TY - GEN
T1 - Design and Simulation Optimization of a Novel Oocyte Ultrasonic Micro-dissection Instrument
AU - Gao, Xiwei
AU - Huang, Haibo
AU - Chen, Liguo
AU - Pan, Mingqiang
AU - Yan, Su
AU - Li, Yaqing
AU - Sun, Lining
N1 - Publisher Copyright:
© 2018 IEEE.
PY - 2018/12/18
Y1 - 2018/12/18
N2 - The zona pellucida (ZP) micro-dissection technology has played a key role in the field of artificial assisted reproduction (such as ZP thinning, preimplantation genetic diagnosis (PGD), etc.). Currently, laser ZP micro-cutting technology using far-infrared beam has the disadvantages of high price, thermal damage, and low degree of freedom. Piezoelectric ultrasonic micro-cutting technology has matured at the biological tissue level, but ultrasonic cutting at the single-cell level is still difficult to achieve. In this paper, based on piezoelectric ultrasonic tissue micro-cutting theory, the mechanism of ultrasonic cutting of the oocyte ZP was researched, and a cutting method for the ZP was proposed. Based on the design formula of flexure's stiffness, this paper analyzes the effects of dimension parameters on the vibration condition of micro-needle. An ultrasonic cell surgery instrument based on a three-dimensional stereoscopic flexure-guided structure was designed. The modal analysis and the harmonic response analysis of the structure were performed using finite element software. The experimental results show that the lateral amplitude of the newly designed device's needle tip is smaller than the traditional one in the specified range of frequency. Among them, when the operating frequency is around 22.1 kHz, the lateral amplitude of the needle tip is reduced to 0.021\mu \mathrm{m}. Finally, the theoretical method of piezoelectric ultrasonic cutting on single cell layer is presented for the first time, which has a broad prospect and significance for artificial assisted reproduction.
AB - The zona pellucida (ZP) micro-dissection technology has played a key role in the field of artificial assisted reproduction (such as ZP thinning, preimplantation genetic diagnosis (PGD), etc.). Currently, laser ZP micro-cutting technology using far-infrared beam has the disadvantages of high price, thermal damage, and low degree of freedom. Piezoelectric ultrasonic micro-cutting technology has matured at the biological tissue level, but ultrasonic cutting at the single-cell level is still difficult to achieve. In this paper, based on piezoelectric ultrasonic tissue micro-cutting theory, the mechanism of ultrasonic cutting of the oocyte ZP was researched, and a cutting method for the ZP was proposed. Based on the design formula of flexure's stiffness, this paper analyzes the effects of dimension parameters on the vibration condition of micro-needle. An ultrasonic cell surgery instrument based on a three-dimensional stereoscopic flexure-guided structure was designed. The modal analysis and the harmonic response analysis of the structure were performed using finite element software. The experimental results show that the lateral amplitude of the newly designed device's needle tip is smaller than the traditional one in the specified range of frequency. Among them, when the operating frequency is around 22.1 kHz, the lateral amplitude of the needle tip is reduced to 0.021\mu \mathrm{m}. Finally, the theoretical method of piezoelectric ultrasonic cutting on single cell layer is presented for the first time, which has a broad prospect and significance for artificial assisted reproduction.
KW - Flexure-guided
KW - Lateral amplitude
KW - Micro-dissection
KW - Single cell layer
UR - https://www.scopus.com/pages/publications/85060775939
U2 - 10.1109/ICARCV.2018.8581216
DO - 10.1109/ICARCV.2018.8581216
M3 - 会议稿件
AN - SCOPUS:85060775939
T3 - 2018 15th International Conference on Control, Automation, Robotics and Vision, ICARCV 2018
SP - 591
EP - 596
BT - 2018 15th International Conference on Control, Automation, Robotics and Vision, ICARCV 2018
PB - Institute of Electrical and Electronics Engineers Inc.
T2 - 15th International Conference on Control, Automation, Robotics and Vision, ICARCV 2018
Y2 - 18 November 2018 through 21 November 2018
ER -