes the
mismatch called shunt

3. High ventilation-perfusion ratio:

dead space
the alveoli do not have adequate blood
supply for gas exchange to occur
(pulmonary embolism)
There is no problem in gas exchange or
delivery of the gas, but the problem is there
is no blood flow, such as embolism that has
a blockage, so there is no blood flow for gas
exchange which is called dead space
○ embolism - blocked artery caused by
a foreign body, such as a blood clot
or an air bubble

4. Silent unit

absence of V and Q or decrease in both
V&Q (pneumothorax).
Both problems occur the shunt and dead
space. There is no air and there is no blood
flow. Common in pneumothorax (collapsed
lungs - air leaks between lung & chest wall)

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 NCM 212 - OXYGENATION CONCEPT

REGULATION OF RESPIRATION
Additional Notes:
NEURAL REGULATION
Regulation of respiration
Respiratory Centers
Unlike the heart, breathing has both
Medulla Oblongata
automatic and voluntary components.
○ inspiration center
What regulates respiration
○ expiratory center
○ neural, chemicals, and other
inspiration and respiratory
proprioceptors, but the important
center is responsible for the
is to maintain the correct
cyclic pattern of breathing
concentration of oxygen, carbon
Pons of the brainstem
dioxide, and hydrogen ions in the
○ modify the output of the medullary
body.
centers
The primary stimulus for breathing in
Upper and lower pons
healthy individuals is arterial C02
○ Apneustic center
The secondary stimulus is arterial
excitatory effect.
hypoxia, which is not clinically significant
if there is a need for air, it
until PA02 is less than 6ommHg.
can prolong and deepen the
inspiration for more air
In cases of COPD, due to obstruction, there is air
○ Pneumotaxic center
trapping, so the CO2 is always high which
switch inspiration off if there
eventually causes the central chemoreceptors to
is an excessive inspiration to
become used to it or become insensitive since
start expiration
the CO2 is always high. This means the increase
of CO2 will not function anymore as a stimulating
CHEMORECEPTORS
factor to breathe in and out in COPD, but rather
assist the brain control of respiratory
the decrease in oxygen level (PaO2) which is
functions. The need for O2 and CO2 is
called hypoxic drive. That’s why in providing
regulated by the chemoreceptors
oxygen therapy in COPD, be careful to not
to respond to chemical changes:
remove the oxygen tension because if excessive,
○ blood levels of carbon dioxide,
it can cause the patient to be dependent on
oxygen, and pH
oxygen therapy.
Two Types
○ Central chemoreceptors
increase in CO2 and H+
Sense if there is an increase
in CO2 or hydrogen. Send
signals in the respiratory
system to breathe in because
the CO2 is high, to exhale
○ Peripheral chemoreceptors
decrease in PaO2
function if the arterial oxygen
concentration (PaO2) is
below 60 mmHg
located at the carotid
(carotid sinus) and aortic
bodies (aortic arch)

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 NCM 212 - OXYGENATION CONCEPT

LUNG RECEPTORS the body needs oxygen due to increased
Monitoring the status of breathing in terms of activity,
airway resistance and lung expansion
VOLUNTARY CONTROL COMPONENT
THREE TYPES HYPOTHALAMUS
modifies the output from the medulla,
1. Stretch receptors (hering - Breuer particularly in the emotion
reflexes) Emotions
Detect stretching and send impulses ○ anger = increase RR
to the medulla to depress the ○ fright = gasp
inspiratory center
If it senses the overinflation, it will CEREBRAL CORTEX
detect so that the lung won’t Enables us to voluntarily change breathing
overstretch rate or rhythm
○ talking, singing
2. Irritant receptors
Stimulated by noxious gases such PROCESSES INVOLVES IN GAS EXCHANGE
as cigarette smoke, inhaled dust, A. VENTILATION
and cold air Flow of gas in and out of the lungs
The response is vasoconstriction Inspiration
and rapid shallow breathing ○ air flows from the environment into
Initiate periodic sighing and yawning the trachea, bronchioles, and alveoli
○ increases the amount of air Expiration
into 1,5-2x. So it will make it ○ alveolar gas travels the same route
1,000-2,000 ml (since normal in reverse.
TV is 500 ml) ○ Passive phase
Pulmonary diffusion
3. Juxtacapillary or J receptors ○ is the process by which oxygen and
Are located in the alveolar wall, carbon dioxide are exchanged from
close to the pulmonary capillaries: areas of high concentration to areas
thought to sense lung congestion of low concentration at the air-blood
instead of air; the response is rapid interface
breathing Pulmonary perfusion
Senses lung congestions with fluids. ○ the actual blood flow through the
Response is rapid shallow breathing, pulmonary vasculature.
and dyspnea
B. RESPIRATION
PERIPHERAL PROPRIOCEPTORS Whole process of gas exchange between the
proprioceptors in muscles, tendons, joints atmospheric air and in the blood and between the
and skin, respond to body movement; send blood and cells of the body.
stimulatory signals to the medullary External Respiration
respiratory center ○ the exchange of gasses between the
Proprioceptors in joints and tendons may be alveoli and the pulmonary
important in initiating and maintaining capillaries.
increased ventilation at the beginning of ○ In lungs
exercise Internal respiration
Sense body movements send signals to the ○ the exchange of gasses between the
respiratory system, particularly the blood in the systemic capillaries and
pressoreceptors in joints & tendons once the systemic tissue
they start running, it sends the signal to ○ Inside the body, from blood vessels
increase the deep, rhythm or the rate. Since to different parts of the body

