Monitoring the adequacy of tissue oxygenation in critically ill patients is a challenging task 1. Despite extensive research, tissue capnometry remains the only clinically relevant approach to monitoring regional perfusion and oxygenation. Elevation in tissue partial carbon dioxide tension (PCO₂) might represent a better surrogate of hypoperfusion than other systemic and regional parameters 23.

During the past 20 years a large body of clinical evidence was developed supporting the usefulness of gastrointestinal PCO₂ tonometry for the monitoring of tissue perfusion 4. Gastric tonometry can readily be performed in the critically ill and gives significant information on outcomes 56. It may also be a helpful guide in therapeutic decision making 7. Nevertheless, technical difficulties and frequent artefacts have dampened the initial enthusiasm 8. In an attempt to overcome the limitations of gastric tonometry, sublingual capnometry was then developed 9. Despite initial interest and potential advantages, this technique has neither been completely validated nor widely used 10.

More recently, tissue perfusion has been assessed with continuous monitoring of bladder PCO₂ using fibreoptic sensor technology 1112, yielding interesting findings in experimental models of ischaemia/reperfusion. Although the equipment required may be expensive, bladder PCO₂ can readily be measured via a urinary catheter incorporating a silicone balloon. Our goal in the present study was to compare bladder PCO₂ measured using saline tonometry versus other tissue and venous PCO₂ values. Our hypothesis was that bladder PCO₂ will track ileal PCO₂ during ischaemia and reperfusion.

The main finding in the present study is the consistent expression of hypercapnia during low flow states. High PCO₂ values were evident in veins, ileum and even urinary bladder. In contrast to the other carbon dioxide gradients, bladder ΔPCO₂ remained elevated after reperfusion.

The prevention, detection and correction of tissue dysoxia are main goals in the management of critically ill patients 1. Gastric tonometry has been considered the only available method to track tissue oxygenation in the clinical arena 1. However, tissue hypercapnia is not just a marker of dysoxia but is also an indicator of hypoperfusion. Tissue and venous PCO₂ remain unchanged in states of tissue dysoxia with preserved blood flow, such as hypoxic and anaemic hypoxia 131415. On the other hand, in a high flow state, such as sepsis, measurements of intramucosal acidosis remain helpful because of the frequent presence of microcirculatory derangements 16. Moreover, increased blood flow may correct tissue hypercapnia in endotoxaemia 17.

Although most studies dealing with tissue capnometry have focused on the gastrointestinal tract, others have been performed in muscle 1819, renal parenchyma 2021 and subcutaneous tissue 22. Few studies have assessed urinary PCO₂ for the monitoring of tissue oxygenation. Lin and coworkers 23 measured urinary PCO₂ in critically ill patients to evaluate the adequacy of perfusion. Urinary PCO₂ was higher in shock than in control patients (79 ± 10 mmHg versus 43 ± 2 mmHg; P < 0.0001). Lang and colleagues 11 measured urinary bladder gases using a fibreoptic sensor in a swine model of ischaemia/reperfusion. After 30 min of aortic clamping bladder PCO₂ increased from 57 ± 5 mmHg to 117 ± 7 mmHg, and it returned to baseline after 60 min of reperfusion. Clavijo-Alvarez and coworkers 12 studied this issue in a model of haemorrhagic shock in which pigs were bled and kept at a mean arterial pressure of 40 mmHg until decompensation. Animals were then resuscitated with shed blood plus lactated Ringer's solution and observed for 2 hours. In contrast to our findings, those investigators found greater increases in bladder PCO₂; basal PCO₂ was 49 ± 6 mmHg and increased to 71 ± 7 mmHg at the end of shock. Jejunal intramucosal PCO₂ exhibited similar behaviour.

These differences might be related to the use of different animal species but also, and primarily, to the longer period of shock. Because the pigs in the study by Clavijo-Alvarez and coworkers 12 reached a lower cardiac output than did the sheep in our study, changes in surrogates of hypoperfusion such as base excess bicarbonate and bladder PCO₂ were more pronounced. Nevertheless, gut intramucosal acidosis was similar in both studies, which might be related to the greater vulnerability of sheep intestinal mucosa to hypoperfusion. In addition, differences might be explained by diverse surgical preparations and methods for measuring intramucosal PCO₂. Clavijo-Alvarez and coworkers completely isolated the bladder, and the PCO₂ sensor was encased within the mucosa so that they could avoid interference. In this way, the measurements should reflect those from the bladder wall more accurately. Furthermore, they used a more sensitive method to measure PCO₂. Nevertheless, it is difficult to reproduce this type of measurement in patients, and our methodology seems more suitable for clinical application.

