Abstract

In recent years, carbon nanotubes have emerged as a potentially revolutionary material with numerous uses in biomedical applications. Compared to other nanoparticles, discrete multiwalled carbon nanotubes (dMWCNTs) have been shown to exhibit advantageous characteristics such as a high surface area-to-volume ratio, biocompatibility, and unique chemical and physical properties. dMWCNTs can be modified to load various molecules such as proteins and nucleic acids and are capable of crossing the cell membrane, making them attractive delivery vehicles for biomolecules. To investigate this, we measured the impact of dMWCNTs on the number of live and dead cells present during different stages of cell proliferation. Furthermore, we used transmission electron microscopy to produce evidence suggesting that dMWCNTs enter the cytoplasm of mammalian cells via an endocytosis-like process and ultimately escape into the cytoplasm. And lastly, we used live-cell staining, qPCR, and a T-cell activation detection assay to quantify the use of dMWCNTs as a delivery vehicle for a toxic, membrane-impermeable peptide, mRNA, siRNA, and a T-cell activating synthetic dsRNA. We demonstrate successful delivery of each payload into a range of cell types, providing further evidence of dMWCNTs as a versatile delivery platform for biomolecular cargo.

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