Ventilatory Failure
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Transcript Ventilatory Failure
Respiratory Failure/ ARDS
Ian B. Hoffman, MD, FCCP
Pulmonary & Critical Care Medicine
September 4, 2013
A 32-year-old man is evaluated for persistent hypoxemia on mechanical ventilation in
the intensive care unit. His medical history is significant for paraplegia and a chronic
indwelling urinary catheter for neurogenic bladder. He presented to the emergency
department 2 days ago with sepsis. At that time, he received piperacillin/tazobactam,
normal saline, and vasopressors. He was endotracheally intubated for decreased level
of consciousness. His initial chest radiograph was normal.
On physical examination on the second day of hospitalization, temperature is 37.1 °C
(98.8 °F), blood pressure is 90/50 mm Hg, pulse rate is 96/min, and respiration rate is
26/min. His need for supplemental oxygen has steadily increased; his oxygen
saturation on an FIO2 of 0.8 is 89%. Pulmonary examination reveals bilateral inspiratory
crackles. Cardiac examination reveals distant, regular heart sounds.
Urine and blood cultures are positive for Escherichia coli. A follow-up chest radiograph
shows diffuse bilateral infiltrates without cardiomegaly. Central venous pressure is 8
mm Hg.
Laboratory studies:
Hemoglobin
13.2 g/dL (132 g/L)
Leukocyte count
10,000/µL (10 × 109/L)
Arterial blood gas studies (on an
FIO2 of 0.8):
pH
7.48
PCO2
30 mm Hg (4.0 kPa)
PO2
60 mm Hg (8.0 kPa)
Which of the following is the most likely cause of this
patient’s hypoxemia?
A. Acute respiratory distress syndrome
B. E. coli pneumonia
C. Heart failure
D. Eosinophilic pneumonia
Respiratory Failure
Any disruption of function of respiratory
system – CNS, nerves, muscles, pleura,
lungs
Any process resulting in low pO2 or high
pCO2 – arbitrarily 50/50
Acute respiratory failure can be exacerbation
of chronic disease or acute process in
previously healthy lungs
History
1940’s – polio, barbiturate OD
1960’s – blood gas analysis readily available,
aware of hypoxemia
1970’s – decreased hypoxic mortality,
increased multiorgan failure (living longer)
1973 – relationship between resp muscle
fatigue and resp failure
Types of Respiratory Failure
Type 1 (nonventilatory) – hypoxemia with or
without hypercapnia – disease involves lung
itself (i.e, ARDS)
Type 2 – failure of alveolar ventilation –
decrease in minute ventilation or increase in
dead space (i.e. COPD, drug OD)
Goals of Treatment
Correct hypoxemia or hypercapnia without
causing additional complications
Noninvasive ventilation vs. intubation and
mechanical ventilation
Goal of mechanical ventilation is NOT
necessarily to normalize ABGs
Ventilation–perfusion (V/Q) relationships and
associated blood gas abnormalities
Shunt
The influence of shunt fraction on the relationship
between the inspired oxygen (FiO2) and the
arterial PO2 (PaO2).
Ventilatory Failure
Failure of respiratory pump to adequately
eliminate CO2
pCO2 :
VCO2
VA
VCO2 determined by rate of total body
metabolism
ALVEOLAR HYPOVENTILATION IN THE ICU
Respiratory Muscles
Acute or acute-on-chronic overloading
COPD, hyperinflation, fatigue
Electrolyte imbalances
Sepsis
Shock
Malnutrition
Drugs
Atrophy related to prolonged mechanical ventilation
Hypothyroidism
Myopathies
What factors leading to respiratory
muscle weakness can be reversed?
Reduce respiratory load
treat asthma, COPD, upper airway problems
treat pneumonia, pulm edema, reduce dynamic
hyperinflation, drain large pleural effusions, evacuate PTX
Replace K, Mg, PO4, Ca
Treat sepsis
Nutritional support w/o overfeeding
Rest muscles 24-48 hrs, then exercise
Stop aminoglycosides
Rule out hypothyroidism, oversedation, critical illness
myopathy/neuropathy
To intubate or not
Decision to mechanically ventilate is clinical
Some criteria:
Decreased level of consciousness (ER always
tells us that GCS = 3 and pt tubed to protect
airway!)