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NCM 212 - OXYGENATION CONCEPT

MECHANICS OF BREATHING
The degree to which the lungs inflate and deflate
depends on Respiratory Pressures, Lung
Compliance, and Airway resistance
RESPIRATORY PRESSURES
Air flows from a region of higher pressure to a
region of lower pressure.
Intrapulmonary pressure OR Alveolar
pressure
○ the pressure inside the airways and
alveoli of the lungs
Intrapleural pressure
○ the pressure in the pleural cavity; is
always negative in relation to
alveolar pressure, approximately - 4
mmHg between breaths
○ negative pressure that helps in lung
inflation
Intrathoracic pressure
○ is the pressure in the thoracic cavity.
It is essentially equal to intrapleural
pressure and is the pressure to
which the lungs, heart, and great
vessels are exposed.
○ causes pressure including the
mediastinum space
Additional Notes:
Any decrease of the lumen or diameter of the
airways, even very small, can highly increase
respiratory resistance. So, the higher the
resistance, the more difficult the passage of air

LUNG COMPLIANCE
Refers to the ease with which the lungs can be
inflated
The elasticity and expandability of the lungs
and thoracic structure
○ Elastin and collagen fibers
○ Surface tension of the alveoli
○ Water content of the lungs
○ Compliance of thoracic cavity
Elastic recoil
○ describes the ability of the elastic
components of the lung to return to
their original position after having
been stretched
Airway resistance
○ Resistance is determined by the
radius, or size of the airway through
which the air is flowing

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 NCM 212 - OXYGENATION CONCEPT

OXYHEMOGLOBIN DISSOCIATION CURVE EFFECTS OF PRESSURE ON OXYGEN
PARTIAL PRESSURE OF GASES TRANSPORT
The pressure exerted by each type of gas in Partial pressure of oxygen in the arteries
a mixture of gases. (PaO2)
○ proportional to the concentration of ○ the volume of oxygen physically
that gas in the mixture dissolved in the plasma or blood
The air we breathe is a gaseous mixture The higher the PaO2, the greater the
consisting mainly of Nitrogen (78.6%, 597 amount of oxygen dissolved
mmHg) and Oxygen (20.8%, 158 mmHg),
with traces of Carbon Dioxide (0.04%),
For Example:
Water Vapor (0.05%), Helium, and Argon.
A PaO2 of 10 mmHg, 0.03mL of Oxygen
○ The air that we breathe in is higher
is dissolved in 100 mL of plasma
in nitrogen than oxygen
At PaO2 of 20 mmHG, twice this amount
The atmospheric pressure at sea level is
is dissolved in plasma
about 760 mmhg
100 mL of normal arterial blood carries
The partial pressure of Nitrogen in the
0.3 mL of oxygen physically dissolved in
atmosphere at sea level is 78.6% of 760 or
the plasma and 20 mL of oxygen in
597 mmHg; that of Oxygen is 20.8% of 760,
combination with hemoglobin
or 158 mmHg.
(oxyhemoglobin)
The amount of oxygen that combines with
Partial Pressure Abbreviations
hemoglobin depends on both the amount of
P = Pressure hemoglobin in the blood and on PaO2
When the PaO2 is 150 mmHg, hemoglobin
PO2 = Partial pressure of oxygen is 100% saturated.
○ If the PaO2 is less than 150 mmHg,
PCO2 = Partial pressure of carbon dioxide the percentage of hemoglobin
saturated with oxygen decreases
PAO2 = Partial pressure of alveolar oxygen

