Principles of Mechanical Ventilation

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Principles of Mechanical Ventilation

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Raw increases with secretions, mucosal edema, bronchospasm, kinked ET tube or ... Increase Raw from ET Tube, expiratory valve, PEEP valve. Monitoring Airway Pressures ... – PowerPoint PPT presentation

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Title: Principles of Mechanical Ventilation

1
Principles of Mechanical Ventilation

RET 2284
Module 4.0 Ventilator Management
- Initial Assessment

2
Assessment and Documentation of MV

This module will review the assessment and
documentation of the patient-ventilator
interaction in the initial stages

3
Assessment and Documentation of MV

Verify the physicians order
Some orders are specific
Mode, rate, Vt, FiO2, PEEP
Some orders are flexible
Desired range of PaCO2 and PaO2
Initial settings Mode, rate, Vt, FiO2, PEEP
which can be manipulated to achieve the desired
blood gas results

4
Assessment and Documentation of MV

Verify that the ventilator has passed OVP
OVP Operational Verification Procedure
Usually an automated self-test
Usually includes a system-leak test to check the
integrity of the ventilator circuit, humidifier
and related equipment
Done before placing a patient on the ventilator
for the first time and before reconnecting the
patient to a ventilator if the circuit has been
changed or disassembled for any reason
Must be documented

5
Assessment and Documentation of MV

Place the patient on the ventilator
Set parameters on ventilator in accordance with
the physicians orders
Connect the patient to the ventilator
Listen to breath sounds to confirm adequate
volume delivery and proper placement of ET Tube

6
Assessment and Documentation of MV

Check patients vital signs especially heart
rate and blood pressure because these may be
affected by mechanical ventilation
Note Positive pressure ventilation can reduce
venous return to the heart, cardiac output, and
blood pressure

7
Assessment and Documentation of MV

Activate alarms (e.g., apnea, low pressure, low
Vt, and high pressure limits)
Obtain ABG about 15 minutes after ventilation
Evaluates effectiveness of ventilation and
oxygenation

8
Assessment and Documentation of MV

Chest x-ray Verify ET tube placement
If the patients clinic presentation indicates a
need, other determinations my be include
CBC
Glucose, sodium, potassium, chloride, CO2, blood
urea nitrogen, creatinine, phosphate, magnesium
PT, PTT, platelet count
Blood, sputum, urine culture

9
Assessment and Documentation of MV

Documentation of the PT-Vent System
AKA Vent Check
Patient information and ventilator settings
should be documented regularly when a patient is
receiving ventilator support every 1 4 hours
depending on the institutions policy
Documentation is done on a ventilator flow sheet
electronic or paper record

10
Assessment and Documentation of MV

Documentation of the PT-Vent System
AARC Recommendations
Data relevant to the patient-ventilator system
check are recorded on the appropriate hospital
form and become part of the patients medical
record
The patient-ventilatory system check includes
patient information and observations of
ventilator settings at the time of the check

11
Assessment and Documentation of MV

Documentation of the PT-Vent System
AARC Recommendations
The record should include the physicians order
for mechanical ventilator settings
The patient-ventilatory system check includes a
brief narrative of the clinical observations of
the patients response to mechanical ventilation
at the time of the check

12
Assessment and Documentation of MV

Documentation of the PT-Vent System
Patient information

13
Patient and ventilator parameters
14
Patient and ventilator parameters

Patient and ventilator parameters (cont.)

15
Patient and ventilator parameters

Patient and ventilator parameters (cont.)

16
Patient and ventilator parameters

Patient and ventilator parameters (cont.)

17
Patient and ventilator parameters

Patient and ventilator parameters (cont.)

18
Patient and ventilator parameters

Patient and ventilator parameters (cont.)

