Magnetoelectric nanoparticles shape modulates their electrical output

Marrella, A.; Suarato, G.; Fiocchi, S.; Chiaramello, E.; Bonato, M.; Parazzini, M.; Ravazzani, P.

doi:10.3389/fbioe.2023.1219777

Cited by 7 publications

(6 citation statements)

References 78 publications

(91 reference statements)

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“…This involves not only optimizing the materials but also the overall design of the transducer and the tuning of the magnetic field generator and ultrasonic modulation. Engineers and scientists are exploring various transducer geometries and configurations to enhance their energy conversion capabilities, ensuring that the implants receive sufficient power to function effectively ( Iqbal et al, 2022 ; Marrella et al, 2023 ; Sasmal and Arockiarajan, 2023 ).…”

Section: Existing Methods Of Delivering Power To Implantsmentioning

confidence: 99%

Comparative analysis of energy transfer mechanisms for neural implants

Miziev,

Pawlak,

Howard

2024

Front. Neurosci.

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As neural implant technologies advance rapidly, a nuanced understanding of their powering mechanisms becomes indispensable, especially given the long-term biocompatibility risks like oxidative stress and inflammation, which can be aggravated by recurrent surgeries, including battery replacements. This review delves into a comprehensive analysis, starting with biocompatibility considerations for both energy storage units and transfer methods. The review focuses on four main mechanisms for powering neural implants: Electromagnetic, Acoustic, Optical, and Direct Connection to the Body. Among these, Electromagnetic Methods include techniques such as Near-Field Communication (RF). Acoustic methods using high-frequency ultrasound offer advantages in power transmission efficiency and multi-node interrogation capabilities. Optical methods, although still in early development, show promising energy transmission efficiencies using Near-Infrared (NIR) light while avoiding electromagnetic interference. Direct connections, while efficient, pose substantial safety risks, including infection and micromotion disturbances within neural tissue. The review employs key metrics such as specific absorption rate (SAR) and energy transfer efficiency for a nuanced evaluation of these methods. It also discusses recent innovations like the Sectored-Multi Ring Ultrasonic Transducer (S-MRUT), Stentrode, and Neural Dust. Ultimately, this review aims to help researchers, clinicians, and engineers better understand the challenges of and potentially create new solutions for powering neural implants.

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Section: Existing Methods Of Delivering Power To Implantsmentioning

confidence: 99%

Comparative analysis of energy transfer mechanisms for neural implants

Miziev,

Pawlak,

Howard

2024

Front. Neurosci.

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“…Following, the steps are illustrated in detail. Leveraging on the results of our previous works [19,20], the MENPs were modeled as dipolar distributions aligned along the hypothesized direction of the external low-amplitude magnetic field used for eliciting the ME effect. The dipole was modeled as a positive hemisphere of 2.5 mV and a negative hemisphere of -2.5 mV separated by an insulating layer of techotane material (V = 0 mV, σ = 0 S/m, ε = 3.4, and μr = 1).…”

Section: Methodsmentioning

confidence: 99%

“…Initially, we hypothesized to inject a single MENP to investigate the effects of a highly localized stimulation. The MENP was modeled as a sphere with a diameter of 80nm (Figure 1), in accordance with computational and experimental studies [14,[19][20][21]. Additionally, considering that experimental studies [7] indicate that MENPs tend to agglomerate when injected into biological means, with the size of the agglomerates depending on the injected MENPs concentration, we also included larger MENPs agglomerates of varying size (referred to as 'clusters') in our simulations.…”

Section: Electromagnetic Simulationmentioning

confidence: 98%

Magnetoelectric Nanoparticles for Wireless Peripheral Nerve Stimulation: A Computational Study

Galletta,

Chiaramello,

Fiocchi

et al. 2024

Preprint

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This study aims to precisely characterize the use of magnetoelectric nanoparticles (MENPs) for stimulating peripheral nerves. Numerical methods were employed to quantify the interaction between MENPs and nervous tissue. The influence of MENPs orientation, concentration and distance was assessed in terms of the external potential distribution exerted by the MENPs, the amplification of the exerted MENPs stimulation required to excite the neural fibers and the current injected into the intracellular space. The results highlight the significance of MENPs concentration for stimulation accuracy and efficiency, the impact of MENPs orientation on the electric potential distribution sensed by the nervous tissue, as well as the importance of the MENPs distance over the fibers’ recruitment. Given the considerable variability in the interaction between MENPs and nerves, our research provides a crucial step towards understanding this interaction, offering quantitative support for the application of MENPs in nervous tissue stimulation.

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“…Leveraging the results of our previous multiphysics studies [18,19], the electric model of the core-shell CoFe 2 O 4 -BaTiO 3 composites consisted of a dipolar distribution aligned along the hypothesized direction of the external low-frequency magnetic field used for eliciting the ME effect. The dipole was modeled as a positive hemisphere of 2.5 mV and a negative hemisphere of −2.5 mV separated by an insulating layer of techotane material (V = 0 mV, σ = 0 S/m, ε = 3.4, and µ r = 1).…”

Section: Menps Modelmentioning

confidence: 98%

“…The electromagnetic physical quantities generated by the presence of MENPs and their interactions with the dynamics of the nervous system were quantified by a computational approach. Starting from the results obtained by previous multiphysics models of such nanoparticles [18,19], which included the investigation of the magnetostriction and piezoelectric effect multiphysics coupling, this work presents the modeling of the electric behavior of MENPs when placed into a uniform AC magnetic field at a frequency of 50 Hz and amplitude above magnetic saturation. Furthermore, this study focused on the quantification of the electric field distribution induced by MENPs in the human body, the thresholds needed to elicit action potentials, the impact of pulse shape and the selectivity of axons' activation inside the neuronal fibers, and, finally, the complex interplay between the two [20,21].…”

Section: Introductionmentioning

confidence: 99%

Magnetoelectric Nanoparticles for Wireless Peripheral Nerve Stimulation: A Computational Study

Galletta,

Chiaramello,

Fiocchi

et al. 2024

Applied Sciences

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This study aims to precisely characterize the use of magnetoelectric nanoparticles (MENPs) for stimulating peripheral nerves. Numerical methods were employed to quantify the interaction between MENPs and nervous tissue. The influence of MENPs’ orientation, concentration and distance was assessed in terms of the external potential distribution exerted by the MENPs, the amplification of the exerted MENPs’ stimulation required to excite the neural fibers and the current injected into the intracellular space. The results highlight the significance of MENPs’ concentration for stimulation accuracy and efficiency, the impact of MENPs’ orientation on the electric potential distribution sensed by the nervous tissue, as well as the importance of the MENPs’ distance over the fibers’ recruitment. Given the considerable variability in the interaction between MENPs and nerves, our research provides a crucial step towards understanding this interaction, offering quantitative support for the application of MENPs in nervous tissue stimulation.

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Magnetoelectric nanoparticles shape modulates their electrical output

Cited by 7 publications

References 78 publications

Comparative analysis of energy transfer mechanisms for neural implants

Comparative analysis of energy transfer mechanisms for neural implants

Magnetoelectric Nanoparticles for Wireless Peripheral Nerve Stimulation: A Computational Study

Magnetoelectric Nanoparticles for Wireless Peripheral Nerve Stimulation: A Computational Study

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