Self‐Powered Nanostructured Piezoelectric Filaments as Advanced Transducers for New Cochlear Implants

Mokhtari, Fatemeh; Danti, Serena; Azimi, Bahareh; Hellies, Filippo; Zanoletti, Elisabetta; Albertin, Giovanna; Astolfi, Laura; Varley, Russell J.; Razal, Joselito M.

doi:10.1002/eem2.12807

Energy & Environ Materials

2024

DOI: 10.1002/eem2.12807

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Self‐Powered Nanostructured Piezoelectric Filaments as Advanced Transducers for New Cochlear Implants

Fatemeh Mokhtari,

Serena Danti,

Bahareh Azimi

et al.

Abstract: The conversion of sound vibration into electrical potential is a critical function performed by cochlear hair cells. Unlike the regenerative capacity found in various other cells throughout the body, cochlear sensory cells lack the ability to regenerate once damaged. Furthermore, a decline in the quantity of these cells results in a deterioration of auditory function. Piezoelectric materials can generate electric charge in response to sound wave vibration, making them theoretically suitable for replacing hair … Show more

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Cited by 4 publications

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Implantable Self‐Powered Systems for Electrical Stimulation Medical Devices

Cui,

Wu,

Zhang

et al. 2024

Advanced Science

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With the integration of bioelectronics and materials science, implantable self‐powered systems for electrical stimulation medical devices have emerged as an innovative therapeutic approach, garnering significant attention in medical research. These devices achieve self‐powering through integrated energy conversion modules, such as triboelectric nanogenerators (TENGs) and piezoelectric nanogenerators (PENGs), significantly enhancing the portability and long‐term efficacy of therapeutic equipment. This review delves into the design strategies and clinical applications of implantable self‐powered systems, encompassing the design and optimization of energy harvesting modules, the selection and fabrication of adaptable electrode materials, innovations in systematic design strategies, and the extensive utilization of implantable self‐powered systems in biological therapies, including the treatment of neurological disorders, tissue regeneration engineering, drug delivery, and tumor therapy. Through a comprehensive analysis of the latest research progress, technical challenges, and future directions in these areas, this paper aims to provide valuable insights and inspiration for further research and clinical applications of implantable self‐powered systems.

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Implantable Self‐Powered Systems for Electrical Stimulation Medical Devices

Cui,

Wu,

Zhang

et al. 2024

Advanced Science

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Role of Piezoelectricity in Disease Diagnosis and Treatment: A Review

Tripathi,

Dubey

2024

ACS Biomater. Sci. Eng.

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Because of their unique electromechanical coupling response, piezoelectric smart biomaterials demonstrated distinctive capability toward effective, efficient, and quick diagnosis and treatment of a wide range of diseases. Such materials have potentiality to be utilized as wireless therapeutic methods with ultrasonic stimulation, which can be used as self-powered biomedical devices. An emerging advancement in the realm of personalized healthcare involves the utilization of piezoelectric biosensors for a range of therapeutic diagnosis such as diverse physiological signals in the human body, viruses, pathogens, and diseases like neurodegenerative ones, cancer, etc. The combination of piezoelectric nanoparticles with ultrasound has been established as a promising approach in sonodynamic therapy and piezocatalytic therapeutics and provides appealing alternatives for noninvasive treatments for cancer, chronic wounds, neurological diseases, etc. Innovations in implantable medical devices (IMDs), such as implantable piezoelectric energy generator (iPEG), offer significant advantages in improving physiological functioning and ability to power a cardiac pacemaker and restore the heart function. This comprehensive review critically evaluates the role of piezoelectricity in disease diagnosis and treatment, highlighting the implication of piezoelectric smart biomaterials for biomedical devices. It also discusses the potential of piezoelectric materials in healthcare monitoring, tissue engineering, and other medical applications while emphasizing future trends and challenges in the field.

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Advancement in piezoelectric nanogenerators for acoustic energy harvesting

Jean,

Khan,

Alazzam

et al. 2024

Microsyst Nanoeng

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The demand for sustainable energy sources to power small electronics like IoT devices has led to exploring innovative solutions like acoustic energy harvesting using piezoelectric nanogenerators (PENGs). Acoustic energy harvesting leverages ambient noise, converting it into electrical energy through the piezoelectric effect, where certain materials generate an electric charge in response to mechanical stress or vibrations. This review paper provides a comprehensive analysis of the advancements in PENG technology, emphasizing their role in acoustic energy harvesting. We begin by discussing the essential principles of piezoelectricity and the design considerations for nanogenerators to optimize energy capture from sound waves. The discussion includes a detailed examination of various piezoelectric materials, such as polyvinylidene fluoride (PVDF), lead zirconate titanate (PZT), and zinc oxide (ZnO) nanowires, which are known for their superior piezoelectric properties. A critical aspect of this review is the exploration of innovative structural designs and resonance devices that enhance the efficiency of PENGs. We delve into the mechanisms and benefits of using Helmholtz resonators, quarter-wavelength tubes, and cantilever beams, which are instrumental in amplifying acoustic signals and improving energy conversion rates. Each device’s design parameters and operational principles are scrutinized to highlight their contributions to the field. The review addresses practical applications of PENGs in various domains. Environmental monitoring systems, wearable electronics, and medical devices stand to benefit significantly from the continuous and sustainable power supplied by PENGs. These applications can reduce reliance on batteries and minimize maintenance by harnessing ambient acoustic energy, leading to more efficient and longer-lasting operations. Despite the promising potential of PENGs, several challenges remain, including material degradation, efficiency limitations, and integrating these devices into existing technological frameworks. This paper discusses these obstacles in detail and proposes potential solutions to enhance the longevity and performance of PENG systems. Innovations in material science and engineering are crucial to overcoming these hurdles and realizing the full potential of acoustic energy harvesting.

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Self‐Powered Nanostructured Piezoelectric Filaments as Advanced Transducers for New Cochlear Implants

Cited by 4 publications

References 64 publications

Implantable Self‐Powered Systems for Electrical Stimulation Medical Devices

Implantable Self‐Powered Systems for Electrical Stimulation Medical Devices

Role of Piezoelectricity in Disease Diagnosis and Treatment: A Review

Advancement in piezoelectric nanogenerators for acoustic energy harvesting

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