Vital capacity <15 ml/kg
Severe hypoxemia
Hypercarbia (acute or acute-on-chronic)
Vd/Vt >0.60
NIF < -25 cm H20
ARDS – Acute Respiratory
Distress Syndrome
ARDS - Definition
Severe end of the spectrum of acute lung injury
Diffuse alveolar damage
Acute and persistent lung inflammation with
increased vascular permeability – inflammatory
cytokines
Diffuse infiltrates
Hypoxemia
No clinical evidence of elevated left atrial pressure
(PCWP <18 if measured)
ARDS – History/Definitions
1967 – Ashbaugh described 12 pts with acute
respiratory distress, refractory cyanosis,
decreased lung compliance, diffuse infiltrates;
7 of the 12 died
1988 – 4 point lung injury score (level of
PEEP, pO2/FiO2, lung compliance, degree of
infiltrates)
1994 – acute onset, bilateral infiltrates, no
direct or clinical evidence of LV failure,
pO2/FiO2)
1994 American European Consensus
Acute Lung Injury
ARDS
Acute onset
Acute onset
Bilateral infiltrates c/w
Bilateral infiltrates c/w
pulmonary edema
No clinical evidence of
left-sided CHF (PCWP
<18)
pulmonary edema
No clinical evidence of
left-sided CHF (PCWP
<18)
paO2/FiO2 ratio <300
paO2/FiO2 ratio <200
100/0.40 = 250
100/0.60 = 167
New Definition of ARDS - 2012
• Acute onset (within 7 days of some defined
event)
• Bilateral infiltrates (on CXR or CT)
• No need to exclude heart failure (respiratory
failure “not fully explained by CHF”)
• Hypoxemia – mild, moderate, severe
Severity of ARDS (2012)
ARDS Severity
PaO2/FiO2
(on PEEP 5)
Mortality
Mild
200 - 300
27%
Moderate
100 - 200
32%
Severe
<100
45%
ARDS - Incidence
Annual incidence 75 per 100,000 (1977)
9% of American critical care beds occupied
by pts with ARDS
ARDS - Diagnosis
Clinically and radiographically resembles
cardiogenic pulmonary edema
PCWP can be misleading – should be normal
or low, but can be high
20% of pts with ARDS may have LV
dysfunction
ARDS - Causes
Direct injury to the lung
Indirect injury to the lung in setting of
systemic process
Multiple predisposing disorders substantially
increase risk
Increased risk with alcohol abuse, chronic
lung disease, acidemia
ARDS - Causes
Direct Lung Injury
Pneumonia
Gastric aspiration
Lung contusion
Fat emboli
Near drowning
Inhalation injury
Reperfusion injury
Indirect Lung Injury
Sepsis
Multiple trauma
Cardiopulm bypass
Drug overdose
Acute pancreatitis
Blood transfusion
ARDS - Physiologic Derangements
Inflammatory injury producing diffuse alveolar damage
Alveolar epithelium (eg, aspiration)
Vascular endothelium (eg, sepsis)
Proinflammatory cytokines (TNF, IL-1, IL-8)
Neutrophils recruited – release toxic mediators
Normal barriers to alveolar edema are lost, protein and
fluid flow into air spaces, surfactant lost, alveoli
collapse; inhomogeneous process
Impaired gas exchange
Decreased compliance
Pulmonary hypertension
ARDS – Features
Severe initial hypoxemia
Increased work of breathing (decreased compliance)
– generally a prolonged need for mechanical
ventilation
Initial exudative stage
Proliferative stage
resolution of edema, proliferation of type II
pneumocytes, squamous metaplasia, collagen
deposition
Fibrotic stage
ARDS – Course
Early
Inciting event
pulmonary dysfunction (worsening
tachypnea, dyspnea, refractory hypoxemia)
Nonspecific labs
CXR – diffuse alveolar infiltrates
Subsequent
Eventual improvement in oxygenation
Continued ventilator dependence
Complications
Large dead space, high minute ventilation requirement
Organization and fibrosis in proliferative phase
ARDS - Complications
Ventilator induced lung injury
Sedation and neuromuscular blockade
Nosocomial infection
Pulmonary emboli
Multiple organ dysfunction
ARDS - Prognosis
Improved survival in recent years – mortality was 50-
60% for many years, now 35-40%
Improvements in supportive care, improved
mechanical ventilatory management
Early deaths (3 days) usually from underlying cause
of ARDS
Later deaths from nosocomial infections, sepsis,
MOSF
Respiratory failure only responsible for ~16% of
fatalities
Long-term survivors usually show mild abnormalities
in pulmonary function (DLCO)
Question 2
•
A 63-year-old man with acute respiratory distress syndrome (ARDS) is
evaluated in the intensive care unit. He has just been intubated and
placed on mechanical ventilation for ARDS secondary to aspiration
pneumonia. Before intubation, his oxygen saturation was 78%
breathing 100% oxygen with a nonrebreather mask.
