A. Delogu scite author profile

The aim of this study is to propose setups for in vitro assessment of RFID (radiofrequency identification) interference on pacemakers (PM). The voltage induced at the input stage of the PM by low-frequency (LF) and high-frequency (HF) RFID transmitters has been used to quantify the amount of the interference. A commercial PM was modified in order to measure the voltage at its input stage when exposed to a sinusoidal signal at 125 kHz and 13.56 MHz. At both frequencies, two antennas with different dimensions (diameter = 10 cm and 30 cm, respectively) were used to generate the interfering field, and the induced voltage was measured between the lead tip and the PM case (unipolar voltage), and between the tip and ring electrodes (bipolar voltage). The typical lead configurations adopted in similar studies or proposed by international standards, as well as lead paths closer to actual physiological implants were tested. At 125 kHz, the worst-case condition differs for the two antennas: the 10 cm antenna induced the highest voltage in the two-loop spiral configuration, whereas the 30 cm antenna in the 225 cm(2) loop configuration. At 13.56 MHz, the highest voltage was observed for both the antennas in the 225 cm(2) loop configuration. Bipolar voltages were found to be lower than the unipolar voltages induced in the same configurations, this difference being not as high as one could expect from theoretical considerations. The worst-case scenario, in terms of the induced voltage at the PM input stage, has been identified both for LF and HF readers, and for two sizes of transmitting antennas. These findings may provide the basis for the definition of a standard implant configuration and a lead path to test the EMI effects of LF and HF RFID transmitters on active implantable devices.

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An optically coupled system for quantitative monitoring of MRI gradient currents induced into endocardial leads

Mattei¹,

Triventi²,

Delogu³

et al. 2013

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The time-varying gradient fields generated during Magnetic Resonance Imaging (MRI) procedures have the potential to induce electrical current on implanted endocardial leads. Whether this current can result in undesired cardiac stimulation is unknown. This paper presents an optically coupled system with the potential to quantitatively measure the currents induced by the gradient fields into endocardial leads during MRI procedures. Our system is based on a microcontroller that works as analog-to-digital (A/D) converter and sends the current signal acquired from the lead to an optical high-speed light-emitting-diode transmitter. Plastic fiber guides the light outside the MRI chamber, to a photodiode receiver and then to an acquisition board connected to a PC. The preliminary characterization of the performances of the system is also presented.

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Radome design and measurements

Audone¹,

Delogu²,

Moriondo³

1988

IEEE Trans. Instrum. Meas.

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SOSTAR-X Program: SELEX GALILEO Contributions

Zei¹,

Delogu²,

Montanari³

et al. 2008

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A. Delogu

Microwave absorption properties in epoxy resin Multi Walled Carbon Nanotubes composites

Setups forin vitroassessment of RFID interference on pacemakers

An optically coupled system for quantitative monitoring of MRI gradient currents induced into endocardial leads

Radome design and measurements

SOSTAR-X Program: SELEX GALILEO Contributions

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