University of Warwick - Equipment Account
Lead Research Organisation:
University of Warwick
Department Name: Chemistry
Abstract
This proposal is to design, build, validate and exploit the features of a new Raman spectrometer that will collect Raman, Raman Optical Acitity (ROA), and Raman Linear Difference (RLD) spectra. ROA is well-established, but comparatively under-used as a means of probing secondary and tertiary structures of proteins and other biomacromolecules. RLD is a newly invented technique (Rodger et al. Analytical Chemistry, 2012) that can be used to give relative orientations of subunits of complex molecular assemblies. Raman spectroscopy provides access to the wealth of information available in vibrational spectroscopy without the challenges which confront infra red absorbance where water signals dominate. This project builds on the investigators' acknowledged expertise in developing novel spectroscopies for the study of biomolecules. It follows their success (measured by the increase in publications and linear dichroism (LD) instrument sales triggered by their work over the past 10 years) in making UV-LD an available technology.
The motivation for developing a new form of spectroscopy is that the structures and arrangements of molecules, including sugars and lipids, that play key roles in the structures and functions of biomacromolecules are invisible to many techniques. Further, existing techniques do not provide sufficient information for many applications. Atomic-level techniques including crystallography and NMR are not well-suited to large irregular molecular assemblies where the structures of both the macromolecule and surrounding molecules contribute to the function of the components. Circular dichroism, which is currently the most widely used method for determining solution-phase secondary structures of proteins, has comparatively low information content and usable concentration ranges. Thus we need alternative approaches to provide the required information. We believe different forms of Raman spectroscopy can contribute to addressing these issues, but the required instrumentation has not yet been invented.
The main applications of the instrument in the lifetime of the funding will be:
1. Understand atomic-level structures and functions of biomacromolecules in cellular assemblies which is essential if we wish to control biological processes, such as cell division, for disease control and biotechnology applications.
2. Enhance efficiency in the development and production of pharmaceutical (small molecule) and biopharmaceutical (proteins, nucleic acids, viruses, bacteria) products by improving the approach to Process Analytical Technology (PAT) and helping to enable 'Quality by Design' (QbD). The hypothesis underlying QbD for pharmaceutical drugs, is that quality in production can be planned, and that most quality crises and problems relate to the way in which quality was (or was not) planned in the first place. QbD operates fairly effectively in the pharmaceutical industry. Regulators such as the European Medicines Agency are looking to expand the concept and process of QbD from pharmaceutical products to biopharmaceuticals. However, the analytical methodologies that are possibly sufficient for pharmaceuticals are clearly not adequate for biopharmaceuticals. New challenges are also being brought by the emerging 'Biosimilars' market: most simply, what is 'highly similar'?
A wide user community will be established. The applications of the first users will be mainly with proteins, protein fibres, protein assemblies including bacteriophage, and membrane systems.
The motivation for developing a new form of spectroscopy is that the structures and arrangements of molecules, including sugars and lipids, that play key roles in the structures and functions of biomacromolecules are invisible to many techniques. Further, existing techniques do not provide sufficient information for many applications. Atomic-level techniques including crystallography and NMR are not well-suited to large irregular molecular assemblies where the structures of both the macromolecule and surrounding molecules contribute to the function of the components. Circular dichroism, which is currently the most widely used method for determining solution-phase secondary structures of proteins, has comparatively low information content and usable concentration ranges. Thus we need alternative approaches to provide the required information. We believe different forms of Raman spectroscopy can contribute to addressing these issues, but the required instrumentation has not yet been invented.
The main applications of the instrument in the lifetime of the funding will be:
1. Understand atomic-level structures and functions of biomacromolecules in cellular assemblies which is essential if we wish to control biological processes, such as cell division, for disease control and biotechnology applications.
