Limpet Tooth-Inspired Painless Microneedles Fabricated by Magnetic Field-Assisted 3D Printing

Li Xiangjia; Shan Weitong; Yang Yang; Joralmon Dylan; Zhu Yizhen; Chen Yiyu; Yuan Yuan; Xu Han; Rong Jiahui; Dai Rui; Nian Qiong; Chai Yang; Chen Yong

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Limpet Tooth-Inspired Painless Microneedles Fabricated by Magnetic Field-Assisted 3D Printing

机译：耐磁场辅助3D印刷制造的颗粒耐牙齿启发无痛微针

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Microneedle arrays show many advantages in drug delivery applications due to their convenience and reduced risk of infection. Compared to other microscale manufacturing methods, 3D printing easily overcomes challenges in the fabrication of microneedles with complex geometric shapes and multifunctional performance. However, due to material characteristics and limitations on printing capability, there are still bottlenecks to overcome for 3D printed microneedles to achieve the mechanical performance needed for various clinical applications. The hierarchical structures in limpet teeth, which are extraordinarily strong, result from aligned fibers of mineralized tissue and protein-based polymer reinforced frameworks. These structures provide design inspiration for mechanically reinforced biomedical microneedles. Here, a bioinspired microneedle array is fabricated using magnetic field-assisted 3D printing (MF-3DP). Micro-bundles of aligned iron oxide nanoparticles (aIOs) are encapsulated by polymer matrix during the printing process. A bioinspired 3D-printed painless microneedle array is fabricated, and suitability of this microneedle patch for drug delivery during long-term wear is demonstrated. The results reported here provide insights into how the geometrical morphology of microneedles can be optimized for the painless drug delivery in clinical trials.

机译：由于它们的便利性和感染风险降低，微针阵列在药物递送应用中显示了许多优点。与其他微尺度制造方法相比，3D打印容易克服了具有复杂几何形状和多功能性能的微针的制造中的挑战。然而，由于材料特性和对印刷能力的限制，仍然有瓶颈克服3D印刷的微针来实现各种临床应用所需的机械性能。恒星齿中的分层结构是非常强的，导致矿化组织和基于蛋白质的聚合物增强框架的对齐纤维产生。这些结构为机械增强的生物医学微针提供了设计灵感。这里，使用磁场辅助3D打印（MF-3DP）制造生物悬浮的微针阵列。在印刷过程中，通过聚合物基质包封了一团对准的氧化铁纳米颗粒（AIO）。制造了生物悬浮的3D印刷无痛的微针阵列，并证明了这种微针贴片用于长期磨损期间的药物递送的胶片。此处报告的结果提供了对微针的几何形态如何优化临床试验中无痛药物递送的态度。

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来源
《Advanced Functional Materials 》 |2021年第5期| 2003725.1-2003725.11| 共11页
作者
Li Xiangjia; Shan Weitong; Yang Yang; Joralmon Dylan; Zhu Yizhen; Chen Yiyu; Yuan Yuan; Xu Han; Rong Jiahui; Dai Rui; Nian Qiong; Chai Yang; Chen Yong;
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Arizona State Univ Sch Engn Matter Transport & Energy Dept Aerosp & Mech Engn 501 E Tyler Mall Tempe AZ 85287 USA;

Univ Southern Calif Viterbi Sch Engn Mork Family Dept Chem Engn & Mat Sci 925 Bloom Walk Los Angeles CA 90089 USA;

San Diego State Univ Dept Mech Engn 5500 Campanile Dr San Diego CA 92182 USA;

Arizona State Univ Sch Engn Matter Transport & Energy Dept Aerosp & Mech Engn 501 E Tyler Mall Tempe AZ 85287 USA;

Arizona State Univ Sch Engn Matter Transport & Energy Dept Aerosp & Mech Engn 501 E Tyler Mall Tempe AZ 85287 USA;

Univ Southern Calif Viterbi Sch Engn Dept Aerosp & Mech Engn 3650 McClintock Ave Los Angeles CA 90089 USA;

