Watch now the webinars focused on connecting industrial R&D staff to state-of-the-art neutron methods

In the frame of the H2020 project ACCELERATE, a series of webinars focused on state-of-the-art neutron methods are being held since October 2020. This series of webinars is facilitated by experts from the European Spallation Source, with the aim of bringing together researchers from industry as well as R&D staff from both academia and industry to exchange knowledge and expertise.

Each talk is focused on a specific field of application which would be of high interest for researchers working in the food, pharmaceutical, and energy sectors.

1st webinarNeutrons: A Natural Tool for Industrial Research        

Speaker: Dr. Andrew Jackson, Acting Head Neutron Instruments Division, Group Leader Instrument Scientists (European Spallation Source). Read here the speaker’s biography.

Overview

Neutron beams are highly penetrating, non-destructive, and sensitive to light elements and magnetic structures. As such neutron scattering, imaging and spectroscopy form a family of methods that provide unique insight into structure, dynamics and kinetics from the atomic to macroscopic scale.

Whilst neutrons have played a key role in many fields of academic research, the special characteristics of neutrons, and the maturity of many of the techniques, lend themselves to application in industrial R&D. Neutron methods have been successfully employed in areas ranging from formulations and personal care products, through to understanding strains in aircraft wings.

This talk highlighted the reasons why we choose to study materials with neutrons, how we generate neutron beams, and what types of measurements are possible. Examples of applications from a broad spectrum of industrial research were also presented.

► Watch here the 1st webinar recording.

2nd webinarNanoscale to Microscale Structural Analysis with Neutrons

Speaker: Dr. Judith Houston, Instrument Scientist for LoKI (European Spallation Source). Read here the speaker’s biography.

Overview

The interactions and assembly behaviour of a product’s components in the nano-range, such as the colloidal building blocks in milk, or the polymer chains in plastic thin film coverings, determine not only the structure of the material at the nanoscale, but also directly influence that materials’ structure, rheology and functional properties at the macroscopic scale. Therefore, when designing new products, such as food, drug formulations or packaging, it is increasingly important to understand the relationship between the structural and functional properties of that material’s constituent components.

Small-angle neutron scattering (SANS) is an ideal technique to help us unravel complex soft matter structures on the 1-500 nm scale. The specific properties of neutrons, such as their capability to distinguish light elements and their isotopes (e.g. 1H (hydrogen) and 2H (deuterium)), or their negligible absorption, make them particularly useful in the field of soft matter. Firstly, by selectively deuterating components of a complex material, we can create contrast in an otherwise homogenous system without altering its physico-chemical properties. Such components can then be rendered effectively invisible in the measured scattering data when combined with judicious selection of the solvent. Therefore, this method of contrast-variation enables full structural characterisation of not only the global structure, but also its constituent components and their interaction, which cannot be obtained by light or x-ray scattering. In addition, the comparatively weak interaction between neutrons and matter, enables them to penetrate most materials. As a result, we can design relatively complex sample environments for in situstudies with neutrons. This has powerful implications for studying the evolution of nanoscale structures in industrial processes, without the need for overly simplified model set-ups. Finally, their non-invasive nature makes neutron perfect to study bio-relevant material without radiation damage.

This talk incorporated numerous examples from the literature aiming to highlight the versatility of neutron scattering for industrial applications, from understanding the structure of food or packaging to demonstrating the flexibility of neutrons to study processing techniques.

► Watch here the 2nd webinar recording.

3rd webinar: Neutron protein crystallography reveals molecular details of inhibitor binding to clinical targets.

Speaker: Dr. Zöe Fisher, Group Leader Deuteration and Macromolecular Crystallisation (European Spallation Source). Read here the speaker’s biography.

Overview:

 Ligand binding to proteins are mediated through numerous interactions. These can include direct hydrogen bonds, water-mediated interactions, electrostatics, metal coordination, energetic changes through water displacement, aromatic ring stacking, and hydrophobic interactions.

Using X-ray crystallography as a tool for the study of protein: ligand complexes is a powerful and high throughput approach, but cannot elucidate many of the atomic details of the types of interactions involved. Neutrons can fill this knowledge gap as they have unique properties that enable us to determine the location of light atoms [1H (Hydrogen), and its isotope 2H (Deuterium)]. By extension then it is possible to observe hydrogen bonds and infer electrostatics based on presence or absence of a hydrogen atoms on the protein but also the ligand. This can inform the researcher on the charged state of a ligand, the involvement of water molecules, and the charged state of amino acid side chains involved in binding.

Combining the unique information from neutron crystallography with high resolution X-ray crystallography, it is then possible to obtain a complete and accurate view of the interactions that drive ligand binding. This talk incorporated examples from the literature on where this strategy was employed to investigate novel compounds binding to a cancer metastasis marker, and clinically used protease inhibitors to HIV protease.

► Watch here the 3rd webinar recording.