To round out the year, here are three tutorials on the blood gas machine, blood gas analysis and the blood gas printout.
The first tutorial looks at how oxygen is measured using the Clark Electrode on the blood gas analyser and demonstrates the importance of co-oximetry in modern blood analysis. From that the fractional saturation of hemoglobin with oxygen is derived.
The second tutorial explains the Glass Electrode that measures pH and PCO2. Subsequently I cover problems you might encounter with blood gas sampling. If you don’t want to watch the technical stuff, I strongly recommend you scroll to the middle of the tutorial (12 minutes in) as it covers information that all healthcare practitioners must know.
The final tutorial looks at all of that other data that appears on blood gas printouts that you may never have understood – and it can be really confusing – DERIVED or calculated variables (bicarbonate, temperature correction, TCO2, O2 content, Base Excess, Standard Bicarbonate, Anion Gap etc.). I cover both the Radiometer ABL machines and the GEM 5000. I guarantee you’ll learn something.
Here are three tutorials on inspiratory and expiratory CO2 gas analysis. Tutorial 1 looks at Capnometry and the process behind measuring CO2 in exhaled gas. I cover mainstream CO2 analysis and explain why the end tidal CO2 (EtCO2) may be high or low. Tutorial 2 addresses the Capnograph, the trace and anomalies of the Capnograph at the time of intubation. I also explain Sidestream and Microstream CO2 and gas analysis. The final tutorial will be very helpful to anesthesiologists, particularly those taking exams: I go through a series of abnormal Capnographs, explaining why they are abnormal. I guarantee that you will 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.).
When patients arrive in the ICU, as soon as they are settled, an AP portable chest x-ray (CXR) is ordered. That x-ray will look different from one done in the radiology department, as the patient is likely semi-recumbent, may be in expiration and the projection is different than from an CXR taken from the back.
The lung has 5 lobes – three on the right and two on the left (the left lung is smaller to accommodate the heart). Each one of these lobes is connected to the trachea by one major airway, that may become plugged off, resulting in atelectasis or collapse of the lobe. As we often need to remove mucus plugs or other material causing these obstructions, it is imperative that you are able to identify the particular lobe that has collapsed. I sequentially go through each lobe of the lungs.
To identify a collapsed lung lobe I suggest that you follow the “Ds” listed in the image below.
In addition, radiologists often report lung units as being “consolidated.” This is a catch all phrase that identifies the presence of liquid or semisolid material in airspaces – infectious exudate, blood, mucus, water-fluid, gastric contents etc. You should be able, with you anatomical knowledge, to identify which lung lobe is affected, in particular if you are planning on performing a broncho-alveolar lavage. @ccmtutorials
One of the most intimidating things about entering the ICU for the first time is the “life support machine” – the mechanical ventilator. Although I have posted an extensive series of tutorials on Mechanical Ventilation, covering most of the modes, oxygen therapy and applied respiratory physiology, I have attempted, in this tutorial, to distill everything to the “least you have to know” in 40 minutes. Keep in mind that modern machines look more like iPhones, and are far easier to use than the devices I grew up with that looked to me, on day 1, like something in the cartoon below.
I start with a discussion about the difference between normal breathing, CPAP and Positive Pressure Ventilation (PPV). PEEP is, effectively, CPAP during PPV. I then go on to discuss pressure limited modes of ventilation; worldwide this are the most widely used modes in ICU. I limit my discussion to Pressure Assist Control, Volume Guaranteed Pressure Control (VG_PC) and Pressure Support Ventilation (PSV). VG-PC is a popular and flexible option as an ICU’s default mode. However, as it is a pressure controlled mode, there is significant variability in tidal volume and airway pressure from minute to minute.
Several important rules are emphasized: the tidal volume should, in general be lower than 6ml/kg of ideal body weight, the plateau pressure lower than 30cmH2O and the driving pressure lower than 15cmH2O. I introduce the Spontaneous Breathing Index (SBI = RR/TV in L). The magic number is 100. We use the SBI to determine the success of weaning on PSV.
Volume Controlled Ventilation is the predominant mode use in the Operating Rooms (Theatres), and Volume Assist Control is a popular mode in North America. In ICU you must set a peak inspiratory flow and be aware that this may be insufficient during assisted breaths and lead to dys-synchrony. Volume Control is often used in ARDS to “lock in” the Tidal Volume (TV) but the operator must be aware that the TV that matters is not what is dialed up on the ventilator, but what the patient exhales.
