Continuous mandatory ventilation

Continuous mandatory ventilation (CMV) is a mode of mechanical ventilation in which breaths are delivered based on set variables. Still used in the operating room, in previous nomenclature CMV referred to "controlled mechanical ventilation" ("control mode ventilation"), a mode of ventilation characterized by a ventilator that makes no effort to sense patient breathing effort. In continuous mandatory ventilation, the ventilator can be triggered either by the patient or mechanically by the ventilator. The ventilator is set to deliver a breath according to parameters selected by the operator. "Controlled mechanical ventilation" is an outdated expansion for "CMV"; "continuous mandatory ventilation" is now accepted standard nomenclature of mechanical ventilation. CMV today can assist or control dynamically, depending on transient presence or absence of spontaneous breathing effort. Thus, today's CMV would have been called ACV (assist-control ventilation) in older nomenclature, and the original form of CMV is a thing of the past. But despite continual technological improvement over the past half century, CMV sometimes may still be uncomfortable for the patient.

Expected outcomes and considerations

Continuous mandatory ventilation is associated with profound diaphragm muscle dysfunction and atrophy.[1] CMV is no longer the preferred mode of mechanical ventilation.[2]

Volume-controlled CMV

Limit

Limits in VC-CMV may be set and pressure based. The ventilator will attempt to deliver the set tidal volume utilizing whatever pressure is required to reach its setting. A pressure limit may be added to limit damage to the lungs (barotrauma).

Cycle

Expiration cycling can be set by time or the pressure limit. Once the T_i (inspiratory time) is reached, or a pressure limit is reached the ventilator will cycle into expiratory mode and allow passive exhalation until another breath is triggered.

Pressure-controlled CMV

Pressure control (PC) is a pressure-controlled mode of ventilation. The ventilator delivers a flow to maintain the preset pressure at a preset respiratory rate over a preset inspiratory time.[3]

The pressure is constant during the inspiratory time and the flow is decelerating. If for any reason pressure decreases during inspiration, the flow from the ventilator will immediately increase to maintain the set inspiratory pressure.[4]

Dual-control modes

Dual-control modes are pressure controlled modes with an exhaled tidal volume target. They work on a breath-by-breath basis and provide pressure-limited time-cycled breaths, increasing or decreasing the pressure of the next breath as necessary to achieve a user-selected desired tidal volume. They are known by various vendor-specific terms such as pressure-regulated volume control (Siemens), autoflow (Dräger), adaptive-pressure ventilation (Hamilton Medical), volume-control plus (Covidien), among others.

Out-dated terminology

Many terms have been developed to describe the same modes of mechanical ventilation. Nomenclature of mechanical ventilation has become more standardized and these terms are no longer preferred but still may be seen in older research[5] there are many different names that historically were used to reference CMV but now reference Assist Control.[5] Names such as: volume control ventilation, and volume cycled ventilation in modern usage refer to the Assist Control mode.

Assist/control
A/C
CMV
Volume assist/control
Volume control
Volume limited ventilation
Volume controlled ventilation
Controlled ventilation
Volume targeted ventilation

References

Sassoon CS, Zhu E, Caiozzo VJ (2004). "Assist-control mechanical ventilation attenuates ventilator-induced diaphragmatic dysfunction". Am J Respir Crit Care Med. 170 (6): 626–32. doi:10.1164/rccm.200401-042OC. PMID 15201132.
Macintyre N (2011). "Counterpoint: Is Pressure Assist-Control Preferred Over Volume Assist-Control Mode for Lung Protective Ventilation in Patients With ARDS? No". Chest. 140 (2): 290–2. doi:10.1378/chest.11-1052. PMID 21813526.
MAQUET, "Modes of ventilation in SERVO-i, Invasive and Non-invasive, 2008 MAQUET Critical Care AB, Order No 66 14 692
MAQUET, "Modes of ventilation in SERVO-s, Invasive and Non-invasive", 2009 MAQUET Critical Care AB, Order No 66 61 131
Chatburn RL. Classification of ventilator modes: update and proposal for implementation. Respir Care 2007; 52:301–323.

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[pmid15201132-1] Sassoon CS, Zhu E, Caiozzo VJ (2004). "Assist-control mechanical ventilation attenuates ventilator-induced diaphragmatic dysfunction". Am J Respir Crit Care Med. 170 (6): 626–32. doi:10.1164/rccm.200401-042OC. PMID 15201132.

[pmid21813526-2] Macintyre N (2011). "Counterpoint: Is Pressure Assist-Control Preferred Over Volume Assist-Control Mode for Lung Protective Ventilation in Patients With ARDS? No". Chest. 140 (2): 290–2. doi:10.1378/chest.11-1052. PMID 21813526.

[3] MAQUET, "Modes of ventilation in SERVO-i, Invasive and Non-invasive, 2008 MAQUET Critical Care AB, Order No 66 14 692

[4] MAQUET, "Modes of ventilation in SERVO-s, Invasive and Non-invasive", 2009 MAQUET Critical Care AB, Order No 66 61 131

[ReferenceA-5] Chatburn RL. Classification of ventilator modes: update and proposal for implementation. Respir Care 2007; 52:301–323.

Mechanical ventilation
Fundamentals	Modes of mechanical ventilation Mechanical ventilation in emergencies Nomenclature of mechanical ventilation
Modes	IMV/SIMV CMV ACV CSV PAP BPAP/NIV CPAP APRV MMV PAV ASV HFV
Related illness	ARDS Atelectotrauma Biotrauma Pulmonary barotrauma Pulmonary volutrauma Rheotrauma 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 Mechanical power