Respiratory System Assessment and Diseases Management PDF

Summary

This document provides an overview of the respiratory system, including its physiology, diseases, and management. It covers topics such as breathing, lung compliance, airway resistance, and pulmonary diffusion, along with assessment and health history.

Full Transcript

RESPIRATORY
SYSTEM
Physiology of Breathing
Physiologic Dead Space
 Lung Compliance

Lung compliance refers to the ease with which the lungs can be inflated

3 factors
Elastin and collagen fibers
Elastin – makes lung inflation more easily
Collagen – make lung inflation more difficult
In pulmonary disease – elastin is replaced by fibrous (scar) tissue
Water content
Surface tension
 Lung Compliance

Low pulmonary compliance = less elastic = work of breathing
- ex. Pulmonary fibrosis, ARDS, pulmonary edema

Increase pulmonary compliance = more elastic = work of breathing
- Overcompliance – ex. Emphysema
>> loss of elastic recoil = air trapping = chest barrel
Airway Resistance

Refers to opposition to the flow of gases in the airways
Factors
Airway length, diameter, and flow rate of gases

Increased airway resistance = more effort = inadequate ventilation
Bronchoconstriction, presence of artificial airway
Increased air flow
Pulmonary
perfusion
Movement of blood through the
pulmonary capillaries
Perfusion

Hypoxia induced vasoconstriction

blood vessels in the pulmonary circulation are highly sensitive to
alveolar oxygen levels and undergo marked vaso-constriction
when exposed to hypoxia
Purpose:
to redirect blood flow away from the hypoxic regions of the lungs to those
alveoli that are ventilated

Generalized hypoxia (ex. Anemia, COPD, high altitudes)
- Generalized vasoconstriction throughout the lungs =
pulmonary hypertension = RV failure
A
While one is sitting or standing, the upper lobes are
ventilated best, and the lower lobes are perfused
best

B
While one is lying on one side, the superior lung is
ventilated best, and the inferior lung is perfused best

C
In exercise ventilation and perfusion are increased
and optimally matched throughout
Pulmonary
diffusion
movement of gases between the
alveoli, plasma, and RBCs
Ventilation-Perfusion (V/Q) Mismatch

Normal Ratio
1:1 ratio
Healthy lungs

Low Ventilation-Perfusion Ratio: Shunts
Perfusion exceeds ventilation (1:2)
Pneumonia, atelectasis, tumor, or mucus plug
Ventilation-Perfusion (V/Q) Mismatch

High Ventilation-Perfusion Ratio: Dead Space
Ventilation exceeds perfusion (2:1)
Pulmonary embolism, pulmonary infarction, cardiogenic shock

Silent unit
Absence of both ventilation and perfusion (0:0)
Pneumothorax and acute respiratory distress syndrome
Venous oxygen saturation (SvO2)
Measurement of blood’s oxygen content
returning to the right side of the heart

Normal: 60-75%

Increased SvO2 – decreased utilization
(ex. Early septic shock, hypothermia)

Decreased SvO2 – increased utilization
(ex. Low cardiac output, fever, exercise,
late stage of sepsis, acidosis or increased
metabolic demands)
Regulation of Breathing
Respiratory Center
Apneustic center
✓lower pons
✓Prolongs inhalation

Pneumotaxic Center
✓Upper pons
✓Controls rate and pattern of breathing

Brain damage
connection to these 2 centers are lost, leading to irregular breathing
pattern that consists of prolonged inspiratory gasps interrupted by
expiratory efforts
Regulation of Breathing

Chemoreceptors
Central – near respiratory center in medulla
Peripheral – carotid and aortic bodies

