Linear and nonlinear optical propagation in 2D materials

Curreli, Nicola; Fanti, Alessandro; Mazzarella, Giuseppe; Kriegel, Ilka

doi:10.23919/ursirsb.2021.9829345

Cited by 5 publications

(2 citation statements)

References 148 publications

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“…The system shown in Fig. 1b is analyzed by using the waveamplitude transmission matrix (WATM) method [54], [72], [77], [78]. By knowing the amplitude of the propagating and reflected electric field along the x-axis at the first layer, E…”

Section: Propagation Modelmentioning

confidence: 99%

Feasibility Analysis of Theranostic Magnetic Scaffolds for Microwave Monitoring of Hyperthermia Treatment of Bone Tumors

Lodi¹,

Curreli²,

Dachena³

et al. 2023

Preprint

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<p>Magnetic biomaterials are multifunctional tools currently under investigation as theranostic platforms for biomedical applications. They can be implanted in bone tissue after bone cancer resection to perform local interstitial hyperthermia treatment. Given the requirements of high quality treatment, the hyperthermia therapy should be performed monitoring the system temperature, to avoid hot spots and control the treatment outcome. It is known that the magnetic properties of such implants vary with temperature. It is hypotesized that the treatment dynamic could be monitored using a microwave monitoring system. The variation of the electromagnetic properties of the biological tissues and the magnetic implant during the therapy would result in a different propagation of the microwave signal. This work investigates the feasibility of using microwaves to non-invasively monitor hyperthermia treatments with a simplified monodimensional propagation model. The forward problem is solved to identify the working frequencies, the matching medium properties and study several candidate materials. By using the numerical solutions from nonlinear and multiphysics simulations of the bone tumor hyperthermia treatment using magnetic scaffolds, the microwave signal propagation dynamic is studied. From our feasibility analysis, we found that it is possible to correlate the average tumor temperature with significant (~20 dB) variations in the transmission coefficient during a typical interstitial hyperthermia session using magnetic scaffolds. Our work brings together, for the first time, the electromagnetic material properties, the physio-pathology and physics of the hyperthermia treatment and the microwave propagation problem, thus paving the route for the development of an innovative theranostic system.</p>

show abstract

Section: Propagation Modelmentioning

confidence: 99%

Feasibility Analysis of Theranostic Magnetic Scaffolds for Microwave Monitoring of Hyperthermia Treatment of Bone Tumors

Lodi¹,

Curreli²,

Dachena³

et al. 2023

Preprint

View full text Add to dashboard Cite

show abstract

“…The system shown in Fig. 1(b) is analyzed by using the waveamplitude transmission matrix (WATM) method [54], [72], [77], [78]. By knowing the amplitude of the propagating and reflected electric field along the x-axis at the first layer, E (1) x+ and E (1) x− , respectively, the multilayered structure can be fully described by…”

Section: Propagation Modelmentioning

confidence: 99%

Feasibility Analysis of Theranostic Magnetic Scaffolds for Microwave Monitoring of Hyperthermia Treatment of Bone Tumors

Lodi

Curreli

Dachena

et al. 2023

IEEE J. Electromagn. RF Microw. Med. Biol.

Self Cite

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Magnetic biomaterials are multifunctional tools currently under investigation as theranostic platforms for biomedical applications. They can be implanted in bone tissue after bone cancer resection to perform local interstitial hyperthermia treatment. Given the requirements of high quality treatment, the hyperthermia therapy should be performed monitoring the system temperature, to avoid hot spots and control the treatment outcome. It is known that the magnetic properties of such implants vary with temperature. It is hypotesized that the treatment dynamic could be monitored using a microwave monitoring system. The variation of the electromagnetic properties of the biological tissues and the magnetic implant during the therapy would result in a different propagation of the microwave signal. This work investigates the feasibility of using microwaves to non-invasively monitor hyperthermia treatments with a simplified monodimensional propagation model. The forward problem is solved to identify the working frequencies, the matching medium properties and study several candidate materials. By using the numerical solutions from nonlinear and multiphysics simulations of the bone tumor hyperthermia treatment using magnetic scaffolds, the microwave signal propagation dynamic is studied. From our feasibility analysis, we found that it is possible to correlate the average tumor temperature with significant (∼20 dB) variations in the transmission coefficient during a typical interstitial hyperthermia session using magnetic scaffolds. Our work brings together, for the first time, the electromagnetic material properties, the physio-pathology and physics Manuscript

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A Preliminary Propagation Study on Magnetic Scaffolds for Microwave Theranostics

Lodi

2023

2023 IEEE 23rd International Conference on Nanotechnology (NANO)

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Linear and nonlinear optical propagation in 2D materials

Cited by 5 publications

References 148 publications

Feasibility Analysis of Theranostic Magnetic Scaffolds for Microwave Monitoring of Hyperthermia Treatment of Bone Tumors

Feasibility Analysis of Theranostic Magnetic Scaffolds for Microwave Monitoring of Hyperthermia Treatment of Bone Tumors

Feasibility Analysis of Theranostic Magnetic Scaffolds for Microwave Monitoring of Hyperthermia Treatment of Bone Tumors

A Preliminary Propagation Study on Magnetic Scaffolds for Microwave Theranostics

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