•
On physical examination, temperature is 37.0 °C (98.6 °F), blood
pressure is 150/90 mm Hg, and pulse rate is 108/min. His height is
150 cm (59 in) and his weight is 70.0 kg (154.3 lb). Ideal body weight
is calculated to be 52.0 kg (114.6 lb). Central venous pressure is 8 cm
H2O. Cardiac examination reveals normal heart sounds and no
murmurs. Crackles are auscultated in the lower left lung field. The
patient is sedated. Neurologic examination is nonfocal.
•
Mechanical ventilation is on the assist/control mode at a rate of
18/min. Positive end-expiratory pressure is 8 cm H2O, and FIO2 is 1.0.
Which of the following is the most appropriate tidal
volume?
A. 300 ml
B. 450 ml
C. 700 ml
D. 840 ml
Ventilatory Goals in ARDS
Provide adequate oxygenation without
causing damage related to:
Oxygen toxicity
Hemodynamic compromise
Barotrauma
Alveolar overdistension
Alveolar shear
Mechanical Ventilation in ARDS
Reliable oxygen supplementation
Decrease work of breathing
Increased due to high ventilatory
requirements, increased dead space, and
decreased compliance
Recruitment of atelectatic lung units
Decreased venous return can help decrease
fluid movement into alveolar spaces
Ventilator Induced Lung Injury
Known for decades that high levels of positive
pressure ventilation can rupture alveolar units
In 1950’s became known that high FiO2 can
produce lung injury
More recently, effects of alveolar
overdistension, shearing, cyclical opening
and closing have become apparent
Ventilator Induced Lung Injury
Macrobarotrauma
Pneumothorax, interstitial emphysema,
pneumomediastinum, SQ emphysema,
pneumoperitoneum, air embolism
? resulting from high airway pressures, or just
a marker of severe lung injury
Higher PEEP predicts barotrauma
Ventilator Induced Lung lnjury
Microbarotrauma
Alveolar overinflation exacerbating and
perpetuating lung injury – edema, surfactant
abnormalities, inflammation, hemorrhage
Less affected lung accommodates most of
tidal volume – regional overinflation
Cyclical atelectasis (shear) – adds to injury
Low tidal volume strategy (initial tidal volume
6 ml/kg IBW, plateau pressure <30) – lower
mortality
Ventilatory Strategies
Therapeutic target of mechanical ventilation in patients with
ARDS has shifted from maintenance of "normal gas exchange”
to the protection of the lung from ventilator-induced lung injury
Low tidal volume, plateau pressure <30
peak pressure = large airways
plateau pressure = small airways/alveoli
PEEP – enough, not too much
Pressure controlled vs. volume cycled
Prolonging inspiratory time (increase mean airway pressure and
improve oxygenation)
APRV
Recent data suggests high frequency oscillation is bad
Permissive hypercapnia
Secondary effect of low tidal volumes
Maintain adequate oxygenation with less risk of barotrauma
Sedation/paralysis often necessary
The only method of mechanical ventilation that
has been shown in randomized controlled trials
to improve survival in patients with ARDS is low
tidal volume ventilation.