PACO2 = Partial pressure of alveolar carbon dioxide For Example:
At a PaO2 of 100 mmHg (normal value),
PaO2 = Partial pressure of arterial oxygen saturation is 97%
At a PaO2 of 40 mmHg, saturation is 70%
PaCO2 = Partial pressure of arterial carbon dioxide

PvO2 = Partial pressure of venous oxygen

PvCO2 = Partial pressure of venous carbon dioxide

P50 = Partial pressure of oxygen when the
hemoglobin is 50% saturated

Additional Notes
PaO2
Partial pressure of arterial oxygen
Refers to the amount of oxygen that
mixes with the plasma
PaCO2
Shows the relationship between the partial
Partial pressure of alveolar carbon dioxide
pressure of oxygen (PaO2) and the percentage of
saturation of oxygen (SaO2)

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 NCM 212 - OXYGENATION CONCEPT

OXYHEMOGLOBIN DISSOCIATION CURVE
Additional Notes:
The oxyhemoglobin dissociation curve is marked to
There are conditions that would shift to the left
show three oxygen levels:
and to the right curve.

Normal levels PaO2 >70 mmHg Left-shifted curve
Implications
Relatively safe levels PaO2 45-70 mmHg ○ increased oxygen affinity
ability of the hemoglobin to
Dangerous levels PaO2 1 cm Dilatation and destruction involve entire
acini
Variable location within peripheral lung
In alpha 1-antitrypsin deficiency
parenchyma 2. CENTRIACINAR
*they occupy space in the lungs but do not the central part of the acinus (common in
participate much in the gas exchange smokers)

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 NCM 212 - OXYGENATION CONCEPT

Signs & Symptoms
Additional Notes:
Progressive dyspnea - airwary limitations
Accroding to Tubal Obstructive Lung Disease
Progressive cough and increase in
Association, there are three (3) pirmary
sputum production
symptoms of emhpysema
Anorexia - because of difficulty breathing, pt
chronic cough sputum production
will not eat;
dyspnea
Weight loss - they spend energy more on
tripod sitting
the exhalation phase
Respiratory acidosis
Tripod sitting or holding the wall
Use of accessory muscles when breathing
one way of stabilizing accessory muscles
Barrel chest - clinical sign
for breathing; common in emphysema
pursed –lip breathing
Barrel chest
Hyper resonant chest - due to the
has an increased anteroposterior
excessive air or the trapped air
diameter, this shape is normal during
Decrease tactile fremitus
infancy and often accompanies normal
aging and chronic obstructive pulmonary
disease
Hyperinflation of the lungs
because of air trapping that flattened the
diaphragm. So its important to do the
diagphragmatic breathing to strenmgthen
the diaphragm

Diagnostic Tests
Pulmonary function test(spirometry)
○ will compute FEV1/ FVC
Radiologic Exam - checks if there are other
complications
ABG - to know O2 status of pt
Ventilation
○ perfusion lung scan
○ to determine if obstructive
Serum alpha antitrypsin level - e request ito
if may symptoms ang pt kahit na di pa sya
40-45 ang edad

Management
Smoking cessation
Bronchodilators
○ anticholinergic (effective in stopping
the bronchoconstriction)
Corticosteroid - acts on the inflammatory
process
○ stepwise approach to therapy, in
which the dose and number of
medications and frequency of
administration are increased as
necessary and decreased when
possible,
O2 therapy - given once there is hypoxia

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 NCM 212 - OXYGENATION CONCEPT

documented CHRONIC BRONCHITIS
Antimicrobials - if may nakitang bacterial Chronic inflammation in the lungs causes
infection sa CXR scarring of the airways and excessive
Breathing exercise production of mucus that results in a chronic
Resection of Bleb/Bullectomy cough; affecting the bronchioles
only diagnose if:
○ Productive cough that last 3 months
a for 2 consecutive years
Sometimes termed as smokers cough/cap
“Blue Bloater:

Pharmacologic Therapy
medication regimens used to manage
COPD are based on disease severity.
For grade I (mild) COPD
○ a short-acting bronchodilator
For grade II or III COPD
○ a short-acting bronchodilator and
with one or more long-acting
bronchodilators
For grade III or IV (severe or very severe)
COPD
○ one or more bronchodilators and/or
inhaled corticosteroids for repeated
exacerbations

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 NCM 212 - OXYGENATION CONCEPT

