This tutorial looks at hypernatremia and hyperosmolar syndrome. Hypernatremia is usually caused by three things: 1) Profound dehydration, 2) Too much sodium intake – most of the time this is due to over-resuscitation with isotonic fluids, 3) Central or Nephrogenic Diabetes Insipidis. I explain how to calculate water deficit and water replacement and how to evaluate and treat patients with diabetes insipidus. @ccmtutorials
I often wonder if the obsession amongst physicians regarding the prevention of Osmotic Demyelination Syndrome (ODS or Central Pontine Myelinolysis – CPM) results in adverse patient outcomes – for example a greater incidence of iatrogenic complications, prolonged length of stay etc.
In this discussion, I look at the history of ODS/CPM, how it became identified with rapid correction of hyponatremia and what patients are at particular risk of this disorder. In the second part of the discussion I address the re-ignited controversy about Sodium/Osmolality correction subsequent to the publication of a major study in NEJM Evidence in 2023.
Ultimately each clinician must make up their own minds on the evidence that is available. It appears to me that there is little or no risk of ODS/CPM in patients with acute hyponatremia, symptomatic or not, and those with a plasma sodium of greater than 120mmol/L. Patients with Sodium levels below 105mmol/L, alcoholics or cirrhotics and malnourished patient appear to be at very high risk. Finally attention should be paid not only to the speed of correction, but where the plasma sodium levels ends up. In many studies – ODS/CMP is a late diagnosis and patients, at the time of diagnosis are hypernatremic (greater than 145mmol/l) – although the rise in Sodium/Osmolality may appear slow over days or weeks.
This discussion came about following a discussion with my colleague, Dr Bairbre McNicholas. It focuses principally on the problem of hyponatremia in elderly patients and undernourished alcoholics. I explain why the lack of dietary salt and protein intake massively inhibits water excretion resulting in hypotonic hyponatremia, often with fluid overload. The traditional approach to managing hyponatremia – fluid restriction – frequently fails because it is a problem of solute “underload” rather than water overload. Commencing iv fluids may precipitate a rapid and potentially dangerous diuresis – hence the most effective therapy for these patients is the FEED them.
I guarantee you’ll learn something.
This tutorial is about the Syndrome of Inappropriate Diuresis. SIAD also known as SIADH is a form of hypotonic hyponatremia associated with iso- or hypervolemia, high urinary osmolality and high urinary sodium. Traditionally this is associated with high levels of circulating vasopressin (antidiuretic hormone – ADH), that may be associated with sepsis, acute critical illness, pneumonia or mechanical ventilation. However, SIAD is also associated with a variety of brain injuries, drugs (SSRIs and anticonvulsants) and a variety of cancers.
Treatment of symptomatic SIAD is with hypertonic saline (150ml of 3% over 20 minutes). Chronic or asymptomatic SIAD is treated with fluid restriction (determined by the Furst equation uNa + uK/pNa – if the result is less than1 the patient is suitable for fluid restriction).
Alternative inexpensive therapies include Urea (30 to 60mg per day), salt tablets plus frusemide or demeclocycline.
Vaptan agents, the block the V2 receptors, appear to be effective for long term therapy. Tolvaptan is available commercially but quite expensive for the majority of patients.
Cerebral salt wasting is associated with subarachnoid hemorrhage. It shares the same blood and urinary profile as SIAD(H) but is associated with hypovolemia. The disorder is self limiting and is treated with isotonic fluids.
This is Tutorial 4 in the Acid Base Series – on the topic of Metabolic Acidosis. The tutorial is based on a single blood gas – a random sample that was handed to me in the ICU recently. Blood Gas Used in This Tutorial: pH 7.19 PaCO2 32mmHg (4.1kPa) HCO3- 13.1 BE – 16.5 AG 20 Na+ 126 K+ 3.1 Cl- 96 Lactate- 7.2 Ketones- 0.6mmol/L Albumin 21g/L Creatinine 3.3mg/dl (293mmol/l)
Metabolic Acidosis is characterized by an increase in the relative ratio of strong anions to strong cations in the plasma. The PaCO2 and the Bicarbonate fall in a predictable manner. It is possible to compute the effectiveness of respiratory compensation for metabolic acidosis by using the Winters equation.
To understand the mechanism of metabolic acidosis – caused by accumulation of mineral (Chloride) and organic (Lactate, Ketones, Metabolic Junk Products) anions – one needs to apply the law of Electrical Neutrality. All of the positive charges must equal all of the negative charges. As Bicarbonate is consumed in the process of buffering metabolic acidosis, the change in the Bicarbonate level (downwards) can be used to quantify the degree of acidosis. This is important because the pH may be within the normal range due to respiratory compensation. Be aware that the HCO3- quantum that is displayed on a blood gas is derived from the pH and PCO2 by the Henderson Hasselbalch equation.
