(Invited) An in Vitro Model of Mechanical Strain Enhances Cellular Uptake of Single-Walled Carbon Nanotubes

Abstract

Single-walled carbon nanotubes (SWCNTs) are ideal optical biosensors due to their intrinsic near-infrared (NIR) emission, which is highly sensitive, easily tunable, and indefinitely photostable. Due to such desirable properties coupled with appropriate functionalization strategies, SWCNTs have been used in numerous in vitro, live-cell, and in vivo applications. Depending on the type of functionalization as well as cell type, SWCNTs can be internalized by live cells via demonstrated energy-dependent endocytosis processes where they are retained within the endosomal pathway or are expelled by the cells. While this uptake and intracellular processing of SWCNTs has been recently examined, these studies are usually performed with standard cell culture techniques in petri dishes or 3D cultures. Unlike these cultures, cells in living organisms are continuously exposed to a wide variety of stimuli, e.g., periodic mechanical strain, during both normal and disease-related conditions. Thus, it is important to investigate how cells under physiological stretching compare to those grown in standard cultures. Herein, using a novel cell stretching platform to mimic physiological conditions, we investigate the uptake of SWCNTs into different human cancer cells.Our results indicate that cells exposed to uniform radial stretching display significantly higher rates of nanoparticle uptake, which can be correlated to their increased level of cellular activity. This approach recognizes the importance of studying cellular responses in environments that more closely resemble the complex conditions found in living organisms. It suggests a potential connection between mechanical stimuli and cellular processes related to SWCNT uptake. This finding has implications for understanding how nanotube uptake differs in different cellular stress environments and how cells respond to their dynamic and ever-changing microenvironment.Investigating how the mechanical strain influences the endocytosis processes and subsequent intracellular fate of SWCNTs can provide valuable insights into the interplay between nanomaterials and living cells under more realistic conditions. Further aiding us in the development of more accurate intracellular biosensors and effective drug delivery platforms using SWCNTs.