2222 PART 8 Critical Care Medicine
daily spontaneous breathing trials can identify patients who are ready
for extubation. Accordingly, all intubated, mechanically ventilated
patients should undergo daily screening of respiratory function. If oxygenation is stable (i.e., Pao2
/FIo2
[partial pressure of oxygen/fraction
of inspired oxygen] >200 and PEEP ≤5 cmH2
O), cough and airway
reflexes are intact, and no vasopressor agents or sedatives are being
administered, the patient has passed the screening test and should
undergo a spontaneous breathing trial (SBT). If sedatives are being
administered, the patient can undergo a spontaneous awakening trial
(SAT), as well, to determine if he or she is able to maintain adequate
alertness and respiratory status without sedatives. The SAT/SBT trial
consists of a period of breathing through the endotracheal tube without ventilator support (continuous positive airway pressure [CPAP] of
5 cmH2
O with or without low-level pressure support [e.g., 5 cmH2
O]
and an open T-piece breathing system have all been validated) for
30–120 min. The spontaneous breathing trial is declared a failure and
stopped if any of the following occur: (1) respiratory rate >35/min for
>5 min, (2) O2
saturation <90%, (3) heart rate >140/min or a 20% increase
or decrease from baseline, (4) systolic blood pressure <90 mmHg or >180
mmHg, or (5) increased anxiety or diaphoresis. If, at the end of the
spontaneous breathing trial, none of the above events has occurred,
the patient can be considered for an extubation trial. Such protocoldriven approaches to patient care can have an important impact on
the duration of mechanical ventilation and ICU stay. In spite of such
a careful approach to liberation from mechanical ventilation, up to
10% of patients develop respiratory distress after extubation and may
require resumption of mechanical ventilation. Many of these patients
will require reintubation. The use of noninvasive ventilation in patients
in whom extubation fails may be associated in some patients with worse
outcomes than are obtained with immediate reintubation. Some studies
suggest that there are subgroups of patients who might benefit from
administration of high-flow nasal oxygen therapy postextubation, as it is
believed that low levels of PEEP delivered by this device may be helpful.
MULTIORGAN SYSTEM FAILURE
Multiorgan system failure, which is commonly associated with critical
illness, is defined by the simultaneous presence of physiologic dysfunction and/or failure of two or more organs. Typically, this syndrome
occurs in the setting of severe sepsis, shock of any kind, severe inflammatory conditions such as pancreatitis, and trauma. The fact that
multiorgan system failure occurs commonly in the ICU is a testament
to our current ability to stabilize and support single-organ failure. The
ability to support single-organ failure aggressively (e.g., by mechanical
ventilation or by renal replacement therapy) has reduced rates of early
mortality in critical illness. As a result, it is less common for critically
ill patients to die in the initial stages of resuscitation. Instead, many
patients succumb to critical illness later in the ICU stay, after the initial
presenting problem may have been stabilized.
Although there is debate regarding specific definitions of organ failure, several general principles governing the syndrome of multiorgan
system failure apply. First, organ failure, no matter how it is defined,
must persist beyond 24 h. Second, mortality risk increases with the
accrual of failing organs. Third, the prognosis worsens with increased
duration of organ failure. These observations remain true across various critical care settings (e.g., medical vs surgical).
MONITORING IN THE ICU
Because respiratory failure and circulatory failure are common in critically ill patients, monitoring of the respiratory and cardiovascular systems is undertaken frequently. Evaluation of respiratory gas exchange
is routine in critical illness. The “gold standard” remains arterial bloodgas analysis, in which pH, Pao2
, partial pressure of carbon dioxide
(Pco2
), and O2
saturation are measured directly. With arterial bloodgas analysis, the two main functions of the lung—oxygenation of arterial blood and elimination of CO2
—can be assessed directly. In fact, the
arterial blood pH, which has a profound effect on the drive to breathe,
can be assessed only by such sampling. Although sampling of arterial
blood is generally safe and may be undertaken more frequently through
insertion of a temporary indwelling arterial line, it may be painful and
cannot provide continuous information. In light of these limitations,
noninvasive monitoring of respiratory function is often employed.
■ PULSE OXIMETRY
The most commonly utilized noninvasive technique for monitoring
respiratory function, pulse oximetry takes advantage of differences
in the absorptive properties of oxygenated and deoxygenated hemoglobin. At wavelengths of 660 nm, oxyhemoglobin reflects light more
effectively than does deoxyhemoglobin, whereas the reverse is true in
the infrared spectrum (940 nm). A pulse oximeter passes both wavelengths of light through a perfused digit such as a finger, and the relative intensity of light transmission at these two wavelengths is recorded.
From this information, the relative percentage of oxyhemoglobin is
derived. Since arterial pulsations produce phasic changes in the intensity of transmitted light, the pulse oximeter is designed to detect only
light of alternating intensity. This feature allows distinction of arterial
and venous blood O2
saturations.
■ RESPIRATORY SYSTEM MECHANICS
Respiratory system mechanics can be measured in patients during
mechanical ventilation (Chap. 302). When volume-controlled modes
of mechanical ventilation are used, accompanying airway pressures
can easily be measured as long as the patient is breathing passively.
The peak airway pressure is determined by two variables: airway resistance and respiratory system compliance. At the end of inspiration,
inspiratory flow can be stopped transiently. This end-inspiratory pause
(plateau pressure) is a static measurement, affected only by respiratory
system compliance and not by airway resistance. Therefore, during
volume-controlled ventilation, the difference between the peak (airway
resistance + respiratory system compliance) and plateau (respiratory
system compliance only) airway pressures provides a quantitative
assessment of airway resistance. Accordingly, during volume-controlled
ventilation, patients with increases in airway resistance typically have
increased peak airway pressures as well as abnormally high gradients
between peak and plateau airway pressures (typically >10–15 cmH2
O)
at a constant inspiratory flow rate of 1 L/s. The compliance of the
respiratory system is defined by the change in volume of the respiratory
system per unit change in pressure.
The respiratory system can be divided into two components: the
lungs and the chest wall. Normally, respiratory system compliance is
~100 mL/cmH2
O. Pathophysiologic processes such as pleural effusions, pneumothorax, and increased abdominal girth all reduce chest
wall compliance. Lung compliance may be reduced by pneumonia,
pulmonary edema, alveolar hemorrhage, interstitial lung disease, or
auto-PEEP. Accordingly, patients with abnormalities in compliance of
the respiratory system (lungs and/or chest wall) typically have elevated
peak and plateau airway pressures but a normal gradient between these
two pressures. Auto-PEEP occurs when there is insufficient time for
emptying of alveoli before the next inspiratory cycle. Because the alveoli
have not decompressed completely, alveolar pressure remains positive at
the end of exhalation (functional residual capacity). This phenomenon
results most commonly from obstruction of distal airways in disease
processes such as asthma and COPD. Auto-PEEP with resulting alveolar overdistention may result in diminished lung compliance, reflected
by abnormally increased plateau airway pressures. Modern mechanical
ventilators allow breath-to-breath display of pressure and flow, permitting detection of potential problems such as patient–ventilator dyssynchrony, airflow obstruction, and auto-PEEP (Fig. 300-6).
