mechanical ventilation powerpoint presentation

Positive Pressure Ventilation
• Uses positive pressure to bring air into the lungs
• Can be used for both invasive and non invasive ventilation
• Also has 3 types:
1. Volume type
2. Pressure Type
3. Pressure and Volume (Advance modes)

Relationship of Barometric Pressure and Alveolar Pressure during
Spontaneous Breathing
Spontaneous
Breathing
PB(cmH2O) PALV(cmH2
O)
∆Pressur
e
Flow
Inspiration 0 -5 -5 into lungs
End-Inspiration 0 0 0 none
Expiration 0 +5 +5 out of lungs
End-expiration 0 0 0 none

Relationship of Inspiratory Pressure and Alveolar Pressure during
Positive Pressure Ventilation
Spontaneous
Breathing
Pi(cmH2O) PALV(cmH2
O)
∆Pressur
e
Flow
Inspiration 20 0 20 into lungs
End-Inspiration 20 20 0 none
Expiration 0 20 20 out of lungs
End-expiration 0 0 0 none

Airway pressures such as:
PAP, Pplat, mPaw = Vt, PFR, Raw
Compliance
have direct impact on:
a. intrathoracic pressure
b. blood flow
c. blood pressure
indirectly on major organs

Compliance
Lungs with normal compliance
- 50% of airway pressure is transmitted to the thoracic cavity.
Lungs with low compliance
- pressure transmitted to the thoracic cavity is much less due
to dampening effect of nonelastic tissues.
- for this reason the decrease in cardiac due to excessive PIP or
PEEP is less severe

Cardiovascular Considerations
1. Mean Airway Pressure and Cardiac Output
PIP, I Time, RR, PEEP – shld be kept at minimum to keep mPaw
at lowest possible level
2. Decrease in Cardiac Output and delivery
O2 content x ↓ CO = ↓ O2 delivery
3. Blood Pressure Changes

Diagram of PPV leading to decrease in O2
Delivery
PPV
↑ Intrathoracic Pressure
Compression of Pulmonary Vessels and great vessels
Reduction in stroke volume
Reduction of Cardiac Output and Pulmonary bloodflow
(High) V//Q mismatch
Hypoxemia
Decrease Oxygen Content
Decrease in O2 delivery to the tissues

Cont…
3. Blood Pressure Changes
Pulsus Paradoxus: Spont breathing
↓ in systolic in asthma patient, cardiac tamponade > 10 mmHg
Reverse Pulsus Paradoxus: Spont to PPV
↑ in systolic > 15 mmHg – hypovolemia
note: PPV + PEEP may further lower cardiac output/ compromise cardiovascular
functions in patients with cardiopulmonary disease.

Pulmonary Blood flow and Thoracic Pump
mechanism
PPV affects pulmonary blood flow entering and leaving the heart
Hypotensive patients: ↑ in lung volume results in ↓pulmonary venous
return to the Left ventricle
Hypertensive Patients: ↑ in lung volume results in ↑pulmonary venous
return to the Left ventricle due to:
1. compression of pulmonary blood vessel is minimal
2. due to thoracic pump mechanism
- blood flow is enhanced during expiratory phase of PPV.

EFFECTS OF PPV ON HEMODYNAMIC
MEASUREMENTS
↑ Intrathoracic Pressure
↓ Pulmonary blood Volume and ↑ systemic blood volume
↓ venous return (CVP)
↓ Right Ventricle stroke volume
↓ Pulmonary Artery Pressure (PAP)
↓ filling pressures (ventricles)
↓ Left ventricle stroke volume

Renal Considerations
 Eliminating waste, clearance of certain drugs, regulating fluid,
electrolytes and acid-base balance
 Affected due to hypoperfusion
 Can lead to:
1. renal failure – urine output of < 400ml in 24 hours,
↑ BUN and Creatinine level

Hepatic Considerations
 Perfusion accounts for 15% of total CO
 Can lead to liver dysfunction
- prothrombin (coagulation) time > 4 sec
- bilirubin level level > 50mg/L
- albumin < 20g/L
 Affects rate of drug clearance – increased concentration and
prolonged drug effect

Abdominal Considerations
 ↑ Intraabdominal Pressure (IAP), due to:
1. bowel edema or obstruction
2. ascites
3. procedures such as:
a. pneumatic anti shock garments b. surgical
repair of abdominal hernia

