Optical collection of extracellular vesicles in a culture medium enhanced by interactions with gold nanoparticles.

Extracellular vesicles (EVs) exist in biological fluids such as blood, urine, and cerebrospinal fluid and are promising cancer biomarkers. Attempts to isolate and analyze trace EVs, however, have been a challenge for researchers studying their functions and secretion mechanisms, which has stymied the options for diagnostic application. This study demonstrated a collection of EVs that was enhanced by gold nanoparticles (AuNPs) via the use of optical force. The collection system consists of an inverted microscope equipped with a CCD camera, a square capillary connected with a PTFE tube, and an Nd:YAG laser that generates optical force. The laser beam was focused on a capillary wall in which a cell culture medium containing EVs flowed continuously. Control of the surface charges on both the capillary wall and the AuNPs achieved the collection and retention of EVs on the capillary wall. The positively charged capillary wall retained EVs even after the laser irradiation was halted due to the negative charges inherent on the surface of EVs. Conversely, positively charged AuNPs had a strong electrostatic interaction with EVs and enhanced the optical force acting on them, which made collecting them a much more efficient process.

Indirect capillary electrophoresis immunoassay of membrane protein in extracellular vesicles.

Extracellular vesicles (EVs) exist in biological fluids such as blood, urine, and cerebrospinal fluid, and these have shown promise for use as biomarkers of cancers. Conventional methods for determination of EVs include direct detection via enzyme-linked immunosorbent assay and detection of their membrane proteins via western blotting. These techniques, however, have individual shortcomings in terms of the need for large sample consumption, processes that are time-consuming, and a lack of the capacity for quantification. In this study, we developed a method to determine the EV membrane protein, CD63, by coupling capillary electrophoresis immunoassay with laser-induced fluorescence (CEIA-LIF). In this process, the EVs were isolated from a culture medium and were subsequently reacted with a fluorescently labeled anti-CD63 antibody to form a CD63 complex localized on the surface of EVs. After removing the EVs containing the CD63 immune complex by centrifugation, the supernatant containing the free fluorescent antibody was injected into a capillary to serve as a sample. A decrease in the peak area of the free fluorescent antibody became apparent when the amount of EVs was increased while that of the fluorescent antibody remained constant. The peak areas were decreased proportionally against the increased amounts of EVs. The concentration of the CD63 could then be estimated based on the slope of the linear relationship. This study is the first to quantify CD63 immobilized on EVs via CEIA-LIF, which is a novel method with the potential to determine membrane proteins localized on the surface of EVs.

Enhancement of optical force acting on vesicles via the binding of gold nanoparticles.

Here we found that gold nanoparticles (AuNPs) enhance the optical force acting on vesicles prepared from phospholipids via hydrophobic and electrostatic interactions. A laser beam was introduced into a cuvette filled with a suspension of vesicles and it accelerated them in its propagation direction via a scattering force. The addition of the AuNPs exponentially increased the velocity of the vesicles as their concentration increased, but polystyrene particles had no significant impact on velocity in the presence of AuNPs. To elucidate the mechanism of the increased velocity, the surface charges in the vesicles and the AuNPs were controlled; the surface charges of the vesicles were varied via the use of anionic, cationic and neutral phospholipids, whereas AuNPs with positive and negative charges were synthesized by coating with citrate ion and 4-dimethylaminopyridine, respectively. All vesicles increased the velocity at different degrees depending on the surface charge. The vesicles were accelerated more efficiently when their charges were opposite those of the AuNPs. These results suggested that hydrophobic and electrostatic interactions between the vesicles and the AuNPs enhanced the optical force. By accounting for the binding constant between the vesicles and the AuNPs, we proposed a model for the relationship between the concentration of the AuNPs and the velocity of the vesicles. Consequently, the increased velocity of the vesicles was attributed to the light scattering that was enhanced when AuNPs were adsorbed onto the vesicles.