Signs & Symptoms
Additional Notes:
persistent cough that last 3 months a year in
The airway is very limited due to inflamed bronchi
2 consecutive years
lining, enlarged goblet cells and inner linings
sputum production Primarily mucoid
thickened.
Copious amount, thick tenacious Cyanosi
Constant irritations such as smoking
bloated appearance
could stimulate the mast cells that would
release mediators particularly cytokines
that causes bronchospasm which in turn
constriction
Also called blue bloaters because it can
cause heart problem like COR pulmonale,
where there is a hypertrophy that there is
peripheral congestion thats why bloated.
Because of compromised gas exchange
the person could turn bluish, incontrast to
emphysema that is pink puffers that
occurs in the alveoli whereas blue
bloaters occurs in the large bronchioles
that has alternations in the goblet cells.
Diagnostic Tests
ABG
PATHOPHYSIOLOGY
pulse oximetry
chest x-ray

Management
Bronchodilators
Postural drainage (when secretions are
severe and requires drainage)
Chest percussion (every after
bronchodilator meds. to help with excretion
of sputum)
Proper hydration
High calorie
High CHON ; Low CHO (small, frequent,
easily swallowed feeding, regulates blood
sugar) (byproducts of CHO is more CO2,
not good for hypercapnia)

72 |BSN 3
 NCM 212 - OXYGENATION CONCEPT

BRONCHIECTASIS Causes:
Is a disorder that is characterized by Smoking/ exposure to toxic gasses
permanent dilatation and destruction of Cystic fibrosis - affects reproduction and GI
cartilage containing airways Repeated Lung infection - leads to
Thinning of cartilage permanent damage, erodes cartilages
(permanent damage to cartilage = not
smooth; cannot cough ou/expel secretions 3 Different Types of Bronchiectasis
and will stay in the dilated part of the 1. CYLINDRICAL OR TUBULAR
cartilage therefore, become a source of BRONCHIECTASIS
constant reinfection) - involves dilated airways alone

2. VARICOSE BRONCHIECTASIS
- characterized by focal constrictive
areas between the dilated airways

3. SACCULAR OR CYSTIC
BRONCHIECTASIS
- characterized by progressive
dilatation of the airways, which form
grape-like clusters.

PATHOPHYSIOLOGY

(cause of airway limitations= damage in cartilages
+ secretions in dilated portion that cannot be
expelled out)

73 |BSN 3
 NCM 212 - OXYGENATION CONCEPT

Signs & Symptoms ASTHMA
Chronic cough heterogeneous disease, usually
Production of purulent sputum, characterized by chronic airway
○ Layering out (outside) frothy inflammation (GINA [Global Initiative for
○ Middle: clear layer Bottom: dense Asthma], 2015).
particulate ○ has different etiologies
Hemoptysis (coughing of blood) Airway hyperresponsiveness, mucosal
Clubbing of fingers edema, and mucus production.
May be precipitated by exposure to one or
more of a wide range of stimuli including:
○ Allergens, Exertion, Emotion, Air
pollution

Types of Asthma
1. EXTRINSIC ASTHMA/I GE MEDIATED
Allergic form; seen mostly in children
due to external agents of specific allergens.
○ Ex. pollens, dusts

2. INTRINSIC/ NON-ALLERGIC due to:
URTI
emotional stress
non-specific factors
Ex. change in weather, cold/dry’heat air,
strong odor/perfume/smoke, occupational
gas, foods. exercise

PATHOPHYSIOLOGY

Diagnostic Tests
CT scan - identity which affected cartilage
bronchoscopy - view location, diagnostic,
and therapeutic
ABG - for oxygen concentrations and
acid-base imbalances

Management
Postural drainage
Bronchoscopy - clear off secretion (bronchospasm refers to the diameter of the airway
Chest percussion - included with postural while bronchoconstriction refers to smooth muscles
drainage that constrict.)
Smoking cessation - remove common
inflammatory cause
Antimicrobial therap
Bronchodilators - promote gas exchange,
expectoration on secretion

74 |BSN 3
 NCM 212 - OXYGENATION CONCEPT

Classical Signs
cough with or without sputum (phlegm)
production
dyspnea
Wheezing
Chest tightness
○ often occur at night maybe due to
circardian rhythm may influence the
receptor threshold

STATUS ASTHMATICUS (SILENT CHEST)
Severe asthma that is unresponsive to
usual emergency method of treatment and
ventilatory failure is imminent Peak Flow Meters
PRECIPITATED BY: Infection, Anxiety,
Nebulizer abuse, Dehydration, Aspirin measure the highest airflow during a forced
hypersensitivity expiration
(narrowing and bronchospasm cannot be recommended to patient with moderate or
relieved by usual medication taken) severe asthma
helps measure asthma severity and
Danger Signs: indicates the current degree of asthma
Unable to talk control (forceful expiration is measured, not
Absence of breath sound according to how long you expire)
Cough becomes ineffective despite being can be done till 3 attempts and use the best
repetitive & hacking result

