Biocompatible piezoelectric lattice materials with ultrasound-regulated multimodal responses

Annan Chen; Jin Su; Muran Zhou; Mingpei Cang; Yinjin Li; Yunsong Shi; Zhen Zhang; Yangzhi Zhu; Bin Su; Yang Liu; Zuo-Guang Ye; Yusheng Shi; Jüergen Röedel; Huachen Cui; Haibo Zhang; Kun Zhou; Jian Lu; Chunze Yan

doi:10.1016/j.mser.2024.100876

Biocompatible piezoelectric lattice materials with ultrasound-regulated multimodal responses

Annan Chen, Jin Su, Muran Zhou, Mingpei Cang, Yinjin Li, Yunsong Shi, Zhen Zhang, Yangzhi Zhu, Bin Su, Yang Liu, Zuo-Guang Ye, Yusheng Shi, Jüergen Röedel, Huachen Cui, Haibo Zhang^*, Kun Zhou^*, Jian Lu^*, Chunze Yan^*

^*Corresponding author for this work

Research output: Journal Publications and Reviews › RGC 21 - Publication in refereed journal › peer-review

12 Citations (Scopus)

Abstract

Piezoelectric biomaterials, capable of converting electrical energy to mechanical energy and vice versa, are desirable for implantable devices that can achieve biosensing, tissue regeneration, anti-infection, and tumor treatment. However, their low piezoelectricity, simple geometry, and monotonous functionality remain challenging towards practical applications. Here, we report the design and additive manufacturing of a series of biocompatible piezoelectric lattice materials with bone-mimicking designs and ultrasound-regulated electrical responses. Barium calcium zirconate titanate (BCZT) with a piezoelectric coefficient d₃₃ up to 580 pC/N was synthesized and used as the parent material of the lattices for additive manufacturing. The as-fabricated BCZT lattices have compressive strength comparable to native trabecular bones, making them promising candidates for implantation and in vivo activation. We show that the lattices allow on-demand activation of anti-tumor or osteogenic functions with programmable non-invasive ultrasound stimuli, both in vitro and in vivo. Our findings provide new insights and a widely applicable strategy for developing versatile, non-invasive, and regulatable biomedical devices via bio-mimicking designs and additive manufacturing. © 2024 Elsevier B.V.

Original language	English
Article number	100876
Journal	Materials Science and Engineering R: Reports
Volume	162
Online published	16 Nov 2024
DOIs	https://doi.org/10.1016/j.mser.2024.100876
Publication status	Published - Jan 2025

Funding

This work was supported by grants from the National Natural Science Foundation of China (52235008, 52205363, and 12302157), the Program for Innovative Research Team of the Ministry of Education (IRT1244), the Shenzhen-Hong Kong Science and Technology Innovation Cooperation Zone Shenzhen Park Project (HZQB-KCZYB-2020030), the Shenzhen Science and Technology Program (JCYJ20220818101204010), the RGC General Research Fund (No. AoE/M-402/20), the Guangdong Provincial Key Lab of Integrated Communication, Sensing and Computation for Ubiquitous Internet of Things (No.2023B1212010007), the Guangzhou-HKUST(GZ) Joint Funding Program (No. 2023A03J0003, 2024A03J0535, and 2024A03J0680), and the Fundamental Research Funds for the Central Universities (2019kfyRCPY044 and 2021GCRC002).

Research Keywords

Additive manufacturing
Bio-mimicking design
Bioengineering
Piezoelectric lattice material
Ultrasound-regulated functionalities

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10.1016/j.mser.2024.100876

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Chen, A., Su, J., Zhou, M., Cang, M., Li, Y., Shi, Y., Zhang, Z., Zhu, Y., Su, B., Liu, Y., Ye, Z.-G., Shi, Y., Röedel, J., Cui, H., Zhang, H., Zhou, K., Lu, J., & Yan, C. (2025). Biocompatible piezoelectric lattice materials with ultrasound-regulated multimodal responses. Materials Science and Engineering R: Reports, 162, Article 100876. https://doi.org/10.1016/j.mser.2024.100876

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title = "Biocompatible piezoelectric lattice materials with ultrasound-regulated multimodal responses",

abstract = "Piezoelectric biomaterials, capable of converting electrical energy to mechanical energy and vice versa, are desirable for implantable devices that can achieve biosensing, tissue regeneration, anti-infection, and tumor treatment. However, their low piezoelectricity, simple geometry, and monotonous functionality remain challenging towards practical applications. Here, we report the design and additive manufacturing of a series of biocompatible piezoelectric lattice materials with bone-mimicking designs and ultrasound-regulated electrical responses. Barium calcium zirconate titanate (BCZT) with a piezoelectric coefficient d33 up to 580 pC/N was synthesized and used as the parent material of the lattices for additive manufacturing. The as-fabricated BCZT lattices have compressive strength comparable to native trabecular bones, making them promising candidates for implantation and in vivo activation. We show that the lattices allow on-demand activation of anti-tumor or osteogenic functions with programmable non-invasive ultrasound stimuli, both in vitro and in vivo. Our findings provide new insights and a widely applicable strategy for developing versatile, non-invasive, and regulatable biomedical devices via bio-mimicking designs and additive manufacturing. {\textcopyright} 2024 Elsevier B.V.",