■ CIRCULATORY STATUS
Oxygen delivery (Qo2
) is a function of cardiac output and the content
of O2
in the arterial blood (Cao2
). The Cao2
is determined by the
hemoglobin concentration, the arterial hemoglobin saturation, and
dissolved O2
not bound to hemoglobin. For normal adults:
Qo2
= 50 dL/min × (1.39 × 15 g/dL [hemoglobin concentration]
× 1.0 [hemoglobin % saturation] + 0.0031 × 100 [Pao2
])
= 50 dL/min (cardiac output) × 21.6 mL O2
per dL blood (Cao2
)
= 1058 mL O2
per min
2223Approach to the Patient with Critical Illness CHAPTER 300
It is apparent that nearly all of the O2
delivered to tissues is bound
to hemoglobin and that the dissolved O2
(Pao2
) contributes very little
to O2
content in arterial blood or to O2
delivery. Normally, the content
of O2
in mixed venous blood (C–
vo2
) is 15.76 mL/dL since the mixed
venous blood is 75% saturated. Therefore, the normal tissue extraction
ratio for O2
is Cao2
– C–
vo2
/Cao2
([21.16 – 15.76]/21.16) or ~25%. A
pulmonary artery catheter (see discussion below) allows measurements
of O2
delivery and the O2
extraction ratio.
Information on the venous O2
saturation allows assessment of global
tissue perfusion. A reduced venous O2
saturation may be caused by inadequate cardiac output, reduced hemoglobin concentration, and/or reduced
arterial O2
saturation. An abnormally high Vo2
may also lead to a reduced
venous O2
saturation if O2
delivery is not concomitantly increased.
Abnormally increased Vo2
in peripheral tissues may be caused by problems such as fever, agitation, shivering, and thyrotoxicosis.
The pulmonary artery catheter originally was designed as a tool to
guide therapy for acute myocardial infarction but has been used in the
ICU for evaluation and treatment of a variety of other conditions, such
as ARDS, septic shock, congestive heart failure, and acute renal failure.
This device has never been validated as a tool associated with reduction
in morbidity and mortality rates. Indeed, despite numerous prospective
studies, mortality or morbidity rate benefits associated with use of the
pulmonary artery catheter have never been reported in any setting.
Accordingly, it appears that routine pulmonary artery catheterization
is not indicated as a means of monitoring and characterizing circulatory status in most critically ill patients, especially as monitoring of
the venous O2
saturation has proven helpful in many critical illness
settings. However, there are still select circumstances where pulmonary artery catheterization may prove helpful when used by those with
appropriate experience in its insertion and data interpretation.
PREVENTION OF COMPLICATIONS OF
CRITICAL ILLNESS
■ SEPSIS IN THE CRITICAL CARE UNIT
(See also Chap. 304) Sepsis is defined as life-threatening organ dysfunction (i.e., an increase in SOFA of 2 points or more) caused by a dysregulated response to infection. Poor outcomes can be anticipated in patients
with two or more of the following: respiratory rate ≥22 breaths/min,
altered mentation, and systolic blood pressure ≤100 mmHg. Sepsis is a
leading cause of death in noncoronary ICUs in the United States, with case
rates expected to increase as the population ages and a higher percentage
of people are vulnerable to infection.
■ NOSOCOMIAL INFECTIONS IN THE ICU
Many therapeutic interventions in the ICU are invasive and predispose patients to infectious complications. These interventions include
endotracheal intubation, indwelling vascular catheters, transurethral
bladder catheters, and other catheters placed into sterile body cavities (e.g., tube thoracostomy, percutaneous intraabdominal drainage
catheterization). The longer such devices remain in place, the more
prone to infections patients become from these devices. For example,
ventilator-associated events such as ventilator-associated pneumonia
correlate strongly with the duration of intubation and mechanical ventilation. Therefore, an important aspect of preventive care is the timely
removal of invasive devices as soon as they are no longer needed.
Moreover, multidrug-resistant organisms are commonplace in the ICU.
Infection control is critical in the ICU. Care bundles, which
include measures such as frequent hand washing, are effective but
underutilized strategies. Other components of care bundles, such as
protective isolation of patients colonized or infected by drug-resistant
organisms, are also commonly used. Studies evaluating multifaceted,
evidence-based strategies to decrease catheter-related bloodstream
infections have shown improved outcomes with strict adherence to
measures such as hand washing, full-barrier precautions during catheter insertion, chlorhexidine skin preparation, avoidance of the femoral
site, and timely catheter removal.
■ DEEP-VENOUS THROMBOSIS (DVT) (SEE ALSO CHAP. 279)
All ICU patients are at high risk for this complication because of their
predilection for immobility. Therefore, all should receive some form
of prophylaxis against DVT if feasible. The most commonly employed
forms of prophylaxis are subcutaneous chemoprophylaxis (e.g., lowdose heparin) injections and sequential compression devices for the
lower extremities. Observational studies report an alarming incidence
of DVTs despite the use of these standard prophylactic regimens. Furthermore, heparin prophylaxis may result in heparin-induced thrombocytopenia, another nosocomial complication in critically ill patients.
Low-molecular-weight heparins such as enoxaparin are more effective than unfractionated heparin for DVT prophylaxis in high-risk
patients (e.g., those undergoing orthopedic surgery) and are associated with a lower incidence of heparin-induced thrombocytopenia,
although their use may be limited in patients with renal dysfunction
given their renal clearance.
■ STRESS ULCERS
Prophylaxis against stress ulcers is not necessary for all ICU patients. It
should only be administered to high-risk patients, such as those with
coagulopathy or respiratory failure requiring mechanical ventilation.
While there has been debate about the optimal agent for stress ulcer
prophylaxis, a number of recent studies have supported improved
efficacy of proton pump inhibitors (PPIs) in reducing bleeding risk
compared with other agents (e.g., histamine-2 receptor antagonist [H2
blocker] or sucralfate). There exist concerns for increased risk of pneumonia and Clostridium difficile colitis with PPIs compared with other
agents, although the data are not definitive, and the improved efficacy
of PPIs in patients at high risk for stress ulcers may outweigh these
potential infectious risks.