2. Enhance efficiency in the development and production of pharmaceutical (small molecule) and biopharmaceutical (proteins, nucleic acids, viruses, bacteria) products by improving the approach to Process Analytical Technology (PAT) and helping to enable 'Quality by Design' (QbD). The hypothesis underlying QbD for pharmaceutical drugs, is that quality in production can be planned, and that most quality crises and problems relate to the way in which quality was (or was not) planned in the first place. QbD operates fairly effectively in the pharmaceutical industry. Regulators such as the European Medicines Agency are looking to expand the concept and process of QbD from pharmaceutical products to biopharmaceuticals. However, the analytical methodologies that are possibly sufficient for pharmaceuticals are clearly not adequate for biopharmaceuticals. New challenges are also being brought by the emerging 'Biosimilars' market: most simply, what is 'highly similar'?
A wide user community will be established. The applications of the first users will be mainly with proteins, protein fibres, protein assemblies including bacteriophage, and membrane systems.
Planned Impact
SCIENTIFIC IMPACT
Analytical science is a key feature of the success of any fundamental or applied research programme and underpins industrial progress and production. Therefore to achieve the next level of innovation in European research and industry we need new techniques and scientists trained in new ways to use them. The goal of this project is to design, build, validate and encourage use of a new instrument for biomacromolecule characterization. Within the lifetime of the project our aim is to have the Raman Linear Difference (RLD) and Raman Optical Activity (ROA) instrument being part of the biomacromolecule characterisation armoury of ~12 academic research groups and one industrial group by the end of the project. We shall achieve this by the following.
(i) Involve SGS M-Scan Ltd in the project producing data on their samples in the first instance, then involving then in developing new methods for biopharamceuticals
(ii) Include the new methodology of RLD and also ROA in the UK/EU Circular Dichroism/Linear Dichroism workshop that has been designed to take place mid-term in the project. We shall invite collaborators L. Nafie of Syracuse and BioTools Inc. and J. Cheeseman of Gaussian Inc. to contribute to the workshop.
(iii) Encourage every user of the unique linear dichroism facilities at Warwick to make samples available for RLD data collection. This will help establish a library of useful data and also indicate where scientists will benefit from using RLD.
(iv) Publications in high quality journals and conference presentations.
ENHANCED SKILLS PROVISION
The variety of researchers who will measure spectra on the new instrument will benefit from learning a new technique and expanding their structural characterization possibilities.
OUTREACH PLANS
This is a short project, without any postdoctoral research associates. The direct opportunities for Outreach will be limited to laboratory tours, student placements, and University open days.
INSTRUMENT USE
At the conclusion of the project we shall have a new instrument up and running and available to the wider community. We anticipate that the research groups of the applicants will use ~1/3 of the available time; other Warwick users a further ~1/3; and external users ~1/3. The balance between industrial and academic users is anticipated to evolve as a function of time with initial dominance by researchers in academia followed by increasing use by biopharmaceutical users. The drive towards 'Quality by Design' of pharmaceutical and biopharmaceutical products is motivated by the need to increase the efficiency of the European manufacturing platform in order to increase its economic viability. A step-change in how processes are controlled is required to proceed to the next level. Quality by Design is a driver for the development of the new instrument as it requires more understanding of the nature of a product and production process than has previously been possible. The European approach to QbD has been developed together with the FDA and Japan and is summarized in International Conference on Harmonisation (ICH) guidelines. However, these developments have made it clear that we do not have the technologies required either for the pre-production phases of QbD or for the production phases where continuous, fast, non-peturbative in- or on-line testing at the point of manufacture is required to allow correction or at least to avoid expensive further processing.
SPECTROMETER AND COUETTE CELL SALES
We anticipate that both the new spectrometer and the new Couette flow cell will become products for respectively BioTools Europe Ltd, BioTools Inc. and Crystal Precision Optics. BioTools Inc have already informally discussed how this might work in the future.
Analytical science is a key feature of the success of any fundamental or applied research programme and underpins industrial progress and production. Therefore to achieve the next level of innovation in European research and industry we need new techniques and scientists trained in new ways to use them. The goal of this project is to design, build, validate and encourage use of a new instrument for biomacromolecule characterization. Within the lifetime of the project our aim is to have the Raman Linear Difference (RLD) and Raman Optical Activity (ROA) instrument being part of the biomacromolecule characterisation armoury of ~12 academic research groups and one industrial group by the end of the project. We shall achieve this by the following.