 ↑ IAP (> 20 mmHg) + PPV + PEEP (>15 mmHg) can cause:
1. potentiation of pressures exerted on heart and blood vessels,
leading to:
a. cardiovascular dysfunction - ↓ CO
b. renal dysfunction
↓ renal perfusion
↓Glomerular filtration rate

c. Pulmonary dysfunction
↓ FRC
↑ atelectasis
impaired gas exchange
↑ V/Q/mismatch

Gastrointestinal Considerations
 Complications:
Erosive esophagitis
stress related mucosal damage (SRMD) diarrhea
decreased bowel sound
high gastric residual
constipation

Gastrointestinal Considerations
 Complications are due to:
1. ↓ perfusion to GI tract
2. Medications used during MV

Nutritional Considerations
 malnutrition
- are due to:
frequent interuptions in enteral feeding > protein
catabolism >
loss of muscle performance >
difficulty of weaning due to muscle weakness

Nutritional Considerations
 Diaphragmatic dysfunction
- is due to:
atrophy >
cause by muscle proteolysis - leads to
↓ in muscle fiber content

Nutrition and Work of Breathing
 Total Parenteral Nutrition (TPN) or Hyperalimentation
- a complete nutritional program provided to patients by any
method other than intestinal route

- hypertonic solution consisting of:
Amino acids
glucose
vitamins
electrolytes
fat emulsion

- shld keep dextrose (carbo) to a minimum > ↑ O2
consumption and CO2 production

 Fat based TPN >
provide maximum caloric intake with minimum CO2
production >
less WOB >
patients with significant or persistent CO2 production

Neurologic Consideration
Neurologic Changes in Hyperventilation
Condition Pathophysiologic Changes
Resp Alkalosis (<24 Hours) Decreased cerebral blood flow
Reduced intracranial pressure
Resp Alkalosis ( > 24 Hours) Left shift of oxyhemoglobin curve
Increased O2 affinity for hemoglobin
Reduced O2 releases to tissues
Cerebral tissue hypoxia
Neurologic dysfunction
hypophosphatemia

Neurologic Consideration
Neurologic Changes in Hypercapnia and hypoxemia
Condition Pathophysiologic Changes
Hypercapnia ( with normal pH) Increased cerebral blood flow
increased intracranial pressure
Hypercapnia ( with low pH) Impaired cerebral metabolism
Hypoxemia Decreased mental and motor functions

Effects of Positive Pressure Ventilation
PPV
Increase in
intrathoracic
pressure
Compression of
pulmonary
vessels
Reduction in
stroke volume
Reduction of cardiac
output and
pulmonary blood flow
High V/Q
mismatch
Hypoxemia
Decrease in O2
content
Decrease
in O2
Delivery

Characteristics of mechanical ventilators
1.Limits:
a. Pressure limited
b. volume limited
2. Breath delivered:
a. mandatory breath
b. assisted breath
c. spontaneous breath

3. Triggering: to inspiration
a. Pressure triggered
b. Flow triggered
c. Time triggered

4. Cycling: to expiration
a. volume cycled
b. pressure cycled
c. flow cycled
d. time cycled

5. Variability:
a. Pressure variable
b. Volume variable

Volume Ventilation
• CHARACTERISTICS:
 Volume limited or volume pre – set
 Volume cycled or time cycled
 Pressure variable

Volume Ventilation
Set Parameters:
MODE: Full or Partial ventilator
support
Vt: 8 – 10 kg/IBW
RR: 1o - 16 bpm FiO2: 21% - 100 %
PFR: 40 - 60 lpm PEEP: 5 cmH2O
FLOW PATTERN: Square wave SENSITIVITY: - 2 cmH2O or 1 L

Different Modes On Volume Ventilation
FULL VENTILATORY
SUPPORT
1. Controlled Mandatory
Ventilation (CMV)
2. Assist/Control
PARTIAL VENTILATORY
SUPPORT
1. Intermittent Mandatory
Ventilation (IMV)
2. Synchronized Intermitent
Mandatory Ventilation (SIMV)

Controlled Mandatory Ventilation
CHARACTERISTIC DESCRIPTION
Type of Breath Mechanical breath
Triggering Mechanism time triggered/machine triggered
Cycling Mechanism time cycled
Limit Volume limited
Variable Pressure Variable
Note: correction of PaCO2 level can be done through changing Tidal Volume
and RR settings

Complications with Control Mode
• Potential for apnea and hypoxia due to:
1. disconnection from the ventilator
2. ventilator failure

Controlled Mandatory Ventilation

Assist/Control Ventilation
Triggering Mechanism Patient or time triggered
Cycling Mechanism volume cycled/ time cycled
Note: Correction of PaCO2 level can be done through changing Tidal Volume
and RR settings
Note: The generally accepted minimum RR for AC mode is 2 to 4 breaths per
minute less than the patients assist rate or a minimum of 8-10 BPM

Complications Associated with AC Mode
• alveolar hyperventilation and respiratory alkalosis.

Intermittent Mandatory Ventilation
Type of Breath Mechanical and spontaneous breaths
Cycling Mechanism volume cycled for mechanical breaths
Note: Used as a weaning method. This mode uses a “synchronization window”

Synchronized Intermittent Mandatory Ventilation
Type of Breath Mechanical and spontaneous breaths
Cycling Mechanism volume cycled for mechanical breaths

OTHER SETTINGS
OF VOLUME
VENTILATION

Respiratory rate
• set at 12 – 16 bpm
• usual parameter that is manipulated to correct PaCO2 level
• affects the I:E ratio
• ↑ RR leads to ↓ I:E ratio or shorter E time
• ↓ RR leads to ↑ I:E ratio or longer E time

Tidal volume
• set parameter under volume ventilation, 8 – 10 ml/kg of PBW
• also manipulated to correct PaCO2 level
• affects I:E ratio
• ↑ Vt leads to ↑ I time or ↓ E time or ↓ I:E ratio
• ↓ Vt leads to decrease ↓ I time or ↑ E time or ↑ I:E ratio
• computed by obtaining Predicted Body Weight
▫ Male PBW in kg = 106 + [6 x (Height in inches – 60)] ÷ 2.2
▫ Female PBW in kg = 105 + [5 x (Height in inches – 60)] ÷ 2.2

Peak flow rate
• initially set from 40 – 60 lpm
• determines how fast the set Vt is delivered
• affects I:E ratio
▫ ↑ PFR leads to ↓ I time or ↑ E time or ↑ I:E ratio
▫ ↓ PFR leads to ↑ I time or ↓ E time ↓ I:E ratio
• can cause dyssynchrony

I:E Ratio
• Changing I:E ratio using FLOW RATE
▫ Flow=Minute Volume x Sum of I:E ratio
• Changing I:E ratio using I time
• I time=Time for each breath x [I ratio/sum of I:E ratio]
• Using I time % to set I:E ratio
▫ I time %=I ratio/sum of I:E ratio

Peak flow pattern
• determines the manner of delivery of set Vt
• use to assess or monitor :
1. dyssynchrony
2. auto PEEP
3. changes in expiratory flow

Peak flow pattern
• has 4 available waveforms:
1. square wave – maximum flow is throughout inspiration
2. decelerating – maximum flow at start and diminishes as
inspiration ends
3. sine wave – maximum flow at mid inspiration, resembles
spontaneous breath
4. accelerating – maximum flow at end inspiration
5. decay – has some similarity with decelerating

Most commonly used flow patterns
Volume Pressure

Fio2
• set from .21 to 1.0 or 21% to 100%
• the usual parameter manipulated to correct oxygenation
• causes oxygen toxicity

Sensitivity
• senses patient breathing effort
• has two types:
1. Pressure sensitivity
▫ set from – 0.5 to – 5.0 cm H20
2. Flow sensitivity
• more sensitive to patient breathing effort compared to pressure
• set from 1 to 5 liters

Positive end expiratory pressure
• used in lung recruitment
• prevents collapse of alveoli
• prevents alveolar injury due to shearing effect of opening and
closing of alveoli
• used to correct refractory hypoxemia caused by intrapulmonary
shunting
• a PEEP of 5 cmH2O is used as a physiologic PEEP

Indications of peep
1. Intrapulmonary shunt and refractory hypoxemia
 PaO2 < 60mmHg with FiO2 of 50% and above
 PaO2/FiO2 (P/F) ratio < 200mmHg
2. Decrease FRC and lung compliance
3. auto PEEP not responsive to adjustments in ventilator settings
4. Pulmonary edema

Complications/hazards of peep
1. Barotrauma
2. Decrease venous return
3. Decrease cardiac output
4. Decrease urinary output

Complications/Hazards of PEEP
Decrease O2
delivery
Increase PEEP
Increase mPaw and PIP
Increase pleural pressure
Decrease venous return
Decrease cardiac output
Decrease oxygen delivery

Pressure Ventilation
• CHARACTERISTICS:
 Pressure pre – set
 Pressure limited
 Time cycled, Flow cycled or Pressure cycled
 Volume variable
 use for invasive and non invasive ventilation