■ NUTRITION AND GLYCEMIC CONTROL
Nutrition and glycemic control are important issues that may be associated with respiratory failure, impaired wound healing, and dysfunctional immune response in critically ill patients. Early enteral feeding
is reasonable, with some data suggesting that permissive underfeeding
of nonprotein calories is not inferior to full-goal feeding. Certainly,
enteral feeding, if possible, is preferred over parenteral nutrition, which
is associated with numerous complications, including hyperglycemia,
fatty liver, cholestasis, and sepsis. When parenteral feeding is necessary
to supplement enteral nutrition, delaying this intervention until day 8
in the ICU results in better recovery and fewer ICU-related complications. Tight glucose control has been an area of controversy in critical
care. Although one study showed a significant mortality benefit when
Pressure–Time
Flow–Time
cmH2O
L/s
90
0
1.2
–1.2
0 4
4
FIGURE 300-6 Increased airway resistance with auto-PEEP. The top waveform
(airway pressure vs time) shows a large difference between the peak airway
pressure (80 cmH2
O) and the plateau airway pressure (20 cmH2
O). The bottom
waveform (flow vs time) demonstrates airflow throughout expiration (reflected by
the flow tracing on the negative portion of the abscissa) that persists up to the next
inspiratory effort.
2224 PART 8 Critical Care Medicine
glucose levels were aggressively normalized in a large group of surgical
ICU patients, other studies of both medical and surgical ICU patients
suggested that tight glucose control resulted in increased rates of
mortality likely attributable, in part, to hypoglycemic episodes. Thus,
current guidelines suggest targeting glucose levels of ≤180 mg/dL in
critically ill patients, rather than targeting tighter control.
■ ICU-ACQUIRED WEAKNESS
ICU-acquired weakness occurs frequently in patients who survive
critical illness. Both neuropathies and myopathies have been described,
most commonly after ~1 week in the ICU. The mechanisms behind
ICU-acquired weakness syndromes are poorly understood, and they
are known to present with heterogeneous muscle pathophysiology.
Intensive insulin therapy may reduce polyneuropathy in critical illness. Very early physical and occupational therapy in mechanically
ventilated patients reportedly results in significant improvements in
functional independence at hospital discharge as well as in reduced
durations of mechanical ventilation and delirium.
■ ANEMIA
Studies have shown that most ICU patients are anemic as a result of
chronic inflammation. Phlebotomy also contributes to ICU anemia.
A large multicenter study involving patients in many different ICU
settings challenged the conventional notion that a hemoglobin level of
100 g/L (10 g/dL) is needed in critically ill patients, with similar outcomes noted in those whose transfusion trigger was 7 g/dL. Red blood
cell transfusion is associated with impairment of immune function and
increased risk of infections as well as of ARDS and volume overload, all
of which may explain the findings in this study. A conservative transfusion strategy has shown similar outcomes in septic shock, postcardiac
surgery, and post–hip surgery patients.
■ ACUTE KIDNEY FAILURE
(See also Chap. 310) Acute kidney failure occurs in a significant percentage of critically ill patients. The most common underlying etiology
is acute tubular necrosis, usually precipitated by hypoperfusion and/or
nephrotoxic agents. Currently, no pharmacologic agents are available
for prevention of kidney injury in critical illness. Studies have shown
convincingly that low-dose dopamine, fenoldapam, and vasopressin
are not effective in protecting the kidneys from acute injury.
NEUROLOGIC DYSFUNCTION IN
CRITICALLY ILL PATIENTS
■ DELIRIUM
(See also Chaps. 27 and 28) Delirium is defined by (1) an acute
onset of changes or fluctuations in mental status, (2) inattention, (3)
disorganized thinking, and (4) an altered level of consciousness (i.e.,
a state other than alertness). Delirium is reported to occur in a wide
range of mechanically ventilated ICU patients and can be detected by
the Confusion Assessment Method for the ICU (CAM-ICU) or the
Intensive Care Delirium Screening Checklist (ICDSC). These tools are
used to ask patients to answer simple questions and perform simple
tasks and can be used readily at the bedside. The differential diagnosis
of delirium in ICU patients is broad and includes infectious etiologies
(including sepsis), medications (particularly sedatives and analgesics),
drug withdrawal, metabolic/electrolyte derangements, intracranial
pathology (e.g., stroke, intracranial hemorrhage), seizures, hypoxia,
hypertensive crisis, shock, and vitamin deficiencies (particularly thiamine). The etiology of a patient’s ICU delirium impacts the prognosis.
Those with persistent ICU delirium not related to sedatives have
increases in length of hospital stay, time on mechanical ventilation,
cognitive impairment at hospital discharge, and 6-month mortality
rate. Interventions to reduce ICU delirium are limited. The sedative
dexmedetomidine has been less strongly associated with ICU delirium
than midazolam. In addition, very early physical and occupational
therapy in mechanically ventilated patients has been demonstrated to
reduce delirium.
■ ANOXIC CEREBRAL INJURY
(See also Chap. 307) This condition is common after cardiac arrest
and often results in severe and permanent brain injury in survivors.
Active cooling of patients to 33°C after cardiac arrest is controversial,
with some studies showing improved neurologic outcomes and others
showing no such improvement. Certainly, patients post cardiac arrest
should have a temperature targeted to no higher than normothermia.
■ STROKE
(See also Chap. 426) Stroke is a common cause of neurologic critical
illness. Hypertension must be managed carefully, because abrupt
reductions in blood pressure may be associated with further brain
ischemia and injury. Acute ischemic stroke treated with tissue plasminogen activator (tPA) has an improved neurologic outcome when
treatment is given within 4.5 h of onset of symptoms, with likely
increased benefit associated with earlier administration. The mortality rate is not reduced when tPA is compared with placebo, despite
the improved neurologic outcome. The risk of cerebral hemorrhage
is significantly higher in patients given tPA. No benefit is seen when
tPA therapy is given beyond 4.5 h after symptom onset. Heparin has
not been convincingly shown to improve outcomes in patients with
acute ischemic stroke. Decompressive craniectomy is a surgical procedure that relieves increased intracranial pressure in the setting of
space-occupying brain lesions or brain swelling from stroke; available
evidence suggests that this procedure may improve survival among
select patients (e.g., ≤55 years of age), albeit at a cost of increased
disability for some.