Normal person: respiratory drive – High CO2 in blood

In patients with CHRONICALLY ELEVATED CO2 in blood
- they no longer respond to elevated CO2 for breathing
- respiratory drive: low oxygen levels
- ex. COPD
Assessment
 Physical
Assessment
Health History
1. Tobacco use: delivery method, amount, and number of pack-years
(number of packs of cigarettes per day × number of years smoking).
2. Occupational history, such as coal mining, asbestos work, and farming,
and exposure to dust, fumes, smoke, toxic chemicals, paints, and insulation.
3. History of symptoms such as shortness of breath, dyspnea, cough,
anorexia, weight loss, chest pain, or sputum production; further assessment
of sputum, including amount, color, consistency, time of day, and whether its
appearance is chronic or acute.
4. Use of oral and inhalant respiratory medications, such as bronchodilators
and steroids.
5. Use of over-the-counter or street inhalant drugs.
6. Allergies: medication, food, or environmental.
7. Dates of last chest radiograph and tuberculosis screening.
Inspection

Tongue and sublingual area
- Central cyanosis: bluish, gray, or dark purple tint

Chest wall configuration
- Barrel chest
- Pectus carinatum and pectus excavatum
- Spinal deformities: scoliosis, kyphosis, lordosis

Evaluation of respiratory effort
Systematic method for palpation, percussion, auscultation
Palpation

Position of trachea
Midline

Abnormal Findings
Deviation to either side
indicates
pneumothorax – shift to
opposite side
Severe atelectasis – shift
to same side
Palpation

Thoracic Expansion
Normal findings:
Equal
thumbs should
separate by 3-5 cm

Abnormal Findings
Unequal expansion –
pneumothorax
70%
SvO2 – 60-75%
Pulmonary Function Test

measure lung volumes and airflow to quantify respiratory function

Purpose
preoperative assessment
evaluating lung mechanics
diagnosing and tracking pulmonary diseases
- Bronchodilator reversibility test
monitoring therapy

Takes 2 hours to complete
Pulmonary Function Test

Can be performed in intubated and non-intubated patients

Intubated – spirometer is attached to the end of ET tube

Non-intubated – a nose clip is attached on the patient, and is
instructed to take a deep breathe, then exhale as hard, as fast,
and for as long as possible
Pulmonary Function test

Before
- Avoid scheduling immediately after mealtime
- Avoid or HOLD all inhaled bronchodilator 6hr before
- Assess for respiratory distress

During
- Assess for respiratory distress

After
- Assess for respiratory distress
- Provide rest after procedure
Carbon Dioxide Monitoring
End-tidal carbon dioxide (PetCO2)
Concentration of CO2 present at the end of exhalation
Normal range: 35-45 mmHg

Increased
Hyperthermia, sepsis, seizures, hypoventilation, respiratory
depression

Decreased
Hypothermia, cardiac arrest, pulmonary embolism,
hyperventilation
 Uses pH sensitive colored
paper strips
Uses
- Verify ET placement
- Verify enteral feeding
tubes placement
- low-resource settings

Colorimetric device
 using an electrode placed
on the skin
Commonly used in
neonatal and pediatric
patients

Transcutaneous
 measures the carbon dioxide
level directly by a sensor in
the exhalation port of the
ventilator tubing

Most commonly used

Disadvantage
- weight of the sensor on the
ventilator tubing and possible
obstruction of the sensor by
Mainstream capnometer secretion
 carbon dioxide gas is
continuously aspirated through
a side port in the ventilator
tubing or nasal cannula and is
measured and analyzed by a
side unit

Suitable for not intubated
patients

Disadvantages include
obstruction of the sampling
tube with secretions and slow
Sidestream capnometer response time.
Arterial Blood Gas

Purpose
Assess acid-base balance, ventilation, oxygenation

ABG samples are obtained either
by direct puncture of an artery, usually the radial artery
by withdrawing blood through an indwelling arterial catheter system
 Arterial Blood Gas: Nursing Responsibility
Before:
Indicate whether patient is using O2 (flow rate in L/min).
Avoid change in O2 therapy or interventions (e.g., suctioning, position change) for 15 min
before obtaining sample.