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author = "Annan Chen and Jin Su and Muran Zhou and Mingpei Cang and Yinjin Li and Yunsong Shi and Zhen Zhang and Yangzhi Zhu and Bin Su and Yang Liu and Zuo-Guang Ye and Yusheng Shi and J{\"u}ergen R{\"o}edel and Huachen Cui and Haibo Zhang and Kun Zhou and Jian Lu and Chunze Yan",

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doi = "10.1016/j.mser.2024.100876",

language = "English",

volume = "162",

journal = "Materials Science and Engineering R: Reports",

issn = "0927-796X",

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TY - JOUR

T1 - Biocompatible piezoelectric lattice materials with ultrasound-regulated multimodal responses

AU - Chen, Annan

AU - Su, Jin

AU - Zhou, Muran

AU - Cang, Mingpei

AU - Li, Yinjin

AU - Shi, Yunsong

AU - Zhang, Zhen

AU - Zhu, Yangzhi

AU - Su, Bin

AU - Liu, Yang

AU - Ye, Zuo-Guang

AU - Shi, Yusheng

AU - Röedel, Jüergen

AU - Cui, Huachen

AU - Zhang, Haibo

AU - Zhou, Kun

AU - Lu, Jian

AU - Yan, Chunze

PY - 2025/1

Y1 - 2025/1

N2 - Piezoelectric biomaterials, capable of converting electrical energy to mechanical energy and vice versa, are desirable for implantable devices that can achieve biosensing, tissue regeneration, anti-infection, and tumor treatment. However, their low piezoelectricity, simple geometry, and monotonous functionality remain challenging towards practical applications. Here, we report the design and additive manufacturing of a series of biocompatible piezoelectric lattice materials with bone-mimicking designs and ultrasound-regulated electrical responses. Barium calcium zirconate titanate (BCZT) with a piezoelectric coefficient d33 up to 580 pC/N was synthesized and used as the parent material of the lattices for additive manufacturing. The as-fabricated BCZT lattices have compressive strength comparable to native trabecular bones, making them promising candidates for implantation and in vivo activation. We show that the lattices allow on-demand activation of anti-tumor or osteogenic functions with programmable non-invasive ultrasound stimuli, both in vitro and in vivo. Our findings provide new insights and a widely applicable strategy for developing versatile, non-invasive, and regulatable biomedical devices via bio-mimicking designs and additive manufacturing. © 2024 Elsevier B.V.

AB - Piezoelectric biomaterials, capable of converting electrical energy to mechanical energy and vice versa, are desirable for implantable devices that can achieve biosensing, tissue regeneration, anti-infection, and tumor treatment. However, their low piezoelectricity, simple geometry, and monotonous functionality remain challenging towards practical applications. Here, we report the design and additive manufacturing of a series of biocompatible piezoelectric lattice materials with bone-mimicking designs and ultrasound-regulated electrical responses. Barium calcium zirconate titanate (BCZT) with a piezoelectric coefficient d33 up to 580 pC/N was synthesized and used as the parent material of the lattices for additive manufacturing. The as-fabricated BCZT lattices have compressive strength comparable to native trabecular bones, making them promising candidates for implantation and in vivo activation. We show that the lattices allow on-demand activation of anti-tumor or osteogenic functions with programmable non-invasive ultrasound stimuli, both in vitro and in vivo. Our findings provide new insights and a widely applicable strategy for developing versatile, non-invasive, and regulatable biomedical devices via bio-mimicking designs and additive manufacturing. © 2024 Elsevier B.V.

KW - Additive manufacturing

KW - Bio-mimicking design

KW - Bioengineering

KW - Piezoelectric lattice material

KW - Ultrasound-regulated functionalities

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DO - 10.1016/j.mser.2024.100876

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JO - Materials Science and Engineering R: Reports

JF - Materials Science and Engineering R: Reports

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ER -

Biocompatible piezoelectric lattice materials with ultrasound-regulated multimodal responses

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AoE(UGC)-ExtU-Lead: Aging, Skeletal Degeneration and Regeneration

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Biocompatible piezoelectric lattice materials with ultrasound-regulated multimodal responses

Abstract

Funding

Research Keywords

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AoE(UGC)-ExtU-Lead: Aging, Skeletal Degeneration and Regeneration

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