Cell Transplantation (Mar 2009)
Two-Dimensional Speckle Tracking Strain Analysis for Efficacy Assessment of Myocardial Cell Therapy
Abstract
The subtle effects of transplanted bone marrow cells (BMC) on regional myocardial behavior in patients with ischemic heart disease are difficult to assess. Novel echocardiographic techniques can quantify regional myocardial deformation (strain) and distinguish between passive and active wall motion. We hypothesized that this technique may help delineate cell therapy-induced changes in regional LV contractility that escape clinical routine studies. Twelve patients with coronary artery disease and impaired LV function (LVEF &<35%) underwent CABG surgery plus intramyocardial injection of autologous bone marrow mononuclear cells. Between two and five predefined segments of ischemic myocardium per patient received BMCs, and untreated ischemic segments served as internal controls. Segmental echocardiographic analysis of peak systolic strain by speckle tracking was performed before and 1 year after surgery and compared with standard wall motion analysis. Two patients died during the follow-up period. In the remaining 10 patients, mean LVEF increased from 24.5 ± 10% to 32.1 ± 11% ( p = 0.02). A moderate improvement of systolic function was noted in ischemic control segments by both wall motion score (WMS) and 2D strain echocardiography (2DSE). In BMC-treated segments, WMS improved slightly, but the data failed to reach statistical significance. As assessed by 2DSE, however, systolic function of BMC-treated segments improved by nearly 100%. 2DSE proved to detect BMC-induced change with 30-fold higher sensitivity than WMS, and the Receiver Operating Characteristic curve (ROC) confirmed the diagnostic precision of 2DSE (area-under-the-ROC = 0.87). We conclude that echocardiographic speckle tracking two-dimensional strain analysis can detect cell therapy-induced changes in regional contractile function that may escape detection by standard wall motion assessment. Thus, 2DSE may be a useful tool for the further development of clinical cardiac cell therapy.