■ SUBARACHNOID HEMORRHAGE
(See also Chap. 426) Subarachnoid hemorrhage may occur secondary
to aneurysm rupture and is often complicated by cerebral vasospasm,
re-bleeding, and hydrocephalus. Vasospasm can be detected by either
transcranial Doppler assessment or cerebral angiography; it is typically
treated with the calcium channel blocker nimodipine, aggressive IV
fluid administration to avoid hypovolemia, and therapy aimed at maintaining adequate central perfusion pressure, typically with vasoactive
drugs such as phenylephrine. IV fluids and vasoactive drugs (hypertensive hypervolemic therapy) are used to overcome the cerebral vasospasm. Early surgical clipping or endovascular coiling of aneurysms
is advocated to prevent complications related to re-bleeding. Hydrocephalus, typically heralded by a decreased level of consciousness, may
require ventriculostomy drainage.
■ STATUS EPILEPTICUS (SEE ALSO CHAP. 425)
Recurrent or relentless seizure activity is a medical emergency. Cessation of seizure activity is required to prevent irreversible neurologic
injury. Lorazepam is the most effective benzodiazepine for treating
status epilepticus and is the treatment of choice for controlling seizures
acutely. Maintenance of seizure control should be effected with a loading dose of fosphenytoin, valproate, or levetiracetam, as these agents
have been shown to have similar efficacy and side effects.
■ BRAIN DEATH
(See also Chap. 307) Although deaths of critically ill patients usually
are attributable to irreversible cessation of circulatory and respiratory
function, a diagnosis of death also may be established by irreversible
cessation of all functions of the entire brain, including the brainstem,
even if circulatory and respiratory functions remain intact on artificial
life support. Such a diagnosis requires demonstration of the absence of
cerebral function (no response to any external stimulus) and brainstem
functions (e.g., unreactive pupils, lack of ocular movement in response
to head turning or ice-water irrigation of ear canals, positive apnea test
[no drive to breathe]). Many U.S. institutions have a protocol based
upon their state’s requirements for declaration of brain death. Absence
of brain function must have an established cause and be permanent
without possibility of recovery; a sedative effect, hypothermia, hypoxemia, neuromuscular paralysis, and severe hypotension must be ruled
2225Acute Respiratory Distress Syndrome CHAPTER 301
Acute respiratory distress syndrome (ARDS) is a clinical syndrome
of severe dyspnea of rapid onset, hypoxemia, and diffuse pulmonary
infiltrates leading to respiratory failure. ARDS can be caused by diffuse
lung injury from many underlying medical and surgical disorders. The
lung injury may be direct, as occurs in toxic inhalation, or indirect, as
occurs in sepsis (Table 301-1). The clinical features of ARDS are listed
in Table 301-2. By expert consensus, ARDS is defined by three categories based on the degrees of hypoxemia (Table 301-2). These stages
of mild, moderate, and severe ARDS are associated with mortality risk
and with the duration of mechanical ventilation in survivors.
The annual incidence of ARDS prior to the COVID-19 pandemic
was estimated to be as high as 60 cases/100,000 population. Approximately 10% of all intensive care unit (ICU) admissions involve patients
with ARDS. This chapter will focus on non-COVID-19-ARDS. Please
see Chap. 199 for more information on COVID.
■ ETIOLOGY
While many medical and surgical illnesses have been associated with
the development of ARDS, most cases (>80%) are caused by a relatively
small number of clinical disorders: pneumonia and sepsis (~40–60%),
followed in incidence by aspiration of gastric contents, trauma, multiple transfusions, and drug overdose. Among patients with trauma, the
most frequently reported surgical conditions in ARDS are pulmonary
contusion, multiple bone fractures, and chest wall trauma/flail chest,
whereas head trauma, near-drowning, toxic inhalation, and burns are
rare causes. The risks of developing ARDS are increased in patients
with more than one predisposing medical or surgical condition.
Several other clinical variables have been associated with the
development of ARDS. These include older age, chronic alcohol
abuse, pancreatitis, pneumonia and sepsis (40-60%), [including pandemic COVID pneumonia], and severity of critical illness. Trauma
patients with an Acute Physiology and Chronic Health Evaluation
(APACHE) II score ≥16 (Chap. 300) have a 2.5-fold increased risk of
developing ARDS.
■ CLINICAL COURSE AND PATHOPHYSIOLOGY
The natural history of ARDS is marked by three phases—exudative,
proliferative, and fibrotic—that each have characteristic clinical and
pathologic features (Fig. 301-1).
Exudative Phase In this phase, alveolar capillary endothelial
cells and type I pneumocytes (alveolar epithelial cells) are injured,
with consequent loss of the normally tight alveolar barrier to fluid
and macromolecules. Edema fluid that is rich in protein accumulates
301 Acute Respiratory
Distress Syndrome
Rebecca M. Baron, Bruce D. Levy
TABLE 301-1 Clinical Disorders Commonly Associated with ARDS
DIRECT LUNG INJURY INDIRECT LUNG INJURY
Pneumonia Sepsis
Aspiration of gastric contents Severe trauma
Pulmonary contusion Multiple bone fractures
Near-drowning Flail chest
Toxic inhalation injury Head trauma
Burns
Multiple transfusions
Drug overdose
Pancreatitis
Postcardiopulmonary bypass
out. If there is uncertainty about the cause of coma, studies of cerebral
blood flow and electroencephalography should be performed.
■ WITHHOLDING OR WITHDRAWING CARE
(See also Chap. 12) Withholding or withdrawal of care occurs commonly in the ICU setting. The Task Force on Ethics of the Society
of Critical Care Medicine reported that it is ethically sound to withhold or withdraw care if a patient or the patient’s surrogate makes
such a request or if the physician judges that the goals of therapy are
not achievable. Because all medical treatments are justified by their
expected benefits, the loss of such an expectation justifies the act of
withdrawing or withholding such treatment; these two actions are
judged to be fundamentally similar. An underlying stipulation derived
from this report is that an informed patient should have his or her
wishes respected with regard to life-sustaining therapy. Implicit in
this stipulation is the need to ensure that patients are thoroughly and
accurately informed regarding the plausibility and expected results of
various therapies.
The act of informing patients and/or surrogate decision-makers is
the responsibility of the physician and other health care providers. If a
patient or surrogate desires therapy deemed futile by the treating physician, the physician is not obligated ethically to provide such treatment. Rather, arrangements may be made to transfer the patient’s care
to another care provider. Whether the decision to withdraw life support should be initiated by the physician or left to surrogate decisionmakers alone is not clear. One study reported that slightly more
than half of surrogate decision-makers preferred to receive such a
recommendation, whereas the rest did not. Critical care providers
should meet regularly with patients and/or surrogates to discuss
prognosis when the withholding or withdrawal of care is being
considered. After a consensus among caregivers has been reached,
this information should be relayed to the patient and/or surrogate
decision-maker. If a decision to withhold or withdraw life-sustaining
care for a patient has been made, aggressive attention to analgesia and
anxiolysis is needed.
