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63 results on '"Alessandro Arduino"'

51. Parametric analysis of transient skin heating induced by terahertz radiation

Author

Oriano Bottauscio, Mario Chiampi, Luca Zilberti, and Alessandro Arduino

Subjects
Electromagnetic wave equation, Materials science, Physiology, business.industry, Terahertz radiation, Biophysics, Plane wave, General Medicine, Mechanics, Electromagnetic radiation, Finite element method, Optics, Bioheat transfer, Radiology, Nuclear Medicine and imaging, Transient (oscillation), business, Bioelectromagnetics
Abstract

This paper investigates the effect of relevant physical parameters on transient temperature elevation induced in human tissues by electromagnetic waves in the terahertz (THz) band. The problem is defined by assuming a plane wave, which, during a limited time interval, normally impinges on the surface of a 3-layer model of the human body, causing a thermal transient. The electromagnetic equations are solved analytically, while the thermal ones are handled according to the finite element method. A parametric analysis is performed with the aim of identifying the contribution of each parameter, showing that the properties of the first skin layer (except blood flow) play a major role in the computation of the maximum temperature rise for the considered exposure situation. Final results, obtained by combining all relevant parameters together, show that the deviation from the reference solution of the maximum temperature elevation in skin is included in the coverage intervals from −30% to +10% at 0.1 THz and from −33% to +18% at 1 THz (with 95% confidence level). These data allow bounding the possible temperature increase against the spread of tissue properties that could be reasonably used for dosimetric simulations. Bioelectromagnetics. 35:314–323, 2014. © 2014 Wiley Periodicals, Inc.

Published
2014
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52. In silico evaluation of the thermal stress induced by MRI switched gradient fields in patients with metallic hip implant

Author

Luca Zilberti, Mario Chiampi, Alessandro Arduino, Oriano Bottauscio, and Rüdiger Brühl

Subjects
Electromagnetic field, Hot Temperature, Materials science, Radiological and Ultrasound Technology, Computer simulation, Phantoms, Imaging, Radio Waves, Work (physics), Magnetic Resonance Imaging, Imaging phantom, Body Temperature, 030218 nuclear medicine & medical imaging, 03 medical and health sciences, Electromagnetic Fields, 0302 clinical medicine, Electromagnetic coil, 030220 oncology & carcinogenesis, Humans, Measurement uncertainty, Dosimetry, Computer Simulation, Radiology, Nuclear Medicine and imaging, Hip Prosthesis, Excitation, Biomedical engineering
Abstract

This work focuses on the in silico evaluation of the energy deposed by MRI switched gradient fields in bulk metallic implants and the consequent temperature increase in the surrounding tissues. An original computational strategy, based on the subdivision of the gradient coil switching sequences into sub-signals and on the time-harmonic electromagnetic field solution, allows to realistically simulate the evolution of the phenomena produced by the gradient coils fed according to any MRI sequence. Then, Pennes’ bioheat equation is solved through a Douglas–Gunn time split scheme to compute the time-dependent temperature increase. The procedure is validated by comparison with laboratory results, using a component of a realistic hip implant embedded within a phantom, obtaining an agreement on the temperature increase better than 5%, lower than the overall measurement uncertainty. The heating generated inside the body of a patient with a unilateral hip implant when undergoing an Echo-Planar Imaging (EPI) MRI sequence is evaluated and the role of the parameters affecting the thermal results (body position, coil performing the frequency encoding, effects of thermoregulation) is discussed. The results show that the gradient coils can generate local increases of temperature up to some kelvin when acting without radiofrequency excitation. Hence, their contribution in general should not be disregarded when evaluating patients’ safety.

Published
2019
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55. Douglas-Gunn method applied to dosimetric assessment in magnetic resonance imaging

Author

Alessandro Arduino, Oriano Bottauscio, Mario Chiampi, and Luca Zilberti

Subjects
010101 applied mathematics, Magnetic resonance imaging, Douglas-Gunn method, Biomedical computing, Biomedical computing, Magnetic resonance imaging, Douglas-Gunn method, 010103 numerical & computational mathematics, 0101 mathematics, 01 natural sciences
Published
2016

56. A multiphase model of tumour segregation in situ by a heterogeneous extracellular matrix

Author

Luigi Preziosi and Alessandro Arduino

Subjects
In situ, Chemistry, Applied Mathematics, Mechanical Engineering, Cancer modelling, Cell, Extracellular matrix, tumor growth, multiphase model, Nanotechnology, Relative dimension, Membrane, medicine.anatomical_structure, Mechanics of Materials, Collagen fibres, Cancer cell, Biophysics, medicine, Nucleus
Abstract

Normal and tumour cells live in a fibrous environment that is often very heterogeneous, even characterized by the presence of basal membranes and regions with high density of collagen fibres that physiologically comparmentalize cells in well defined regions, as for in situ tumours. In case of metastatic tumours these porous structures are instead invaded by cancer cells. The aim of this paper is to propose a multiphase model that is able to describe cell segregation by thick porous structures and to relate the transition rule that determines whether cells will pass or not to microscopic characteristics of the cells, such as the stiffness of their nucleus, their adhesive and traction abilities, the relative dimension of their nucleus with respect to the dimension of the pores of the extra-cellular matrix.

