Abstract
BackgroundEx-vivo heart perfusion can be utilized to study a variety of physiologic and molecular pathways in a controlled system outside of the body. It can also be used in clinical settings such as for organ preservation before transplantation. Myocardial oxygen consumption (MVO2) correlates with energy production in the myocardium and can also be used to determine the balance between the oxygen supply and demand of the perfused heart. This study sought to determine an ex-vivo perfusion rate that matches the metabolic demands of the heart according to different temperatures and solution compositions (with and without the addition of erythrocytes), a flow below which the supply of oxygen is not sufficient to maintain an aerobic state of the perfused heart (“DCRIT”).MethodsUnder general anesthesia, rat hearts were procured and preserved by perfusing with the University of Wisconsin Belzer machine perfusion system (UW Belzer MPS) solution saturated with 100% O2. The key elements of this solution include supraphysiological potassium (to stop the heartbeat and reduce the cellular metabolic demand), starch, gluconate and mannitol (to maintain cell wall integrity), glucose (to sustain basal metabolism), and glutathione (to scavenge free radicals). Three groups of rat hearts (n = 7) were randomly allocated to be perfused at 15 °C, 22 °C or 37 °C, at a varying flow index (FI) starting from a minimum of 380 mL/min/100 g to less than 50 mL/min/100 g, decreasing by 50 mL/min/100 g at 10 min intervals while measuring the MVO2 at each FI. Lactate was measured from coronary sinus samples to determine the onset of tissue hypoxia/anaerobic state.ResultsThe DCRIT at 15 °C was 99.9 ± 4.9 mL/min/100 g; however, at 22 °C and 37 °C we could not reach a DCRIT. The myocardial oxygen demand could not be met at 22 °C and 37 °C with the maximum FI above 380 mL/min/100 g even when erythrocytes (10% V/V) were added to the solution. At 15 °C, the production of lactate was evident only below the DCRIT, while at 22 °C lactate production was present at all flow indices.ConclusionsDetermining the DCRIT for optimal ex-vivo perfusion of the heart is necessary to ensure adequate tissue oxygenation and limit anaerobic state. Temperatures employed above 15 °C limit the efficient ex-vivo perfusion preservation of heart with the UW Belzer MPS solution.
Highlights
Ex-vivo heart perfusion can be utilized to study a variety of physiologic and molecular pathways in a controlled system outside of the body
Temperatures employed above 15 °C limit the efficient ex-vivo perfusion preservation of heart with the UW Belzer machine perfusion (MPS) solution
Effects of temperature on the flow index (FI)/Myocardial oxygen consumption (MVO2) relationship Figure 3 shows the relationship between the FI and MVO2 at 15 °C, 22 °C and 37 °C using UW Belzer MPS solution
Summary
Ex-vivo heart perfusion can be utilized to study a variety of physiologic and molecular pathways in a controlled system outside of the body It can be used in clinical settings such as for organ preservation before transplantation. Experimental studies have shown that MVO2 of the arrested heart is approximately 20% of the contracting heart This is attributed to the basal myocardial oxygen requirements needed to maintain critical membrane functions and basal metabolism [4]. Since the heart will decrease its energy utilization if perfused sub-optimally (anaerobic state), measuring the MVO2 in itself, may not provide with certainty whether the oxygen demand of the heart is met or not. Determining the critical flow rate (DCRIT) above which the O2 demand of the heart is met is of paramount importance to prevent the state of myocardial hypoxia and for better organ preservation
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