During:
Assist with positioning (e.g., palm up, wrist slightly hyperextended if radial artery is used).
Collect blood in heparinized syringe.
To ensure accurate results, expel all air bubbles.

After:
Apply pressure to radial artery for at least 5 min after specimen is obtained to prevent
hematoma at the arterial puncture site.
 Arterial Blood Gas Analysis
1. LABEL ALL VALUES (PACO2, HCO3, PH) if acidotic or alkalemic
In pH, use 7.40 as reference. Then indicate if within normal or abnormal range (7.35-7.45)
IF NORMAL RANGE, FULLY COMPENSATED,
IF OUTSIDE RANGE, EITHER PARTIALLY COMPENSATED (OPPOSITE PACO2 AND
HCO3) OR UNCOMPENSATED (NORMAL VALUE ISANG COMPONENT)

2. CHECK WHICH COMPONENT IS SAME AS PH

3. CHECK IF OTHER COMPONENT IS OPPOSITE –
IF YES, COMPENSATED, REFER BACK TO PH IF NORMAL OR OUTSIDE;
IF NOT, UNCOMPENSATED

4. OXYGENATION
Acid-Base Imbalance
Acid-Base Imbalance
Acid-Base Imbalance
Acid-Base Imbalance
 Other
diagnostic
tests
Sputum Studies

rapid identification and treatment of pulmonary infections

obtain a sputum sample by expectoration, tracheal suction, or
bronchoscopy

When the patient is unable to expectorate spontaneously, sputum
may be collected by inhaling an irritating aerosol, usually
hypertonic saline. This is called sputum induction.
Collecting Sputum
Specimen from ET
or tracheostomy
tube
CT-Scan

Diagnose suspicious
lesions difficult to
assess by conventional
x-ray
Types:
✓ High-resolution CT
(HRCT)
✓Spiral / helical CT –
used to diagnose
pulmonary embolism
CT-Scan Nursing Responsibility
Before: Before contrast medium used, evaluate renal
function. Assess if patient is allergic to shellfish, since the
contrast is iodine based. Patient may need to be NPO 4
hr prior to study.

During: Warn patient that contrast injection may cause a
feeling of being warm and flushed. Patient must lie
completely still during scan.

After: Encourage patient to drink fluids to avoid renal
problems with any contrast
Magnetic Resonance Imaging (MRI)

Used for in-depth
diagnosis of lesions difficult
to assess by CT scan and
for differentiating vascular
from nonvascular
structures.

IV contrast agent
(gadolinium) may be given
MRI Nursing Responsibility
Before:
Check for pregnancy, allergies, and renal function before test.
Have patient remove all metal objects. Remove metallic foil patches.
Contraindicated for persons with implanted metallic devices or other metal
fragments unless noted to be MRI safe.
Ask about any history of surgical insertion of staples, plates, dental bridges,
or other metal appliances.
Patient may need to be fasting.
Assess for claustrophobia and the need for antianxiety medication.

During: Patient must lie completely still during scan
Positron Emission Tomography (PET) scan

Glucose-containing nuclear tracer substance injected and
taken up by metabolically active cells.
Follow-up scan shows different colored tissues based on
metabolic rate.
Because cancer cells have an increased uptake of
glucose, “hot spots” reflecting increased glucose
consumption indicate the presence of active cancer.
Used to distinguish benign and cancerous lung nodules.
PET scan Nursing Responsibility
Before:
Obtain IV access to inject the tracer substance.
Patients should be NPO, except for water and medications, for at least 4-6 hr prior.
Low-carbohydrate diet 12 hours before schedule
Hold glucose-containing IV solutions and change to normal saline.
Check blood glucose levels. The glucose level must be between 60–140 mg/dL
(3.3–7.8 μmol/L) for accurate glucose metabolic activity.

During: Patient must lie completely still during scan.

