A feasibility and safety study of intracoronary hemodilution during primary coronary angioplasty in order to reduce reperfusion injury in myocardial infarction

Transcoronary cooling and dilution for cardioprotection during revascularisation for ST-segment elevation myocardial infarction: Design and rationale of the STEMI-Cool study

BACKGROUND

ST-segment elevation myocardial infarction (STEMI) is treated with immediate primary percutaneous coronary intervention (pPCI) to restore coronary blood flow in the acutely ischaemic territory, but is associated with reperfusion injury limiting the benefit of the therapy. No treatment has proven effective in reducing reperfusion injury. Transcoronary hypothermia has been tested in clinical studies and is well tolerated, but is generally established after crossing the occlusion with a guidewire therefore after initial reperfusion, which might have contributed to the neutral outcomes. Transcatheter strategies may also offer additional benefit through haemodilution and the resultant controlled reperfusion, but this has not been fully investigated for pPCI.

DESIGN

STEMI-Cool is a pragmatic, registry-based randomised clinical pilot trial to test the recruitment rate, feasibility, and safety of a simple transcoronary cooling and dilution protocol. Sixty STEMI patients undergoing pPCI will be randomised 1:1 to standard of care or continuous infusion of room temperature saline through the guiding catheter to achieve intracoronary temperature reductions of 6 to 8°C, commencing before crossing the coronary occlusion with a guidewire. Mechanistic outcome measures will include microvascular resistance, biomarkers of inflammation before infusion and at 24 hour, and magnetic resonance imaging of myocardial salvage and infarct size.

CONCLUSIONS

STEMI-Cool will investigate the recruitment rate, feasibility and safety of an innovative and simple cooling and diluting strategy for cardioprotection before and during reperfusion with pPCI, aiming to address limitations faced in other studies. Mechanistic outcome measures will allow insight into inflammatory, microvascular and structural changes induced by transcoronary cooling and dilution.

Myocardial tissue salvage is correlated with ischemic border region temperature at reperfusion

OBJECTIVES

Our pilot study investigated the association between region-specific myocardial tissue temperature and tissue salvage using a novel tri-lumen cooling catheter to provide rapid localized cooling directly to the heart in an open-chest porcine model of ischemia-reperfusion.

BACKGROUND

Therapeutic hypothermia remains a promising strategy to limit reperfusion injury following myocardial ischemia.

METHODS

Large swine underwent 60 min of coronary occlusion followed by 3 hr of reperfusion. Prior to inducing ischemia, six temperature probes were placed directly on the heart, monitoring myocardial temperatures in different locations. Hemodynamic parameters and core temperature were also collected. Approximately 15 min prior to reperfusion, the cooling catheter was inserted via femoral artery and the distal tip advanced proximal to the occluded coronary vessel under fluoroscopic guidance. Autologous blood was pulled from the animal via femoral sheath and delivered through the central lumen of the cooling catheter, delivering at 50 ml/min, 27°C at the distal tip. Cooling was continued for an additional 25 min after reperfusion followed by a 5-min controlled rewarming. Hearts were excised and assessed for infarct size per area at risk.

RESULTS

Although cooling catheter performance was consistent throughout the study (38 W), the resulting tissue cooling was not. Our results show a correlation between myocardial tissue salvage and ischemic border region (IBR) temperature at the time of reperfusion (R² = 0.59, p = 0.027). IBR tissue is the tissue located at the boundary between healthy and ischemic tissues.

CONCLUSIONS

Our findings suggest that localized, rapid, short-term myocardial tissue cooling has the potential to limit reperfusion injury in humans.