Although tissue and venous hypercapnia is a widespread consequence of hypoperfusion, our experiments reveal that the increase in PCO₂ is higher in ileal mucosa than in bladder mucosa and mixed and mesenteric venous blood. The underlying mechanism producing this preferential elevation in ileal ΔPCO₂ might be related to particular characteristics of villi microcirculation. Countercurrent circulation might induce a functional shunt that could place distal microvilli segments at ischaemic risk 24. There is some controversy regarding the meaning of intramucosal PCO₂; specifically, does it reflect whole wall or superficial mucosal perfusion? An ileal ΔPCO₂ greater than the Pvm-aCO₂ suggests that tonometric PCO₂ reflects mucosal rather than transmural PCO₂. On the other hand, the similar increase in bladder–arterial and systemic and intestinal venoarterial PCO₂ gradients suggests the presence of similar degrees of hypoperfusion. As previously described 25, the fraction of cardiac output directed to gut (superior mesenteric artery blood flow/cardiac output) decreased during ischaemia (from 0.23 ± 0.06 to 0.16 ± 0.07; data not shown). However, this was not enough to produce differences between systemic and intestinal venoarterial PCO₂ gradients.

Another interesting finding of this study lies in the persistence of bladder intramucosal acidosis during reperfusion. Recent studies indicated that ischaemia/reperfusion can cause acute inflammation and contractile dysfunction of the bladder 26. Bajory and coworkers 27 demonstrated severe microcirculatory derangements such as decreased functional capillary density, red blood cell velocity, venular and arteriolar diameter, and enhanced macromolecular leakage after bladder ischaemia/reperfusion. We speculate that these microcirculatory alterations might lead to decreased carbon dioxide removal. Again, differential susceptibility to injury between species could explain differences from other studies 1112.

Limitations of the present study could be related to the method of measurement of bladder PCO₂. First, tonometric measurement of PCO₂ has drawbacks 8. Second, urine itself could potentially influence tonometric PCO₂ beyond perfusion deficits. In fact, urine can have variable carbon dioxide content, resulting, for example, from different grades of carbonic anhydrase inhibition or from systemic bicarbonate administration 28. Actually, failure to observe an appropriate increase in urinary-blood PCO₂ during bicarbonate loading has been employed as an index of reduced distal nephron proton secretion in distal renal tubular acidosis 28. Changes in systemic oxygenation can also modify urine composition. Moriguchi and coworkers 29 have showed that urinary bicarbonate, calculated from urinary PCO₂ and pH, increases after anaerobic exercise. Those authors related these findings to systemic carbon dioxide production and later urinary excretion 29. They also described a circadian rhythm in urinary bicarbonate elimination 30. Moreover, an elevated bladder ΔPCO₂ could also represent a late manifestation of renal hypoperfusion. Further studies are needed to clarify the influence of renal carbon dioxide excretion on bladder PCO₂.

Our data suggest that bladder ΔPCO₂ could be a useful indicator of tissue perfusion. However, intestinal ΔPCO₂ is the more sensitive carbon dioxide gradient for monitoring low flow states. Further studies are needed to establish the definitive monitoring value of urinary PCO₂.

• Urinary bladder ΔPCO₂ may be a useful indicator of tissue perfusion, but intestinal ΔPCO₂ is the more sensitive carbon dioxide gradient for the monitoring of low flow states.

• The fact that the observed ileal ΔPCO₂ was greater than Pvm-aCO₂ suggests that tonometric PCO₂ reflects mucosal rather than transmural PCO₂.

CaO₂ = arterial oxygen content; CvmO₂ = mesenteric venous oxygen content; CvO₂ = mixed venous oxygen content; DO₂ = oxygen transport; PCO₂ = partial carbon dioxide tension; PO₂ = partial oxygen tension; Pv–aCO₂ = mixed venous-arterial PCO₂ difference; Pvm–aCO₂ = mesenteric venous–arterial PCO₂ difference; Q = cardiac output; VO₂ = oxygen consumption.

The author(s) declare that they have no competing interests.

AD was responsible for the study concept and design, analysis and interpretation of data, and drafting of the manuscript. MOP, VSKE, GM and HSC performed acquisition of data and contributed to drafting of the manuscript. BM and ML conducted blood determinations and contributed to drafting of the manuscript. MB and GF performed the surgical preparation and contributed to the discussion. EE helped in the drafting of the manuscript and conducted a critical revision for important intellectual content. All authors read and approved the final manuscript.