Acknowledgment
John P. Kress and Jesse B. Hall contributed to this chapter in the 20th
edition and some material from that chapter has been retained here.
■ FURTHER READING
Devlin JW et al: Clinical practice guidelines for the prevention and
management of pain, agitation/sedation, delirium, immobility, and
sleep disruption in adult patients in the ICU. Crit Care Med 46:e825,
2018.
Girard TD et al: An Official American Thoracic Society/American
College of Chest Physicians Clinical Practice Guideline: Liberation
from Mechanical Ventilation in Critically Ill Adults. Rehabilitation
Protocols, Ventilator Liberation Protocols, and Cuff Leak Tests. Am J
Respir Crit Care Med 195:120, 2017.
Guerin C et al: Prone positioning in severe acute respiratory distress
syndrome. N Engl J Med 368:2159, 2013.
Kapur J et al: Randomized trial of three anticonvulsant medications
for status epilepticus. N Engl J Med 381:2103, 2019.
Man S et al: Association between thrombolytic door-to-needle time
and 1-year mortality and readmission in patients with acute ischemic
stroke. JAMA 323:2170, 2020.
The National Heart, Lung, and Blood Institute Petal Clinical
Trials Network et al: Early neuromuscular blockade in the acute
respiratory distress syndrome. N Engl J Med 380:1997, 2019.
Singer M et al: The third international consensus definitions for sepsis
and septic shock (Sepsis-3). JAMA 315:801, 2016.
Surviving Sepsis Campaign: International guidelines for the management sepsis and septic shock. Crit Care Med 45:486, 2017.
Toews I et al: Interventions for preventing upper gastrointestinal
bleeding in people admitted to intensive care units. Cochrane Database Syst Rev 6:CD008687, 2018.
2226 PART 8 Critical Care Medicine
in the interstitial and alveolar spaces (Fig. 301-2). Proinflammatory
cytokines (e.g., interleukin 1, interleukin 8, and tumor necrosis factor
α [TNF-α]) and lipid mediators (e.g., leukotriene B4
) are increased in
this acute phase, leading to the recruitment of leukocytes (especially
neutrophils) into the pulmonary interstitium and alveoli. In addition,
condensed plasma proteins aggregate in the air spaces with cellular
debris and dysfunctional pulmonary surfactant to form hyaline membrane whorls. Pulmonary vascular injury also occurs early in ARDS,
with vascular obliteration by microthrombi and fibrocellular proliferation (Fig. 301-3).
Alveolar edema predominantly involves dependent portions of the
lung with diminished aeration. Collapse of large sections of dependent
lung can contribute to decreased lung compliance. Consequently,
intrapulmonary shunting and hypoxemia develop and the work of
breathing increases, leading to dyspnea. The pathophysiologic alterations in alveolar spaces are exacerbated by microvascular occlusion
that results in reductions in pulmonary arterial blood flow to ventilated
portions of the lung (and thus in increased dead space) and in pulmonary hypertension. Thus, in addition to severe hypoxemia, hypercapnia
secondary to an increase in pulmonary dead space can be prominent
in early ARDS.
The exudative phase encompasses the first 7 days of illness after exposure to a precipitating ARDS risk factor, with the patient experiencing
the onset of respiratory symptoms. Although usually presenting within
12–36 h after the initial insult, symptoms can be delayed by 5–7 days.
Dyspnea develops, with a sensation of rapid shallow breathing and an
inability to get enough air. Tachypnea and increased work of breathing
result frequently in respiratory fatigue and ultimately in respiratory
failure. Laboratory values are generally nonspecific and are primarily indicative of underlying clinical disorders. The chest radiograph
usually reveals opacities consistent with pulmonary edema and often
involves at least three-quarters of the lung fields (Fig. 301-2). While
characteristic for ARDS, these radiographic findings are not specific
and can be indistinguishable from cardiogenic pulmonary edema
(Chap. 305). Unlike the latter, however, the chest x-ray in ARDS may
not demonstrate cardiomegaly, pleural effusions, or pulmonary vascular redistribution as is often present in pure cardiogenic pulmonary
edema. If no ARDS risk factor is present, then some objective evaluation is required (e.g., echocardiography) to exclude a cardiac etiology
for hydrostatic edema. Chest computed tomography (CT) in ARDS
Exudative
Hyaline
Edema Membranes
Day: 0 2 7 14 21 . . .
Interstitial Inflammation Fibrosis
Proliferative Fibrotic
FIGURE 301-1 Diagram illustrating the time course for the development and
resolution of acute respiratory distress syndrome (ARDS). The exudative phase
is notable for early alveolar edema and neutrophil-rich leukocytic infiltration of
the lungs, with subsequent formation of hyaline membranes from diffuse alveolar
damage. Within 7 days, a proliferative phase ensues with prominent interstitial
inflammation and early fibrotic changes. Approximately 3 weeks after the initial
pulmonary injury, most patients recover. However, some patients enter the fibrotic
phase, with substantial fibrosis and bullae formation.
FIGURE 301-2 A representative anteroposterior chest x-ray in the exudative phase
of acute respiratory distress syndrome (ARDS) shows bilateral opacities consistent
with pulmonary edema that can be difficult to distinguish from left ventricular failure.
TABLE 301-2 Diagnostic Criteria for ARDS
SEVERITY: OXYGENATIONa ONSET CHEST RADIOGRAPH
ABSENCE OF LEFT ATRIAL
HYPERTENSION
Mild: 200 mmHg < Pao2
/Fio2
≤ 300 mmHg
Moderate: 100 mmHg < Pao2
/Fio2
≤ 200
mmHg
Severe: Pao2
/Fio2
≤100 mmHg
Acute: Within 1 week of a clinical
insult or new or worsening respiratory
symptoms
Bilateral opacities consistent with
pulmonary edema not fully explained
by effusions, lobar/lung collapse, or
nodules
Hydrostatic edema is not the primary
cause of respiratory failure. If no
ARDS risk factor is present, then
some objective evaluation is required
(e.g., echocardiography) to rule out
hydrostatic edema
a
As assessed on at least 5 cm H2
O of positive end expiratory pressure (PEEP).
Abbreviations: ARDS, acute respiratory distress syndrome; Fio2
, inspired O2
percentage; Pao2
, arterial partial pressure of O2
; PCWP, pulmonary capillary wedge pressure.
also reveals the presence of bilateral pulmonary infiltrates and demonstrates extensive heterogeneity of lung involvement (Fig. 301-4).