Additional Notes:
Increase of wheezing sound indicates that the Incentives spirometer
medication is being effective different with peak flow meters, incentives
spirometer has more balls suspended
means..
Diagnostic Tests
Pulmonary function tests
○ to get the base line result, give 3 ZONES OF MEASUREMENT FOR PEAK FLOW
bronchodilator, then proceed with METERS ACCORDING TO THE AMERICAN
pulmonary function again. If there is LUNG ASSOCIATION
changes, it means that the patient
has asthma, if not, further
examination is needed
○ determines whether it is reversible
Peak flow measurements
Chest X-ray
Allergy testing by skin testing or serum tests
○ to know that the pt is allergic with so
to avoid encountering it in the future
Arterial Blood Gas

75 |BSN 3
 NCM 212 - OXYGENATION CONCEPT

Management Nursing Interventions
Prevent recurrent exacerbation of asthma during acute attacks, stay calm & stay with
○ (if symptoms are too active, it will the patient
lead to inflammation and increase position patient on MHBR or patient’s
mucosal production and then preference (high back rest for lung
infection, it will cause residual expansion)
damage encourage relaxation techniques, pursed lip
Maintain near-normal pulmonary function breathing, deep breathing exercises
Maintain normal activity level observe clue for respiratory arrest
Provide optimal pharmacotherapy with ○ patient cannot talk, decrease or
minimal or no adverse effects absent breath sounds
○ (prevent exacerbation by avoiding
source of allergens through
Additional Notes:
environmental cleanliness) (metered
Patient is having respiratory arresr if the
dose inhalers are just as good as
wheezing disappears or there is no breath
nebulizers if done correctly; portable
sounds
and less expensive)
○ identify what are the allergens that
can exacerbate the asthma RESTRICTIVE LUNG DISEASE
Any disorder that LIMITS lung expansion
and RESTRICTS chest wall movement
resulting in:
○ Decreased Lung Volume
○ Increased Work of Breathing

LONG-ACTING MEDICATIONS
○ used on a regular basis to prevent
attacks, not for treatment during an
attack.
○ Corticosteroids MDI (Azmacort,
AeroBid)
○ Leukotriene inhibitors (Singulair,
Accolate)
○ Long-acting Bronchodilators
(famoterol/formoterol, Serevent) CHEST TRAUMA
○ Xanthine derivatives (Aminophylline) Injury to chest wall or lungs which interferes
○ Mast cell stabilizer (Cromolyn Na) with respiration
QUICK RELIEF MEDICATION Often life-threatening and results in:
○ used to relieve symptoms during ○ Hypoxemia
asthma attack. airway might be disrupts that
○ Short-acting bronchodilators can cause ventilation
(e.g.Proventil, Ventolin, salbutamol) mismatch
○ oral or intravenous corticosteroids ○ Hypovolemia
(e.g., corticosteroids: prednisone, ○ Cardiac Failure
methylprednisolone) -
○ Anticholinergic (ipratropium) Classification of Chest Trauma
1. BLUNT or NON-PENETRATING
Additional Notes: Damages of structures within the chest
if there is already ssmptoms of asthma attack, cavity without disrupting chest wall integrity.
leukotriene inhibitors and Mast cells are not given there might be damage in the lung tissue
but no opening

76 |BSN 3
 NCM 212 - OXYGENATION CONCEPT

2. PENETRATING INJURY
Disrupts chest wall integrity and within chest
cavity; mostly occurs as a result of gunshot
or stabbing.

CHEST TRAUMA CAN BE
A. FRACTURED RIBS
Injury to the bone of the ribs
RIBS 4 & 8 are most commonly injured
during an accident. If impact is on the upper
ribs, it's slightly life- threatening because the *This figure is a sample of surgical fixation
great vessels are located here.
If impact is on the lower rib, it’s hypovolemic Nursing Intervention
because spleen and liver is located here Semi or High Fowler’s position
Monitor client for complications such as:
Additional Notes: ○ Bloody sputum is indicative of lung
Can be treated for conservative penetration
treatment. (meaning giving of pain ○ Observe for signs of hemothorax
medications). Why? Because of the pain, and pneumothorax (asymmetry of
the pain can alter the breathing pattern. the chest per chest expansion) Also
We can manage the pain. decrease in breath sounds