I go on to discuss how to assess the patient on invasive mechanical ventilation, by looking at whether they are breathing spontaneously, in which case we determine whether they are suitable for a Pressure Support wean or not, or whether or not there is a problem with oxygenation (increase FiO2, PEEP, Mean Airway Pressure and seriously consider Prone Positioning) or Ventilation (increase Respiratory Rate, Tidal Volume or both, reduce PEEP).
The final part of the tutorial looks at Non Invasive Ventilation (NIV), and I explain how, in general we only use 2 modes on standalone devices – CPAP and Spontaneous Timed (S/T). The latter is similar to PSV with a backup rate, but I point out that instead of PEEP+PS the breath is EPAP + IPAP and IPAP is not built upon IPAP, as is the case with PSV. If one is delivering NIV on an ICU ventilator, then “leak” adjustment or “leak sync” should be used.
This tutorial looks at the assessment of PaCO2 on the blood gas and how it interfaces with the pH and the Bicarbonate (HCO3-). The control of PaCO2 is a major physiological mechanism for maintaining homeostasis. CO2 production by the body must be balanced by CO2 elimination. PaCO2 rises when there is hypoventilation, this results in a fall in pH and an rise in HCO3 and this is called “Acute Respiratory Acidosis.” If the patient hyperventilates, the PaCO2 and the HCO3 fall and the pH rises: this is “Acute Respiratory Alkalosis.” When there is chronic CO2 retention, the body adapts by wasting Chloride in the urine, the pH normalizes and the HCO3 rises substantially.
Any patient who is intubated, or who has a laryngeal mask in situ, must undergo end tidal (end of exhalation) CO2 monitoring. The capnography waveform is worth evaluating, particularly if airway obstruction or increased resistance is suspected.
Included in this tutorial are various rules of thumb that you can use to determine the Respiratory Acid Base Status of the Patient – including the “Rule of 40.”
Traditionally rules of thumb regarding the changes in PaCO2 and Bicarbonate in acid base balance have utilized mmHg. Unfortunately, in large tracts of the world, particularly in Europe, blood gases are reported in the SI unit kPa. This tutorial is for those people. I cover various acid base abnormalities – pH vs PaCO2, acute and chronic respiratory acidosis, respiratory alkalosis, metabolic acidosis and alkalosis and go through the various acid base rules of thumb using kPa, with examples. I guarantee you’ll learn something.
Rules:
Rule 1 H+ vs pH: a 1nmol/L increase in [H+} results in a 0.01 fall in pH
Rule 2 PaCO2 in Apnea: In apnea the PaCO2 rises by 1.5kPa in the first minute and by 0.5kPa per minute thereafter (this reduces progressively over time to 0.2-3kPa)
Rule 3 PaCO2 vs pH: For every 1kPa increase in the PaCO2 the pH falls by 0.06
Rule 4 PaCO2 vs HCO3 in Acute Respiratory Failure: For every 1kPa increase in the PaCO2, the HCO3 rises by 1mmol/L
Rule 5 PaCO2 vs HCO3 in Chronic Respiratory Failure: For every 1kPa increase in the PaCO2, the HCO3 rises by 3mmol/L and the Chloride falls by an equal value.
Rule 6 PaCO2 vs HCO3 in Acute Respiratory Alkalosis: For every 1kPa increase in the PaCO2, the HCO3 falls by 2mmol/L
Rule 7 PaCO2 versus Base Deficit in Acute Metabolic Acidosis: For every 1mmol/L increase in the Base Deficit (-BE e.g. from -1 to -2), the PaCO2 falls by 0.13kPa e.g. if the BD is -10 the PaCO2 will fall by 1.3kPa from 5.3 to 4
Rule 8 PaCO2 vs HCO3 in Chronic Metabolic Alkalosis (in ICU): For every 1mmol/L increase in the Base Excess (or HCO3) the PaCO2 increase by 0.13kPa e.g. if the BE is +10 then the PaCO2 will increase from 5.3 to 6.6
Proportional assist ventilation has been around in various shapes and forms since the late 1990s. The most advanced current iteration – PAV+ – is unique to Puritan Bennett ventilators. It is a closed loop mode of ventilation. That means that the ventilator dynamically changes the level of assistance that the patient receives in response to patient effort. PAV+ is neither volume controlled nor pressure controlled but is patient (and operator) controlled. The operator adjusts the percentage support that the ventilator delivers to the patient. The patient breathes – triggering the ventilator – and the ventilator amplifies the patient’s breath. Consequently the more work that the patient does to generate muscular effort the more work the ventilator performs to match the patient’s workload.
