2. Content
• Introduction
• Epidemiology
• Causes
• Clinical course and pathophysiology
• Clinical features
• Diagnostic criteria
• Differential diagnosis
• Investigations
• Management
• Prognosis and recovery
3. Introduction
• ARDS is a clinical syndrome of dyspnea of rapid onset,hypoxemia and
diffuse pulmonary infiltrates leading to respiratory failure.
• ARDS is also referred with variety of terms like
Stiff Lung
Non cardiogenic pulmonary edema
Shock lung
Wet lung
Post traumatic lung
Adult respiratory distress syndrome
Adult hyaline membrane disease
Capillary leak syndrome &
Congestive atelectasis.
4. Epidemiology
• Annual incidence : 60 cases/ 1,00,000 population
• Approximately 10% of all intensive care unit (ICU) admissions involve
patients with ARDS
• The mortality rate was traditionally very high (50–70%), Changes in
patient care have led to mortality decline to 30%
5. Causes
• Clinical disorder associated with development of ARDS
• Direct Lung Injury:
Pneumonia
Aspiration of gastric contents
Pulmonary contusion
Near drowning
Inhalation injury
7. Clinical course and pathophysiology
Natural history of ARDS is marked by 3 distinct phases:
• Exudative (0-7 days)
• Proliferative ( 7-21 days)
• Fibrotic ( > 21 days)
8.
9. Exudative (0-7 day)
• Capillary endothelial cells and alveolar epithelial cells are injured,
• Exudation and protein rich edema fluid accumulates in the interstitial and
alveolar spaces.
• Increased pro-inflammatory cytokines
• Recruitment of leukocytes (especially neutrophils) into the interstitium and
alveoli.
• Formation of hyaline membrane
• Alveolar edema in dependent portions of the lung
• Intrapulmonary shunting
• Hypoxemia
• Work of breathing increases, leading to dyspnea.
10. Proliferative phase
• This phase of ARDS usually lasts from day 7 to day 21
• Marked, with the initiation of lung repair
• Exudates cleared and a shift from neutrophil- to lymphocyte-
predominant pulmonary infiltrates.
• Type II pneumocytes regenerate along alveolar basement
membranes. These specialized epithelial cells synthesize new
pulmonary surfactant
• And differentiate into type I pneumocytes.
11. Fibrotic ( > 21 days)
• Most patients with ARDS recover
• Very few progresses into fibrotic phase
• There is extensive alveolar-duct and interstitial fibrosis.
• Marked disruption of acinar architecture leads to emphysema-like
changes, with large bullae.
• Intimal fibro proliferation in the pulmonary microcirculation causes
progressive vascular occlusion and pulmonary hypertension.
• The physiologic consequences include an increased risk of
pneumothorax, reductions in lung compliance, and increased
pulmonary dead space.
12.
13. Clinical features
• Precipitating insult is usually evident
• Fever
• Cough
• Dyspnea
• Tachypnea
• Tachycardia
• Restlessness
• Due to worsening hypoxemia
Agitation, anxiety, confusion
• Cyanosis even with supplemental oxygen ( refractory hypoxemia)
14. Berlin Diagnostic criteria
1. Acute onset (within 7 days of a known clinical insult )
2. Chest x-ray:
• Bilateral opacities not fully explained by lobar collapse, mass or effusion
3. Absence of left atrial hypertension (no hydrostatic edema)
4. Severity:
Pao2/fio2 ≤ 300 mm of Hg , with a positive end-expiratory pressure (PEEP)
of at least 5 cm H2o
• Mild ARDS ( pao2/fio2 ≤ 300 mm of Hg )
• Moderate ARDS (pao2/fio2 ≤ 200 mm of Hg)
• Severe ARDS (pao2/fio2 ≤ 100 mm of Hg )
22. TRALI Vs TACO
• Fever No Fever
• Hypotension Hypertension
• JVP Unchanged JVP Raised
• EF- Normal Decreased
• Pulmonary Edema Fluid- Exudate Transudate
• Response To Diuretic- Minimal Significant
23.
24. Management
1. TREATMENT of the cause
e.g. antibiotics for pneumonia, sepsis
2.Supportive therapy
Protective lung ventilation,
Fluid management
Prone positioning
3.Pharmacological treatment
Steroids, vasodilators, DVT prophylaxis & sedation.
25. Lung protective ventilation
Patients meeting clinical criteria for ARDS frequently become fatigued
from increased work of breathing and progressive hypoxemia, requiring
mechanical ventilation for support.
• Mechanical ventilation with low tidal volume (4-6 mL/kg ideal body
weight)
• PEEP of atleast 5cm of H2O
• P plateau <30 cm of H2O
• Alveolar over distension and cyclic atelectasis are the principal causes
of ventilator- associated lung injury(VALI)
26.
