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Ventilation, Assist Control

2017 
Mechanical ventilation is a lifesaving procedure that is often performed when patients require respiratory support[1]. Assist-Control (AC) mode is one of the most common methods of mechanical ventilation in the intensive care unit[2]. AC ventilation is a volume-cycled mode of ventilation. It works by setting a fixed tidal Volume (VT) that the ventilator will deliver at set intervals of time or when the patient initiates a breath. The VT delivered by the ventilator in AC always will be the same regardless of compliance, peak, or plateau pressures in the lungs. When AC mode is selected in the ventilator, four parameters may be quickly modified: Tidal Volume (VT): This is the set amount of volume that will be delivered with each breath. Changing the VT will, in turn, change the minute ventilation (VT x RR); an increase in minute ventilation will result in a decrease in carbon dioxide (CO2), by the same token a decreased VT will result in a decreased minute ventilation and increase in the patient's blood CO2. Respiratory Rate (RR): This is the set rate for delivering breaths per minute (bpm). For example, if the set rate is 15 then the delivery is 15 bpm or 1 breath every 4 seconds. This is called time-triggered control. In AC, this set rate can be overturned by the patient, meaning that, if the patient inhales, the ventilator will sense the drop in pressure and deliver that breath, even if the patient is breathing above the set rate. For example, if a patient is breathing at 20 bpm and the ventilator is set at 15 bpm, the ventilator will follow the patient and deliver 20 bpm (one each time the patient initiates a breath). This is called patient-triggered breaths. The ventilator will only deliver breaths at the set RR if the patient does not trigger it faster. As with VT, increasing RR will increase minute ventilation and decrease the patient's blood CO2. A caveat on this is that by increasing the RR, the dead space is also increased, so increasing RR may not be as effective as increasing VT in improving ventilation. The ventilator in AC mode is programmed to sense changes in the system pressure when a patient initiates a breath. When the diaphragm contracts, the intrathoracic pressure becomes more negative. The negative pressure is transmitted to the airways and then to the ventilator tubing, where sensors detect the change in pressure and deliver a breath to the set tidal volume. The amount of negative pressure needed to trigger a breath is called the trigger sensitivity and is usually set up by the respiratory therapist. The Fraction of Inspired Oxygen (FiO2): This is the percentage of oxygen in the air mix that is delivered by the ventilator during each respiratory cycle. Increasing the FiO2 will increase the patient's oxygen saturation. Positive End Expiratory Pressure (PEEP): The positive pressure that will remain in the system at the end of the respiratory cycle (end of expiration) is the PEEP. As with FiO2, PEEP can be used to increase oxygenation. By Henry's law, we know that the solubility of a gas in a liquid is directly proportional to the pressure of that gas above the surface of the solution. This applies to mechanical ventilation in that increasing PEEP will increase the pressure in the system. This increases the solubility of oxygen and its ability to cross the alveolocapillary membrane and increase the oxygen content in the blood. PEEP also can be used to improve ventilation-perfusion mismatches by opening or "splinting" airways to improve ventilation throughout the system. Apart from these four main parameters, the way the ventilation is delivered also can be adjusted. For every setting, regardless of the rate and volume, the breath will always be delivered to the patient in the same way. The ventilator allows flow change; the flow may be constant through the inhalation (square waveform) or decelerating as the breath is delivered (ramp waveform). 1. Square waveform will allow for a faster delivery of the inspiration, decreasing the inspiratory time and increasing the expiratory time. This can be useful for patients with asthma or chronic obstructive pulmonary disease or in cases of increased RR to prevent auto-PEEP and allow for enough time for exhaling. 2. Ramp waveform will decrease the flow as the delivered volume increases. This usually is more comfortable for the patient and allows for a better volume distribution and equalization in patients with heterogeneous lung such as with ARDS. The speed at which this flow is delivered also can be controlled by setting inspiratory and expiratory times[3]. This can be adjusted for patient comfort or to prevent auto-PEEP. After the inspiration is finished, the expiratory valve of the ventilator opens and the air is allowed to come out until the pressure in the system reaches PEEP. (figure 1)
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