Myocardial tissue CO2 tension detects coronary blood flow reduction after coronary artery bypass in real-time†

S E Pischke; S Hyler; C Tronstad; J Bergsland; E Fosse; P S Halvorsen; H Skulstad; T I Tønnessen

doi:10.1093/bja/aeu381

Myocardial tissue CO2 tension detects coronary blood flow reduction after coronary artery bypass in real-time†

Br J Anaesth. 2015 Mar;114(3):414-22. doi: 10.1093/bja/aeu381. Epub 2014 Nov 12.

Authors

S E Pischke¹, S Hyler², C Tronstad³, J Bergsland², E Fosse⁴, P S Halvorsen², H Skulstad⁵, T I Tønnessen⁶

Affiliations

¹ The Intervention Centre, Division for Emergencies and Critical Care Medicine.
² The Intervention Centre.
³ Department of Clinical and Biomedical Engineering.
⁴ The Intervention Centre, Institute for Clinical Medicine, University of Oslo, Oslo, Norway.
⁵ Clinic of Cardiology, Oslo University Hospital and.
⁶ Division for Emergencies and Critical Care Medicine, Institute for Clinical Medicine, University of Oslo, Oslo, Norway t.i.tonnessen@medisin.uio.no.

PMID: 25392231
DOI: 10.1093/bja/aeu381

Abstract

Background: Coronary stenosis after coronary artery bypass grafting (CABG) may lead to myocardial ischaemia and is clinically difficult to diagnose. In a CABG model, we aimed at defining variables that detect hypoperfusion in real-time and correlate with impaired regional ventricular function by monitoring myocardial tissue metabolism.

Methods: Off-pump CABG was performed in 10 pigs. Graft blood flow was reduced in 18 min intervals to 75, 50, and 25% of baseline flow with reperfusion between each flow reduction. Myocardial tissue Pco2 (Pt(CO2)), Po2, pH, glucose, lactate, and glycerol from the graft supplied region and a control region were obtained. Regional cardiac function was assessed as radial strain.

Results: In comparison with baseline, myocardial pH decreased during 75, 50, and 25% flow reduction (-0.15; -0.22; -0.37, respectively, all P<0.05) whereas Pt(CO2) increased (+4.6 kPa; +7.8 kPa; +12.9 kPa, respectively, all P<0.05). pH and Pt(CO2) returned to baseline upon reperfusion. Lactate and glycerol increased flow-dependently, while glucose decreased. Regional ventricular contractile function declined significantly. All measured variables remained normal in the control region. Pt(CO2) correlated strongly with tissue lactate, pH, and contractile function (R=0.86, R=-0.91, R=-0.70, respectively, all P<0.001). New conductometric Pt(CO2) sensors were in agreement with established fibre-optic probes. Cardiac output was not altered.

Conclusions: Myocardial pH and Pt(CO2) monitoring can quantify the degree of regional tissue hypoperfusion in real-time and correlated well with cellular metabolism and contractile function, whereas cardiac output did not. New robust conductometric Pt(CO2) sensors have the potential to serve as a clinical cardiac monitoring tool during surgery and postoperatively.

Keywords: carbon dioxide; coronary artery bypass; diagnostic equipment; monitoring, intraoperative; monitoring, physiologic; perioperative care.

Publication types

Research Support, Non-U.S. Gov't

MeSH terms

Animals
Blood Gas Analysis / methods
Carbon Dioxide / metabolism*
Cardiac Output / physiology
Coronary Artery Bypass, Off-Pump / methods*
Coronary Circulation / physiology*
Female
Hemodynamics / physiology
Male
Models, Animal
Monitoring, Physiologic / methods*
Myocardium / metabolism*
Regional Blood Flow / physiology*
Swine

Substances

Carbon Dioxide