The aim of the research is to develop novel approaches for the analysis of biomolecules, and in particular proteins, directly from their natural (or actual) environment, i.e., to develop approaches for in situ biomolecular analysis. Proteins are the work-horses of the cell and perform all the functions required for life. They also find uses as therapeutics and in consumer products. To gain insight into the various and specific roles of proteins in life processes, or to determine the therapeutic efficacy of protein drugs, or to establish the environmental fate of protein additives in consumer products, it is necessary to be able to analyse proteins at a molecular level. Mass spectrometry, in which ionised molecules are characterised according to their mass-to-charge, is ideally suited to this challenge, offering high sensitivity, broad specificity (all molecules have a mass), and the capability for chemical structure elucidation. The ultimate goal is to link molecular analysis directly to molecular environment. Much like a forensics officer tasked with determining the presence of an illicit substance, there is much greater reliability and credibility afforded to an analysis performed at the scene of the crime than to one performed following removal of the sample to a separate location and alternative surroundings. Growing evidence suggests in situ protein analysis has groundbreaking roles to play in biomarker discovery, diagnosis & early detection of disease, targeting therapeutics (personalised medicine) and assessment of therapeutic efficacy. The benefits of in situ protein analysis can be illustrated by considering a thin tissue section through a drug-treated tumour. In principle, in situ analysis would inform on drug-target interactions (i.e., is the drug binding to the correct protein?). Moreover, with in situ protein analysis the capacity for artefact introduction as a result of sample preparation (e.g., application of a matrix) or sample damage is eliminated. Nevertheless, a number of challenges exist. Proteins are large molecules associated with a vast array of chemical modifications, and which form loosely-bound complexes with themselves, other proteins and other molecule types. It is not only their chemical structure but also their overall 3-D structure which dictate their function. Other molecular classes that are hugely important in biological processes also have an intricate relationship with proteins. Any in situ mass spectrometry approach needs to be able to meet these analyte-driven challenges, i.e., it must be capable of (a) measuring proteins and characterising any modifications, (b) detecting protein complexes and determining their constituents, (c) providing information on 3-D structure, and (d) detecting other relevant molecular classes. Moreover, there are technique-driven challenges for in situ analysis including inherently high sample complexity and wide ranging concentrations, and opportunities for quantitation. The research will meet these challenges by developing a newly emerging in situ approach, liquid extraction surface analysis mass spectrometry, in combination with two complementary types of ion mobility spectrometry (which can either provide information on 3-D structure, or separate ionised molecules in the mass spectrometer on the basis of their 3-D shape) and a structural elucidation strategy known as electron-mediated dissociation mass spectrometry. The research will be undertaken primarily at the University of Birmingham in the Advanced Mass Spectrometry Facility in the School of Biosciences and the School of Chemistry mass spectrometry facility. The programme involves a number of academic and industrial collaborators and additional research will be carried out during scientific visits to National Physical Laboratory (NPL), Thermo Fisher Scientific, Waters, Owlstone, Florida State University, Texas A&M University and Université d'Aix-Marseille.

The current advancement of technology very much depends upon the discovery of new materials. It has been known for some time that combinations of elements not involving carbon (called inorganic materials) can have important uses in areas from electronics, computing and UV protection in products, to harnessing energy from the sun. In particular, when inorganic particles are very small, typically made up of a few hundred atoms (called nanomaterials), they can have unusual and exciting properties. The discovery of such nanomaterials is very much hampered by our inability to make these materials fast enough and then to be able to test them adequately for their properties.The proposed research seeks to develop a new, faster way of making and discovering inorganic nanomaterials that can absorb sunlight (as an free energy source), and use this energy to split water into its constituents, hydrogen and oxygen (in a process known as photocatalysis). The hydrogen can then be used for powering cars or devices of the future. Such a process is important to sustain the energy requirements of mankind on this earth when our fossil fuels (e.g. oil) are exhausted.

Abstracts are not currently available in GtR for all funded research. This is normally because the abstract was not required at the time of proposal submission, but may be because it included sensitive information such as personal details.

Abstracts are not currently available in GtR for all funded research. This is normally because the abstract was not required at the time of proposal submission, but may be because it included sensitive information such as personal details.

The current advancement of technology very much depends upon the discovery of new materials. It has been known for some time that combinations of elements not largely involving carbon (called inorganic materials) can have important uses in areas from electronics, computing, UV protection in products, to harnessing energy from the sun. In particular, when inorganic particles are very small, typically made of a few hundred atoms (called nanomaterials), they become can have unusual and exciting properties. The discovery of such nanomaterials very much is hampered by our inability to make these materials fast enough and then to be able to test them adequately for their properties.The proposed research seeks to develop a new way of making and discovering inorganic nanomaterials using a very fast approach. This project is seeking to discovery better nanomaterials, which can absorb the suns rays (as an free energy source), and use this energy to split water into its constituents, hydrogen and oxygen (in a process known as photocatalysis). The hydrogen can then be used for powering cars or devices of the future. Such a process is important to sustain the energy requirements of mankind on this earth when our fossil fuels (e.g. oil) are exhausted.