After: Encourage fluids to excrete radioactive substance.
Treatment
Modalities
Topics

Oxygen Therapy
Artificial airways
Endotracheal intubation
Tracheostomy care
Mechanical ventilation
Chest / Thoracostomy tubes
Oxygen
therapy
Oxygen Therapy

Goal

to provide a sufficient concentration of inspired oxygen to permit
full use of the oxygen-carrying capacity of the arterial blood

To ensure adequate cellular oxygenation, provided that the
cardiac output and hemoglobin concentration are adequate.

Primary indication: treat hypoxemia
Oxygen Therapy
Oxygen Therapy
Indications for Oxygen therapy

Significant hypoxemia
Suspected hypoxemia (e.g., asthma, aspiration, seizure, drug overdose)
Any acute care situation in which hypoxemia is likely
❑Increased myocardial workload (e.g., HF, hypertensive crisis, MI)
❑Decreased cardiac output (e.g., shock, hypotension, cardiopulmonary arrest)
❑Increased oxygen demand (e.g., sepsis, increased ventilatory work, trauma)
❑Before procedures that may cause hypoxemia (e.g., suctioning, during and after
anesthesia, transportation of the unstable patient, bronchoscopy)

Decreased oxygen-carrying capacity (e.g., carbon monoxide or cyanide
poisoning, methemoglobinemia, sickle cell disease, anemia)
 Principles of Oxygen Therapy

Airway is always the first priority; oxygen is useless without an adequate
airway.

If high concentrations are needed, limit duration to prevent toxicity
Frequent ABGs are mandatory if FiO2 is above 40 percent

FiO2 can be estimated by counting the number of reservoirs

Nose and pharynx only (1 reservoir) less than 40%: e.g., nasal cannula

Nose and pharynx + mask (2 reservoirs) 40% to 60%: e.g., simple face mask

Nose and pharynx + mask + reservoir bag (3 reservoirs) 60% to 80%: e.g., partial rebreathing mask

Nose and pharynx + mask + reservoir bag + one-way valves (3 reservoirs + decrease in dilution) 80% to
100%: e.g., nonrebreathing mask
Safety Guidelines for Oxygen therapy

Keep the oxygen source at least 10 feet from open flame
Do not allow smoking in a room with supplemental oxygen
Do not use electrical appliances within 5 feet of the oxygen source.
Do not use petroleum-based products around the oxygen source; use only
water-soluble lubricants and creams
Turn off the oxygen when not in use.
Secure the oxygen tanks to prevent accidental dropping; keep the oxygen
source away from heat or direct sunlight.
Oxygen
Delivery
systems
Low Flow Oxygen Delivery Systems

Do not provide total inspired gas; the remainder of the patient’s
inspiratory volume is met by the patient breathing varying amounts of
room air.
FiO2 dependent on the rate and depth of ventilation and fit of the
device
Criteria indicating that a low-flow O2 delivery system is acceptable
Normal or near-normal VT (~7 ml/kg of ideal body weight [IBW])
Respiratory rate normal or near normal (~15–25 breaths/min)
Regular respiratory rhythm
Specific oxygen concentration not critical to patient’s care
Devices under Low Flow Oxygen System

Nasal cannula

Reservoir systems

Simple face mask

Partial rebreathing mask

Nonrebreathing mask
High Flow Oxygen Delivery Systems

Provide the entire inspired gas by a high flow of gas or entrainment
of room air.
Provide a predictable FiO2 but not necessarily a high FiO2
Criteria indicating that a high-flow O2 delivery system is needed
VT is significantly less than or more than normal (~7 ml/kg of IBW)
Respiratory rate less than 15 breaths/min or more than 25 breaths/min
Irregular respiratory rhythm
Specific oxygen concentration is critical to the patient’s care.
Evidence of alveolar hypoventilation with hypercapnia
Devices under High Flow Oxygen System

Venturi Mask

High-flow nasal cannula (HFNC)

T-piece

Trach collar

Mechanical ventilator
Minute Ventilation = RR X Tidal Volume
Ex. Person in distress = 43 cpm x 450cc = 19350cc or 19.3L

