Active implantable sensor powered by ultrasounds with application in the monitoring of physiological parameters for soft tissues

Rosa, Bruno M. G.; Yang, Guang

doi:10.1109/bsn.2016.7516281

Cited by 9 publications

(7 citation statements)

References 16 publications

(17 reference statements)

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“…The maximum SAR value was studied in [40,41]. The empirical results can be obtained in vivo [8,42,43], using a living organism, or in vitro [44][45][46], outside of a living organism. To mimic the biological effects of human body tissue, the phantom is very popular among researchers in this field.…”

Section: Different Approaches For a Wireless Power Transfer Systemmentioning

confidence: 99%

Wireless Power Transfer Approaches for Medical Implants: A Review

Haerinia

Shadid

2020

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Wireless power transmission (WPT) is a critical technology that provides an alternative for wireless power and communication with implantable medical devices (IMDs). This article provides a study concentrating on popular WPT techniques for IMDs including inductive coupling, microwave, ultrasound, and hybrid wireless power transmission (HWPT) systems. Moreover, an overview of the major works is analyzed with a comparison of the symmetric and asymmetric design elements, operating frequency, distance, efficiency, and harvested power. In general, with respect to the operating frequency, it is concluded that the ultrasound-based and inductive-based WPTs have a low operating frequency of less than 50 MHz, whereas the microwave-based WPT works at a higher frequency. Moreover, it can be seen that most of the implanted receiver’s dimension is less than 30 mm for all the WPT-based methods. Furthermore, the HWPT system has a larger receiver size compared to the other methods used. In terms of efficiency, the maximum power transfer efficiency is conducted via inductive-based WPT at 95%, compared to the achievable frequencies of 78%, 50%, and 17% for microwave-based, ultrasound-based, and hybrid WPT, respectively. In general, the inductive coupling tactic is mostly employed for transmission of energy to neuro-stimulators, and the ultrasonic method is used for deep-seated implants.

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Section: Different Approaches For a Wireless Power Transfer Systemmentioning

confidence: 99%

Wireless Power Transfer Approaches for Medical Implants: A Review

Haerinia

Shadid

2020

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“…Rosa and Yang [75] presented a wirelessly activated implantable device to enable ultrasound emissions for computing biological tissue parameters namely, bio-potentials, thermal gradients, pH, and a concentration of electrolytes. In active mode, the device worked with 0.8 V, and an overall current of 60 µA was consumed at 3 cm separation from the source, by a sinusoid of 400 kHz with 20 mW/cm 2 of power density.…”

Section: B Advancements In Ultrasonic Wptmentioning

confidence: 99%

A Review on Miniaturized Ultrasonic Wireless Power Transfer to Implantable Medical Devices

et al. 2019

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Wireless power transfer has experienced a rapid growth in recent years due to the need for miniature medical devices with prolonged operation lifetime. The current implants utilize onboard batteries as their main source of power. The use of batteries is not, however, ideal because they have constrained lifetime requiring periodic replacement. Energy can be supplied to the implantable devices through wireless power transfer approaches including inductive, ultrasonic, radio frequency, and heat. The implantable devices driven by energy harvesters can operate continuously, offering ease of use and maintenance. Inductive coupling is a conventional approach for the transmission of power to implantable devices. However, the inductive coupling approach is affected by tissue absorption losses inside the human body. To power implantable devices such as neural, cochlear, and artificial heart devices, the inductive coupling approach is being used. On the other hand, ultrasonic is an emerging approach for the transmission of power to implantable devices. The enhanced efficiency and low propagation loss make ultrasonic wireless power transfer an attractive approach for use with implantable devices. This paper presents a study on the inductive and ultrasonic wireless power transfer techniques used to power implantable devices. The inductive and ultrasonic techniques are analyzed from their sizes, operating distance, power transfer efficiency, output power, and overall system efficiency standpoints. The inductive coupling approach can deliver more power with higher efficiency compared to the ultrasonic technique. On the other hand, the ultrasonic technique can transmit power to longer distances. The advantages and disadvantages of both techniques as well as the challenges to implement them are discussed. INDEX TERMS Energy harvesting, implantable devices, wireless power transfer, inductive, ultrasonic, power transmission efficiency.

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“…The DC level powers all electronics with total current consumption close to 100 µA. This allows to operate the device at depths of 4 cm, where the harvested level hardly exceeds 0.8 V [10]. The control of the device is performed by a microcontroller (MSP430L092, Texas Instruments) and current switching through the eight available electrodes is performed by a signal multiplexer (TS4100, Silicon Labs).…”

Section: A Electronic Designmentioning

confidence: 99%

Imaging from the implantable side: Ultrasonic-powered EIT system for surgical site infection detection

Rosa

Yang

2017

2017 IEEE International Ultrasonics Symposium (IUS)

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Abstract-Ultrasounds are a proven medical tool to assess some biological processes, including breast cancer screening, foetal development and blood perfusion. However, ultrasounds also have the potential to deliver power and telemetry capabilities to deeply implant devices, surpassing some of the challenges faced by coils or antennas operating inside the human body. In this paper, we present a small-form implantable device activated by ultrasounds that can perform in situ tissue impedance imaging. The goal is to provide a diagnosis tool to evaluate soft tissue healing after surgery, by searching for areas of bacterial infection as the normal conductivity of tissue will be impaired, a phenomena undetected by standard imaging methods. The benefits that can come from this technology are the reduction of the morbidity rate associated with wound infections and recovery time for patients in hospital. The results obtained by the device have already shown a good performance in tracking conductivity perturbations in two-dimensional domains as part of the experimental setup devised for impedance measurements.

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Active implantable sensor powered by ultrasounds with application in the monitoring of physiological parameters for soft tissues

Cited by 9 publications

References 16 publications

Wireless Power Transfer Approaches for Medical Implants: A Review

Wireless Power Transfer Approaches for Medical Implants: A Review

A Review on Miniaturized Ultrasonic Wireless Power Transfer to Implantable Medical Devices

Imaging from the implantable side: Ultrasonic-powered EIT system for surgical site infection detection

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