Bibliometric and Visualized Analysis of Piezoelectric Materials in Biomedical Application

Wang, Jia-bo; Wu, Jie; Zhang, Jian; Guan, Li-an; Feng, Hai-bo; Zhu, Ke-yan; Zhang, Yu; Sun, Hua; Cheng, Ye-dong; Zhang, Liang

doi:10.1021/acsaelm.3c01596

ACS Appl. Electron. Mater.

2024

DOI: 10.1021/acsaelm.3c01596

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Bibliometric and Visualized Analysis of Piezoelectric Materials in Biomedical Application

Jia-bo Wang,

Jie Wu,

Jian Zhang

et al.

Abstract: Piezoelectric materials have been extensively utilized in the field of biomedicine. Despite multiple studies reviewing the progress in biomedical piezoelectric materials, there is still a lack of research that provides an objective summary and analysis of research trends in this crucial field. Consequently, this study employs a range of bibliometric methods to comprehensively assess the development of piezoelectric material-related biomedical fields. The number of citations is a critical metric for gauging the… Show more

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Cited by 2 publications

References 71 publications

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Promoting Piezoelectricity in Amino Acids by Fluorination

Hu,

Lee,

Huang

et al. 2024

Advanced Materials

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Bioinspired piezoelectric amino acids and peptides are attracting attention due to their designable sequences, versatile structures, low cost, and biodegradability. However, it remains a challenge to design amino acids and peptides with high piezoelectricity. Herein, a high piezoelectric amino acid by simple fluorination in its side chain is presented. The three phenylalanine derivatives are designed: Cbz‐Phe, Cbz‐Phe(4F), and Cbz‐pentafluoro‐Phe. The effect of fluorination on self‐assembly and piezoelectricity is investigated. Cbz‐Phe(4F) can self‐assemble into crystals with a C2 space group, while Cbz‐Phe and Cbz‐pentafluoro‐Phe form aggregated self‐assemblies. Moreover, Cbz‐Phe(4F) crystals exhibit a remarkably higher piezoelectric coefficient () of ≈17.9 pm V−1 than Cbz‐Phe and Cbz‐pentafluoro‐Phe. When fabricated as a piezoelectric nanogenerator, it generates an open‐circuit voltage of ≈2.4 V. Importantly, Cbz‐Phe(4F) crystals as a flexible piezoelectric sensor for the classification of various nuts and their quality sorting, which includes those as small as individual pumpkin seeds with high sensitivity and accuracy of sorting and quality checks. When mounted onto soft grippers, the sensor performs the tactile self‐sensing functions. This work provides a promising approach to designing high piezoelectric amino acids by simple fluorination, offering exciting prospects for advancements in bioinspired piezoelectric materials in the application of smart agriculture and soft robotics.

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Promoting Piezoelectricity in Amino Acids by Fluorination

Hu,

Lee,

Huang

et al. 2024

Advanced Materials

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Research progress of piezoelectric materials in protecting oral health and treating oral diseases: a mini-review

Yang,

Sa,

Wang

et al. 2024

Front. Bioeng. Biotechnol.

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Piezoelectric materials, as a class of materials capable of generating electrical charges under mechanical vibration, have special piezoelectric effects and have been widely applied in various disease treatment fields. People generate vibrations in the oral cavity during daily activities such as brushing teeth, using electric toothbrushes, chewing, and speaking. These natural vibrations (or external ultrasound) provide ideal conditions for activating piezoelectric materials, leading to their high potential applications in protecting oral health and treating oral diseases. Based on this, this review reports on the research progress and trends of piezoelectric materials in the protection of oral health and the treatment of oral diseases in the past 5 years, and discusses its treatment mechanism, challenges and shortcomings, aiming to provide theoretical basis and new ideas for the future application of piezoelectric materials in the field of oral cavity. Finally, a brief outlook is provided, suggesting that the potential of piezoelectric materials may enable them to quickly move towards real clinical applications.

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Bibliometric and Visualized Analysis of Piezoelectric Materials in Biomedical Application

Cited by 2 publications

References 71 publications

Promoting Piezoelectricity in Amino Acids by Fluorination

Promoting Piezoelectricity in Amino Acids by Fluorination

Research progress of piezoelectric materials in protecting oral health and treating oral diseases: a mini-review

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