Hybrid microswimmers which contain a biological power source for the propulsion of artificially synthetized microstructures is an appealing approach for the controlled actuation on the small scale. In particular, biological swimmers offer a biocompatible solution for the motion and cargo delivery in the low Reynolds number regime. Our approach to a hybrid microswimmer consists of ferromagnetic nanomembranes which roll up into microtubes and capture single bovine spermatozoa. The single motile cell is able to propel the rolled up microtube forward while an external magnetic field can be used to guide the sperm-flagella driven micro-bio-robot to desired locations. As our project title reveals, the aim of this work is, on the one hand to gain a deeper understanding of sperm motion in the confinement of microtubes, on the other hand to go step by step towards biomedical applications which the sperm-driven micro-bio-robots are promising for. The main goal of the fundamental studies of this project is to understand the biophysical dynamics of sperm-driven micro-bio-robots in more realistic environments. This includes higher viscosity media, non-Newtonian fluids and other conditions that are given in the natural surroundings of spermatozoa and also in general in body fluids. Furthermore, we will investigate the influence of stimuli on the sperm-driven micro-bio-robots and explore their suitability as control mechanisms. Taxis mechanisms such as rheotaxis (orientation against fluid flow) and thigmotaxis (interaction with surfaces) will be in the focus of our investigations. Especially interesting and challenging in the taxis-based context will be the interplay of the different control mechanisms of the sperm-driven micro-bio-robots. For instance, what is the minimum magnetic field strength needed to overrule the rheotactic orientation, will the sperm-driven micro-bio-robot reorient in the flow after the magnetic field is turned off? These and further questions will be addressed in this part of the project. Furthermore, we plan to study the interaction of the sperm-driven micro-bio-robots with the cumulus cell layer, which is a viscous cell layer which the spermatozoa encounter on their way to the oocyte. Surface modifications of the microtubes will be implemented in order to degrade the cumulus cells locally and free the way to the oocyte. The potential of the sperm-driven micro-bio-robots to serve as active drug carriers will be explored. In summary, this will lead to important progress in the fundamental understanding of sperm motion but also be helpful towards applications of the sperm-driven micro-bio-robots in assisted reproduction or drug delivery.

DFG Programme Priority Programmes

Subproject of SPP 1726:  Microswimmers - From Single Particle Motion to Collective Behaviour

International Connection Netherlands

Cooperation Partner Professor Sarthak Misra, Ph.D.