Because the early features of ARDS are nonspecific, alternative
diagnoses must be considered. In the differential diagnosis of ARDS,
the most common disorders are cardiogenic pulmonary edema, bilateral pneumonia, and alveolar hemorrhage. Less common diagnoses to
consider include acute interstitial lung diseases (e.g., acute interstitial
pneumonitis; Chap. 293), acute immunologic injury (e.g., hypersensitivity pneumonitis; Chap. 288), toxin injury (e.g., radiation pneumonitis; Chap. 75), and neurogenic pulmonary edema (Chap. 37).
Proliferative Phase This phase of ARDS usually lasts from
approximately day 7 to day 21. Many patients recover rapidly and are
liberated from mechanical ventilation during this phase. Despite this
improvement, many patients still experience dyspnea, tachypnea, and
hypoxemia. Some patients develop progressive lung injury and early
changes of pulmonary fibrosis during the proliferative phase. Histologically, the first signs of resolution are often evident in this phase, with
the initiation of lung repair, the organization of alveolar exudates, and
a shift from neutrophil- to lymphocyte-predominant pulmonary infiltrates. As part of the reparative process, type II pneumocytes proliferate
along alveolar basement membranes. These specialized epithelial cells
synthesize new pulmonary surfactant and differentiate into type I
pneumocytes.
Fibrotic Phase While many patients with ARDS recover lung function 3–4 weeks after the initial pulmonary injury, some enter a fibrotic
phase that may require long-term support on mechanical ventilators
and/or supplemental oxygen. Histologically, the alveolar edema and
inflammatory exudates of earlier phases convert to extensive alveolarduct and interstitial fibrosis. Marked disruption of acinar architecture
leads to emphysema-like changes, with large bullae. Intimal fibroproliferation in the pulmonary microcirculation causes progressive vascular
2227Acute Respiratory Distress Syndrome CHAPTER 301
TREATMENT
Acute Respiratory Distress Syndrome
GENERAL PRINCIPLES
Recent reductions in ARDS mortality rates are largely the result of
general advances in the care of critically ill patients (Chap. 300).
Thus, caring for these patients requires close attention to (1) the
recognition and treatment of underlying medical and surgical
disorders (e.g., pneumonia, sepsis, aspiration, trauma); (2) the minimization of unnecessary procedures and their complications; (3)
standardized “bundled care” approaches for ICU patients, including prophylaxis against venous thromboembolism, gastrointestinal bleeding, aspiration, excessive sedation, prolonged mechanical
ventilation, and central venous catheter infections; (4) prompt
recognition of nosocomial infections; and (5) provision of adequate
nutrition via the enteral route when feasible.
MANAGEMENT OF MECHANICAL VENTILATION
(See also Chap. 302) Patients meeting clinical criteria for ARDS
frequently become fatigued from increased work of breathing
and progressive hypoxemia, requiring mechanical ventilation for
support.
Minimizing Ventilator-Induced Lung Injury Despite its lifesaving potential, mechanical ventilation can aggravate lung injury.
Experimental models have demonstrated that ventilator-induced
Alveolar
air space
Protein-rich
edema fluid
Inactivated
surfactant
Activated
neutrophil
Alveolar
macrophages
Type I cell
Type II cell
Red blood
cell
Endothelial
cell
Endothelial
basement
membrane
Fibroblasts
Neutrophils
Gap formation
Procollagen
Proteases
IL-8
TNF-α MIF
IL-6, IL-8
Leukotrienes
Oxidants
PAF
Proteases
IL-8
Migrating
neutrophil
Fibroblasts
Capillary
Swollen, injured
endothelial cell
Platelets
Interstitium
Widened
edematous
interstitium
Epithelial
basement
membrane
Sloughing of
bronchial epithelium
Necrotic or apoptotic
type I cell
Red blood cell
Intact type II cell
Cellular
debris
Fibrin
Denuded basement
membrane
Hyaline membrane
Surfactant
layer
Normal alveolus Injured alveolus during the acute phase
FIGURE 301-3 The normal alveolus (left) and the injured alveolus in the acute phase of acute lung injury and the acute respiratory distress syndrome (right). In the acute
phase of the syndrome (right), there is sloughing of both the bronchial and alveolar epithelial cells, with the formation of protein-rich hyaline membranes on the denuded
basement membrane. Neutrophils are shown adhering to the injured capillary endothelium and transmigrating through the interstitium into the air space, which is filled
with protein-rich edema fluid. In the air space, an alveolar macrophage is secreting proinflammatory cytokines—i.e., interleukins 1, 6, 8 (IL-1, 6, 8) and tumor necrosis factor
α (TNF-α)—that act locally to stimulate chemotaxis and activate neutrophils. IL-1 can also stimulate the production of extracellular matrix by fibroblasts. Neutrophils can
release oxidants, proteases, leukotrienes, and other proinflammatory molecules, such as platelet-activating factor (PAF). A number of anti-inflammatory mediators are also
present in the alveolar milieu, including the IL-1 receptor antagonist, soluble TNF-α receptor, autoantibodies to IL-8, and cytokines such as IL-10 and IL-11 (not shown).
The influx of protein-rich edema fluid into the alveolus can lead to the inactivation of surfactant. MIF, macrophage inhibitory factor. (From LB Ware, MA Matthay. The acute
respiratory distress syndrome. N Engl J Med 342:1334, 2000. Copyright © 2000 Massachusetts Medical Society. Reprinted with permission from Massachusetts Medical Society.)
FIGURE 301-4 A representative CT scan of the chest during the exudative phase of
acute respiratory distress syndrome (ARDS), in which dependent alveolar edema
and atelectasis predominate.
occlusion and pulmonary hypertension. The physiologic consequences
include an increased risk of pneumothorax, reductions in lung compliance, and increased pulmonary dead space. Patients in this late phase
experience a substantial burden of excess morbidity. Lung biopsy evidence for pulmonary fibrosis in any phase of ARDS is associated with
increased mortality risk.
2228 PART 8 Critical Care Medicine
lung injury can arise from at least two principal mechanisms:
“volutrauma” from repeated alveolar overdistention from excess
tidal volume (that might also coincide with increased alveolar pressures, or “barotrauma”) and “atelectrauma” from recurrent alveolar
collapse. As is evident from chest CT (Fig. 301-4), ARDS is a heterogeneous disorder, principally involving dependent portions of
the lung with relative sparing of other regions. Because compliance
differs in affected versus more “normal” areas of the lung, attempts
to fully inflate the consolidated lung may lead to overdistention of
and injury to the more normal areas. Ventilator-induced injury can
be demonstrated in experimental models of acute lung injury, in
particular with high-tidal-volume (VT) ventilation.
A large-scale, randomized controlled trial sponsored by the
National Institutes of Health and conducted by the ARDS Network
compared low VT ventilation (6 mL/kg of predicted body weight)
to conventional VT ventilation (12 mL/kg predicted body weight).