(i) Involve SGS M-Scan Ltd in the project producing data on their samples in the first instance, then involving then in developing new methods for biopharamceuticals
(ii) Include the new methodology of RLD and also ROA in the UK/EU Circular Dichroism/Linear Dichroism workshop that has been designed to take place mid-term in the project. We shall invite collaborators L. Nafie of Syracuse and BioTools Inc. and J. Cheeseman of Gaussian Inc. to contribute to the workshop.
(iii) Encourage every user of the unique linear dichroism facilities at Warwick to make samples available for RLD data collection. This will help establish a library of useful data and also indicate where scientists will benefit from using RLD.
(iv) Publications in high quality journals and conference presentations.
ENHANCED SKILLS PROVISION
The variety of researchers who will measure spectra on the new instrument will benefit from learning a new technique and expanding their structural characterization possibilities.
OUTREACH PLANS
This is a short project, without any postdoctoral research associates. The direct opportunities for Outreach will be limited to laboratory tours, student placements, and University open days.
INSTRUMENT USE
At the conclusion of the project we shall have a new instrument up and running and available to the wider community. We anticipate that the research groups of the applicants will use ~1/3 of the available time; other Warwick users a further ~1/3; and external users ~1/3. The balance between industrial and academic users is anticipated to evolve as a function of time with initial dominance by researchers in academia followed by increasing use by biopharmaceutical users. The drive towards 'Quality by Design' of pharmaceutical and biopharmaceutical products is motivated by the need to increase the efficiency of the European manufacturing platform in order to increase its economic viability. A step-change in how processes are controlled is required to proceed to the next level. Quality by Design is a driver for the development of the new instrument as it requires more understanding of the nature of a product and production process than has previously been possible. The European approach to QbD has been developed together with the FDA and Japan and is summarized in International Conference on Harmonisation (ICH) guidelines. However, these developments have made it clear that we do not have the technologies required either for the pre-production phases of QbD or for the production phases where continuous, fast, non-peturbative in- or on-line testing at the point of manufacture is required to allow correction or at least to avoid expensive further processing.
SPECTROMETER AND COUETTE CELL SALES
We anticipate that both the new spectrometer and the new Couette flow cell will become products for respectively BioTools Europe Ltd, BioTools Inc. and Crystal Precision Optics. BioTools Inc have already informally discussed how this might work in the future.
Publications
Kemp TF
(2016)
Dynamic Nuclear Polarization enhanced NMR at 187 GHz/284 MHz using an Extended Interaction Klystron amplifier.
in Journal of magnetic resonance (San Diego, Calif. : 1997)
Khastgir S
(2017)
Towards increased reliability by objectification of Hazard Analysis and Risk Assessment (HARA) of automated automotive systems
in Safety Science
Khastgir S
(2017)
Advances in Human Aspects of Transportation
Khastgir S
(2018)
The Science of Testing: An Automotive Perspective
Khastgir S
(2018)
Calibrating trust through knowledge: Introducing the concept of informed safety for automation in vehicles
in Transportation Research Part C: Emerging Technologies
Seddon SD
(2021)
Real-space observation of ferroelectrically induced magnetic spin crystal in SrRuO3.
in Nature communications
Khastgir S
(2021)
Systems Approach to Creating Test Scenarios for Automated Driving Systems
in Reliability Engineering & System Safety
Tognetti J
(2022)
Optimisation of 1H PMLG homonuclear decoupling at 60 kHz MAS to enable 15N-1H through-bond heteronuclear correlation solid-state NMR spectroscopy.
