Doyle Brendan, Kemp Brad J, Chareonthaitawee Panithaya, Reed Cynthia, Schmeckpeper Jeffrey, Sorajja Paul, Russell Stephen, Araoz Philip, Riederer Stephen J, Caplice Noel M
Molecular Medicine Program, Mayo Clinic College of Medicine, Rochester, Minnesota, USA.
J Nucl Med. 2007 Oct;48(10):1708-14. doi: 10.2967/jnumed.107.042838.
We assessed the feasibility of dynamic 3-dimensional (3D) PET/CT tracking of (18)F-FDG-labeled circulating progenitor cell (CPC) therapy during intracoronary injection, using a porcine model of acute myocardial infarction (MI).
Human and porcine CPC were radiolabeled with (18)F-FDG, with variation in temperature and incubation time to determine optimal conditions. For in vivo experiments, CPC were harvested before induction of infarction (using 90-min coronary balloon occlusion). At 48 h, animals underwent cardiac MRI to assess infarct size. A balloon catheter was placed in the infarct artery at the same location as that used for induction of MI, and during dynamic 3D PET/CT 3 x 10(7) autologous (18)F-FDG progenitor cells were injected through the central lumen using either (a) 3 cycles of balloon occlusion and reperfusion or (b) high-concentration, single-bolus injection without balloon occlusion (n = 3 for both protocols). Peripheral blood was drawn at 1-min intervals during cell injection.
Labeling efficiency was optimized by 30-min incubation at 37 degrees C (human CPC, 89.9% +/- 4.8%; porcine CPC, 91.6% +/- 6.4%). Cell-bound activity showed a nonsignificant decrease at 1 h (human, 74.3% +/- 10.7%; porcine, 77.7% +/- 12.8%; P > 0.05) and a significant decrease at 2 h (human, 62.1% +/- 8.9%; porcine, 68.6% +/- 5.4%; P = 0.009). Mean infarct size was similar for both injection protocols (16.3% +/- 3.4% and 20.6% +/- 2.7%; P > 0.05). Dynamic scanning demonstrated a sharp rise in myocardial activity during each cycle of balloon-occlusion cell delivery, with a significant fall in activity (around 80%) immediately after balloon deflation. The latter was associated with a transient spike in peripheral blood (18)F-FDG activity, consistent with the first pass of labeled cells in the systemic circulation. A single spike and gradual fall in myocardial activity was observed with high-concentration, single-bolus therapy. At 1 h, myocardial activity was 8.7% +/- 1.5% of total injected dose for balloon-occlusion delivery and 17.8% +/- 7.9% for high-concentration, single-bolus delivery (P = 0.08).
Dynamic tracking during intracoronary injection of (18)F-FDG-labeled CPC is feasible and demonstrates significant cell washout from the myocardium immediately after balloon deflation. High-concentration, single-bolus therapy may be as effective as balloon-occlusion delivery. This tracking technique should facilitate development of improved delivery strategies for cardiac cell therapy.
我们使用急性心肌梗死(MI)猪模型,评估了在冠状动脉内注射期间对(18)F - FDG标记的循环祖细胞(CPC)治疗进行动态三维(3D)PET/CT追踪的可行性。
人和猪的CPC用(18)F - FDG进行放射性标记,通过改变温度和孵育时间来确定最佳条件。对于体内实验,在梗死诱导前(使用90分钟冠状动脉球囊闭塞)采集CPC。48小时时,对动物进行心脏MRI以评估梗死面积。将球囊导管放置在与诱导MI相同的梗死动脉位置,在动态3D PET/CT期间,通过中心腔注入3×10(7)个自体(18)F - FDG祖细胞,采用以下两种方式之一:(a)3个周期的球囊闭塞和再灌注;(b)无球囊闭塞的高浓度单次推注(两种方案各n = 3)。在细胞注射期间每隔1分钟采集外周血。
在37℃孵育30分钟可优化标记效率(人CPC,89.9%±4.8%;猪CPC,91.6%±6.4%)。细胞结合活性在1小时时无显著下降(人,74.3%±10.7%;猪,77.7%±12.8%;P>0.05),在2小时时显著下降(人,62.1%±8.9%;猪,68.6%±5.4%;P = 0.009)。两种注射方案的平均梗死面积相似(16.3%±3.4%和20.6%±2.7%;P>0.05)。动态扫描显示,在球囊闭塞细胞递送的每个周期中,心肌活性急剧上升,并在球囊放气后立即显著下降(约80%)。后者与外周血(18)F - FDG活性的短暂峰值相关,这与标记细胞在体循环中的首次通过一致。高浓度单次推注治疗观察到心肌活性有一个单一峰值并逐渐下降。在1小时时,球囊闭塞递送的心肌活性为总注射剂量的8.7%±1.5%,高浓度单次推注递送为17.8%±7.9%(P = 0.08)。
在冠状动脉内注射(18)F - FDG标记的CPC期间进行动态追踪是可行的,并表明在球囊放气后心肌中有明显的细胞清除。高浓度单次推注治疗可能与球囊闭塞递送一样有效。这种追踪技术应有助于开发改进的心脏细胞治疗递送策略。