ARDS Network Trial
NEJM 2000; 342:1301-1308.
Initial tidal volume of 6 ml/kg IBW and plateau
pressure <30
vs.
Initial tidal volume of 12 ml/kg IBW and
plateau pressure <50
Reduction in mortality of 22% (31% vs 40%)
Ventilator management in patients with acute respiratory distress syndrome or acute lung injury
N Engl J Med 2000; 342:1301
Question 3
A 25-year-old woman is admitted to the intensive care unit (ICU) for a 6hour history of respiratory distress. She has acute lymphoblastic leukemia
and received cytotoxic chemotherapy 2 weeks before ICU admission. She
has had fever and leukopenia for 7 days.
On physical examination, she is in marked respiratory distress.
Temperature is 39.0 °C (102.2 °F), blood pressure is 110/70 mm Hg, pulse
rate is 130/min, and respiration rate is 42/min. Weight is 50.0 kg (110.2 lb).
Ideal body weight is calculated as 50.0 kg (110.2 lb).
Acute respiratory distress syndrome is diagnosed. She is intubated and
started on mechanical ventilation in the assist/control mode at a rate of
12/min, tidal volume of 300 mL, positive end-expiratory pressure (PEEP) of
5 cm H2O, and FIO2 of 1.0. An arterial blood gas study on these settings
shows a pH of 7.47, PCO2 of 30 mm Hg (4.0 kPa), and PO2 of 45 mm Hg
(6.0 kPa). Peak airway pressure is 26 cm H2O, and the plateau pressure
is 24 cm H2O.
Which of the following is the most appropriate
treatment to improve this patient’s oxygenation?
A. Increase PEEP to 10 cm H2O
B. Increase respiratory rate to 18/min
C. Increase tidal volume to 500 ml
D. Start inhaled nitric oxide
PEEP in ARDS
Increases FRC (volume of air remaining in lungs
following a normal tidal exhalation) – recruits
“recruitable” alveoli, increases surface area for gas
exchange
Decreases shunt, improves V/Q matching
No consensus on optimal level of PEEP
ALVEOLI trial
NEJM 2004; 351:327-336.
High PEEP vs. low PEEP
Low tidal volume for all (6 ml/kg predicted weight)
Higher PEEP patients had better oxygenation, but no
difference in mortality, duration of mechanical
ventilation, duration of non-pulmonary organ failure
No benefit from recruitment maneuvers (CPAP 35-40
cm H20 for 30 seconds) – but other studies suggest
that recruitment maneuvers do help
Prone Positioning
Thought to improve oxygenation and
respiratory mechanics by:
alveolar recruitment
redistribution of ventilation toward dorsal areas
resulting in improved V/Q matching
elimination of compression of the lungs by the
heart
reduction of parenchymal lung stress and
strain
Prone Positioning
Several studies demonstrate improved
oxygenation, but no overall reduction in
mortality
Greatest benefit of prone positioning occurs
in the sickest patients if used early after the
diagnosis of ARDS
Other modalities - None of these have proven
superior to more standard techniques
APRV
High-frequency ventilation
Partial liquid ventilation
Inverse ratio ventilation
ECMO
Nitric Oxide, prostacyclin
Ketoconazole, ibuprofen
Glutathione (anti-oxidant)
Surfactant
Steroids
Intravenous beta-agonists (increases clearance of
alveolar edema) – needs more study
APRV
Pharmacotherapy - Nitric Oxide
Selectively dilates vessels that perfuse better
ventilated lung zones, resulting in improved
V/Q matching, improved oxygenation,
reduction of pulmonary hypertension
Less benefit in septic patients
No clear improvement in mortality
Pharmacotherapy - Surfactant
First tried in 1980’s
No benefit in adult population
One study did demonstrate improvement in
oxygenation and mortality in children
Pharmacotherapy - Steroids
No consensus on effectiveness – no clear
benefit, some risks
ARDSnet - NEJM 2006; 354:1671-1684.
some benefit in subgroups, but not overall;
increased mortality if started after 14 days;
neuromyopathy
Meduri - Chest 2007; 131:954-963.
