Magnetic resonance imaging and its role in myocardial regenerative therapy

Two novel direct SPIO labels and in vivo MRI detection of labeled cells after acute myocardial infarct

BACKGROUND

Acute myocardial infarction (AMI) is a leading cause of morbidity and mortality worldwide. Cellular decay due hypoxia requires rapid and validated methods for possible therapeutic cell transplantation.

PURPOSE

To develop direct and rapid superparamagnetic iron oxide (SPIO) cell label for a large-animal model and to assess in vivo cell targeting by magnetic resonance imaging (MRI) in an experimental AMI model.

MATERIAL AND METHODS

Bone marrow mononuclear cells (BMMNCs) were labeled with SPIO particles using two novel direct labeling methods (rotating incubation method and electroporation). Labeling, iron incorporation in cells and label distribution, cellular viability, and proliferation were validated in vitro. An AMI porcine model was used to evaluate the direct labeling method (rotating incubation method) by examining targeting of labeled BMMNCs using MRI and histology.

RESULTS

Labeling (1 h) did not alter either cellular differentiation potential or viability of cells in vitro. Cellular relaxation values at 9.4 T correlated with label concentration and MRI at 1.5 T showing 89 ± 4% signal reduction compared with non-labeled cells in vitro. In vivo, a high spatial correlation between MRI and histology was observed. The extent of macroscopic pathological myocardial changes (hemorrhage) correlated with altered function detected on MRI.

CONCLUSION

We demonstrated two novel direct SPIO labeling methods and demonstrated the feasibility of clinical MRI for monitoring targeting of the labeled cells in animal models of AMI.

Magnetic Resonance Imaging-Guided Cardiac Interventions

Performing intraoperative cardiovascular procedures inside an MR imaging scanner can potentially provide substantial advantage in clinical outcomes by reducing the risk and increasing the success rate relative to the way such procedures are performed today, in which the primary surgical guidance is provided by X-ray fluoroscopy, by electromagnetically tracked intraoperative devices, and by ultrasound. Both noninvasive and invasive cardiologists are becoming increasingly familiar with the capabilities of MR imaging for providing anatomic and physiologic information that is unequaled by other modalities. As a result, researchers began performing animal (preclinical) interventions in the cardiovascular system in the early 1990s.

Reporter gene PET for monitoring survival of transplanted endothelial progenitor cells in the rat heart after pretreatment with VEGF and atorvastatin

It has been suggested that vascular endothelial growth factor (VEGF) and statins enhance the survival, proliferation, and function of endothelial progenitor cells (EPCs). We investigated whether reporter gene PET can be used to detect the effects of atorvastatin and VEGF on survival of EPCs after transplantation in the rat heart.

METHODS

Healthy nude rats received an intramyocardial injection of 4 million human EPCs retrovirally transduced with the sodium/iodide symporter gene for reporter gene imaging. Reporter gene expression was imaged at days 1 and 3 after injection on a small-animal PET scanner with (124)I, and the presence of EPCs was confirmed by immunohistochemistry with human CD31 antibodies. The control group received EPCs transduced only with the reporter gene, whereas treatment groups received oral atorvastatin (10 mg/kg/d) and EPCs cotransduced with adenoviral vectors encoding VEGF in addition to sodium/iodide symporter.

RESULTS

Immunohistochemistry showed more EPCs at the site of injection after atorvastatin treatment and in the presence of VEGF expression in EPCs than in controls. PET successfully visualized EPCs as focal (124)I accumulation at the site of injection. The quantitative amount of (124)I accumulation assessed by PET was significantly higher in the pretreatment than control group. Autoradiography confirmed (124)I accumulation in the myocardium that correlated with the number of EPCs.

CONCLUSION

Early survival of transplanted EPCs in the rat myocardium is prolonged by pretreatment with a combination of atorvastatin and VEGF. Reporter gene PET, by successfully quantifying the effect, is an attractive tool for monitoring stem cell survival in vivo.

Imaging in cardiac cell-based therapy: in vivo tracking of the biological fate of therapeutic cells

Clinical trials in cardiac cell-based therapy (CBT) have demonstrated the immense potential of stem progenitor cells (SPCs) to repair the injured myocardium. The bulk of evidence so far has shown that CBT can lead to structural and functional improvements. Unresolved issues remain, however, including gaps in the understanding of mechanisms and mixed results from CBT trials. To try to provide answers for these issues, assessment of the biological fate of SPCs once delivered to the injured heart has been called for. Advances in contrast agents and imaging modalities have made feasible the objective assessment of the in vivo molecular and cellular evolution of transplanted SPCs. In vivo imaging can target fundamental processes related to SPCs to gain information on their biological activities and outcomes within specific authentic microenvironments. Advantages and inherent drawbacks of imaging techniques, such as reporter-gene systems, optical imaging, radionuclide imaging, and MRI, are discussed in this Review. More than ever, it has become clear to scientists and clinicians that parallel developments in cell-based therapies and in vivo imaging modalities will strengthen this blossoming field.