Review on Medical Implantable Antenna Technology and Imminent Research Challenges

Soliman, Mohiuddin; Chowdhury, Muhammad E. H.; Khandakar, Amith; Islam, Mohammad Tariqul; Qiblawey, Yazan; Musharavati, Farayi; Nezhad, Erfan Zal

doi:10.3390/s21093163

Cited by 38 publications

(22 citation statements)

References 87 publications

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“…Along with for wireless power transmission a radio frequency (RF) based energy harvester will be integrated with the current system. With this further work, this technology has the potential to be used as a complete implantable system that is hermetically sealed into the implant and detectable through wireless transmission using implantable micro antenna [41,42]. In addition to that this technique can be transformed to force detection (tactile sensor) by correlating the change in displacement to force in multiple axes along with aiding the electromyography sensor (EMG) for reducing its false positive response [43][44][45].…”

Section: Discussionmentioning

confidence: 99%

Development of a Multi-Sensor Array for Non-Radiographic Micromotion Detection of Joint Prostheses

et al. 2022

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Section: Discussionmentioning

confidence: 99%

Development of a Multi-Sensor Array for Non-Radiographic Micromotion Detection of Joint Prostheses

et al. 2022

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“…Recently, flexible antennas have been used in wireless sensor networks [2,4,6]. The use of wire less medical networks, such as WBAN (Wireless Body Area Networks), encourages the creation of new flexible antennas for telemedicine [1,4,9]. The purpose of the calculation is to develop a flexible antenna design with a characteristic impedance of 50 ohms for the frequency range of 900-1300 MHz with the following electrical pa rameters: peak radiation power 23 dBm, standing wave ratio VSWR ≤ 3.5.…”

Section: Methodsmentioning

confidence: 99%

“…The rapid development of wireless infocommunica tion technologies stimulates the development, production and use of new types of LTE devices [1,2]. Currently, new generation cellular communication systems NBIoT, LTEm1 [3] are widely used.…”

Section: Introductionmentioning

confidence: 99%

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Development of a flexible antenna-wristband for wearable wrist-worn infocommunication devices of the LTE standard

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Pinaiev

et al. 2022

TAPR

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The object of research is the process of radiation of electromagnetic waves from a flexible antenna-wristband. The subject of research is the wave parameters and directional properties of a flexible antenna-wristband. The existing problem is that it is necessary to ensure the electromagnetic compatibility of the radio frequency units of the wrist-worn infocommunication device. This problem is due to the fact that LTE/NB-IoT, Bluetooth/Wi-Fi, and GPS antennas must be placed inside the small-sized case of the infocommunication device. To solve this problem, let’s propose a simple and cheap version of a broadband flexible bracelet antenna for LTE networks, located outside the device case. As a basis for the development of a flexible antenna-wristband, the authors chose a patch antenna, which is the base of the theory of microstrip antennas. This is due to the fact that the theoretical material is well developed for the calculation and study of the patch antenna. Structurally, a patch antenna consists of an upper metal layer that emits electromagnetic waves, a solid dielectric base, and a lower metal layer that acts as a reflector. With the classical approach to constructing a patch antenna, the width and length of its upper layer are commensurate, and its lower metal layer has geometric dimensions much larger than the upper metal layer. In contrast to the classical design, the authors proposed a new shape of the patch antenna, in which the length of the upper layer of the radiation surface is much greater than its width (5–6 times), and the lower metal layer has dimensions slightly larger than the dimensions of the upper layer. The authors have developed a flexible antenna-wristband for the frequency range of 800–1300 MHz with a wave impedance of 50 ohms, 118.7×23 mm of the upper metal layer, and 124.7×25 mm of the lower metal layer. The length of the microstrip feed line of the antenna is 54.6 mm, its width is 2 mm, and the length of the insert is 51.6 mm. The flexible antenna-wristband is connected to the printed circuit board of the infocommunication device by soldering or using a mini-coaxial cable. The authors developed an experimental layout of a flexible antenna-wristband and studied its wave and directional properties. It has been established that in the frequency range 800–1300 MHz the voltage standing wave ratio coefficient of this antenna does not exceed 3.5. The flexible antenna-wristband has directional properties, which allows reducing the level of electromagnetic radiation in the direction of the human body.

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“…Future wireless medical technologies are expected to explosively grow for controlling the bodily functions and to gather the data of different physiological parameters [1]. Over the last decade, implanted devices, especially implanted antennas, have got the attention of researchers due the compatible connection between the patient and physical doctors [2,3]. Multiple-input, multiple-output (MIMO) antennas are commonly used in the wireless communication systems due to the advanced capability in supporting data even under interference situations [4,5].…”

Section: Introductionmentioning

confidence: 99%

Deep Learning Assisted Automatic Methodology for Implanted MIMO Antenna Designs on Large Ground Plane

2021

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This paper provides a novel methodology for designing implanted multiple-input and multiple-output (MIMO) antennas in the automatic fashion. The proposed optimization consists of two sequential phases for firstly configuring the geometry of an implanted MIMO antenna and then sizing the design parameters through the hierarchy top-down optimization (TDO) and regression deep neural network (DNN), respectively. It tackles the difficulty in constructing the structure of antennas and also provides optimal values for the determined variables, sufficiently. This methodology results in valid electromagnetic (EM)-verified post-layout generation that is ready-to-fabricate. The effectiveness of the proposed optimization-oriented method is verified by designing and optimizing the implanted MIMO antenna in the frequency band of 4.34–4.61 GHz and 5.86–6.64 GHz suitable for medical applications at the emerging wireless band. For our design, we employ the actual biological tissues as bone, liquid (%1 sodium chloride, %40 sugar in distilled water), and plexiglass surroundings with a bio-compatible substrate, as aluminium oxide on a large ground plane, that is suitable to be used in a particular biomedical applications involving smart implants.

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Review on Medical Implantable Antenna Technology and Imminent Research Challenges

Cited by 38 publications

References 87 publications

Development of a Multi-Sensor Array for Non-Radiographic Micromotion Detection of Joint Prostheses

Development of a Multi-Sensor Array for Non-Radiographic Micromotion Detection of Joint Prostheses

Development of a flexible antenna-wristband for wearable wrist-worn infocommunication devices of the LTE standard

Deep Learning Assisted Automatic Methodology for Implanted MIMO Antenna Designs on Large Ground Plane

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