Felicidades al nuevo graduado de doctorado del ICFO
El Dr. Unai Ortiz de Orruño Cuesta se ha graduado con una tesis titulada ‘Optical Holographic Microscopy for Bio- and Nanoparticle Characterization’
Felicitamos el Dr. Unai Ortiz de Orruño Cuesta que hoy ha defendido su tesis en el auditorio del ICFO.
El Dr. Ortiz de Orruño Cuesta obtuvo su máster en Fotónica por la Universitat Politècnica de Catalunya. Se unió como estudiante de doctorado en el grupo de investigación de Molecular Nanophotonics en ICFO dirigido por el Profesor ICREA Niek van Hulst. La tesis del Dr. Ortiz de Orruño Cuesta titulada ‘Optical Holographic Microscopy for Bio- and Nanoparticle Characterization’ fue supervisada por el Profesor ICREA Niek van Hulst.
RESUMEN:
Nowadays, being able to precisely characterize nanoparticles is of key relevance in a wide range of scenarios. For instance, chemical and pharmaceutical industries often rely in particle-sizing for quality control. In a clinical context, in contrast, sensitive bioparticle characterization platforms can lead to the diagnosis of early-stage illnesses. However, the needs between each scenario vary, due to the differences in samples’ composition and the particle-property of interest. Hence, several nanoparticle characterization techniques have emerged, each one based on a different physical principle and best suited for particular usage scopes.
In this thesis, I improve the optical nanoparticle sizing techniques by using holography. I present different optical systems that image nanoparticles and record their scattering signal into holograms. I show how to reconstruct the scattered light’s wavefront using holographic processing tools and how to extract the particle size information from it. I prove the capabilities of the holographic imaging systems that I introduce by providing their technical characterization and by measuring relevant samples.
First, I introduce an imaging system with an extended the dynamic range compared to conventional darkfield microscopes. I demonstrate the nanoparticle sizing capabilities of such holographic platform using calibration samples. Moreover, I provide a proof-of-concept in the form of the characterization of a clinical sample, composed by extracellular vesicles, to demonstrate the feasibility of the platform for the development of point-of-care systems.
Afterwards, I show how nanoparticle tracking analysis (NTA), that is to size particles from their diffusion, can be improved by using holography. The use of holography not only increases the NTA’s precision, thanks to its ability to capture better the particles’ diffusion, but also provides the refractive index information of the sample. The latter is of especial interest when measuring samples of unknown compositions, such as clinical extractions. I present experimental evidence of the improvements in the NTA’s sizing precision and the simultaneous retrieval of the refractive index. Additionally, I measure the radial shift of the nanoparticles induced by the formation of protein-coronas, which I believe that proves the platform’s relevance for studying the particles’ behaviour in biological fluids.
Finally, I present a system that confines particles in the volume-of-view of a holographic imaging system for further improving the NTA’s sizing precision. Such platform’s design was motivated by the promising results obtained using holographic NTA and its potential usage on fundamental research of protein-corona formation. The idea behind the system is to obtain longer particle-diffusion trajectories for pushing the holographic NTA sensitivity down to what is necessary to detect the absorption of a single protein onto a nanoparticle. I demonstrate the capabilities of such platform by showing a thorough technical evaluation based on experimental evidence.
I foresee that the presented holographic platforms will find many applications of both fundamental and applied nature. In particular, considering the ability of such platforms to analyse polydisperse samples, I expect to contribute to advances in the fundamental research of extracellular vesicles.
Comité de Tesis:
Prof. Dr. Valerio Pruneri, ICFO
Prof. Dr. Laura Lechuga Gómez, Institut Català de Nanociència i Nanotecnologia (ICN2)
Dr. Ramón Ángel Álvarez Puebla, Universitat Rovira i Virgili (URV)