Here are the first 9 Tutorials in the Series – the majority are useful for Anesthesiologists and Intensive Care practitioners. Every tutorial contains something that you may not have previously known: I guarantee, who ever you are, that you’ll learn something.
This is the final tutorial on the basics of Chest Imaging in the ICU. It includes a discussion about the extrapulmonary tissues – pleural and mediastinal and lung diseases (pneumonia, ARDS, PJP etc.).
The patient is turning purple in the bed, alarms are going off, he is desaturating: he is “fighting the ventilator.” Although a widely used description I believe that it is misused to redefine the problem away from an issue of ventilator operator competency and reframe it as a patient problem. It is not. Most of the time that patient have negative interactions with the ventilator it is a problem of triggering, flow or expiratory cycling. The treatment is not deep sedation and controlled ventilation. The treatment requires skill and nuance, and does not always work. This tutorial looks at inspiration and reasons why it may go wrong.
The most frequently seen patient ventilator dysynchrony is scooping of the pressure waveform, usually associated with flow limited volume controlled ventilation. This can be resolved by increasing the peak flow or changing to pressure control.
In general the ambition to establish a patient on spontaneous assisted ventilation is laudable, but oftentimes we have no idea about what is going on underneath the pressure, flow and volume waveforms. In this tutorial I try and correct the narrative about patient-ventilator interaction when using pressure support. I suggest that volume support in some situations may be a superior approach. I point out that the tidal volume in pressure support has little to do with patient effort and more to do with lung compliance.
I finish the tutorial with a discussion about the inspiratory rise time and explain why you must be careful when using older ventilators.
In the previous tutorial we looked at the problem of high airway pressures and addressed inspiratory airway resistance in two ways: peak to plateau pressure gradient and dynamic and static inspiratory resistance.
In this tutorial we will look at three more ways of assessing airflow resistance: the identification and measurement of Auto-PEEP, Flow-Volume Loops and capnography.
Subsequently I discuss high airway pressure due to low total respiratory system compliance. I explain that when “compliance” is low – this may be a problem with the lungs as well as the chest wall – including the abdomen. I finish with the introduction into this course of Abdominal Compartment Syndrome.
The alarm goes off like an air raid siren – everybody starts to panic – somebody starts to do the saturation countdown. There is nothing quite as distressing for the anesthesiologist or intensivist than for the ventilator to pressure cycle and fail to deliver tidal volumes due to high airway pressure.
Generally high pressures are caused by one of three things – a problem with the equipment (kinked tubing, patient biting the tubing etc.), an airway resistance problem (e.g. bronchospasm) or a pulmonary compliance problem (e.g. consolidation or pulmonary edema) or a combination of these. The first thing that the clinician should do when there pressure alarm goes off – is to silence the alarm and increase the Pmax.
Then go looking for the problem: start at the mouth and work your way back to the machine. If you can’t find a fault, put the patient on a manual breathing circuit and commence ventilation. If the patient is easy to bag, there is a machine problem, if difficult – then there is a problem with pulmonary resistance or compliance. In this first tutorial I look at assessing airway resistance. I do this in two ways. First I discuss peak to plateau pressure gradients and then look at airway resistance: dynamic versus static and how to calculate it. I will finish the discussion in the next tutorial.
This tutorial looks at the pressure waveform in patients undergoing anesthesia or mechanically ventilated in ICU. All modern ventilators will provide a pressure time waveform and display volume pressure (often called “pressure volume” loops).
This tutorial commences with a discussion about pressure-flow loops – to demonstrate the relationship between flow and airway pressure. I then discuss and describe normal airway pressure versus time waveforms.
Subsequently I explore normal and abnormal dynamic volume pressure loops. I briefly discuss static VP-curves and why they are important in ARDS. Finally I demonstrate how you can measure real plateau pressure and static compliance by pushing one button and performing an inspiratory hold.