Pressure Ventilation
Set Parameters:
MODE: Full or Partial ventilator
support
PIP: 20cmH2O
RR: 1o - 16 bpm FiO2: 21% - 100 %
I time: 0.5-1 sec PEEP: 5 cmH2O
I:E ratio: 1:3 SENSITIVITY: - 2 cmH2O or 1 L

Modes On Pressure Ventilation
FULL VENTILATORY
SUPPORT
1. PCV
2. Assist/Control
3. PC - IRV
PARTIAL VENTILATORY
SUPPORT
1. PSV
2. CPAP
3. BiPAP

Pressure Controlled Ventilation
Triggering Mechanism time triggered/machine triggered
Limit Pressure limited
Variable Volume Variable
Note: usually indicated for patients with RDS

Assist/Control ventilation
Triggering Mechanism time triggered/patient triggered
Cycling Mechanism time cycled/pressure cycled

Pressure Control-Inverse Ratio Ventilation
Triggering Mechanism time triggered
Note: used to treat ARDS patients with refractory hypoxemia not responsive
to conventional mechanical ventilation and PEEP

Pressure Support Ventilation
Triggering Mechanism patient triggered
Cycling Mechanism Flow cycled
Note: used as weaning method

Continuous Positive Airway Pressure Ventilation
CHARACTERISTICS:
▫Pressure limited
▫use as a weaning method especially in infants
▫used during non invasive ventilation (NIPPV)
▫is a PEEP applied to the airway of a patient who is breathing
spontaneously

Bilevel Positive Airway Pressure
Triggering Mechanism patient triggered/time triggered
Cycling Mechanism Flow cycled/time cycled

Bilevel Positive Airway Pressure
▫ Bi-level positive airway pressure allows the clinician to
apply independent positive airway pressures to both
inspiration and expiration.
▫ Inspiratory (IPAP) and Expiratory (EPAP) are used to
define when the positive airway pressure is present.

OTHER SETTINGS
OF PRESSURE
VENTILATION

Respiratory rate
• set at 10 – 16 bpm
• usual parameter that is manipulated to correct PaCO2 level
• affects the I:E ratio
• affects mean airway pressure
▫ ↑ RR leads to ↓ I:E ratio or shorter E time
▫ ↓ RR leads to ↑ I:E ratio or longer E time

Peak Inspiratory pressure (PIP)
• manipulated to correct PaCO2 level
• affects mean airway pressure (mPaw)

Fio2
• set from .21 to 1.0 or 21% to 100%
• the usual parameter manipulated to correct oxygenation
• can cause oxygen toxicity

Sensitivity
• senses patient breathing effort
• has two types:
▫ Pressure sensitivity
 set from – 0.5 to – 5.0 cm H20
▫ Flow sensitivity
 more sensitive to patient breathing effort compared to pressure
 set from 1 to 5 liters

I time
• set from 1 sec to 1.5 seconds

I:E Ratio
• ratio of inspiration to expiration
• normally set at 1:2 to 1: 4
• use inversely in conjunction with pressure ventilation (PCV-IRV)
during:
severe hypoxemia not responsive to conventional
ventilation

Positive end expiratory pressure
• used in lung recruitment
• prevents collapse of alveoli
• prevents shearing effect
• used to correct refractory hypoxemia caused by intrapulmonary
shunting
• a PEEP of 5 cmH2O is used as a physiologic PEEP

Points to remember in pressure ventilation
•
Increase in: pCO2 pO2 MAP
FiO2 no change increase no change
Rate decrease usually no change increase
PIP decrease increase increase
Inspiratory time usually no change increase increase
PEEP usually no change increase increase

Terminologies
• Peak Inspiratory Pressure (PIP) or Peak Airway Pressure
 pressure used to deliver the tidal volume to the lung
• Plateau Pressure (Pplat)
 pressure that maintains lung inflation in the absence of airflow
• Mean airway Pressure (mPaw)
 average pressure within the airway during one complete respiratory cycle

Mean airway Pressure (mPaw)
• Normal value: < 30 cmH20 in adult
• Equation:
mPaw = (f x I time) x (PiP – PEEP) + PEEP
60
Where:
mPaw – mean airway pressure (cmH20)
f– respiratory in 1 minute
I time – inspiratory time in 1 sec
PIP – Peak inspiratory Pressure (cmH20)
PEEP – Positive end expiratory Pressure

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