19
Assessment and Documentation of MV

Mode
Institution determines the method for charting
mode
Sensitivity
Check for autotriggering
Assess the patients ability to trigger the vent
Documentation
Pressure triggered (e.g., - 2 cmH2O)
Flow triggered (e.g., 2 L/min)

20
Assessment and Documentation of MV

Tidal Volume, Rate, Minute Ventilation
Usually displayed digitally
May be verified with respirometer
Correcting Tubing Compliance
Volume loss due to tubing compliance
(compressible volume)
Accounts for approximately 1.5 2.5 mL/cm H2O of
lost volume
Newer vents automatically compensate

21
Assessment and Documentation of MV

Determination of Circuit Compressible Volume Loss
Set VT to 100-200 and PEEP to zero
Set inspiratory pause at 2 seconds
Select a minimum flow rate and maximum pressure
limit
Occlude Y-connection and initiate a mechanical
breath
Record the exhaled volume (ml) and peak
inspiratory pressure (cm H2O)
Divide exhaled volume by PIP (V/PIP) circuit
compression factor
Multiply compression factor by the patients PIP
(PIP minus PEEP if PEEP is used)
Example
Circuit compression factor 150 ml / 50 cm H2O
3 ml/cm H2O
Circuit compression volume 3 ml/cm H2O x (60 cm
H2O PIP 10 cm H2O PEEP)
3 ml/cm H2O x 50 cm H2O 150 ml (circuit
volume Loss)

22
Assessment and Documentation of MV

Alveolar Ventilation
Because of the use of HMEs and other circuit
adapters that add mechanical dead space to the
ventilator circuit, a knowledge of the effect of
dead space on alveolar volume delivery is
important especially in infants, children, small
adults, and adults with ARDS treated with low
tidal volumes

23
Assessment and Documentation of MV

Alveolar Ventilation
Anatomical Dead Space
Normal anatomical dead space (VDanat) is about 1
mL/lb IBW
Note Bypassing the upper airway with an
artificial airway reduces VDanat by about one half

24
Assessment and Documentation of MV

Alveolar Ventilation
Added Mechanical Deadspace (VDmech)
Y-connectors, HMEs, and/or flex tubing all add
mechanical deadspace
To measure this volume, fill the device with
water and empty into graduated container)
When determining actual alveolar ventilation, the
volume of these devices must be subtracted from
the tidal volume
Example VT VDanat VDmech Alveolar
Ventilation

25
Assessment and Documentation of MV

Alveolar Ventilation
Final Alveolar Ventilation
VA (VT VDanat VDmech) x f

.
26
Assessment and Documentation of MV

Alveolar Ventilation - QUESTION
A 36-year-old male patient with ARDS is
ventilated with a VT of 400mL. The patients IBW
is 176 lb (80 kg). The HME has a volume of 50
mL. What is the approximate alveolar volume for
one breath for this patient?
350 mL
260 mL
400 mL
190 mL

27
Assessment and Documentation of MV

Alveolar Ventilation - ANSWER
VDant is about 180 ml (80 kg IBW x 2.2 lb
176). With an ET tube in place, the VDant is
reduced to about half to 90 mL. The HME adds
about 50 mL of mechanical dead space. VD is
about 140 mL.
VT VD VA
400 140 260 mL/breath
VA 260 mL

28
Assessment and Documentation of MV

Monitoring Airway Pressures
Ensures that very high pressure limits are not
exceeded
Provide information about the patients conditions

29
Assessment and Documentation of MV

Monitoring Airway Pressures
Peak Inspiratory Pressure (PIP or PPeak)

30
Assessment and Documentation of MV

Monitoring Airway Pressures
Peak Inspiratory Pressure (PIP or PPeak)
The highest pressure observed during inspiration
Used to calculate dynamic compliance (CD)
A constant VT with an ? PIP may indicate a ? in
lung compliance (CL) or an ? in Raw
A declining PIP may indicate a leak or may a sign
of improvement in CL or Raw

31
Assessment and Documentation of MV

Monitoring Airway Pressures
Plateau Pressure (PPlateau)

32
Assessment and Documentation of MV

Monitoring Airway Pressures
Plateau Pressure (PPlateau)
Obtained by using the ventilators inspiratory
pause of 0.5 1.5 seconds
Static pressure is read when no gas flow is
occurring
Reflects the elastic recoil of the alveolar walls
and thoracic cage against the volume of air in
the lungs
Cannot be measured accurately if the patient
makes active respiratory efforts

33
Assessment and Documentation of MV

Monitoring Airway Pressures
Set Pressure
The operator sets a target pressure to be
delivered to the patient during PC-CMV, PC-SIMV
and PSV
Example

22 cm H2O
15 cm H2O
34
Assessment and Documentation of MV

Monitoring Airway Pressures
Peak Pressure Minus Plateau Pressure
The difference between PIP and PPlateau is the
transairway pressure (PTA) this is the amount of
pressure required to overcome Raw (Raw
PTA/Flow)