27. Low tidal volumes
• Prevents from volutrauma and barotrauma by alveolar overdistention
• Because of the mortality benefit, the pCO2 of the patient is allowed to
rise. (known as permissive hypercapnia)
• For patients in ARDS, the pH is allowed to drift down to 7.30
• When pH< 7.2 then it needs to be buffered.
28. Advantages of PEEP:
• Minimize cyclic atelectasis
• It opens collapsed alveoli /
Reverse atelectasis - known as lung
Recruitment, and it increases the available surface area in the lungs for
gas exchange
• Increases arterial oxygenation at lower fio2 by decreasing
intrapulmoary shunting
29. Neuromuscular blockade
• In severe ARDS sedation alone is not beneficial for lung protective
ventilation but also adequate for ventilator patient synchrony.
• Early NMB is the preferred in severe ARDS for initial 48 hrs.
• This increase rate of survival and ventilator free days without
increasing ICU acquired paresis
30. Prone position
• A recent trial demonstrated a significant reduction in 28-day mortality
with prone positioning (32.8 to 16%) for patients with severe ARDS
• Possible mechanisms :
Recruitment of dependent lung zones,
Improved ventilation-perfusion matching
Relief of compression of the lung by the heart and mediastinal structures
• This maneuver requires a critical-care 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
31.
32. Fluid management
• Primary cause is leakage of fluid and pulmonary edema, so negative
fluid balance should be done
• Fluid restriction and diuretics is an important aspect of ARDS
management, not causing hypotension or hypoperfusion of vital
organs(MAP>65 mm hg)
• Maintaining a low left atrial pressure minimizes pulmonary edema
and improves oxygenation and lung compliance.
33. Inhaled Nitric Oxide
• It is very short acting pulmonary vasodilator
• When delivered (5-10ppm) improves blood flows to well ventilated
areas, thus improving V/Q matching
• Effect lasts only for 48 hour and rebound effect can occur if
withdrawn
• No mortality benefit is shown in clinical trials
• Used as Rescue therapy , when other modality has failed
• Also in patients with PAH
34. Glucocorticoids use
• Many attempts have been made to treat both early and late ARDS
with glucocorticoids, with the goal of reducing potentially deleterious
pulmonary inflammation.
• Current evidence does not support the routine use of glucocorticoids
in the care of ARDS patients.
35. Extracorporeal membrane oxygenation (ECMO)
• There use is restricted to specialized centres.
• Controlled trials indicate improved survival in severe ards pts
• Veno-venous ECMO is designed to provide gas exchange
• ARDS associated with pneumonia (viral or bacterial) is the most
common cause of refractory hypoxemia that requires ECMO
36.
37. Bundled Care For ICU Patients
• Venous thrombosis should be prevented with the use of sc low-molecular-
weight heparin
• To help prevent decubitus ulcers, frequent changes in body position and the
use of soft mattress overlays and air mattresses are employed.
• To prevent gi mucosal injury h2 –receptor antagonists, antacids, and
sucralfate have all been used
• Nutritional support by enteral feeding through either a nasogastric or an
orogastric tube should be initiated and maintained whenever possible.
• Delayed gastric emptying is common in critically ill patients taking sedative
medications but often responds to promotility agents such as
metoclopramide.
38.
39. Decision To Wean From Mechanical Ventilation
Conditions as indicating amenability to weaning:
1. Lung injury is stable or resolving;
2. Gas exchange is adequate, with low PEEP<8 cm of H2O and FiO2<0.5
3. Hemodynamically stable , not on vasopressors
4. Able to initiate spontaneous breaths
If the patient passes the wean screen then can be tried for spontaneous breathing
trials (SBT)consist of breathing through the ET tube without ventilator support or
minimal pressure support (T-piece using 1–5 cmH2O CPAP or PSV from the
ventilator to offset resistance from the endotracheal tube) for period of 30-120
min.
40. 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) Pulse :20% increase or decrease from baseline
(4) systolic blood pressure >180 mmHg or <90 mm Hg
(5) increased anxiety or diaphoresis.
If, at the end of the spontaneous breathing trial, none of the above
events has occurred and the ratio of the respiratory rate and tidal
volume in liters (f/VT) is <105 , patient can be extubated
41. Prognosis
• Mortality declined from 50% to ~30% in past decade
• In the recent report from LUNG SAFE trial, hospital mortality
estimates for ARDS range from
34.9% for mild ARDS,
40.3% for moderate ARDS, and
46.1% with severe ARDS.
• Risk factors having higher mortality rates:
Advanced age>70yr
Non pulmonary cause of ards(sepsis)
Chronic medical illness
>60 yr and sepsis
Severe ARDS
42. Functional Recovery in ARDS Survivors
• 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.
• A year later, 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.