Ventilator-associated lung injury

Ventilator-associated lung injury
Classification and external resources
ICD-9-CM	J95859
MeSH	D055397

Ventilator-associated lung injury (VALI) is an acute lung injury that develops during mechanical ventilation and is termed ventilator-induced lung injury (VILI) if it can be proven that the mechanical ventilation caused the acute lung injury. In contrast, ventilator-associated lung injury (VALI) exists if the cause cannot be proven. VALI is the appropriate term in most situations because it is virtually impossible to prove what actually caused the lung injury in the hospital.^[1]

Cause

One major causative factor is the over stretching of the airways and alveoli(volutrauma). During mechanical ventilation, the flow of gas into the lung will take the path of least resistance. Areas of the lung that are collapsed (atelectasis) or filled with secretions will be underinflated, while those areas that are relatively normal will be overinflated. These areas will become over distended and injured. This may be reduced by using smaller tidal volumes.^[2]^[3]

During positive pressure ventilation, atelectatic regions will inflate, however the alveoli will be unstable and will collapse during the expiratory phase of the breath(atelectrauma). This repeated alveolar collapse and expansion (RACE) is thought to cause VALI. By opening the lung and keeping the lung open RACE (and VALI) is reduced.^[4]

Another possible ventilator associated lung injury is known as biotrauma. Biotrauma involves the lung suffering injury from any mediators of the inflammatory response or from bacteremia.

Pathogenesis

Overdistension of alveoli and cyclic atelectasis are the primary causes for alveolar injury during positive pressure mechanical ventilation. Severe injury to alveoli causes swelling of the tissues (edema) in the lungs, bleeding of the alveoli, loss of surfactant (decrease in lung compliance) and complete alveoli collapse.^[1]^[5]

Diagnosis

VALI does not need to be distinguished from progressive ALI/ARDS because management is the same in both. Additionally, definitive diagnosis of VALI may not be possible because of lack of sign or symptoms.

Prevention

Preventing alveolar overdistension – Alveolar overdistension is mitigated by using small tidal volumes, maintaining a low plateau pressure, and using pressure limited ventilation.

Preventing cyclic atelectasis – Applied positive end-expiratory pressure (PEEP) is the principal method used to keep the alveoli open and lessen cyclic atelectasis.

Open lung ventilation – Open lung ventilation is a ventilatory strategy that combines small tidal volumes (to lessen alveolar overdistension) and an applied PEEP above the low inflection point on the pressure-volume curve (to lessen cyclic atelectasis).

Non-conventional ventilation as a technique for management

High frequency ventilation is thought to reduce ventilator-associated lung injury, especially in the context of ARDS and acute lung injury.^[4]

Epidemiology

VALI is most common in patients receiving mechanical ventilation for acute lung injury or acute respiratory distress syndrome (ALI/ARDS).^[1]

Possible reasons for predisposition to VALI include:

An injured lung may be at risk for further injury
Cyclic atelectasis is particularly common in an injured lung

Incidence

24 percent of all patients mechanically ventilated will develop VALI for reasons other than ALI or ARDS.^[1] The incidence is probably higher among patients who already have ALI/ARDS, but estimates vary widely.^[1] The variable estimates reflect the difficulty in distinguishing VALI from progressive ALI/ARDS.^[1]

References

1 2 3 4 5 6 International consensus conferences in intensive care medicine: Ventilator-associated Lung Injury in ARDS. This official conference report was cosponsored by the American Thoracic Society, The European Society of Intensive Care Medicine, and The Societé de Réanimation de Langue Française, and was approved by the ATS Board of Directors, July 1999. Am J Respir Crit Care Med 1999; 160:2118.
↑ Calvin SH Ng, Ahmed A Arifi, Song Wan, Anthony MH Ho, Innes YP Wan, Eric MC Wong, Anthony PC Yim. Ventilation during Cardiopulmonary Bypass: Impact on Cytokine Response and Cardiopulmonary Function. Ann Thorac Surg 2008;85:154-62
↑ Calvin SH Ng, Song Wan, Anthony MH Ho, Malcolm J Underwood. Gene Expression Changes with “Non-injurious” Ventilation Strategy. Crit Care 2009;13:403
1 2 Krishnan JA, Brower RG (2000). "High-frequency ventilation for acute lung injury and ARDS". Chest. 118 (3): 795–807. doi:10.1378/chest.118.3.795. PMID 10988205. Free Full Text.
↑ Rouby JJ, Brochard L (2007). "Tidal recruitment and overinflation in acute respiratory distress syndrome: yin and yang.". Am J Respir Crit Care Med. 175 (2): 104–6. doi:10.1164/rccm.200610-1564ED. PMID 17200505.

Mechanical ventilation

Fundamentals	Modes of mechanical ventilation Mechanical ventilation in emergencies Mechanical ventilation in neonates Nomenclature of mechanical ventilation

Modes	IMV/SIMV CMV ACV CSV PAP BPAP CPAP APRV MMV PAV ASV HFV

Related illness	ARDS Pulmonary barotrauma Pulmonary volutrauma Ventilator-associated pneumonia Oxygen toxicity Ventilator-associated lung injury

Pressure	P_EEP FiO₂ Δ_P P_IP P_S P_AW P_plat

Volumes	V_T V_E V_f

Other	C_dyn C_static P_AO₂ V_D/V_T OI A-a gradient

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