35
Assessment and Documentation of MV

Monitoring Airway Pressures
Peak Pressure Minus Plateau Pressure
A higher than expected difference between PIP and
PPlateau usually indicates increased Raw
Raw increases with secretions, mucosal edema,
bronchospasm, kinked ET tube or patient biting on
ET tube, partly occluded HME (moisture or
secretions)

36
Assessment and Documentation of MV

Monitoring Airway Pressures
End-Expiratory Pressure (EEP)
The lowest pressure measured in the expiratory
phase

37
Assessment and Documentation of MV

Monitoring Airway Pressures
End-Expiratory Pressure (EEP)
The lowest pressure measured in the expiratory
phase
PEEP Positive End Expiratory Pressure
CPAP Continuous Positive End Expiratory
Pressure
Auto-PEEP

38
Assessment and Documentation of MV

Monitoring Airway Pressures
End-Expiratory Pressure (EEP)
Auto-PEEP air trapping during positive pressure
ventilation AKA
Air trapping
Breath stacking
Inadvertent PEEP
Dynamic hyperinflation
Occult PEEP
Intrinsic PEEP

39
Assessment and Documentation of MV

Monitoring Airway Pressures
Causes of Auto-PEEP

Increased Raw
Airway collapse on expiration
Bronchospasm
COPD
Mucosal edema
Secretions
Short TE

Long TI
Slow peak flow rate
High rate
High VE
High IE ratio
Increase Raw from ET Tube, expiratory valve, PEEP
valve

40
Assessment and Documentation of MV

Monitoring Airway Pressures
Auto-PEEP Suspected

Accessory muscle use
Decreased breath sounds
Decreased chest wall movement
Dyspnea
Increased resonant percussion
Increased radiolucency on CXR

Inspiratory efforts do not trigger ventilator
Patient still exhaling when vent delivers next
breath
Patients respiratory rate greater than
ventilators response (assuming sensitivity is
set correct)

41
Assessment and Documentation of MV

Monitoring Airway Pressures
Auto-PEEP Suspected

42
Assessment and Documentation of MV

Monitoring Airway Pressures
Measuring Auto-PEEP
Exhalation valve is occluded for 1-2 seconds just
prior to inspiration
Expiratory Pause control on newer ventilators
Level of auto-PEEP is reflected on the pressure
gauge during the pause
Reading is accurate only if the patient is not
actively breathing
Auto-PEEP Total PEEP set PEEP

43
Assessment and Documentation of MV

Monitoring Airway Pressures
Methods to reduce Auto-PEEP

Brochodilators / suction
Steroids
Allow more spontaneous breathing (SIMV, PS, CPAP)
Larger ET Tube
Apply PEEP (up to 80 of auto-PEEP)

Increase TE
Decrease respiratory rate (? TE )
Decrease VT (? TI)
Decrease TI
Increase peak flow rate (? TI)

44
Assessment and Documentation of MV

Monitoring Airway Pressures
Mean Airway Pressure
Closely parallels the mean alveolar pressure
Newer vents calculate and display mean airway
pressure
Affected by
PIP
EEP
TI/Total cycle time
f
Inspiratory flow patterns and modes
Important to tissue oxygenation!!!
Affects lung volumes and cardiac output

45
Assessment and Documentation of MV

Monitoring Airway Pressures
Pressure Limit
Usually set 10 15 cm H2O above PIP
Audible and visual alarms are activated if PIP
exceeds a set limit
Activation of high pressure limit alarm ends
inspiration
Often activated by coughing
High peak pressures may indicate ? Raw or ? CL

46
Assessment and Documentation of MV

Monitoring Airway Pressures
Low Pressure Alarm
Visual or audible alarm is activated when
pressure within the vent circuit has fallen
significantly
Leak or disconnect
Usually set 10 cm H2O below PIP
Note If the leak is not obvious, the patient
must be manually ventilated until the cause of
the leak is determined

47
Assessment and Documentation of MV

Vital Signs
Observing and recording the patients blood
pressure (BP), heart rate (HR), temperature (T),
respiratory rate (f), oxygen saturation (SpO2),
and color every few hours help staff members
evaluate possible changes in the patients
overall condition
Moderate changes in vital signs should alert the
practitioner to the possibility of hypoxemia,
impending cardiovascular collapse, or infection

