Acoustically triggered disassembly of multilayered polyelectrolyte thin films through gigahertz resonators for controlled drug release applications

Zhixin Zhang; Zifan Tang; Wenpeng Liu; Hongxiang Zhang; Yao Lu; Yanyan Wang; Wei Pang; Hao Zhang; Xuexin Duan

doi:10.3390/mi7110194

Acoustically triggered disassembly of multilayered polyelectrolyte thin films through gigahertz resonators for controlled drug release applications

Zhixin Zhang, Zifan Tang, Wenpeng Liu, Hongxiang Zhang, Yao Lu, Yanyan Wang, Wei Pang, Hao Zhang, Xuexin Duan^*

^*Corresponding author for this work

Tianjin University

Research output: Contribution to journal › Article › peer-review

5 Citations (Scopus)

Abstract

Controlled drug release has a high priority for the development of modern medicine and biochemistry. To develop a versatile method for controlled release, a miniaturized acoustic gigahertz (GHz) resonator is designed and fabricated which can transfer electric supply to mechanical vibrations. By contacting with liquid, the GHz resonator directly excites streaming flows and induces physical shear stress to tear the multilayered polyelectrolyte (PET) thin films. Due to the ultra-high working frequency, the shear stress is greatly intensified, which results in a controlled disassembling of the PET thin films. This technique is demonstrated as an effective method to trigger and control the drug release. Both theory analysis and controlled release experiments prove the thin film destruction and the drug release..

Original language	English
Article number	194
Journal	Micromachines
Volume	7
Issue number	11
DOIs	https://doi.org/10.3390/mi7110194
Publication status	Published - 1 Nov 2016
Externally published	Yes

Keywords

Bulk acoustic resonator
Controlled drug release
Layer-by-layer (LbL)
MEMS

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10.3390/mi7110194

Cite this

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title = "Acoustically triggered disassembly of multilayered polyelectrolyte thin films through gigahertz resonators for controlled drug release applications",

abstract = "Controlled drug release has a high priority for the development of modern medicine and biochemistry. To develop a versatile method for controlled release, a miniaturized acoustic gigahertz (GHz) resonator is designed and fabricated which can transfer electric supply to mechanical vibrations. By contacting with liquid, the GHz resonator directly excites streaming flows and induces physical shear stress to tear the multilayered polyelectrolyte (PET) thin films. Due to the ultra-high working frequency, the shear stress is greatly intensified, which results in a controlled disassembling of the PET thin films. This technique is demonstrated as an effective method to trigger and control the drug release. Both theory analysis and controlled release experiments prove the thin film destruction and the drug release..",

keywords = "Bulk acoustic resonator, Controlled drug release, Layer-by-layer (LbL), MEMS",

author = "Zhixin Zhang and Zifan Tang and Wenpeng Liu and Hongxiang Zhang and Yao Lu and Yanyan Wang and Wei Pang and Hao Zhang and Xuexin Duan",

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AU - Zhang, Zhixin

AU - Tang, Zifan

AU - Liu, Wenpeng

AU - Zhang, Hongxiang

AU - Lu, Yao

AU - Wang, Yanyan

AU - Pang, Wei

AU - Zhang, Hao

AU - Duan, Xuexin

PY - 2016/11/1

Y1 - 2016/11/1

N2 - Controlled drug release has a high priority for the development of modern medicine and biochemistry. To develop a versatile method for controlled release, a miniaturized acoustic gigahertz (GHz) resonator is designed and fabricated which can transfer electric supply to mechanical vibrations. By contacting with liquid, the GHz resonator directly excites streaming flows and induces physical shear stress to tear the multilayered polyelectrolyte (PET) thin films. Due to the ultra-high working frequency, the shear stress is greatly intensified, which results in a controlled disassembling of the PET thin films. This technique is demonstrated as an effective method to trigger and control the drug release. Both theory analysis and controlled release experiments prove the thin film destruction and the drug release..

AB - Controlled drug release has a high priority for the development of modern medicine and biochemistry. To develop a versatile method for controlled release, a miniaturized acoustic gigahertz (GHz) resonator is designed and fabricated which can transfer electric supply to mechanical vibrations. By contacting with liquid, the GHz resonator directly excites streaming flows and induces physical shear stress to tear the multilayered polyelectrolyte (PET) thin films. Due to the ultra-high working frequency, the shear stress is greatly intensified, which results in a controlled disassembling of the PET thin films. This technique is demonstrated as an effective method to trigger and control the drug release. Both theory analysis and controlled release experiments prove the thin film destruction and the drug release..

KW - Bulk acoustic resonator

KW - Controlled drug release

KW - Layer-by-layer (LbL)

KW - MEMS

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Acoustically triggered disassembly of multilayered polyelectrolyte thin films through gigahertz resonators for controlled drug release applications

Abstract

Keywords

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