Host Research Group
ES5_SPECTROSCOPY _Francisco José Basterretxea Elguezabal
Francisco José Basterretxea Elguezabal
+34 94 601 2532
franciscojose.basterretxea@ehu.eus
http://www.grupodeespectroscopia.es
Group description
The Spectroscopy Group works in research lines that comprise different subjects, all focusing on a molecular and nanometric scale. It designs and applies state of the art spectroscopic techniques to a variety of problems in chemistry that partly overlap with the fields of biology or physics. The group works in spectroscopic instrumentation to achieve high resolutions, both in time and energy, and high control of physical and chemical properties at the nanoscale. Thus, ultrafast lasers allow detection of phenomena in the timescale of femtoseconds, whereas microwave spectrometers can resolve molecular energy levels that differ only a few kHz. On the other hand, combining nanosecond laser pulses with mass spectrometric detection it is possible to discriminate among different molecular conformers of the same species. Finally, and the most relevant for this call, laser lithography techniques, together with magneto-optical spectroscopy, allow fabrication and characterization of singular patterned nanostructures.
A brief list of the ongoing research lines of the group is given below:
• The study of ultrafast molecular phenomena using femtosecond laser pulses, such as dissociative processes, energy transfer among excited electronic states, or between solute and solvent molecules, that are essential to understand intra- and intermolecular interactions.
• Microwave spectroscopy techniques, combined with laser vaporization techniques, allow to obtain molecular structures and gas-phase dynamics of biomolecular building blocks, such as sugars. These studies are also the basis for the detection of prebiotic molecules in the interstellar space.
• Laser electronic spectroscopy with pulsed supersonic jets and mass resolution is a powerful tool to characterize electronic transitions of rather big molecules and can further discriminate among a usually numerous family of conformers. This techniques are adequate to study interactions between molecular moieties of interest in the biosciences, such as anesthesic-receptor, or bonding among the nitrogenated bases in DNA and RNA chains.
• More specific mass spectrometric techniques, such as Matrix Assisted Laser Desorption Ionization (MALDI), allow the obtention of bidimensional images of biological tissues; that allow quick monitoring of the distributions of lipids or other substances. This technique has immediate medical applications.
• Nanofabrication and characterization of structures at the nanometer scale allow designing of magnetic nanostructures (discs, rods and other geometries) with distinctive properties, different from those of macroscopic elements. These patterned structures have a wide application in fields such as magnetic storage of information or biomedicine, for example, cancer diagnostics.
Keywords
- ultrafast processes
- rotational spectroscopy
- laser spectroscopy
- MALDI
- magnetic nanostructures
- nanofabrication
Team Description
-
Francisco J. Basterretxea Elguezabal (Principal Investigator)
ORCID: 0000-0002-0420-2625
-
Rafael Morales Arboleya (Research staff)
ORCID: 0000-0003-1733-2039
-
Carolina Redondo Esteban (Research staff)
ORCID: 0000-0002-2236-8629
-
José Andrés Fernández (Research staff)
ORCID: 0000-0002-7315-2326
-
Asier Longarte Aldama (Research staff)
ORCID: 0000-0001-6191-4576
-
Emilio José Cocinero Pérez (Research staff)
ORCID: 0000-0001-7632-3728
-
Imanol Usabiaga Gutiérrez (Research staff)
ORCID: 0000-0002-1621-8536
-
Ernesto García Para (Research staff)
ORCID: 0000-0001-8778-8141
-
Roberto Martínez Pérez de Mendiola (Research staff)
ORCID: 0000-0003-4228-821X
Projects
-
Novel magnetic nanostructures for medical applications
Pl: Rafael Morales Arboleya
Funding Agency*: European
Ongoing: yes
Project reference: H2020-MSCA-RISE14/05
-
Magnetic textures in multilayers and nanodisks: Optical manipulation and biomedical application
Pl: Rafael Morales Arboleya
Funding Agency*: National
Ongoing: yes
Project reference: MINECOR19/P53
-
Espectroscopía y dinámica en expansiones supersónicas: Interacciones no covalentes en moléculas de interés biológico y prebiótico
Pl: José Andrés Fernández González
Funding Agency*: National
Ongoing: yes
Project reference: MINECOG18/P26
-
Propiedades estructurales de fluoroazúcares para aplicaciones biomédicas
Pl: Emilio José Cocinero Pérez y Francisco J. Basterretxea
Funding Agency*: National
Ongoing: yes
Project reference: PID2020-117892RB-I00
-
Ayudas para Apoyar las Actividades de Grupos de Investigación del Sistema Universitario Vasco
Pl: Francisco J. Basterretxea
Funding Agency*: Regional
Ongoing: yes
Project reference: GIC21/108
Publications
-
L. Peixoto, R. Magalhães, D. Navas, S. Moraes, C. Redondo, R. Morales, J. P. Araújo, and C. T. Sousa, Magnetic nanostructures for emerging biomedical applications, Applied Physics Reviews, 2020
10.1063/1.5121702 -
B. Mora, A. Perez-Valle, C. Redondo, M. D. Boyano, R. Morales, Cost-Effective Design of High-Magnetic Moment Nanostructures for Biotechnological Applications, ACS Applied Materials & Interfaces, 2018
10.1021/acsami.7b16779 -
C. Calabrese, I. Uriarte, et al., Observation of the Unbiased Conformers of Putative DNA-Scaffold Ribosugars, ACS Central Science, 2020
10.1021/acscentsci.9b01277 -
Iris A. Bermejo, Imanol Usabiaga, et. al., Water Sculpts the Distinctive Shapes and Dynamics of the Tumor-Associated Carbohydrate Tn Antigens: Implications for Their Molecular Recognition, Journal of the American Chemical Society, 2018
10.1021/jacs.8b04801
Research Lines
ADVANCED MATERIALS AND PROCESSES
- Functional materials emerge as invaluable constituents to develop new concepts in biomedical applications. In particular, disk-shaped magnetic materials with feature sizes below one micron can be designed to exhibit a unique configuration known as vortex state. This special magnetic configuration makes them suitable for biomedical assays with important advantages: large magnetic moments and magneto-mechanical actuation.
- A proper functionalization of disk surfaces and metallic interfaces with conjugated antibodies or specific aptamers provides advanced nanomagnets for a broad bunch of novel applications in diagnosis and therapy medical areas.
- The main goal of this research line is to produce advanced functional nanodisks and validate their performance in three biomedical innovations: cancer diagnosis using magnetic-based biosensors, cancer cell annihilation in-vitro assay with alternating magnetic fields, and signaling activation in neuron cultures.
Our Research Group has recently initiated a collaboration with Professors Jeanne Leblond Chain and Laurent Azéma from the University of Bordeaux. The RG from Bordeaux is a partner of an international project currently presented to the M-ERA.NET call 2022. The RG from the UPV/EHU coordinates the submitted proposal titled Advanced functional nanodisks and spintronic biosensors for cancer diagnosis. This is a multidisciplinary project that involves physicists, chemists and biologists to develop advanced materials and novel biosensing devices. The collaboration with the University of Bordeaux’s group is fundamental for the production of highly specific functionalized materials for cancer diagnosis.