Non-rebreather Mask = High Flow Nasal Cannula
10lpm = 30lpm
Partial Rebreather Mask
Non-Rebreather Mask
High Flow Nasal Cannula

high-flow nasal cannula (HFNC) oxygen devices are capable of
delivering well-humidified, blended, and actively warmed oxygen

HFNC can provide oxygen at very high flow rates, between 30
and 60 L/min

Can provide moderate PEEP.
Complications of Oxygen Therapy

Alveolar Hypoventilation / O2 induced hypoventilation

At risk: in patients with COPD – breathing stimulus to high CO2 is
lost

Management
Use oxygen with caution. Maximum 1-2LPM
Target O2 saturation: 90%
Complications of Oxygen Therapy

Absorptive Atelectasis

High concentrations of oxygen (an absorbable gas) wash out the
nitrogen (a nonabsorbable gas) that normally holds the alveoli
open at the end of expiration.

Prevention
Do not administer O2 that is not needed
Avoid long duration of high concentrations of oxygen if not
needed
Complications of Oxygen Therapy

Oxygen Toxicity
Cause: too high O2 concentration over long period of time

Pathophysiology
Overproduction of oxygen free radicals
Free radicals overwhelms neutralizing enzymes
Damage to alveolar-capillary membrane
Leads to ARDS
Complications of Oxygen Therapy

Oxygen Toxicity
Sign and Symptoms
Early
substernal chest pain that increases with breathing
Followed by dry cough and tracheal irritation and upper airway
changes (ex. Nasal stuffiness, sore throat)

Late
CXR changes: atelectasis or pneumonia
Decreased vital capacity
Complications of Oxygen Therapy

Oxygen Toxicity
Prevention
Use lowest FiO2 possible to maintain SaO2 of 90%
Limit duration of 100% FiO2 to 60% FiO2 to 2-3 days

Assess ABG if FiO2 is above 40% to ensure that high
concentration is still needed
Artificial
airway
Artificial Airway

Oropharyngeal airway (OPA)
Nasopharyngeal airway (NPA)
Laryngeal mask airway (LMA)
Endotracheal (ET) tube
Tracheostomy tube
 Oropharyngeal Airway
used to relieve upper airway obstruction caused by tongue
relaxation, secretions, seizures, or biting down on oral ETs
indications: unconscious patients
not recommended in alert patients because it triggers gag
reflex causing vomiting

Nursing interventions
Remove airway every 24h to:
Assess lips and tongue for pressure injuries
Provide oral hygiene
Oropharyngeal airway
 Nasopharyngeal Airway

Made of soft malleable rubber or soft plastic, the nasal airway ranges in
sizes from 26 to 35 Fr
Indications
o Oropharyngeal airway is contraindicated due to oral trauma or during
seizure
o Conscious patients
Insertion
o Lidocaine and lubricant
o Assess for patency – listen or feel for air movement during exhalation
o Chevron tape technique
 Nasopharyngeal Airway

Nursing interventions

Frequent assessment of pressure injuries and obstruction due to
died secretions
Need for airway assessed daily
Rotation of airway from nostril to nostril on daily basis
 Laryngeal Mask Airway

is an ET with a small mask on one end that can be passed
orally over the larynx to provide ventilatory assistance and
prevent aspiration
Placement of the LMA is easier than intubation using a
standard ET
Temporary airway
Used in management of difficult airway insertion- “cannot
intubate”
 Endotracheal Tube
most commonly used artificial airway for providing short-term airway
management
ETT is made of polyvinyl chloride or silicone material with distal cuff (balloon) that
is inflated
Purpose of the cuff is to facilitate ventilation by sealing the trachea and allowing
the air to pass through, not around, the ETT.
Indications
o Maintain airway patency
o Patients requiring mechanical ventilation
o Severe airway obstruction
o Also allows easier secretion removal
o Protect from aspiration of oral or gastric contents
 Endotracheal Intubation

