Rajebi et al., 2024 - Google Patents
An optimized microstrip antenna to generate intense localized heating at target sites for maximum effectRajebi et al., 2024
View HTML- Document ID
- 2174916325182575502
- Author
- Rajebi S
- Pedrammehr S
- Al-Abdullah K
- Asadi H
- Lim C
- Publication year
- Publication venue
- Discover Applied Sciences
External Links
Snippet
Nowadays, the use of electromagnetic waves in medical applications has become common, and hyperthermia is one of the popular areas. Nonetheless, designing effective antennas for electromagnetic hyperthermia poses a key challenge. In designing of hyperthermia …
- 238000010438 heat treatment 0 title abstract description 22
Classifications
-
- A—HUMAN NECESSITIES
- A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
- A61N—ELECTROTHERAPY; MAGNETOTHERAPY; RADIATION THERAPY; ULTRASOUND THERAPY
- A61N5/00—Radiation therapy
- A61N5/02—Radiation therapy using microwaves
Similar Documents
| Publication | Publication Date | Title |
|---|---|---|
| Paulides et al. | The HYPERcollar: a novel applicator for hyperthermia in the head and neck | |
| Nguyen et al. | Microwave hyperthermia for breast cancer treatment using electromagnetic and thermal focusing tested on realistic breast models and antenna arrays | |
| Yacoob et al. | FDTD analysis of a noninvasive hyperthermia system for brain tumors | |
| Curto et al. | Design and characterisation of a phased antenna array for intact breast hyperthermia | |
| He et al. | Optimal design of focused arrays for microwave‐induced hyperthermia | |
| Wessapan et al. | Temperature induced in human organs due to near-field and far-field electromagnetic exposure effects | |
| Koo et al. | Development of a high SAR conformal antenna for hyperthermia tumors treatment | |
| Stauffer et al. | Conformal microwave array (CMA) applicators for hyperthermia of diffuse chest wall recurrence | |
| Rajebi et al. | An optimized microstrip antenna to generate intense localized heating at target sites for maximum effect | |
| Iero et al. | Optimal constrained field focusing for hyperthermia cancer therapy: A feasibility assessment on realistic phantoms | |
| Rajebi et al. | SAR enhancement of slot microstrip antenna by using silicon layer in hyperthermia applications | |
| Kim et al. | Numerical and experimental assessments of focused microwave thermotherapy system at 925 MHz | |
| Hajiahmadi et al. | Metasurface-based time-reversal focusing for brain tumor microwave hyperthermia | |
| Lodi et al. | Towards the robust and effective design of hyperthermic devices: Improvement of a patch antenna for the case study of abdominal rhabdomyosarcoma with 3D perfusion | |
| Ramu et al. | Miniaturized 434 MHz cavity encapsulated patch antenna for superficial hyperthermia treatment | |
| Singh et al. | External microwave applicators for hyperthermia therapy: a review | |
| Abd Rahman et al. | Design method of a focusing dielectric lens antenna and temperature increment measurement at the focusing spot | |
| Kok et al. | Improved power steering with double and triple ring waveguide systems: the impact of the operating frequency | |
| Sharma et al. | Development of metasurface based hyperthermia lens applicator for heating of cancerous tissues | |
| Kaur et al. | A metamaterial backed hybrid fractal microstrip patch antenna, integrated with an EM lens for non-invasive hyperthermia of skin cancer | |
| Sharma et al. | Design and development of a double spiral antenna with an artificial magnetic conductor structure for hyperthermia treatment | |
| Hu et al. | Compact slot microstrip patch antenna loaded with open metal cavity for microwave hyperthermia | |
| Rajebi et al. | Discover Applied Sciences | |
| Tayel et al. | Pencil beam grid antenna array for hyperthermia breast cancer treatment system | |
| Murat et al. | A novel ISM band reflector type applicator design for microwave ablation systems |