Unfortunately, because respiratory abnormalities may complicate the diagnosis of metabolic acidosis, and pH and PCO2 are altered by changes in temperature, the precision of a single reading of PCO2 and HCO3- may be poor. Consequently, the Standard Base Excess was developed to excise the respiratory component from the change in bicarbonate. Again it is a derived variable and may be imprecise. Nevertheless, BE (or 1-BE the Base Deficit BD) is a terrific scanning tool to identify the presence of a metabolic acidosis (BD) or alkalosis (BE). It is defined as the amount of strong cation (BD) or strong anion (BE) required to bring the pH back to 7.4 when the temperature is 37 degrees Celcius and the the PaCO2 is 40mmHg or 5.3kPa.
The Base Deficit does not indicate the source of the acidosis, but it can be recalculated to remove the impact of the [Na+], the [Cl-], the body water and the serum Albumin (and the Lactate) to determine the Base Deficit Gap – indicative of the quantity of Unmeasured Anions (UMA, Ketones, if not measured, and Renal Acids (metabolic junk products – MJP).
Traditionally clinicians use the Anion Gap to determine whether a patient has a Hyperchloremic Acidosis (no gap) from a UMA acidosis. I find this quite a dated concept. If the [Cl-] exceeds 105 and the plasma Sodium is normal, the patient has a Hypercloremic acidosis. We can easily measure Ketones and Lactate. The AG is imprecise and should be adjusted for the Albumin level, which tends to hover around 25g per liter in critically ill patients (narrowing the Gap and alkalinizing the patient). I do think if you are calculating the AG that you must include the K+ on the Cation side, the Lactate on the Anion side and adjust the Albumin.
The Strong Ion Gap is a more advanced, more precise and more cumbersome version of the AG. Regardless of the approach, one eventually ends up with a quantify of unidentifiable anions (SIG) that may be of medley origin (metabolism, poisoning etc). It is my opinion that it is useful to tease out all of the different acidifying and alkalinizing processes (the Fencl approach) to determine what is going on with the patient. All of these calculations can be done in seconds with smartphone apps and spreadsheets.
I guarantee you will learn something. @ccmtutorials http://www.ccm-tutorials.com
This is the first tutorial in a new series on acid base balance. This is not a beginners course – although I will attempt to cover everything the bedside clinician should know, particularly in the ICU. I have been teaching and writing about acid base for more than 25 years and I find it disappointing how many clinicians fail to understand even the basics of physical chemistry that underpin this topic.
This course is built on the foundation of physical and electrochemistry (all acid base reactions occur in water, all ionizing processes must be accounted for electrical neutrality must always hold.
The first tutorial is titled “The Power of Hydrogen” and it looks at the chemistry of water, the tendency for water to dissociate into moieties that display hydrogen ions and hydroxyl ions, and how temperature impacts that dissociation equilibrium. It is imperative that you understand that there are effectively no free protons (hydrogen ions) in the extracellular fluid. When we measure [H+] or its corollary, pH, we are measuring hydrogen ion ACTIVITY not hydrogen ion concentration. I explain the origin of pH and how pH varies with temperature despite the aqueous solution remaining chemically neutral. I explain the history of acid base, starting with O’Shaughnessy and then moving on to Arrhenius and Bronsted and Lowry. It is easier to understand acid base if one utilizes the Arrhenius theory, but the concepts are fully consistent with the BL approach, because water is amphiprotic (it can act as a “proton donor” or “proton acceptor.”
I explain how blood gas machines measure pH and why pH (and PCO2) should almost always be measured at 37 degrees Celsius. At the end of the tutorial I explain the terms acidosis and alkalosis, respiratory and metabolic. @ccmtutorials http://www.ccmtutorials.org
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.
I guarantee you will learn something. @ccmtutorials www.ccmtutorials.org
Expiratory dysynchrony is a major unrecognized problem in critical care. Usually it takes one of two forms: a terminal upstroke on the pressure waveform, indicating pressure cycling (breath too long) or a W shaped anomaly in the expiratory flow waveform – indicative of the breath being too short or too long. I call this the “Wibbly Wobbly Waveform”.
This tutorial looks at expiratory dysynchrony – why it happens and how to make adjustments to resolve the problem. I also introduce a relatively new technology: IE Sync.
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.
@ccmtutorials http://www.ccmtutorials.org
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.
ORtoICU 