in Physical chemistry chemical physics : PCCP
Tatman B
(2023)
Nuclear spin diffusion under fast magic-angle spinning in solid-state NMR
in The Journal of Chemical Physics
| Description | The award EP/K011618/1 is an institutional equipment account, into which the EPSRC paid the capital part of our strategic equipment grant awards EP/K011618/1 for each strategic equipment grant, the EPSRC also created separate grants with different codes. All of the outcomes for the strategic equipment award are associated with: EP/N010825/1: Ultrafast Spectroscopy of Advanced Materials at the University of Warwick (James Lloyd-Hughes ) EP/M022706/1: Vector field and pulsed light assisted variable temperature scanning probe microscope for time and space resolved nano-characterisations (Marin Alexe) BB/T018119/1: Renewal of the 600 MHz solid-state NMR console for biological applications (Józef Lewandowski ) EP/L007010/1: Underpinning Power Electronics 2012: Devices Theme (Phil Mawby) |
| Exploitation Route | In respect of EP/N010825/1, EPSRC Strategic Equipment Grant has led to the creation of a new research facility at the University of Warwick: the Warwick Centre for Ultrafast Spectroscopy (WCUS). This research facility will enable a large number of potential users of this research facility from across the UK and further afield, including a number of university researchers and a variety of SMEs and larger companies (around 50 users from academic and industrial partners at present). In respect of EP/M022706/1, EPSRC grant has played a pivotal role in the development of a novel tool designed for probing functional properties at the nanoscale under extreme conditions. This state-of-the-art instrumentation not only provides the UK research landscape with a distinctive investigative infrastructure but also serves as a paradigm for integrating diverse and often unrelated methodologies. Consequently, our unique research tool has provided an unprecedented opportunity to delve into the magnetic properties of ancient functional materials such as pyrrhotite, offering valuable insights into the historical aspects of our planet and extra-terrestrial materials and well as oldest functional materials used by humans. The integrated approach offered by this grant facilitates comprehensive and in-depth examinations, ushering in a new era of capability for nanoscale investigations under extreme conditions. Further details on outcomes for projects associated with this award can be viewed on Gateway to Research, urls as follows: https://gtr.ukri.org/projects?ref=EP%2FN010825%2F1 https://gtr.ukri.org/projects?ref=EP%2FM022706%2F1 https://gtr.ukri.org/projects?ref=BB%2FT018119%2F1 https://gtr.ukri.org/projects?ref=EP%2FL007010%2F1 |
| Sectors | Electronics Healthcare Manufacturing including Industrial Biotechology Pharmaceuticals and Medical Biotechnology |
| Description | In respect of project EP/N010825/1, this EPSRC Strategic Equipment Grant has led to the creation of a new research facility at the University of Warwick: the Warwick Centre for Ultrafast Spectroscopy (WCUS). We have evolved into a university-supported research facility (a Research Technology Platform) with dedicated staff and strict financial plans to ensure sustainability. This has led to growth in the usage of ultrafast spectroscopy, and has help aid the recruitment of new academic staff and early career researchers. At the WCUS we use the advanced laser equipment funded on this EPSRC grant to create short pulses of light, which we use to probe how materials respond to absorbing light. By establishing a facility where these methods are available to the wider community we have achieved three major impacts: (1) Made ultrafast spectroscopy accessible more broadly in academia and by providing a central location where this expertise and equipment is available, we have lowered the barrier to entry for materials scientists, chemists, engineers, and physicists who do not have a background in ultrafast spectroscopy, but which nonetheless have benefited from access to the scientific information available via WCUS. (2) Made ultrafast spectroscopy available to industry and developed a number of partnerships with industry, underpinned by the support from the EPSRC Strategic Equipment grant. This has led to impact in multiple sectors, including healthcare (e.g. we contributed to the development of light-actived anti-cancer drugs), energy (e.g. we investigated new semiconductors for solar cell applications), electronics (e.g. we investigated the performance of new semiconductors with an SME), agriculture (e.g. we lead a multi-national EU project on enhancing crop growth, involving SMEs and universities). (3) Generated significant academic impact. Research from the WCUS has featured in publications in high-profile materials science and nanoscience journals (Advanced Functional Materials, Nano Letters, ACS Nano), major chemistry journals (e.g. Nature Chemistry, J. Phys. Chem.), interdisciplinary journals (Physical Review