Insertion of ETT into the trachea through either the mouth or nose

Orally inserted – preferred during emergency

Nasally inserted – preferred in patients with oral trauma, jaw
fracture and provides greater comfort overtime
 Endotracheal Intubation
1. Preparation of materials
2. Preoxygenation with 100% oxygen for 3-5 minutes via bag valve mask connected to simple
face mask
3. Premedicate – sedative (midazolam, propofol, diazepam) and paralytic (succinylcholine and
rocuronium)
4. Positioning patient – sniff position
5. Placement of ET tube
a. Each attempt limited to 30 seconds
b. After insertion, check for bilateral breath sounds and equal chest movement
c. End tidal CO2 detector – to initially verify placement after which the cuff is inflated
d. Finally chest radiograph to confirm placement
6. Postintubation
a. Level of insertion at the teeth is noted
b. Secure ET tube using commercial tube holder
Sniff Position
 Tracheostomy
tracheostomy tube provides an airway directly into the anterior
portion of the neck

indications
Long term airway or mechanical ventilation
Bypass an upper airway obstruction that prevents placement of
ETT tube
 Tracheostomy

Methods
Traditional – surgical tracheostomy – done in OR

Percutaneous dilational tracheostomy (PDT)
✓ may be done bedside
✓Advantages: procedure is shorter and less expensive; perioperative
infection rates are less
✓Contraindications
- Inability to hyperextend neck
- Morbid obesity
 Tracheostomy Tube Designs

Cuffed vs Uncuffed
Single vs Double cannula
Fenestrated vs unfenestrated tracheostomy tube
Speaking tracheostomy valves
 Tracheostomy Tube Designs
Cuffed
Patient require mechanical
ventilation
Prevent aspiration
Used in short-term

Uncuffed
Patient does not require
mechanical ventilation*
Low risk of aspiration
For long term
 Tracheostomy Tube Designs

Single Cannula

Double Cannula
Outer cannula – holds tracheostomy / airway open
Inner cannula – removable; prevent tube occlusion from
accumulated secretions by cleaning the inner lumen
 Tracheostomy Tube Designs
Fenestrated
Have openings on outer cannula
Allows the patient to speak and
produce more effective cough

Unfenestrated
Do not have openings on outer
cannula
Patient is unable to speak
 Tracheostomy Tube Designs
Speaking valve device

Allows patient to speak
Uses one-way valve
Cuff must be deflated first
before attaching the
speaking valve device*
Mechanism of
Speaking Valve
Device
Preparing the Patient for tracheostomy

Pre-procedure Care
Consent
Ensure all appropriate personnel are present
BVM, suction machine, emergency resuscitation equipment
should be readily available, especially if bedside procedure
Baseline vital signs
Ensure patent IV line
Position the patient supine
Give analgesia and sedation as ordered
Preparing the Patient for tracheostomy

During the procedure
Monitor hemodynamic status.
Observe the patient’s response to analgesia and/or sedatives.
Note the patient’s tolerance to the procedure.
Observe the SpO2 and immediately notify the HCP if the SpO2 is
less than 92%
Preparing the Patient for tracheostomy

Post-procedure Care
Confirm correct tube placement (similar with ETT)
Tracheostomy cuff is inflated
Tracheostomy tube is sutured and secured in placed with
tracheostomy ties, tapes, or Velcro strap
Monitor vital signs
Obtain chest x-ray
Note and record ventilator settings, including mode, FiO2 and PEEP
WOF complications: airway obstruction, bleeding, infection, potential
dislodgment
Nursing Management: Patient with Tracheostomy
assess the tracheostomy site and confirm patency every shift, or
more often based on your assessment

Observe the site for any redness, inflammation, edema,
ulceration, or signs of infection

Perform sterile dressing changes every 12 to 24 hours

Clean around the stoma with normal saline and apply a sterile
precut dressing around the tracheostomy tube site
Nursing Management: Patient with Tracheostomy
Maintain cuff inflation pressure to 20-30 mmHg with cuff using
manometer every 8 hours
Higher cuff – tracheal necrosis
Too loose – aspiration
Minimal occluding volume (MOV) technique