Univ Southern Calif Ctr Craniofacial Mol Biol 2250 Alcazar St Los Angeles CA 90089 USA;

Univ Southern Calif Epstein Dept Ind & Syst Engn 3715 McClintock Ave Los Angeles CA 90089 USA;

Univ Southern Calif Viterbi Sch Engn Dept Aerosp & Mech Engn 3650 McClintock Ave Los Angeles CA 90089 USA;

Arizona State Univ Sch Engn Matter Transport & Energy Dept Aerosp & Mech Engn 501 E Tyler Mall Tempe AZ 85287 USA;

Arizona State Univ Sch Engn Matter Transport & Energy Dept Aerosp & Mech Engn 501 E Tyler Mall Tempe AZ 85287 USA;

Univ Southern Calif Ctr Craniofacial Mol Biol 2250 Alcazar St Los Angeles CA 90089 USA;

Univ Southern Calif Viterbi Sch Engn Dept Aerosp & Mech Engn 3650 McClintock Ave Los Angeles CA 90089 USA|Univ Southern Calif Epstein Dept Ind & Syst Engn 3715 McClintock Ave Los Angeles CA 90089 USA;

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正文语种 eng
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关键词
3D printing; limpet teeth; magnetic field; mechanical reinforcement; microneedles;

机译：3D打印;颗粒齿;磁场;机械加固;微针;

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专利

1. Characterizations of continuous carbon fiber-reinforced composites for electromagnetic interference shielding fabricated by 3D printing [J] . Yin Lixian, Tian Xiaoyong, Shang Zhentao, Applied Physics . 2019 ,第4期

机译：通过3D打印制造的用于电磁干扰屏蔽的连续碳纤维增强复合材料的特性
2. Characterizations of continuous carbon fiber-reinforced composites for electromagnetic interference shielding fabricated by 3D printing [J] . Yin Lixian, Tian Xiaoyong, Shang Zhentao, Applied Physics . 2019 ,第4期

机译：3D打印制造的电磁干扰屏蔽连续碳纤维增强复合材料的特征
3. Electromagnetic interference shielding and mechanical properties of Si~(3N)4-SiOC composites fabricated by 3D-printing combined with polymer infiltration and pyrolysis [J] . Duan Wenyan, Fan Zhe, Wang Hui, Journal of Materials Research . 2017 ,第17期

机译：3D打印结合聚合物渗透与热解制备的Si〜（3N）4-SiOC复合材料的电磁干扰屏蔽和力学性能
4. MAGNETIC FIELD ASSISTED 3D PRINTING OF LIMPET TEETH INSPIRED POLYMER MATRIX COMPOSITE WITH COMPRESSION REINFORCEMENT [C] . Dylan Joralmon, Evangeline Amonoo, Yizhen Zhu, International Manufacturing Science and Engineering Conference . 2021

机译：磁场辅助3D印刷颗粒齿启发了聚合物基质复合材料，采用压缩加固
5. Micro-3D Printing of Bio-inspired Microneedle with Enhanced Adhesion Capabilities [D] . Morde, Riddish Sudhir 2018

机译：具有增强粘合能力的生物启发式微针的Micro-3D打印
6. Simple and customizable method for fabrication of high-aspect ratio microneedle molds using low-cost 3D printing [O] . Kevin J. Krieger, Nicky Bertollo, Manita Dangol, 2019

机译：使用低成本3D打印制造高纵横比微针模具的简单且可定制的方法
7. 3D Printing—A “Touch-Button” Approach to Manufacture Microneedles for Transdermal Drug Delivery [O] . Merima Sirbubalo, Amina Tucak, Kenan Muhamedagic, 2021

机译：3D打印 - 一种制造微针的“触摸按钮”方法，用于透皮药物输送

Limpet Tooth-Inspired Painless Microneedles Fabricated by Magnetic Field-Assisted 3D Printing

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