妥协
免疫原性
动力学(音乐)
免疫系统
物理
计算机科学
纳米技术
人机交互
生物
材料科学
免疫学
社会学
声学
社会科学
作者
Immihan Ceren Yasa,Hakan Ceylan,Ugur Bozuyuk,Anna‐Maria Wild,Metin Sitti
出处
期刊:Science robotics
[American Association for the Advancement of Science]
日期:2020-06-10
卷期号:5 (43)
被引量:193
标识
DOI:10.1126/scirobotics.aaz3867
摘要
The structural design parameters of a medical microrobot, such as the morphology and surface chemistry, should aim to minimize any physical interactions with the cells of the immune system. However, the same surface-borne design parameters are also critical for the locomotion performance of the microrobots. Understanding the interplay of such parameters targeting high locomotion performance and low immunogenicity at the same time is of paramount importance yet has so far been overlooked. Here, we investigated the interactions of magnetically steerable double-helical microswimmers with mouse macrophage cell lines and splenocytes, freshly harvested from mouse spleens, by systematically changing their helical morphology. We found that the macrophages and splenocytes can recognize and differentially elicit an immune response to helix turn numbers of the microswimmers that otherwise have the same size, bulk physical properties, and surface chemistries. Our findings suggest that the structural optimization of medical microrobots for the locomotion performance and interactions with the immune cells should be considered simultaneously because they are highly entangled and can demand a substantial design compromise from one another. Furthermore, we show that morphology-dependent interactions between macrophages and microswimmers can further present engineering opportunities for biohybrid microrobot designs. We demonstrate immunobots that can combine the steerable mobility of synthetic microswimmers and the immunoregulatory capability of macrophages for potential targeted immunotherapeutic applications.
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