Monthly Archives: June 2023

Pressure Controlled Ventilation – The Fundamentals Part 1

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It is time to discuss Pressure Controlled Ventilation. In general if a patient has normal lungs or minimal disease, it really does not matter what mode of ventilation you use, pressure or volume controlled. However, there are some major advantages to using Pressure Control – principally in Acute Hypoxic Respiratory Failure. There are also many disadvantages. This is the first of two tutorials that cover the fundamentals of Pressure Control. I start with a discussion of the terminology that I will be using – the Pressure Limit (PL), the Inspiratory Pressure (IP), the Driving Pressure (DP)/Inspiratory Ramp, the Inspiratory Time (Ti) and the Expiratory Time (Texp). Pressure Controlled Ventilation (PCV) is pressure targeted/limited and volume variable. Breaths are time cycled – in inspiration, expiration or both. The flow pattern is always decelerating.

Following the introduction of a clinical scenario – a patient who is developing ARDS, I describe the process of PCV. I explain that tidal volumes are variable in all settings and all modes of PCV and later describe how changing patient position, chest wall elastance and airway resistance can all impact the tidal volume. I discuss why pressure control is the best option for mechanically ventilating children (particularly where there is no endotracheal tube cuff and a significant air leak) and why you need to pay attention to the rise time and respiratory rate. Finally I discuss the major disadvantages of using PCV. I guarantee you’ll learn something!
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Positive End Expiratory Pressure – Phasic Shunting, Auto-PEEP & ARDS

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In the previous tutorials I explained how hypoxemia results from low lung volumes, resulting in low functional residual capacity, airway closure and atelectasis. We looked at the mechanisms by which CPAP reduces the work of breathing in obstructed airways and how, following lung recruitment, PEEP maintains FRC.

In this tutorial I elaborate on these themes. I look at the problem of phasic V/Q mismatch (shunt) during expiration and how it may cause dis-correlation between pulse oximeters and blood gasses. PEEP prevents this at the expense of increasing dead space and negatively impacting ventilation. Optimal PEEP should restore lung compliance – compliance is low with low and high lung volumes. Compliance may also appear poor in pressure control when there is clinically significant auto-PEEP: the ventilator cannot distinguish auto-PEEP from driving pressure and lower than expected tidal volumes may result.

I explain the concept of the “Waterfall” effect to overcome Auto-PEEP. Finally, in our first visit to ARDS, I introduce the problem of deciding on optimal PEEP in that setting. I guarantee that you will learn something. @ccmtutorials http://www.ccmtutorials.org

@ccmtutorials

Why We Use CPAP and PEEP (part 1)

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For most of us, the terms CPAP (continuous positive airway pressure) and PEEP (positive end expiratory pressure) have existed for all of our careers. But this was not always the case. Although mechanical ventilation, including the positive pressure variant, was a child of the 1950s – PEEP was not described until the late 1960s and even then was seen as a therapy for postoperative atelectasis in cardiac surgery patients. PEEP subsequently became the mainstay of therapy for hypoxic respiratory failure, but was always used in associated with positive pressure breaths. CPAP was developed in the early 1980s as a therapy for sleep disordered breathing. Over two decades the non invasive CPAP therapy and the invasive ventilation (pressure targeted breaths with PEEP) coalesced such that CPAP became a therapy for hypoxic respiratory failure and congestive heart failure, and pressure support (BiPAP or NIV) became a therapy for sleep apnea.

Strictly speaking PEEP and CPAP are different. It is possible to apply PEEP at end expiration and then commence the next breath from atmospheric pressure (try slapping your hand over your mouth mid expiration – then remove it and take a breath) – spontaneous PEEP. However this is almost never used in clinical practice. In CPAP the patients sinusoidal respiratory pattern persists – but starts and ends at an elevated baseline pressure. In PEEP the positive pressure breath starts and ends at that pressure (i.e. pre inspiration and end expiration). So, these days, in most scenarios PEEP and CPAP are indistinguishable. How they are delivered is, of course, different. Nevertheless they serve the same functions 1. To overcome airway resistance that causes disrupted or obstructed gas flow in expiration; 2. To reduce the work of breathing by reducing the magnitude of negative pleural pressure required to generate a tidal volume; 3. Most importantly – to restore functional residual capacity (FRC); 3. To prevent derecruitment of vulnerable lung units in the posterior dorsal segments of the lungs.

PEEP does not easily re-expand collapsed lung tissue – this is usually achieved by applying a recruitment maneuver (30cmH2O or more for 10 seconds during anesthesia, for 30 seconds in lung injury). The application of PEEP then prevents derecruitment. As such the majority of lung tissue may be re-expanded during anesthesia. This may not be the case in diseased lungs – the principle is to restore a functional residual capacity even if that effectively utilizes the inspiratory reserve volume.  

@ccmtutorials

Why Low Lung Volumes Are Bad

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In previous tutorials I discussed the problem of ventilation perfusion mismatch, intrapulmonary shunt and physiologic dead space. I explained how different injuries to the lung (the 6 s approach – slimy, soggy, sticky etc.) resulted in poorly aerated airways and atelectasis. Before moving on to a discussion about CPAP/PEEP we need to explore the problem of low lung volumes. Although the lungs can hold up to 6L of air – in reality most of the time there is 2-2.5L in the alveoli. This is the resting lung volume that is found at end expiration and results when the tendency for the chest wall to spring outwards is balanced by the tendency for the lungs to collapse inwards. That resting lung volume is established by negative pleural pressure and it represents the expiratory reserve volume and residual volume – together the functional residual capacity (FRC).

FRC is the lung capacity in which most oxygenation takes place, in which lung compliance is highest, airway resistance lowest and pulmonary vascular resistance optimal. Loss of FRC (“low lung volumes”) – results in hypoxemia, increased work of breathing, autopeep and pulmonary hypertension.

During the tutorial I elaborate on lung volumes – how they are affected by position and age, how airway closure becomes a major issue as we get older – particularly in the supine position, and I introduce the volume pressure curve which is essential for understanding dynamic respiratory system compliance.