B. FLAIL CHEST
Assessment findings: Fracture of three or more ribs and instability
Pain during inspiration of the chest wall. To the point na nasira na
Tenderness and bruising at injury site, ang ability of the chest thoracic cavity to
splinting with shallow rapid respirations. help in the ventilation
(mugamay sad ang tidal nvolume or minute Chest wall unable to provide bone structure
volume and needs to be restored) nnecessary for adequate ventilation
Diagnostic test: Chest X-ray reveals type, MAJOR MANIFESTATION: If there is
area and degree of fracture Paradoxical chest movements (meaning
opposite)
Medical Management
Narcotics - The pain can alleviate 4-7 days
and fractured bones can heal in 3-6 weeks
○ Narcotics have strong effects but
make sure that pt is not fully sedated
to the point where the respiratory
centers are depressed
Chest binder
Surgical fixation - very seldom to use in
managing fracture ribs

Figure: Dahil nadamage man ang upper ribs, once
mag-inhale, hindi makaexpand ang lungs so
magpunta sya sa opposite direction and ang
movement sa air madisplace inside the lungs.

77 |BSN 3
 NCM 212 - OXYGENATION CONCEPT

Assessment findings: promotes bone healing.
MAJOR SIGN: paradoxical chest movement ○ Pero if pt condition has a chance na
(air on the opposite fractured site would pag iintubate kay hindi na ma
move to the opposite direction during extubate, they might do fix the
inspiration and expiration) thoracic gauge first
Severe pain Surgery — internal or external fixture
Tachypnea and shallow breathing
Cyanosis; tachycardia, hypotension
○ Why hypotension? When
paradoxical chest movement
happens, the mediastinal space
would also shift to the left and right,
and in the mediastinal space is the
heart. So in short, maapektuhan ang
cardiac functioning
○ Might have a chance for hypotension
to occur depending on the severity

Medical Management Nursing Interventions
Supportive Management includes: Maintain open airway, suction secretions
Ventilatory support Monitor mechanical ventilation
Clearing secretions from the lungs Encourage turning, deep breathing, and
Controlling pain - para di abnormal ang coughing exercises
breathing pattern Monitor for signs of shock

The specific management depends on the PNEUMOTHORAX
DEGREE OF RESPIRATORY DYSFUNCTION: Is the presence of air in the pleural space
caused by a rupture in the visceral pleura or
1. IF Small segment of the chest: parietal pleura and chest wall

3 Types of Pneumothorax
To clear the airway through positioning – 1. Spontaneous Pneumothorax/ Primary
coughing, deep breathing
To aid in the expansion of the lung – Air enters the pleural space through a
suctioning breach of either the parietal or visceral
To relieve pain – intercostal nerve blocks, pleura
high thoracic epidural blocks, IV opioids Causes include: rupture of bleb, pulmonary
tuberculosis (PTB), bronchogenic cancer,
2. IF Mild to moderate flail chest injuries: emphysema.
○ no obvious cause but common in tall
Appropriate fluid replacement and thin male gender, because the
Closely monitored for further respiratory pressure of air in the higher is
compromise (signs of hypoxia, restlessness, stronger than in lower area
tachycardia) can be considered Primary-
○ cannot identify any illness or disease
3. IF Severe flail chest injury to lead as to why air escaped into
the pleural space)
Endotracheal intubation and mechanical Secondary
ventilation ○ identified a disease or illness, e.g.
○ (to support the ventilation at the emphysema
same time internal suction that

78 |BSN 3
 NCM 212 - OXYGENATION CONCEPT

S/Sx:
○ Tracheal deviation
○ distended neck veins
○ subcutaneous emphysema
○ shock

2. Traumatic Pneumothorax

Air enters the pleural space through an
opening in the chest wall; or from a
laceration in the lung itself.
Hemopneumothorax → may be due to a
major trauma that can produce blood
Causes include:
○ fractured or dislocated ribs
○ stab wound
○ Transthoracic needle aspiration
○ intubation/mechanical ventilation
○ complications of CPR
Open
○ like stab wounds, e.g. when a
patient inhales or exhales, air leaves
through the hole.
Closed
○ damage is into the visceral pleura,
air from the lungs escapes to the
pleural space.