Lower airway pressures were also targeted in the low-tidal-volume
group (i.e., plateau pressure measured on the ventilator after a 0.5-s
pause after inspiration), with pressures targeted at ≤30 cm H2
O
in the low-tidal-volume group versus ≤50 cm H2
O in the hightidal-volume group. The mortality rate was significantly lower in
the low VT patients (31%) than in the conventional VT patients
(40%). This improvement in survival represents a substantial ARDS
mortality benefit.
Minimizing Atelectrauma by Prevention of Alveolar Collapse In
ARDS, the presence of alveolar and interstitial fluid and the loss
of surfactant can lead to a marked reduction of lung compliance.
Without an increase in end-expiratory pressure, significant alveolar
collapse can occur at end-expiration, with consequent impairment
of oxygenation. In most clinical settings, positive end-expiratory
pressure (PEEP) is adjusted to minimize Fio2
(inspired O2
percentage) and provide adequate Pao2
(arterial partial pressure of
O2
) without causing alveolar overdistention. Currently, there is no
consensus on the optimal method to set PEEP, because numerous
trials have proved inconclusive. Possible approaches include using
the table of PEEP-Fio2
combinations from the ARDS Network trial
group, generating a static pressure-volume curve for the respiratory system and setting PEEP just above the lower inflection
point on this curve to maximize respiratory system compliance,
and measuring esophageal pressures to estimate transpulmonary
pressure (which may be particularly helpful in patients with a
stiff chest wall). Of note, a recent phase 2 trial in patients with
moderate-to-severe ARDS demonstrated no benefit of routine use
of esophageal pressure-guided PEEP titration over empirical high
PEEP-Fio2
titration. Until more data become available on how
best to optimize PEEP settings in ARDS, clinicians can use these
options or a practical approach to empirically measure “best PEEP”
at the bedside to determine the optimal settings that best promote
alveolar recruitment, minimize alveolar overdistention and hemodynamic instability, and provide adequate Pao2
while minimizing
Fio2 (Chap. 302).
Prone Positioning While several prior trials demonstrated that
mechanical ventilation in the prone position improved arterial oxygenation without a mortality benefit, a 2013 trial demonstrated a significant reduction in 28-day mortality with prone positioning (32.8 to
16.0%) for patients with severe ARDS (Pao2
/Fio2
<150 mm Hg). Thus,
many centers are increasing the use of prone positioning in severe
ARDS, with the understanding that this maneuver requires a criticalcare team that is experienced in “proning,” as repositioning critically
ill patients can be hazardous, leading to accidental endotracheal
extubation, loss of central venous catheters, and orthopedic injury.
OTHER STRATEGIES IN MECHANICAL VENTILATION
Recruitment maneuvers that transiently increase PEEP to high
levels to “recruit” atelectatic lung can increase oxygenation, but
a mortality benefit has not been established, and in fact, recruitment maneuvers may increase mortality when they are combined
with higher baseline PEEP settings. Alternate modes of mechanical
ventilation, such as airway pressure release ventilation and highfrequency oscillatory ventilation, have not been proven beneficial
over standard modes of ventilation in ARDS management. In
one study, lung-replacement therapy with extracorporeal membrane
oxygenation (ECMO) was shown to improve mortality for patients
with ARDS in the United Kingdom who were referred to an ECMO
center (though only 75% of referred patients received ECMO) and
thus may have utility in select adult patients with severe ARDS as
a rescue therapy. A subsequent study demonstrated that initial use
of ECMO in patients with severe ARDS was not superior to use of
ECMO as a rescue strategy for patients who failed standard ARDS
management.
FLUID MANAGEMENT
(See also Chap. 300) Increased pulmonary vascular permeability
leading to interstitial and alveolar edema fluid rich in protein is a
central feature of ARDS. In addition, impaired vascular integrity
augments the normal increase in extravascular lung water that occurs
with increasing left atrial pressure. Maintaining a low left atrial
filling pressure minimizes pulmonary edema and prevents further
decrements in arterial oxygenation and lung compliance; improves
pulmonary mechanics; and shortens ICU stay and the duration of
mechanical ventilation. Thus, aggressive attempts to reduce left atrial
filling pressures with fluid restriction and diuretics should be an
important aspect of ARDS management, limited only by hypotension
and hypoperfusion of critical organs such as the kidneys.
NEUROMUSCULAR BLOCKADE
In severe ARDS, sedation alone can be inadequate for the
patient-ventilator synchrony required for lung-protective ventilation. In a multicenter, randomized, placebo-controlled trial of early
neuromuscular blockade (with cisatracurium besylate) for 48 h,
patients with severe ARDS had increased survival and ventilatorfree days without increasing ICU-acquired paresis. A subsequent
trial demonstrated no mortality benefit for early neuromuscular
blockade for 48 h in patients with moderate-to-severe ARDS. This
more recent study supports the notion that selective use of neuromuscular blockade might be beneficial in those ARDS patients with
ventilatory dyssynchrony despite sedation.
GLUCOCORTICOIDS
Many attempts have been made to treat both early and late ARDS
with glucocorticoids, with the goal of reducing potentially deleterious pulmonary inflammation. Few studies have shown any
significant mortality benefit. Current evidence does not support the
routine use of glucocorticoids in the care of ARDS patients.
OTHER THERAPIES
Clinical trials of surfactant replacement and multiple other medical
therapies have proved disappointing. Pulmonary vasodilators such
as inhaled nitric oxide and inhaled epoprostenol sodium can transiently improve oxygenation but have not been shown to improve
survival or decrease time on mechanical ventilation.
RECOMMENDATIONS
Many clinical trials have been undertaken to improve the outcome
of patients with ARDS; most have been unsuccessful in modifying
the natural history. While results of large clinical trials must be
judiciously applied to individual patients, evidence-based recommendations are summarized in Table 301-3, and an algorithm for
the initial therapeutic goals and limits in ARDS management is
provided in Fig. 301-5. Please note that these recommendations
apply to non-COVID-19-ARDS. Please see recommendations for
COVID-19-ARDS in Chap. 199.
■ PROGNOSIS
Mortality In the recent report from the Large Observational
Study to Understand the Global Impact of Severe Acute Respiratory
Failure (LUNG SAFE) trial, hospital mortality estimates for ARDS
were 34.9% for mild ARDS, 40.3% for moderate ARDS, and 46.1%
2229Acute Respiratory Distress Syndrome CHAPTER 301
with severe ARDS. There is substantial variability, but a trend toward
improved ARDS outcomes over time appears evident. Of interest,
mortality in ARDS is largely attributable to nonpulmonary causes, with
sepsis and nonpulmonary organ failure accounting for >80% of deaths.