Suction tracheostomy as needed – sterile; try to avoid suctioning
few hours after tracheostomy
Change the tracheostomy tapes after the first 24 hours and PRN
Types of Suctioning
Closed Suctioning
suction catheter that is enclosed in a plastic sleeve connected directly to the
patient-ventilator circuit
exposure to the patient’s secretions and infection is reduced for the patient and
HCP’s safety
Open Suctioning
Performed when we need sterile sputum samples or CST is not available
Best performed with 2 persons – one uses BVM, the other person suctions
Higher risk for infection and exposure
Closed
Suctioning
 Decannulation

Removal of the tracheostomy from the trachea

Indications
The condition for tracheostomy is needed has been resolved
- Hemodynamically stable
- Stable, intact respiratory drive
- Able to adequately exchange air
- Independently expectorate secretions
 Decannulation

Pre-procedure

Explain to the patient on what will occur
Monitor vital signs
Suction the patient’s airway, also clear any oral secretions
Loosen or cut tracheostomy ties
Remove any visible sutures
Deflate the cuff
Pull tracheostomy tube outwards in one smooth motion. Stop if
there is resistance and inform HCP
 Decannulation

After removal

Apply sterile occlusive dressing
Monitor for bleeding, respiratory status, oxygen saturation
Change dressing if soiled
Close the stoma with tape strips
Teach patient to splint the stoma with fingers when coughing,
swallowing or speaking
Epithelial tissue begins to form in 24 to 48 hours, and the
opening closes within 4 or 5 days. Surgery to close the
tracheostomy is usually not needed.
 ACCIDENTAL Decannulation
Immediately call for help !!

If tube can be replaced (especially if tract has matured)

Using hemostat
Use hemostat to spread the opening where the tube was
Insert the obturator in the replacement tube, lubricate the saline, and insert the
tube into the stoma
Once inserted, remove the obturator

Using a suction catheter
Insert suction catheter to allow air passage and guide for insertion
Thread tracheostomy tube over the catheter, then remove the catheter
 ACCIDENTAL Decannulation

If tube can’t be replaced due to tract immaturity

Immediately place patient in semi-fowlers position
Cover the stoma with sterile dressing and ventilate the patient with the
BVM over the nose and mouth
Mechanical Ventilation

Using a ventilator to deliver oxygen
to the lungs

a means of supporting patients until
they recover the ability to breathe
independently

NOT CURATIVE
Types of Ventilators

Negative pressure ventilators
o use of chambers that encase the chest or body and surround it with
intermittent sub-atmospheric (or negative) pressure
o ex. Iron lung used in polio
o Uses: limited to chronic neuromuscular diseases and central nervous system
problems
o Rarely used for critically ill patients
Positive pressure ventilators
o Main method used for critically ill patients
o During inspiration, ventilator pushes air into the lungs under positive pressure.
Adjustable Ventilator Settings

Respiratory rate – 6-20 breaths per minute
Tidal volume – 6-10 ml/kg; 4-8ml/kg in ARDS
O2 concentration (FiO2) – 21%-100%
Peak Inspiratory pressure (PIP) – pressure the ventilator exert during
inhalation to deliver the tidal volume. Once this pressure is reached,
the ventilator ends the breath and spills undelivered volume into the
atmosphere
Adjustable Ventilator Settings

Positive End-Expiratory Pressure (PEEP)
ventilator setting in which positive pressure is applied to the airway during exhalation to keep
airway or alveoli always open
o During exhalation, airway pressure normally drops to near 0.
o With PEEP, exhalation remains passive, but pressure falls to the preset PEEP level, often set
between 5 to 10 cm H2O.
Optimal PEEP – level of PEEP (pressure) to improve oxygenation without compromising
hemodynamics
Indication: ARDS, ARF
Contraindications: traumatic brain injury, increased ICP, low CO, hypovolemia
 Ventilator Settings