3. Tension Pneumothorax

Air that enters the chest cavity with each
inspiration is trapped; it cannot be expelled
during expiration
Open chest wound
○ a one-way valve mechanism occurs;
when patients inspire, the air traps in
the pleural space but trapped durting
expiration
○ (Can also be classified as Open or
Closed)
A life threatening condition
Iatrogenic injury
○ caused by medical procedure, e.g.
CPR, if too deep, mechanical
ventilation.):

79 |BSN 3
 NCM 212 - OXYGENATION CONCEPT

PATHOPHYSIOLOGY Nursing Diagnoses
Impaired Gas Exchange
Ineffective Airway Clearance

Nursing Management
1. Assess the respiratory status and breath
sounds
2. Provide measures promoting chest
expansion and secretion clearance
(incentive, spirometer, nebulization, head of
bed elevated 30 degrees, turn frequently)
3. Perform chest physiotherapy to remove
mucus. Teach slow, pursed-lip breathing.
4. Administer IV fluids and mucolytics to
reduce sputum viscosit

ATELECTASIS
HEMOTHORAX
Not really considered as a disease but it can
blood in the pleural cavity compresses the
be considered as manifestation of a disease
lungs and can produce blood loss resulting
collapse of lung tissue at any structural level
in shock
Types
establish negative pressure in the pleural
○ Primary:
space through insertion of chest tube
d/t decreased surfactant
factors
Management of Pneumothorax
common to premature babies
1. Chest Tube Placement
○ Secondary
Tension pneumothorax initial
d/t obstruction or lung
treatment choice is to insert a
compression like presence of
large-bare needle into the second
pneumothorax
intercostal space midclavicular line
to relieve pressure.
2. Oxygen Therapy
OBSTRUCTIVE COMPRESSION
3. Pain Management – epidural catheter
4. Bed rest
5. Monitor respirations

80 |BSN 3
 NCM 212 - OXYGENATION CONCEPT

CLASSIFICATION OF SECONDARY 2. Compression atelectasis
ATELECTASIS occurs as a result of any thoracic
1. Non-obstructive/compression atelactasis space-occupying lesion compressing
caused of the collapse is due to the lung and forcing air out of the
external pressure alveoli
Causes 3. Adhesive
○ pneumothorax The fluid that lines the alveoli in your
excessive air in the lungs has a material in it called
pleural space that pulmonary surfactant. It helps your
compresses the lung lungs in several ways, including
that it can’t expand keeping the alveoli stable and able
○ pleural effusion to work. If there's a problem with this
presence of material (like if your body doesn’t
excessive fluid in make enough of it), the alveoli can
pleural space collapse. When that happens, it's
○ large mass called adhesive atelectasis. It can be
malignat or tumor that caused by serious lung problems
can compress lungs such as respiratory distress
syndrome or a bruised lung
2. Obstructive/ Absorption Atelectasis - if (pulmonary contusion).
flow of air into an alveolus is blocked - the 4. Cicatricial.
air currently inside would eventually This type of atelectasis is when the
diffeuses out and thus the alevoulus would tissue that makes up your lungs has
collapse scars that keep them from being
Causes able to hold as much air as they
○ mucous plugging should. This scarring can happen
○ foreign objects because of certain serious lung
○ anestehsia, pain narcotics, conditions like sarcoidosis.
immobility 5. Replacement.
This is when your alveoli are filled by
TYPES ATELECTASIS a tumor. That causes an area of your
1. Relaxation or passive lung to collapse.
occurs when contact between the 6. Acceleration.
parietal and visceral pleura is When jet pilots fly straight up really
disrupted fast (between 5 and 9 G-forces), the
the three most common specific acceleration can close the airways in
etiologies of passive atelectasis are their lungs, leading to this type of
pleural effusion, pneumothorax and atelectasis. It can make it hard to
diaphragmatic abnormality breathe and cause chest pain and
The lining of your chest wall and the coughing.
surface of your lungs are usually in 7. Rounded (also called folded lung).
close contact, keeping your lungs This type is linked to pleural
expanded. But if fluid or air builds up diseases, conditions that affect the
and separates them, your lungs can thin tissue that lines your chest
pull inward, and your alveoli can lose cavity and surrounds your lungs (the
air. Depending on where this pleura). One of the most common
happens in your lung, it's either causes is asbestosis, when you
relaxation or compressive breathe in asbestos over a long
atelectasis period of time and this damages the
pleura.

