Abstract
Introduction There is an inverse relationship between cardiac output and the central venous-arterial difference of partial pressures of carbon dioxide (pCO2 gap), and pCO2 gap has been used to guide early resuscitation of septic shock. It can be hypothesized that pCO2 gap can be used outside the context of sepsis to distinguish type A and type B lactic acidosis and thereby avoid unnecessary fluid resuscitation in patients with high lactate, but without organ hypoperfusion. Methods We performed a structured review of the literature enlightening the physiological background. Next, we retrospectively selected a series of case reports of nonseptic critically ill patients with elevated lactate, in whom both arterial and central venous blood gases were simultaneously measured and the diagnosis of either type A or type B hyperlactataemia was conclusively known. In these cases, we calculated venous-arterial CO2 and O2 content differences and pCO2 gap. Results Based on available physiological data, pCO2 can be considered as an acceptable surrogate of venous-arterial CO2 content difference, and it should better reflect cardiac output than central venous saturation or indices based on venous-arterial O2 content difference. In our case report of nonseptic patients, we observed that if global hypoperfusion was present (i.e., in type A lactic acidosis), pCO2 gap was elevated (>1 kPa), whilst in the absence of it (i.e., in type B lactic acidosis), pCO2 gap was low (<0.5 kPa). Conclusion Physiological rationale and a small case series are consistent with the hypothesis that low pCO2 gap in nonseptic critically ill is suggestive of the absence of tissue hypoperfusion, mandating the search for the cause of type B lactic acidosis rather than administration of fluids or other drugs aimed at increasing cardiac output.
Highlights
Differential diagnosis of elevated blood lactate is the daily bread and butter of all clinicians looking after critically ill patients
In order to support this hypothesis, we present a series of patients in whom pCO2 gap was measured, and the cause of lactic acidosis was conclusively known
In very early hours of the morning, he suddenly developed signs of haemorrhagic shock with tachycardia 150/ min, haemoglobin drop from 129 to 92 g/L, and hypotension with an increase of noradrenalin dose from 0.4 to 1.1 μg·kg− 1·min− 1. Lactate at this stage was 1.4 mM, ScvO2 68%, pCO2 gap was 1.02 kPa, and respiratory exchange ratio (RER) 1.86
Summary
Differential diagnosis of elevated blood lactate is the daily bread and butter of all clinicians looking after critically ill patients. We hypothesize that the difference in carbon dioxide partial pressure between central venous and arterial blood (pCO2 gap) can be a useful aid in the differential diagnosis of elevated lactate outside the context of sepsis. Because of 20 times higher diffusibility of CO2 as compared with O2 [22, 23] central venous blood can have normal or high ScvO2 (due to arterialized blood form shunts), whilst CO2 content is elevated proportionally to the degree of peripheral tissue hypoperfusion as shunting capillaries are still capable to drain CO2 from the hypoperfused tissues.
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