48
Assessment and Documentation of MV

Vital Signs
Heart Rate
All patient on ventilatory support must be
continuously monitored with a three-lead ECG
Provides maximum/minimum HR alarms
ECG electrode disconnection
Vent disconnection -
(hypoxemia, hypercapnia)
Myocardium infarction (MI)
Anxiety
Pain
Stress

49
Assessment and Documentation of MV

Vital Signs
Temperature
Hyperthermia
Infection
Tissue necrosis
Metabolic states, e.g., hyperthyroidism
Atelectasis
Accidental or surgical trauma

50
Assessment and Documentation of MV

Vital Signs
Temperature
Hypothermia
Metabolic disease
CNS disorders
Drugs
Alcohol, heroin, carbon monoxide

51
Assessment and Documentation of MV

Vital Signs
Systemic Arterial Blood Pressure
Monitored intermittently
Stethoscope/sphygmomanometer
Automatic BP cuff
Monitored continuously
Invasive intravascular arterial catheters
A-Line

Radial A-Line
52
Assessment and Documentation of MV

Vital Signs
Central Venous Line (CVP)
Placed in the superior vena cava or right atrium
Provide valuable information regarding
Right heart function
Fluid status
Hypervolemia
Hypovolemia

53
Assessment and Documentation of MV

Vital Signs
Pulmonary Artery Pressure
Monitored continuously
Swan-Ganz catheter
AKA Balloon-tip, flow-directed, pulmonary artery
catheter (BTFDC)
Used in patients with severe cardiopulmonary
complications

54
Assessment and Documentation of MV

Physical Examination of Chest
Inspection
Accessory muscles usage - ? WOB
Paradoxical breathing - ? WOB
Abdominal distention
Gas, air swallowing, bleeding, ascites
Impairs ventilation
Palpation
Percussion
Auscultation

55
Assessment and Documentation of MV

ET and Tracheostomy Tube Cuffs
Cuff Pressure Measurement
Checked once per shift
Pressures not to exceed
27 34 cm H2O (20 25 mm Hg)
Excessive pressures my cause tracheal damage if
cuff pressures are greater than tracheal
perfusion pressures

56
Assessment and Documentation of MV

ET and Tracheostomy Tube Cuffs
High Cuff Pressure
Overinflation of tube cuff
Necessary to maintain minimum occlusion
Artificial airway may have moved up into the
larynx of pharynx
Check depth of tube or chest x-ray
ET tube may be too small

57
Assessment and Documentation of MV

ET and Tracheostomy Tube Cuffs
No or Low Cuff Pressure
Cuff not properly inflated
Cuff leak
Check inflate cuff and clamp pilot tube
Resolution change cuff
Pilot balloon leak
Check inflate cuff and place stopcock in pilot
balloon in off position
Resolution clamp pilot tube
Pilot tube leak
Resolution syringe with blunt-tipped needle

58
Assessment and Documentation of MV

Tube and Mouth Care
Reposition ET tube every shift (Pilbeam) and
retape if necessary
Most facilities do this every 24 hours
Prevents pressure injury to gums, mouth, lips
Usually a two-man procedure
Mouth care should be performed every shift
Helps prevents ventilator-acquired pneumonia
(VAP)

JADA Continuing Education
Pneumonia in nonambulatory patients
The role of oral bacteria and oral hygiene
Frank A. Scannapieco, DMD, PhD Background.
Considerable evidence exists to support a
relationship between poor oral health, the oral
microflora and bacterial pneumonia, especially
ventilator-associated pneumonia in
institutionalized patients. Teeth or dentures
have nonshedding surfaces on which oral biofilms
(that is, dental plaque) form that are
susceptible to colonization by respiratory
pathogens. Subsequent aspiration of respiratory
pathogens shed from oral biofilms into the lower
airway increases the risk of developing a lung
infection. In addition, patients may aspirate
inflammatory products from inflamed periodontal
tissues into the lower airway, contributing to
lung insult.

60
Assessment and Documentation of MV

Mouth Care Kit for MV Patients

61
Assessment and Documentation of MV

Monitoring CL and Raw
Static Compliance (Cs)
Normal 70 100 mL/cm H2O (Cs VT/Pplat
PEEP)
Changes in Cs over time is usually considered a
result of change in the patients alveolar
elastic recoil (can be affected by chest wall
compliance)
Causes for ? Cs