improvement in pulmonary and extrapulmonary
organ dysfunction, reduction in duration of
mechanical ventilation and ICU length of stay –
(small sample size, imbalance in treatment arms)
Fluid management in ARDS
Increased extravascular lung water
associated with poor outcome
Reduction in PCWP associated with
increased survival
Fluid and Catheter Treatment Trial (FACTT)
NEJM 2006
Liberal vs conservative fluid management
CVP just as good as PCWP
Conservative management group did better (more
ventilator free days, fewer ICU days, trend toward
lower mortality)
No difference in incidence of hypotension or need for
renal replacement therapy
Excluded patients with shock, was initiated later in ICU course
(mean time 43 hrs) – early aggressive fluid resuscitation appropriate
Liberal group gained ~1 liter/day, conservative had net zero balance
over 1st 7 days
Simplified Algorithm for Conservative Fluid Management
(Target CVP <4 or PCWP <8)
MAP > 60, no vasopressors for > 12 hrs
CVP
PCWP
Average urine output <0.5 cc/kg/hr
Average urine output >0.5 cc/kg/hr
>8
>12
Lasix; reassess in 1 hr
Lasix; reassess in 4 hrs
4-8
8-12
Rapid fluid bolus; reassess 1 hr
Lasix; reassess in 4 hrs
<4
<8
Rapid fluid bolus; reassess 1 hr
No intervention; reassess in 4 hrs
Supportive Care
Treat predisposing factors
Prophylaxis for GI bleeding
DVT prophylaxis
Prevent and treat nosocomial pneumonia –
most important causes are microaspiration, biofilm
formation (VAP bundle?)
Nutritional support
Blood sugar control
?Transfusion (Hgb >7 adequate)
Decrease oxygen utilization
- antipyretics, sedatives, paralysis
VAP Bundle – ?truly evidence based
Elevate head of bed (helpful)
Daily sedation vacation and assessment of readiness
to extubate (shorter duration on vent, should be less
pneumonia)
Daily chlorhexidine mouth rinse (questionable
benefit)
PPI or H2 antagonists (can increase risk)
DVT prophylaxis (nothing to do with pneumonia)
Potentially helpful: subglottic suctioning, lateral headdown positioning, silver-coated ET tubes, “mucus
shaver”
“There is nothing so useless as doing
efficiently that which should not be
done at all.” (Peter Drucker)
Question 4
A 50-year-old man is evaluated in the intensive care unit for
acute respiratory distress syndrome secondary to severe
community-acquired pneumonia. He is intubated and placed on
mechanical ventilation. He was previously healthy and took no
medications before his hospitalization.
On physical examination, temperature is 38.3 °C (100.9 °F), blood
pressure is 120/60 mm Hg, and pulse rate is 110/min. The patient
weighs 60.0 kg (132.3 lb); ideal body weight is 60.0 kg (132.3 lb).
He is sedated and is not using accessory muscles to breathe.
Central venous pressure is 8 cm H2O. Other than tachycardia,
cardiac examination is normal. There are bilateral inspiratory
crackles.
Initial ventilator settings are volume control with a rate of 18/min,
a tidal volume of 360 mL, positive end-expiratory pressure (PEEP)
of 10 cm H2O, an FIO2 of 0.8, a peak pressure of 34 cm H2O, and a
plateau pressure of 32 cm H2O. Oxygen saturation by pulse
oximetry is 96%.
Which of the following is the most appropriate
next step in management?
A. Decrease respiratory rate
B. Decrease tidal volume
C. Increase FiO2
D. Increase PEEP
Simplified Algorithm for Conservative Fluid Management
Shock
CVP
No Shock
Oliguric
Non-Oliguric
>9
Vasopressor
Diuretic
Diuretic
4-8
Fluid bolus
Fluid bolus
Diuretic
<4
Fluid bolus
Fluid bolus
KVO fluid
Flow diagram for the evaluation of
hypoxemia
PVO2 = mixed venous pO2
VO2 = oxygen consumption
DO2 = oxygen delivery
Flow diagram for the evaluation of
hypercapnia
VCO2 = CO2 production