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Organ failure and tissue loss are challenging health issues due to widespread aging population, injury, the lack of organs for transplantation and limitations of conventional artificial implants. There is a fast growing need in surgery to replace and repair soft tissues such as blood vessels, stent, trachea, skin, or even entire organs, such as bladder, kidney, heart, facial organs etc. The high demand for new artificial implants for long-term repair and substantially improved clinical outcome still remains .Our well-publicised successes in using tissue-engineering to replace hollow organs in cases of compassionate need have shown the world that an engineering approach to hollow organ replacement is feasible, as well as serving to highlight those areas where more work is required to provide bespoke manufactured tissue scaffolds for routine clinical use Being able to replicate a functional part of one's body as an exact match and therefore to be able to replace it 'as good as before' is familiar in science fiction. Most implants will share limitations that are associated with either the materials used or the traditional way in which they have been made. With the advancement of additive manufacturing technology, 3D printing, biomaterials and cell production, printing an artificial organs is becoming a science and engineering fact and understandably can save lives and enhance quality of life through surgical transplantation of such printed organs produced on-demand, specifically for the individual of interest. The project seeks to addresses the unmet need in traditional implants by exploiting our proprietary polymer nanocomposites developed at UCL and advanced digital additive manufacturing with surgical practice. we aim to develop a 3D advanced digital bio-printing system for polymer nanocomposites in order to manufacture a new-generation of synthetic soft organs 'on-demand' and bespoke to the patient's particular needs. Our extensive preclinical and on-going preclinical study on the nanocomposite-based organs will ensure the construct is able to induce angiogenesis and to perform function of an epithelium. Here we take these experiences in the compassionate case, and take trachea as an exemplar to develop a manufacturing method of producing bespoke tubular organs for transplantation with nanocomposite material. This proposal will allow us to develop; a) a customer made 3D bioprinter with multi-printing heads and an environmental chamber which can print 'live' soft organs/scaffolds with seeded cells to meet the individual patients needs; b) a series of polymer nanocomposites suitable for 3D printingorgan constructs/host scaffolds; c) a formulations of bio-inks for printing cells, proteins and biomolecules. d) a printed artificial tracheal constructs using their radiographic images with optimised biochemical, biophysical and mechanical properties. e) Establishment of in-vivo feasibility data through observation of restoration of respiratory function and normal tissue integration of pig models which will be surgically transplanted

The motivation for this proposal is that the global reliance on fossil fuels is set to increase with the rapid growth of Asian economies and major discoveries of shale gas in developed nations. The strategic vision of the IDC is to develop a world-leading Centre for Industrial Doctoral Training focussed on delivering research leaders and next-generation innovators with broad economic, societal and contextual awareness, having strong technical skills and capable of operating in multi-disciplinary teams covering a range of knowledge transfer, deployment and policy roles. They will be able to analyse the overall economic context of projects and be aware of their social and ethical implications. These skills will enable them to contribute to stimulating UK-based industry to develop next-generation technologies to reduce greenhouse gas emissions from fossil fuels and ultimately improve the UK's position globally through increased jobs and exports. The Centre will involve over 50 recognised academics in carbon capture & storage (CCS) and cleaner fossil energy to provide comprehensive supervisory capacity across the theme for 70 doctoral students. It will provide an innovative training programme co-created in collaboration with our industrial partners to meet their advanced skills needs. The industrial letters of support demonstrate a strong need for the proposed Centre in terms of research to be conducted and PhDs that will be produced, with 10 new companies willing to join the proposed Centre including EDF Energy, Siemens, BOC Linde and Caterpillar, together with software companies, such as ANSYS, involved with power plant and CCS simulation. We maintain strong support from our current partners that include Doosan Babcock, