Staff member publications
Hinnekens, Charlotte, Harizaj, Aranit, Berdecka, Dominika, Aernout, Ilke, Shariati, Molood, Peeters, Stefanie, Lion, Eva, De Smedt, Stefaan C, Vandekerckhove, Bart, Braeckmans, Kevin, Fraire, Juan C, (2024). Photoporation of NK-92MI cells with biodegradable polydopamine nanosensitizers as a promising strategy for the generation of engineered NK cell therapies Applied Materials Today 40, 102402
Chimeric antigen receptor (CAR)-T cells have made significant advancements in the field of adoptive immune cell therapies and the treatment of hematological malignancies. However, there are several drawbacks associated with the production and administration of these therapies. As a result, there has been interest in using natural killer (NK) cells to develop allogeneic CAR-NK cell therapies instead. While viral transduction is powerful for engineering T cells, NK cells have shown limited efficacy and high toxicity with this method. Therefore, efforts are being made to optimize non-viral transfection technologies for engineering NK cells. One such emerging technology is photoporation, which has demonstrated high efficiency and versatility for transfecting different immune cells. In this study, we evaluated the potential of nanoparticle-sensitized photoporation for genetic engineering of NK cells. Our findings show that both FD500 and eGFP mRNA can be successfully delivered into NK-92MI cells with high efficiency and low toxicity. When compared to state-of-the-art electroporation, photoporation proved to be more efficient, gentle, and capable of preserving the phenotype of NK-92MI cells. Overall, our work highlights the promising prospects of photoporation for NK cell engineering.
JTD Keywords: Cancer immunotherapie, Car, Cell engineering, Deliver, Messenger-rna, Nanoparticles, Natural killer cells, Natural-killer-cells, Photoporation, Polydopamine nanoparticles, T-cells
Ferrer Campos, Rebeca, Bakenecker, Anna C., Chen, Yufen, Spadaro, Maria Chiara, Fraire, Juan, Arbiol, Jordi, Sánchez, Samuel, Villa, Katherine, (2024). Boosting the Efficiency of Photoactive Rod-Shaped Nanomotors via Magnetic Field-Induced Charge Separation Acs Applied Materials & Interfaces 16, 30077-30087
Photocatalytic nanomotors have attracted a lot of attention because of their unique capacity to simultaneously convert light and chemical energy into mechanical motion with a fast photoresponse. Recent discoveries demonstrate that the integration of optical and magnetic components within a single nanomotor platform offers novel advantages for precise motion control and enhanced photocatalytic performance. Despite these advancements, the impact of magnetic fields on energy transfer dynamics in photocatalytic nanomotors remains unexplored. Here, we introduce dual-responsive rod-like nanomotors, made of a TiO2/NiFe heterojunction, able to (i) self-propel upon irradiation, (ii) align with the direction of an external magnetic field, and (iii) exhibit enhanced photocatalytic performance. Consequently, when combining light irradiation with a homogeneous magnetic field, these nanomotors exhibit increased velocities attributed to their improved photoactivity. As a proof-of-concept, we investigated the ability of these nanomotors to generate phenol, a valuable chemical feedstock, from benzene under combined optical and magnetic fields. Remarkably, the application of an external magnetic field led to a 100% increase in the photocatalytic phenol generation in comparison with light activation alone. By using various state-of-the-art techniques such as photoelectrochemistry, electrochemical impedance spectroscopy, photoluminescence, and electron paramagnetic resonance, we characterized the charge transfer between the semiconductor and the alloy component, revealing that the magnetic field significantly improved charge pair separation and enhanced hydroxyl radical generation. Consequently, our work provides valuable insights into the role of magnetic fields in the mechanisms of light-driven photocatalytic nanomotors for designing more effective light-driven nanodevices for selective oxidations.
JTD Keywords: Charge transfer, Dual-responsive nanomotors, Magnetic properties, Photoactive nanomotors, Photocatalysis, Selective oxidations