3 general categories

Full support
o Ventilator does most of the work of breathing for the patient
o There is usually preset Tidal volume, Respiratory rate and PIP limit
Partial support
o Work of breathing is shared responsibility by the patient and ventilator
o There may still be preset tidal volume and respiratory rate, BUT the patient assumes more
responsibility
Spontaneous mode
o Work of breathing assumes almost all breathing
o No preset respiratory rate and tidal volume. ONLY FiO2 and PEEP is provided by mechanical
ventilation
Full Support Modes

Assist-control
o The ventilator delivers preset tidal volume and respiratory rate
o Usually used in postoperative patients and those with neuromuscular disorders
and ARF
o On AC, patient can take a breath whenever they want. However, it may cause
hyperventilation / respiratory alkalosis
Pressure control
o Ventilator delivers pressure-limited breath
o With preset respiratory rate and PIP, BUT NOT tidal volume = variable TV
depending on lung compliance
o Reduces risk of barotrauma
o Used for noncompliant lungs
Partial Support Modes

Synchronized intermittent mandatory ventilation (SIMV)
o Patient and ventilator shares the WOB
o The ventilator delivers preset tidal volume at preset respiratory rate in
SYNCHRONY with patient’s spontaneous breathing.
o In between ventilator-delivered breaths, the patient can breathe
spontaneously and achieve whatever tidal volume they achieve
o used when the patient’s condition is too good for a full support mode of
mechanical ventilation, but they are not yet ready for a spontaneous mode
o Also used for weaning trials
Spontaneous Breathing Modes

pressure support
o patient initiates breathing and the ventilator provides PRESSURE ONLY to
airway during inspiration
Continuous positive airway pressure (CPAP)
o Do not confuse with noninvasive CPAP used in patients with sleep apnea
o Ventilator only provides FiO2 and PEEP (pressure)
Patient does almost all of breathing. Patient determines respiratory rate and tidal
volume
Nursing Management for Mechanically
Ventilated Patients
Maintaining Correct Tube Placement

Note exit point from the mouth or nares
Observe for symmetric chest wall movement and bilateral breath
sounds
During accidental decannulation
Stay with the patient and try to maintain the airway (refer to accidental
decannulation)
Support ventilation with BVM
Nursing Management for Mechanically
Ventilated Patients
Maintaining Proper Cuff Inflation

Excess volume can cause tracheal necrosis
Maintain cuff pressure at 20-30cm H2O
Measure and record cuff pressure using minimal occluding volume q8H
Nursing Management for Mechanically
Ventilated Patients
Maintaining Tube Patency

Suction PRN, minimum at least 1 per shift
Open vs Closed Suction Technique
Hyperoxygenate client before and after suctioning. Limit each suction to 10
seconds or less
Avoid excess suctioning – may lead to hypoxemia and bradycardia
Closely assess patient’s ECG and O2 saturation before, during, and after
suctioning
If the patient does not tolerate, stop immediately
Maintain adequate hydration, humidification, and frequent turning
Nursing Management for Mechanically
Ventilated Patients
Maintaining Alarm Systems

Temporarily suspend or silence alarms for up to 2 minutes for
suctioning
Ways to prevent alarm fatigue
 Ventilator Alarms

Low tidal volume High tidal volume

Leaks or disconnection Anxiety, pain
Low cuff pressure Change in patient condition
(fever, increased metabolic
Airway secretions
demands, patient condition
Oversedation improving)
 Ventilator Alarms

Low pressure limit High pressure limit

Disconnections and leak Kinked or compressed tubing
Loss of airway Increased lung compliance (ex.
Peumothorax)
Patient speaking
Condensate or secretion in
tubing
Patient fighting ventilator
(ventilator dyssynchrony)
Improper alarm settings
 Ventilator Alarms

Apnea alarm

Set for