about
Enhanced thermal effect using magnetic nano-particles during high-intensity focused ultrasoundNon-invasive evaluation of energy loss in the pulmonary arteries using 4D phase contrast MR measurement: a proof of concept.Benefit of ECG-gated rest and stress N-13 cardiac PET imaging for quantification of LVEF in ischemic patients.Noninvasive Electroretinography Assessment of Intravitreal Sustained-Release Methotrexate Microimplants in Rabbit Eyes.Ultrasonographical assessment of implanted biodegradable device for long-term slow release of methotrexate into the vitreous.Diagnostic cutoff for pressure drop coefficient in relation to fractional flow reserve and coronary flow reserve: A patient-level analysis.Pulsatile arterial wall-blood flow interaction with wall pre-stress computed using an inverse algorithm.Lesion flow coefficient: a combined anatomical and functional parameter for detection of coronary artery disease--a clinical study.Methodology for implementing patient-specific spatial boundary condition during a cardiac cycle from phase-contrast MRI for hemodynamic assessment.Optimization of balloon obstruction for simulating equivalent pressure drop in physiological stenoses.Nonlinear derating of high-intensity focused ultrasound beams using Gaussian modal sums.Diagnostic uncertainties during assessment of serial coronary stenoses: an in vitro study.Evaluation of lesion flow coefficient for the detection of coronary artery disease in patient groups from two academic medical centers.The mechanism of nanoparticle-mediated enhanced energy transfer during high-intensity focused ultrasound sonication.Evaluation of Hemodynamics in a Prestressed and Compliant Tapered Femoral Artery Using an Optimization-Based Inverse Algorithm.Assessment of Gold Nanoparticle-Mediated-Enhanced Hyperthermia Using MR-Guided High-Intensity Focused Ultrasound Ablation Procedure.Enhanced capture of magnetic microbeads using combination of reduced magnetic field strength and sequentially switched electroosmotic flow--a numerical study.
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description
researcher
@en
wetenschapper
@nl
name
Rupak K Banerjee
@en
Rupak K Banerjee
@nl
type
label
Rupak K Banerjee
@en
Rupak K Banerjee
@nl
prefLabel
Rupak K Banerjee
@en
Rupak K Banerjee
@nl
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0000-0002-7235-9560