PT  - JOURNAL ARTICLE
AU  - Jakub Lagan
AU  - David Clark
AU  - Anna Reid
AU  - Gavin Lewis
AU  - Josephine Naish
AU  - James Fildes
AU  - Andrew Trafford
AU  - William Critchley
AU  - Erik B Schelbert
AU  - Matthias Schmitt
AU  - Phillip Foden
AU  - Christopher A Miller
TI  - 016 Uspio-enhanced CMR comprehensive methodological investigation and application in acute MI
AID  - 10.1136/heartjnl-2017-311399.16
DP  - 2017 Apr 01
TA  - Heart
PG  - A13--A13
VI  - 103
IP  - Suppl 1
4099  - http://heart.bmj.com/content/103/Suppl_1/A13.short
4100  - http://heart.bmj.com/content/103/Suppl_1/A13.full
SO  - Heart2017 Apr 01; 103
AB  - Introduction Quantification of active myocardial inflammation may improve diagnosis, guide management and provide trial end-points for novel therapies. Ultrasmall particles of iron oxide (USPIO) are phagocytosed by activated leukocytes and USPIO-enhanced CMR is increasingly used to assess tissue inflammation. We aimed to; 1. Compare T2* imaging with T1 mapping, which is proposed as an alternative for ‘native’ cardiac iron measurement; 2. Determine whether imaging at a single time point post-USPIO is sufficient to detect active accumulation in tissue; 3. Determine whether USPIO signal from infarct and remote zones in acute myocardial infarction (MI) reflects active myocardial accumulation or passive ‘wash-through’ in oedematous myocardium.Methods Four healthy volunteers and six patients with acute MI underwent 1.5T CMR, including T1 and T2* mapping, before and at multiple time points following 4 mg/kg ferumoxytol.Results Normalised T2* of spleen, an organ with high active leukocyte activity, dropped post-USPIO and remained low over the study period (Figure 1), with no correlation seen between spleen T2* and blood T1 (rho=−0.43, p=0.875). In comparison, T1 recovery in spleen correlated strongly with T1 recovery in blood (rho=0.924, p&amp;lt;0.001). In healthy myocardium, an organ with low leukocyte activity, T1 and T2*recovery both correlated strongly with blood T1 (rho=0.953, p&amp;lt;0.001; rho=0.935, p&amp;lt;0.001 respectively).In MI, absolute T2* values dropped and remained significantly lower in infarcted (15 vs 27ms, p&amp;lt;0.001, 22 vs 38 ms, p=0.001) and remote myocardium (21 vs 27ms, p=0.05, 28 vs 38 ms, p=0.024) compared to healthy controls. T2* and T1 recovery curves post-USPIO were significantly different in both infarcted (p=0.028) and remote myocardium (p=0.004; Figures 2).Conclusions 0T2* is sensitive to active tissue accumulation of USPIO, likely because T2* reflects field gradients, such as those generated by compartmentalised (phagocytosed) USPIO. T1, which is due to short range dipolar interactions that reduce as USPIOs wash-out, simply tracks passive wash-through. T1 is therefore less suitable for detecting active leukocytes. Measuring T2* at a single time point post-USPIO is insufficient to determine tissue accumulation from passive wash-through. USPIO signal from infarct and remote zones in acute MI appears to genuinely reflect active myocardial accumulation, presumably due to phagocytosis by activated leukocytes.Abstract 016 Figure 1 T1 and T2* in healthy volunteers normalised to baseline values.Abstract 016 Figure 2 a. T1 and T2* in infarcted myocardium (acute MI patients) standardised to myocardium of healthy controls. b. T1 and T2* in remote myocardium (acute MI patients) standardised to myocardium of healthy controls.