For the majority of patients admitted to ICU with hypoxic respiratory failure, a conventional ventilatory strategy using volume, pressure or dual control modes with PEEP is usually very effective. With severe lung injury it may be necessary to administer neuromuscular blockade, turn the patient prone and increase the mean airway pressure using PEEP or inverse ratio ventilation (IRV). If these interventions are unavailable, ineffective or inadequate, rescue therapies may be required.
One easily available rescue therapy is Airway Pressure Release Ventilation (APRV). APRV is an extreme version of IRV that looks analogous to using CPAP at high airway pressure levels (e.g. 28cmH2O). Intermittently that high airway pressure is released to remove CO¬ – the release time (less than 1 second) being too short to cause lung derecruitment. Using modern ventilators it is possible utilize the inspiratory capacity to oxygenate the patient (flipping the respiratory cycle from expiration as the primary time of gas exchange to inspiration) and allow the patient to breath spontaneously.
The spontaneous efforts have been shown to improve both gas exchange and cardiovascular performance – but they are not necessary when using this ventilator strategy. Gasping should be avoided. This tutorial covers the science behind APRV, how to set it up, how to use it as part of a ventilator strategy in ARDS, the strengths and limitations of this approach and how to wean it.
This tutorial is about Volume Guaranteed Pressure Support – known generally as Volume Support (VS). This, I believe, is an underused mode of ventilation in most ICUs – who prefer to use pressure support. Essentially you specify the desired tidal volume and the ventilator alters to pressure support from breath to breath to deliver something akin to that volume. There is little precision, but – as pressure support is biologically variable anyway – the presence of a volume averaged set of tidal breaths is reassuring, particularly if the bedside practitioner is distracted or inexperienced. In the tutorial I explain how to set up volume support, what it looks like on three different ventilators – Puritan Bennett, Drager Evita and Servo-i and the strengths and limitations.
This tutorial is about Volume Guaranteed Pressure Controlled (VG-PC) Ventilation – otherwise known as PC-VG, PRVC, VC+ etc. It is a modern mode of ventilation that aims to deliver a desired tidal volume (volume control) using the pressure controlled paradigm (unlimited flow). As such it is a mode that is often labelled “dual controlled” although, in some ways, it is neither volume controlled, pressure controlled nor both. Confused? Most are. I have labelled the mode VG-PC – because that is the best approximation – but volume is not necessarily guaranteed and it is certainly not limited. So why bother using this mode. Simply – it works! As a general use “unit default” mode of ventilation VG-PC has few peers: it is nimble enough to be used as the mode of ventilation of choice for patients admitted to ICU following intubation: postoperatively or with respiratory failure. If the lungs deteriorate – then the mode is versatile enough to deal with it. Being time cycled – mean airway pressure can be easily altered. If compliance or resistance of position changes – then the tidal volume “guarantee” changes the inspiratory pressure from breath to breath to ensure that things remain stable. If the patient breaths spontaneously, using the assist control or SIMV paradigm, flow is increased to meet patient demands. As such it is a very forgiving mode of ventilation, ideal for novices, reassuring to the ICU clinicians. This tutorial explains VG-PC, demonstrates how it is set up in three different ventilators – Puritan Bennetts, Dragers Evitas, Servo I and GE (Aisys) anesthetic machines. I explain the operation of this mode and its strengths and weaknesses. I guarantee you’ll learn something. @ccmtutorials http://www.ccmtutorials.com
This tutorial is about Automatic Tube Compensation (ATC). ATC is a setting that has been included in most modern ventilators. Its aim is to reduce the work of breathing associated with the drop in pressure across the endotracheal tube. The ventilator senses pressure, flow and resistance and changes the pressure during the breath to ensure that the patient has the sensation that they are breathing through their own airway. There are two configurations of ATC – one is as an alternative to pressure support in patients who are essentially weaned from mechanical ventilation: essentially a spontaneous breathing trial. The second configuration is as an accessory to all pressure limited modes – such that the pressure waveform is crafted in inspiration and expiration to reduce the workload of breathing during both phases of respiration. @ccmtutorials http://www.ccmtutorials.org
ORtoICU 