2021, Ucar, Buket, Kajtez, Janko, Foidl, Bettina M., Eigel, Dimitri, Werner, Carsten, Long, Katherine R., Emnéus, Jenny, Bizeau, Joëlle, Lomora, Mihai, Pandit, Abhay, Newland, Ben, Humpel, Christian

Protection or repair of the nigrostriatal pathway represents a principal disease-modifying therapeutic strategy for Parkinson's disease (PD). Glial cell line-derived neurotrophic factor (GDNF) holds great therapeutic potential for PD, but its efficacious delivery remains difficult. The aim of this study was to evaluate the potential of different biomaterials (hydrogels, microspheres, cryogels and microcontact printed surfaces) for reconstructing the nigrostriatal pathway in organotypic co-culture of ventral mesencephalon and dorsal striatum. The biomaterials (either alone or loaded with GDNF) were locally applied onto the brain co-slices and fiber growth between the co-slices was evaluated after three weeks in culture based on staining for tyrosine hydroxylase (TH). Collagen hydrogels loaded with GDNF slightly promoted the TH+ nerve fiber growth towards the dorsal striatum, while GDNF loaded microspheres embedded within the hydrogels did not provide an improvement. Cryogels alone or loaded with GDNF also enhanced TH+ fiber growth. Lines of GDNF immobilized onto the membrane inserts via microcontact printing also significantly improved TH+ fiber growth. In conclusion, this study shows that various biomaterials and tissue engineering techniques can be employed to regenerate the nigrostriatal pathway in organotypic brain slices. This comparison of techniques highlights the relative merits of different technologies that researchers can use/develop for neuronal regeneration strategies. © 2020

2021, Lomora, Mihai, Larrañaga, Aitor, Rodriguez-Emmenegger, Cesar, Rodriguez, Brian, Dinu, Ionel Adrian, Sarasua, Jose-Ramon, Pandit, Abhay

Translating energy into swarming motion for miniature entities remains a challenge. This translation requires simultaneously breaking the symmetry of the system to enable locomotion and a coupling effect between the objects that are part of the population to induce the collective motion. Here, we report on Robocoliths, engineered Emiliania huxleyi (EHUX) coccolith-based miniature hybrid entities capable of swarming behavior. EHUX coccoliths are characterized by an asymmetric morphology that allows breaking symmetry, playing a central role in generating a net force and directed motion. Their activation with the bioinspired material polydopamine not only endows the asymmetric coccoliths with advanced functionalities, such as thermal- and energy-harvesting responsiveness under visible light exposure to display a collective behavior (i.e., swarming), but it also provides a functional surface from which antifouling polymer brushes are grown. In this context, Robocoliths pave the way for the next generation of multifunctional swarming bio-micromachines. © 2021 The Author(s)Establishment of controlled nano- and mesoscopic energized entities that gather, in a concerted effort, into motile aggregated patterns is at the forefront of scientific discovery. Lomora et al. report on coccolith-polydopamine hybrids (Robocoliths) that heat and move collectively upon light excitation and accommodate antifouling brushes on their surface. © 2021 The Author(s)