Thus, improvement in survival is likely secondary to advances in the
care of septic/infected patients and those with multiple organ failure
(Chap. 300).
The major risk factors for ARDS mortality are nonpulmonary.
Advanced age is an important risk factor. Patients aged >75 years have
a substantially higher mortality risk (~60%) than those <45 (~20%).
Moreover, patients >60 years of age with ARDS and sepsis have a
threefold higher mortality risk than those <60 years of age. Other risk
factors include preexisting organ dysfunction from chronic medical
illness—in particular, chronic liver disease, chronic alcohol abuse, and
chronic immunosuppression (Chap. 300). Patients with ARDS arising
from direct lung injury (including pneumonia, pulmonary contusion,
and aspiration; Table 301-1) are nearly twice as likely to die as those
with indirect causes of lung injury, while surgical and trauma patients
with ARDS—especially those without direct lung injury—generally
have a higher survival rate than other ARDS patients.
Increasing severity of ARDS, as defined by the consensus Berlin
definition, predicts increased mortality. Surprisingly, there is little
additional value in predicting ARDS mortality from other parameters
of lung injury, including the level of PEEP (≥10 cm H2
O), respiratory
system compliance (≤40 mL/cm H2
O), the extent of alveolar infiltrates
on chest radiography, and the corrected expired volume per minute
(≥10 L/min) (as a surrogate measure of dead space).
Functional Recovery in ARDS Survivors While it is common
for patients with ARDS to experience prolonged respiratory failure
and remain dependent on mechanical ventilation for survival, it is
a testament to the resolving powers of the lung that the majority of
patients who survive regain nearly normal lung function. Patients
usually recover maximal lung function within 6 months. One year
after endotracheal extubation, more than one-third of ARDS survivors have normal spirometry values and diffusion capacity. Most of
the remaining patients have only mild abnormalities in pulmonary
function. Unlike mortality risk, recovery of lung function is strongly
associated with the extent of lung injury in early ARDS. Low static
respiratory compliance, high levels of required PEEP, longer durations of mechanical ventilation, and high lung injury scores are all
associated with less recovery of pulmonary function. Of note, when
physical function is assessed 5 years after ARDS, exercise limitation
and decreased physical quality of life are often documented despite
normal or nearly normal pulmonary function. When caring for ARDS
survivors, it is important to be aware of the potential for a substantial
burden of psychological problems in patients and family caregivers,
including significant rates of depression and posttraumatic stress
disorder. Please see Chap. 199 for information regarding COVID
prognosis and recovery.
Acknowledgment
The authors acknowledge the contributions to this chapter by the previous
authors, Drs. Augustine Choi and Steven D. Shapiro.
■ FURTHER READING
ARDS Definition Task Force: Acute respiratory distress syndrome:
The Berlin definition. JAMA 307:2526, 2012.
ARDS Network: Ventilation with lower tidal volumes as compared
with traditional tidal volumes for acute lung injury and the acute
respiratory distress syndrome. N Engl J Med 342:1301, 2000.
Beitler JR et al: Effect of titrating positive end-expiratory pressure
(PEEP) with an esophageal pressure-guided strategy vs an empirical
high PEEP-FiO2 strategy on death and days free from mechanical
ventilation among patients with acute respiratory distress syndrome.
JAMA 321:846, 2019.
Bellani G et al: Epidemiology, patterns of care, and mortality for
patients with acute respiratory distress syndrome in intensive care
units in 50 countries. JAMA 315:788, 2016.
Combes A et al: Extracorporeal membrane oxygenation for severe
acute respiratory distress syndrome. N Engl J Med 378:1965, 2018.
The National Heart, Lung, and Blood Institute Petal Clinical
Trials Network: Early neuromuscular blockade in the acute respiratory distress syndrome. N Engl J Med 380:1996, 2019.
Ware LB, Matthay MA: The acute respiratory distress syndrome.
N Engl J Med 342:1334, 2000.
TABLE 301-3 Evidence-Based Recommendations for ARDS Therapies
TREATMENT RECOMMENDATIONa
Mechanical ventilation
Low tidal volume A
Minimized left atrial filling pressures B
High-PEEP or “open lung” Bb
Prone position Bb
Recruitment maneuvers Cb
High-frequency ventilation D
ECMO Bb
Early neuromuscular blockade (routine use) Cb
Glucocorticoid treatment D
Inhaled vasodilators (e.g., inhaled NO, inhaled
epoprosteol)
C
Surfactant replacement, and other antiinflammatory therapy (e.g., ketoconazole, PGE1
,
NSAIDs)
D
a
Key: A, recommended therapy based on strong clinical evidence from randomized
clinical trials; B, recommended therapy based on supportive but limited clinical
data; C, recommended only as alternative therapy on the basis of indeterminate
evidence; D, not recommended on the basis of clinical evidence against efficacy of
therapy. b
As described in the text, there is no consensus on optimal PEEP setting
in ARDS, but general consensus supports an open lung strategy that minimizes
alveolar distention; prone positioning was shown to improve mortality in severe
ARDS in one randomized controlled clinical trial; recruitment maneuvers combined
with high PEEP were shown to increase mortality in one study; ECMO may be
beneficial in select patients with severe ARDS; early neuromuscular blockade
demonstrated a mortality benefit in one randomized controlled trial in patients with
severe ARDS but was not replicated in a subsequent study, suggesting routine use
of early neuromuscular blockade in all subjects with moderate-severe ARDS may
not be beneficial.
Abbreviations: ARDS, acute respiratory distress syndrome; ECMO, extracorporeal
membrane oxygenation; NO, nitric oxide; NSAIDs, nonsteroidal anti-inflammatory
drugs; PEEP, positive end-expiratory pressure; PGE1
, prostaglandin E1
.
Initiate
volume/pressure-limited
ventilation
Oxygenate
Minimize acidosis
Diuresis
Goals and Limits:
Tidal volume ≤6 mL/kg PBW
Plateau pressure ≤30 cmH2O
RR ≤35 bpm
FIO2 ≤0.6
SpO2 88–95%
MAP ≥65 mmHg
Avoid hypoperfusion
pH ≥7.30
RR ≤35 bpm
FIGURE 301-5 Algorithm for the initial management of acute respiratory distress
syndrome (ARDS). Clinical trials have provided evidence-based therapeutic goals
for a stepwise approach to the early mechanical ventilation, oxygenation, and
correction of acidosis and diuresis of critically ill patients with ARDS. Fio2
, inspired
O2
percentage; MAP, mean arterial pressure; PBW, predicted body weight; RR,
respiratory rate; Spo2
, arterial oxyhemoglobin saturation measured by pulse
oximetry.
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