Nanoparticle-sensitized photoporation is an upcoming approach for intracellular delivery of biologics, combining high efficiency and throughput with excellent cell viability. However, as it relies on close contact between nanoparticles and cells, its translation towards clinical applications is hampered by safety and regulatory concerns. Here, we show that light-sensitive iron oxide nanoparticles (IONPs) embedded in biocompatible electrospun nanofibers induce membrane permeabilization by photothermal effects without direct cellular contact with IONPs. The photothermal nanofibers are successfully used to deliver effector molecules, including CRISPR/Cas9 ribonucleoprotein complexes and siRNA, in adherent and suspension cells, including embryonic stem cells and hard-to-transfect T-cells without affecting cell proliferation or phenotype.
In vivo
experiments furthermore demonstrate successful tumor regression in mice treated with CAR-T cells in which expression of PD1 is downregulated after nanofiber photoporation with siPD1. In conclusion, cell membrane permeabilization with photothermal nanofibers is a promising concept towards the safe and more efficient production of engineered cells for therapeutic applications, including stem cell or adoptive T cell therapy.
The globalization of drug trade leads to the expansion of pharmaceutical counterfeiting. The immense threat of low quality drugs to millions of patients is considered to be an under‐addressed global health challenge. Analytical authentication technologies are the most effective methods to identify active pharmaceutical ingredients and impurities. However, most of these analytical testing techniques are expensive and need skilled personnel. To combat counterfeiting of drugs, the package of an increasing number of drugs is being protected through advanced package labeling technologies. Though, package labeling is only effective if the drugs are not repackaged. Therefore “in‐drug labeling,” instead of “drug package labeling,” may become powerful tools to protect drugs. This review aims to overview how advanced micro‐ and nanomaterials might become interesting markers for the labeling of tablets and capsules. Clearly, how well such identifiers can be integrated into “solid drugs” without compromising drug safety and efficacy remains a challenge. Also, incorporation of tags has so far only been reported for the protection of solid drug dosage forms. No doubts that in‐drug labeling technologies for “liquid drugs,” like injectables which contain expensive peptides, monoclonal antibodies, vaccines, dermal fillers, could help to protect them from counterfeiting as well.
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