about
Low-intensity continuous ultrasound triggers effective bisphosphonate anticancer activity in breast cancer.An Ultrasound Image-Based Dynamic Fusion Modeling Method for Predicting the Quantitative Impact of In Vivo Liver Motion on Intraoperative HIFU Therapies: Investigations in a Porcine Model.First clinical experience of intra-operative high intensity focused ultrasound in patients with colorectal liver metastases: a phase I-IIa study.Intra-operative ultrasound hand-held strain imaging for the visualization of ablations produced in the liver with a toroidal HIFU transducer: first in vivo resultsHigh-intensity focused ultrasound ablation for the treatment of colorectal liver metastases during an open procedure: study on the pig.Transoesophageal ultrasound applicator for sector-based thermal ablation: first in vivo experiments64-element intraluminal ultrasound cylindrical phased array for transesophageal thermal ablation under fast MR temperature mapping: an ex vivo study.Efficacy of high-intensity focused ultrasound-assisted hepatic resection (HIFU-AR) on blood loss reduction in patients with liver metastases requiring hepatectomy: study protocol for a randomized controlled trial.Assisted hepatic resection using a toroidal HIFU device: an in vivo comparative study in pig.Intra-operative high intensity focused ultrasound in patients with colorectal liver metastases: results of a phase I-II study in 21 patients.Non-invasive high-intensity focused ultrasound treatment of the placenta: a preliminary in-vivo study using a simian model.Utility of a tumor-mimic model for the evaluation of the accuracy of HIFU treatments. results of in vitro experiments in the liver.Low dimensional optimization for in vivo real-time porcine liver motion estimation using ultrasound imaging.Thermal Ablation of the Pancreas With Intraoperative High-Intensity Focused Ultrasound: Safety and Efficacy in a Porcine Model.High-intensity focused ultrasound applied to the placenta using a toroidal transducer: a preliminary ex-vivo study.Thermal ablation produced using a surgical toroidal high-intensity focused ultrasound device is independent from hepatic inflow occlusion.Thermal ablation by high-intensity-focused ultrasound using a toroid transducer increases the coagulated volume. Results of animal experiments.[A tumour-mimic pig liver model for guiding focused ultrasound thermal ablation].Toric HIFU transducer for large thermal ablation.Elastography for breast cancer diagnosis using radiation force: system development and performance evaluation.Combination of thermal and cavitation effects to generate deep lesions with an endocavitary applicator using a plane transducer: ex vivo studies.5th International Symposium on Focused Ultrasound: North Bethesda, MD, USA. 28 August- 1 September 2016.Ultrasound cylindrical phased array for transoesophageal thermal therapy: initial studiesIn vivo preclinical evaluation of the accuracy of toroidal-shaped HIFU treatments using a tumor-mimic modelEvaluation of experimental methods for assessing safety for ultrasound radiation force elastographyLow-Intensity Ultrasound Promotes Clathrin-Dependent Endocytosis for Drug Penetration into Tumor CellsEvaluation of the Feasibility, Safety, and Accuracy of an Intraoperative High-intensity Focused Ultrasound Device for Treating Liver Metastases
P50
Q27306861-C7B610E2-58BE-4405-9BF7-3AF5C7DA8591Q30402111-CAC67474-0925-445A-B6C9-40E7B6E90C4DQ30417323-BAE9AD24-3FB5-40D3-964F-E1BD99DC24C4Q30475484-E2B62C78-6B64-4741-91BA-0E2D0760954AQ30483543-07EAC939-9718-40ED-837E-321C0D59830DQ30498783-87F66207-1B4D-49E4-AA78-93E6C0191DF5Q30544266-A76FC3E6-C9BF-41BE-AE08-9ADF9D2352AAQ37627898-CD8CF4B2-4B85-4893-B154-64F924D518FDQ39744428-88C3CEA6-7B85-467A-8875-C0E631A755DFQ45907980-CEFF6FE4-157D-4B4F-BD88-596150F58B35Q47369724-90BB75D9-69D9-4469-ACE0-30B444A07EC9Q47579428-317578AA-407F-47E5-AA8F-9DB08CF9089EQ48841057-CD8D18B8-533F-48C2-A8CA-7300FC9D675CQ50239795-B6DB61BA-38FF-43F0-82B3-AA8611237516Q50243114-41C0950C-FE55-4E1A-B1C4-79A1C4090A89Q50247620-82D3AC22-9366-4BD9-8365-F4E482BC1BE2Q50248240-4851D70D-2159-4584-9732-66696C0D866EQ50248846-323223C6-2BDE-4A2B-AD5F-1EA013AAA473Q50248895-E188EC32-72A6-4775-9D98-92EE29B984EDQ50249803-F65EA427-D9BA-422B-9DBD-D15C33900C63Q50250461-3DBF3891-8937-4AC8-B19A-23F8DBFC01A1Q50317357-486F7632-47A8-41E4-86C4-EDD387247D99Q78718016-0699B5FB-07DE-411D-9A4C-1F3F441B7FEDQ83377164-EEF04A62-2379-4B15-93D3-E2175B0FF8FAQ83648451-EFB8D8E3-6F0A-4DA4-BA9D-13ADB2B79A89Q85653219-9466929F-D067-4B21-ADCD-0A708F799E0DQ91246678-8C53D837-C6C0-4B4D-A3B0-F2E5A718954C
P50
description
researcher
@en
name
David Melodelima
@en
David Melodelima
@nl
type
label
David Melodelima
@en
David Melodelima
@nl
prefLabel
David Melodelima
@en
David Melodelima
@nl
P106
P31
P496
0000-0003-3913-1270