Interferometric plasmonic imaging and detection of single exosomes

Abstract: Exosomes play an important role in numerous cellular processes. Fundamental study and practical use of exosomes are significantly constrained by the lack of analytical tools capable of physical and biochemical characterization. In this paper, we present an optical approach capable of imaging single exosomes in a label-free manner, using interferometric plasmonic microscopy. We demonstrate monitoring of the real-time adsorption of exosomes onto a chemically modified Au surface, calculating the image intensity, … Show more

“…[17] In this way,s ingle exosomes have been visualized and analyzed after image reconstruction. [18] Alternatively,ahigh-spatial-resolution SPR image has been achieved by multidirectional or azimuthal rotation illumination, resulting in an order of magnitude enhancement in resolution compared to that of conventional SPRM. [19] In addition to the lateral (xy-direction) imaging capability, the SPR imaging technique is ultrasensitive in the vertical direction (z-direction).…”

Surface Plasmon Resonance Microscopy: From Single‐Molecule Sensing to Single‐Cell Imaging

“…[17] In this way,s ingle exosomes have been visualized and analyzed after image reconstruction. [18] Alternatively,ahigh-spatial-resolution SPR image has been achieved by multidirectional or azimuthal rotation illumination, resulting in an order of magnitude enhancement in resolution compared to that of conventional SPRM. [19] In addition to the lateral (xy-direction) imaging capability, the SPR imaging technique is ultrasensitive in the vertical direction (z-direction).…”

Surface Plasmon Resonance Microscopy: From Single‐Molecule Sensing to Single‐Cell Imaging

“…This difference could be described as phase, [15] which has not previously been used to describe parabolic patterns.T oq uantify the relationship between the refractive index and the phase of the pattern, ap articlescattering model with ap hase parameter was used. The surface plasmon interferometric scattering field (E s )w as given by: [16]…”

Identification of Nanoparticles via Plasmonic Scattering Interferometry

“…The success of these measurements showed that sensitive optical detection of nano-objects would indeed be possible through non-fluorescent means. In the decade that followed right up to the present day we see a broad array of research efforts, drawn from numerous communities, exploring interferometric detection of single nano-objects such as viruses, DNA, microtubules, exosomes, and proteins [75][76][77][78][79][80][81][82][83][84][85][86][87][88][89][90][91]. Interestingly, interferometric microscopies are also flourishing in the general context of label-free imaging of cells and membranes even if nanoparticles are not at the center of attention [75,76,90,[92][93][94][95][96][97][98][99][100][101][102][103][104][105][106].…”

“…Interestingly, interferometric microscopies are also flourishing in the general context of label-free imaging of cells and membranes even if nanoparticles are not at the center of attention [75,76,90,[92][93][94][95][96][97][98][99][100][101][102][103][104][105][106]. The underlying physics of these methods remains the same although a plethora of acronyms such as interference reflectance imaging sensing (IRIS) [77], rotating coherent scattering (ROCS) [98], interference plasmonic imaging (iPM) [88], coherent bright-field imaging (COBRI) [107], stroboscopic interference scattering imaging (stroboSCAT) [108], interferometric scattering mass spectrometry (iSCAMS) [109] are on the rise. In what follows, we bring all these techniques under the umbrella of iSCAT, emphasizing the two central concepts and mechanisms of interference and scattering as the basis for recording the extinction signal (nano-shadow) generated by nanoparticles.…”

Interferometric Scattering (iSCAT) Microscopy and Related Techniques