Percutaneous Image-Guided Ablation of Lung Tumors

Tumors of the lung, including primary cancer and metastases, are notoriously common and difficult to treat. Although surgical resection of lung lesions is often indicated, many conditions disqualify patients from being surgical candidates. Percutaneous image-guided lung ablation is a relatively new set of techniques that offers a promising treatment option for a variety of lung tumors. Although there have been no clinical trials to definitively compare its efficacy to those of traditional treatments, lung ablation is widely practiced and generally accepted to be safe and effective. Especially encouraging results have recently emerged for cryoablation, one of the newer ablative techniques. This article reviews the indications, techniques, contraindications, and complications of percutaneous image-guided ablation of lung tumors with special attention to cryoablation and its recent developments in protocol optimization.

Study and modulation of cardiac electroporation with a novel model utilizing human induced pluripotent stem cells

Background Cardiac electroporation is a promising novel non-thermal ablation method, gaining significant interest with recent first-in-man data suggesting effective cardiac lesion generation with no collateral damage. Nevertheless, significant knowledge gaps exist regarding its electrophysiological consequences in cardiomyocytes, including; cell specificity, protocol optimization, irreversibility threshold, recovery time-constants, and the mechanistic nature of its cytolytic and anti-arrhythmic properties. Purpose Establishing an innovative in-vitro model for the study of cardiac electroporation-ablation, utilizing human induced pluripotent stem cells (hiPSCs). Methods and results Healthy-control hiPSC-derived cardiomyocytes were enzymatically dissociated and seeded as circular cell sheets (hiPSC-CCSs). Electroporation-ablation experiments were performed using a custom designed high-frequency electroporation (HF-EP) generator. Two needle-shaped electrodes were used for HF-EP delivery (Figure 1). Subsequently, detailed voltage- and Ca2+-mapping studies of the hiPSC-CCSs were conducted (Figure 2). HF-EP application resulted in the generation of electrically isolated lesions within the hiPSC-CCSs (Figure 3). Further characterization of the temporal changes and electrophysiological properties following electroporation revealed that; (1) lesions persisted over prolonged periods of time (days), indicating irreversible electroporation, (2) a temporal decrease in lesion dimensions was noted, consistent with a significant reversible electroporation component (Figures 3–5), (3) most tissue recovery had occurred within the first 15 minutes following electroporation, with little recovery beyond that time-frame, (4) increasing pulse-number augmented lesion area as well as the proportion of irreversible damage, and (5) electroporation sensitization was achieved by increasing extracellular Ca2+, indicating its crucial role in electroporation cytolysis, potentially via direct cellular toxicity and apoptosis facilitation (Figures 5–6). Finally, evaluating for HF-EP anti-arrhythmic properties, we targeted multiple rotors or focal triggered-activity generated in the hiPSC-CCSs. HF-EP application generated sustained line-blocks, isolating arrhythmogenic substrates within the hiPSC-CCSs while blocking the propagation of arrhythmic wavefronts (Figure 7). Conclusion Our results demonstrate the ability to study cardiac electroporation utilizing hiPSC-derived cardiomyocytes, provide novel insights into its temporal and electrophysiological characteristics, facilitate electroporation protocol optimization, screen for potential electroporation sensitizers, and to study its mechanistic nature and anti-arrhythmic properties. FUNDunding Acknowledgement Type of funding sources: Public Institution(s). Main funding source(s): Division of Cardiology, and Tamman Cardiovascular Research Institute, Leviev Heart Center, Sheba Medical Center - Tel Hashomer, Ramat-Gan, Israel Figures 1–4 Figures 5–7

Protocol optimization for the detection of Trypanosoma cruzi DNA in açai (Euterpe oleraceae) pulp

ABSTRACT Chagas disease, caused by the protozoan Trypanosoma cruzi, has often been linked to oral transmission through açai consumption. Molecular methods that allow fast and accurate identification of the pathogen are important for the detection of the presence of the parasite in this food. This study aimed to optimize polymerase chain reaction (PCR)-based detection of T. cruzi DNA in açai pulp. Several dilutions of T. cruzi DTU TcI trypomastigote forms were cultured in liver infusion tryptose (LIT) medium. Trypanosoma cruzi DNA was extracted from the cells and subjected to PCR. Subsequently, culture dilutions were added to açai pulp to evaluate the detection threshold of the optimized PCR assay. We demonstrate that our assay can detect T. cruzi DNA in açai pulp at a concentration of 1.08 × 10-10 ng µL-1. We conclude that our optimized protocol is effective and can be used as an important tool for the detection of T. cruzi contamination in açaí.