25 research outputs found
Feasibility of MRI-guided transurethral ultrasound for lesion-targeted ablation of prostate cancer
Background: MRI-guided transurethral ultrasound ablation (TULSA) has been evaluated for organ-confined prostate cancer (PCa). The purpose of this study was to assess the safety and toxicity, accuracy and short-term evolution of cell-death after lesion-targeted TULSA.Methods: This prospective, registered, Phase-I treat-and-3-week-resect-study enrolled six patients with MRI-visible-biopsy-concordant PCa. Lesions were targeted using TULSA with radical intent, except near neurovascular bundles (NVB). Robot-assisted-laparoscopic-prostatectomy (RALP) was performed at 3 weeks. Post-TULSA assessments included MRI (1 and 3 weeks), adverse events and quality-of-life (QoL) to 3 weeks, followed by RALP and whole-mount-histology. Treatment accuracy and demarcation of thermal injury were assessed using MRI and histology.Results: Six patients (median age = 70 years, prostate volume = 60 ml, PSA = 8.9 ng/ml) with eight biopsy-confirmed MRI-lesions (PIRADS ≥3) were TULSA-treated without complications (median sonication and MRI-times of 17 and 117 min). Foley-catheter removal was uneventful at 2–3 days. Compared to baseline, no differences in QoL were noted at 3 weeks. During follow-up, MRI-derived non-perfused-volume covered ablated targets and increased 36% by 3 weeks, correlating with necrosis-area on histology. Mean histological demarcation between complete necrosis and outer-limit-of-thermal-injury was 1.7 ± 0.4 mm. Coagulation necrosis extended to capsule except near NVB, where 3 mm safety-margins were applied. RALPs were uncomplicated and histopathology showed no viable cancer within the ablated tumor-containing target.Conclusions: Lesion-targeted TULSA demonstrates accurate and safe ablation of PCa. A significant increase of post-TULSA non-perfused-volume was observed during 3 weeks follow-up concordant with necrosis on histology. TULSA achieved coagulation necrosis of all targeted tissues. A limitation of this treat-and-resect-study-design was conservative treatment near NVB in patients scheduled for RALP.</p
Design of Long Circulating Nontoxic Dendritic Polymers for the Removal of Iron <i>in Vivo</i>
Patients requiring chronic red blood cell (RBC) transfusions for inherited or acquired anemias are at risk of developing transfusional iron overload, which may impact negatively on organ function and survival. Current iron chelators are suboptimal due to the inconvenient mode of administration and/or side effects. Herein, we report a strategy to engineer low molecular weight iron chelators with long circulation lifetime for the removal of excess iron <i>in vivo</i> using a multifunctional dendritic nanopolymer scaffold. Desferoxamine (DFO) was conjugated to hyperbranched polyglycerol (HPG) and the plasma half-life (<i>t</i><sub>1/2</sub>) in mice is defined by the structural features of the scaffold. There was a 484 fold increase in <i>t</i><sub>1/2</sub> between the DFO (5 min) versus the HPG–DFO (44 h). In an iron overloaded mouse model, efficient iron excretion by HPG–DFO in the urine and feces was demonstrated (<i>p</i> = 0.0002 and 0.003, respectively) as was a reduction in liver, heart, kidney, and pancreas iron content, and plasma ferritin level (<i>p</i> = 0.003, 0.001, 0.001, 0.001, and 0.003, respectively) compared to DFO. Conjugates showed no apparent toxicity in several analyses including body weight, serum lactate dehydrogenase level, necropsy analysis, and by histopathological examination of organs. These findings were supported by <i>in vitro</i> biocompatibility analyses, including blood coagulation, platelet activation, complement activation, red blood cell aggregation, hemolysis, and cell viability. This nanopolymer-based chelating system would potentially benefit patients suffering from transfusional iron overload