81 |BSN 3
 NCM 212 - OXYGENATION CONCEPT

POSTOPERATIVE ATELECTASIS PULMONARY EMBOLISM
general anesthesia and surgical An embolus blocking the pulmonary artery
manipulation lead to atelectasis (would and distrupting blood flow to one or more
cause distruption of the lung function) by lobes of the lungs
causing diaphragmatic dysfunction & Causes
diminished surfactant activity Almost all pulmonary emnoli arise from
teach: deep breathing, coughing exercises, deep vein thrombosis (blood clot) (DVT) in
early mobilization the lower extremities
○ air
PATHOPHYSIOLOGY careful with IVF therapy na
hindi maubosan kasi if
maubosasn it can cause air
embolus
○ fat
bone marrow injury might
detach that can go into the
circulation that causes
embolism
Remember that there are 2
types of bone marrow Red
(rbc, wbc, plt) & Yellow (fat)
DIAGNOSTIC TEST: ○ amniotic fluid
Chest X-ray during birth, the amniotic fluid
CT scan passed througgh the
Bronchoscopy circulation that can cause
embolus
MANAGEMENT
to improve ventilation
to remove secretions
Treating the underlying cause:
○ administration of surfactant (intubate
or ETT)
○ administration of antimicrobial (due
to inflammatory process d/t collapse)
○ administrtaion of bronchodilators (to
promote expansion to prevent
collapse)
Adminisrtation of Oxygen (depend on ABG)
Chest tube insertion (compressive, fluid/air)
Removal of tumor, foreign body
Prevention:
○ ambulation and body positioning that
favor lung expansion - high back rest
○ Depp breathing, coughing, incentive
spirometry, CPT

Additional notes:
Atelactasis
common manifestation: fine crackles
○ fluids in the alveoli

82 |BSN 3
 NCM 212 - OXYGENATION CONCEPT

ASSESSMENT FINDINGS
Chest pain (pleuritice, sudden onset
Additional Notes:
○ sudden complain of chest pain
Massive embolus
Dyspnea
potentially life-threatening disorder
Tachypnea and tachycardia
because emboli can cause pulmonary
○ since ventilation is interupted
infarctions or pulmonary injury.
Fever (low grade)
Pulmonary Infarctions
Apprehension (anxiety)
mechanically obstructed blood flow, the
cough (productive, blood-steaked)
emboli would block the blood flow to your
shock (massive hemoptysis)
lung tissues might lead to a decrease of
gas exchange (decrease oxygen), and
DIAGNOSTICS:
there will be pulmonary
Pulmonary angiography
bronchoconstriction that would burden the
○ most accurate or gold standard
heart. In short, it can disrupt the function
○ however, seldom done d/t invasive
of ventilation and heart function.
○ usually replaced by ct angiogram
Injury in the Lungs
CT angiogram (computerized tomography)
some patients may experience Frank
○ reveals location and extent of
hemoptysis → is characterized by sputa
embolism
that are grossly bloody but of a low
○ mostly advisable on large emboli
volume (less than 100-200 mL in 24 hrs).
Perfusion Lung Scan
○ determine pulmonary circulation
PHYSIOLOGIC FACTORS THAT CONTRIBUTE
TO DEVELOPMENT OF DVT MEDICAL MANAGEMENT
VIRCHOW’S TRIAD Anticoagulants
○ prevention of clot formation
any of this clot will dislodge, it will become an Thrombolytics
embolus. Usually occur in the small capillaries; ○ to restore blood flow by dissolving
heart, lungs, or brain blood clots
1. Venous stasis ○ w/o for bleeding
stagnant blood flow in the vein; most Dextran 70
likely may form into thrombus ○ add fluid volume and also has
2. Venous endothelial injury anticoagulant properties
injury in the inner lining: response is Vasopressors if with shock
vasoconstriction and stopping the ○ dopamine → to increase
bleeding by creating platelet clot/ sympathetic effect: blood pressure
fibrin clot that can lead to the Surgery: Embolectomy
formation of thrombus ○ removing the emboli
3. Hypercoagulability states
condition that reallty increased NURSING MANAGEMENT
coagulation factor administer meds as ordered
CAUSES: Administer O2 → dyspnea
prolonged bed rest, trauma, surgery, Elevate head of bed → lung expansion
childbirth, fractures of the hip and femur, assist with cough anddeep breathing
Myocardial infarction, and congestive heart exercise, turning hydration
failure Offer support and reassurance
Oral contraceptive, pregnancy, and
hormone replacement therapy

83 |BSN 3
 NCM 212 - OXYGENATION CONCEPT

COR PULMONALE MANAGEMENT:
right-sided heart failure d/t respi, disorder Treatment of underlying lung disease
enlargement of the right ventrible due to long term, low flow O2
high blood pressure in the lungs usually ○ monitor oxygenation status → ABG
caused by chronic lung disease Diuretics/ DIGITALIS
○ Diuretics → for excessive fluid
○ Digitalis → digoxin
It is used to improve the
strength and efficiency of the
heart, or to control the rate
and rhythm of the heartbeat.
This leads to better blood