Published
2015

59. A model to analyze the skin heating produced by millimeter and submillimeter electromagnetic waves

Author

L. Zilberti, Oriano Bottauscio, Mario Chiampi, and Alessandro Arduino

Subjects
Surface (mathematics), Physics, Optics, Parametric analysis, business.industry, Thermal, Plane wave, Layered model, Radiofrequency heating, Millimeter, business, Electromagnetic radiation
Abstract

The paper investigates the heating of tissues exposed to millimeter and sub-millimeter electromagnetic waves. The problem is faced by assuming a plane wave normally incident to the surface of a layered model of the human body and by solving analytically both the electromagnetic and thermal equations. The effect of a possible variability in the relevant parameters is put in evidence through a specific parametric analysis.

Published
2013
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60. Parametric analysis of transient skin heating induced by terahertz radiation

Author

Luca, Zilberti, Alessandro, Arduino, Oriano, Bottauscio, and Mario, Chiampi

Subjects
Time Factors, Humans, Skin Temperature, Models, Biological, Terahertz Radiation, Skin
Abstract

This paper investigates the effect of relevant physical parameters on transient temperature elevation induced in human tissues by electromagnetic waves in the terahertz (THz) band. The problem is defined by assuming a plane wave, which, during a limited time interval, normally impinges on the surface of a 3-layer model of the human body, causing a thermal transient. The electromagnetic equations are solved analytically, while the thermal ones are handled according to the finite element method. A parametric analysis is performed with the aim of identifying the contribution of each parameter, showing that the properties of the first skin layer (except blood flow) play a major role in the computation of the maximum temperature rise for the considered exposure situation. Final results, obtained by combining all relevant parameters together, show that the deviation from the reference solution of the maximum temperature elevation in skin is included in the coverage intervals from -30% to +10% at 0.1 THz and from -33% to +18% at 1 THz (with 95% confidence level). These data allow bounding the possible temperature increase against the spread of tissue properties that could be reasonably used for dosimetric simulations.

Published
2013

61. In silico evaluation of the thermal stress induced by MRI switched gradient fields in patients with metallic hip implant.

Author

Alessandro Arduino, Oriano Bottauscio, Rüdiger Brühl, Mario Chiampi, and Luca Zilberti

Subjects
*THERMAL stresses, *ECHO-planar imaging, *POSTURE, *ELECTROMAGNETIC fields, *PATIENT safety, *BODY temperature regulation
Abstract

This work focuses on the in silico evaluation of the energy deposed by MRI switched gradient fields in bulk metallic implants and the consequent temperature increase in the surrounding tissues. An original computational strategy, based on the subdivision of the gradient coil switching sequences into sub-signals and on the time-harmonic electromagnetic field solution, allows to realistically simulate the evolution of the phenomena produced by the gradient coils fed according to any MRI sequence. Then, Pennes’ bioheat equation is solved through a Douglas–Gunn time split scheme to compute the time-dependent temperature increase. The procedure is validated by comparison with laboratory results, using a component of a realistic hip implant embedded within a phantom, obtaining an agreement on the temperature increase better than 5%, lower than the overall measurement uncertainty. The heating generated inside the body of a patient with a unilateral hip implant when undergoing an Echo-Planar Imaging (EPI) MRI sequence is evaluated and the role of the parameters affecting the thermal results (body position, coil performing the frequency encoding, effects of thermoregulation) is discussed. The results show that the gradient coils can generate local increases of temperature up to some kelvin when acting without radiofrequency excitation. Hence, their contribution in general should not be disregarded when evaluating patients’ safety. [ABSTRACT FROM AUTHOR]

Published
2020
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63. Magnetic resonance-based imaging of human electric properties with phaseless contrast source inversion.

Author

Alessandro Arduino, Oriano Bottauscio, Mario Chiampi, and Luca Zilberti

Subjects
*MAGNETIC resonance, *BACK propagation, *PHASE estimation (Electronics), *MAXWELL-Boltzmann distribution law, *THERMAL dosimetry
Abstract

Magnetic resonance imaging scanners can provide, by B1-mapping techniques, measurements of the transmit sensitivity magnitude, whereas the transmit sensitivity phase can only be approximated under symmetry assumptions of the coil and the sample. Nonetheless, up to now many techniques have been proposed to retrieve electric properties maps at radiofrequency by elaborating the complex transmit sensitivity. These techniques are usually referred to as magnetic resonance-based electric properties tomography. In order to perform imaging of the elecric properties also in cases which do not fulfill the assumptions for transmit sensitivity phase estimation, a variation of the phaseless contrast source inversion technique is proposed in this paper to retrieve the electric properties by elaborating only the magnitude of the transmit sensitivity. The novel technique is described in a generalised framework based on a functional viewpoint and it is specialised to deal with two-dimensional boundary-free problems. Moreover, a phaseless back propagation solution is proposed as initial guess. The proposed technique and initial guess have been tested on realistic two-dimensional model problems, which show that the numerical minimisation converges towards the global minimum when multiple linearly independent measurements are provided and that it is quite robust with respect to noisy inputs. [ABSTRACT FROM AUTHOR]

Published
2018
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