It has been known for some time that the diaphragm becomes both atrophic and dysfunctional in acute critical illness, in particular due to disuse during control of mechanical ventilation. In most assisted modes, all the patient needs to do is trigger the ventilator. Patient workload may be inversely proportional to ventilator workload. Frequently the patient’s diaphragm and ventilator are out of synchrony.
PAV+ is patient triggered and flow cycled so it should be seen as a form of pressure support ventilation. PAV+ contrasts with standard pressure support in that the degree of support changes from breath to breath and indeed within breath depending on patient effort. Pressure support delivers a fixed airway pressure for every single breath irrespective of patient effort. Consequently if we map patient effort to ventilator workload there is only one point where the two will intersect. Conversely in proportional assist ventilation the workload of the ventilator and the workload of the patient increase and decrease linearly.
PAV+ works by utilizing very high quality flow and pressure sensors. The ventilator determines when the patient initiates the breath and when the breath is completed. Having instructed the ventilator what proportion of work of breathing that the ventilator should perform, one observes, using a work of breathing bar, if the patient is doing satisfactory work or whether they need to increase or decrease their workload. The work of breathing (WOB) is determined by the ventilator by measuring compliance, resistance and intrinsic peep dynamically every 9 to 12 breaths. As such a Green Zone between 0.3 and 0.7 joules per litre is indicative of ideal work of breathing for the patient; I call this the “sweet spot.” As long as the patient’s WOB resides within the sweet spot of the toolbar the bedside clinician can be satisfied that the patient is both comfortable and safe.
As the tidal volume relates to the patient’s neural activity that results in diaphragmatic power one should not be unduly concerned about high or low tidal volumes in this mode.
If one wishes to put a patient on proportional assist ventilation it is imperative that one determines if the patient is breathing spontaneously and taking an adequate minute ventilation prior to using this mode. The reason for this is that there is no backup rate in PAV+. Usually one starts with 70% support: that means 70% of the work of breathing is performed by the ventilator on 30% by the patient. After a couple of minutes, once one has observed the work of breathing bar, one can make adjustments either to increase the workload of the ventilator or to reduce it by keeping the patient within that Green Zone sweet spot. Generally failure of the patient to settle on this mode is manifest by a respiratory rate of more than 35. Once the patient has been on 20% support for an hour or more and is awake, obeying commands, protecting their airway, and not being suctioned frequently then the patient can be extubated.
Studies that have looked at PAV+ versus pressure support have indicated that weaning is more rapid with PAV+.
This tutorial is about weaning from mechanical ventilation. This is not an easy topic because every professional in the ICU has their own weaning method and their own opinions regarding how best to wean and liberate patients. The literature is unhelpful. Some patients, for example those who have been intubated for a brief period of time, can be awoken and the tube removed after a couple of spontaneous breaths. Other patients require careful multidisciplinary activity over weeks to months to liberate. This tutorial focuses on the in-between group patient who have been intubated for a week or so, who require both clinical and mechanical assessment of their ability to wean and liberate from the ventilator.
Generally the first intervention in weaning is to change the patient over to a spontaneous breathing mode – pressure support or volume support and ensure that alveolar ventilation is adequate to maintain CO2 clearance.
Then a number of clinical and mechanical assessments can be made: is the patient awake, do they have a cough, are they triggering adequately, what is their rapid shallow breathing index (RSBI)? One can estimate muscle strength by performing an occlusion test – either a partial occlusion (P0.1) or a longer occlusion (NIF). Once the patient is assessed as being a candidate for weaning, then one can perform a spontaneous breathing trial (SBT) that is either supported (PS, VS, ATC) or unsupported (T-piece, C-circuit, Trach mask, Swedish Nose).
If the SBT is successful after 90 minutes – extubate the patient. SBTs may fail due to worsening hypoxemia, hypercarbia or hypocarbia, respiratory distress (increase RSBI or use of accessory muscles) or cardiovascular instability (hypotension, hypertension, tachycardia, bradycardia, arrhythmias) or falling levels of consciousness, agitation or acute delirium.
Is there anything more frustrating in the ICU when you decide to start weaning a patient – they look like they’re assisting the ventilator. You switch them over to a “spontaneous” mode and then……nothing…..no breaths….eventually the backup starts.
This tutorial is about triggering of mechanical ventilation. I will revisit how patients trigger the ventilator, the different systems used and introduce I-Sync – a new method of triggering.
Finally I will discuss the problem of Auto-PEEP and explain why, in the setting of Auto-PEEP, there is no point fiddling with the flow by or negative pressure.
ORtoICU 