Letters, Nature Photonics, Nature Communications, Carbon, J. Mater. Chem.), and condensed matter physics (Physical Review B, Nanotechnology, J. Phys: Cond. Matt.) to name a few. Particular highlights include the first demonstration of intertube excitonics in 1D van der Waals heterostructures (Adv. Func. Mat.); photo-redox catalysis to target cancer cells (Nature Chemistry); developing carbon nanotubes for improved ultrafast lasers (Nano Lett) and fast LEDs based on metal halide perovskites (Nature Photonics). In respect of project EP/M022706/1, this EPSRC grant has played a pivotal role in the development of a novel tool designed for probing functional properties at the nanoscale under extreme conditions. Specifically, a low-temperature Atomic Force Microscope (AFM) has been specially designed and deployed. This state-of-the-art instrumentation not only provides the UK research landscape with a distinctive investigative infrastructure but also serves as a paradigm for integrating diverse and often unrelated methodologies. The utilization of the developed low-temperature AFM has yielded several noteworthy discoveries. Notably, the observation of a magnetic domain structure emerging in oxide ferromagnets, characterized as a spin crystal, has been identified. In conjunction with the well-established skyrmions, this spin crystal manifests a notable topological-like Hall effect. In respect of BB/T018119/1, the methodology enabled by this upgrade facilitates characterisation of proteins involved in natural products biosynthesis, which in turn can be used to guide their rational engineering to produce new compounds using synthetic biology approach. Another area where this upgraded instrument is applied is characterisation of intact plants, which is important in the context of renewable resources, e.g. processing of cellulose. In respect of EP/L007010/1, this project focused on the basic building block of power electronics, namely the semiconductor components. The aim was to enable a step-change in the state of the art. By enabling the development of new technology, gaining deeper theoretical insight into the physics of failure, building predictive reliability models and compact models, this programme will help support and stimulate UK manufacturing industries in the area of power electronics. The beneficiaries of the proposed research include the academic power electronics and power devices communities, and the areas of transport technologies, materials and manufacturing / fabrication techniques. |
| First Year Of Impact | 2020 |
| Sector | Agriculture, Food and Drink,Chemicals,Education,Electronics,Energy,Healthcare,Manufacturing, including Industrial Biotechology,Pharmaceuticals and Medical Biotechnology |
| Description | Solid state and solution NMR spectroscopy and cryo-electron microscopy methodology for the characterisation of aggregation mechanisms in proteins |
| Amount | £105,754 (GBP) |
| Funding ID | BB/V50967X/1 |
| Organisation | Biotechnology and Biological Sciences Research Council (BBSRC) |
| Sector | Public |
| Country | United Kingdom |
| Start | 08/2020 |
| End | 09/2024 |
| Description | Development of fast magic angle spinning instrumentation |
| Organisation | Tallinn University of Technology |
| Country | Estonia |
| Sector | Academic/University |
| PI Contribution | Evaluated and provided feedback about various generations of 0.8 mm MAS probe for application on biomolecules. |
| Collaborator Contribution | Provide experimental 0.8mm MAS probe. |
| Impact | (1) Lamley, J. M.; Iuga, D.; Öster, C.; Sass, H.-J.; Rogowski, M.; Oss, A.; Past, J.; Reinhold, A.; Grzesiek, S.; Samoson, A.; Lewandowski, J. R. J. Am. Chem. Soc. 2014, 136 (48), 16800. |
| Start Year | 2012 |
| Description | Ice dynamics in the presence of antifreeze molecules |
| Organisation | University of Warwick |
| Department | Warwick Evidence |
| Country | United Kingdom |
| Sector | Academic/University |
| PI Contribution | Dr Józef Lewandowski and his team performed SSNMR experiments and analysis |
| Collaborator Contribution | Provide samples and complementary experiments |
| Impact | Elucidated molecular basis for antifreeze properties of PVA |
| Start Year | 2018 |
| Description | Biological solid state NMR tutorial at the Alpine Conference on Magnetic Resonance in Solids |
| Form Of Engagement Activity | A talk or presentation |
| Part Of Official Scheme? | No |
| Geographic Reach | International |
| Primary Audience | Postgraduate students |
| Results and Impact | Dr Józef Lewandowski (a recipient of 'University of Warwick - Equipment Account' funding) achieved further funding as a result of EP/K011618/1 and that further funding included BB/T018119/1 against which this outcome is recorded. About 50 postgraduate students and NMR spectroscopists participated in a general tutorial on biological solid-state NMR. The tutorial was aimed both at people in the field and outside of the field. |
| Year(s) Of Engagement Activity | 2023 |
| URL | https://alpine-conference.org/ |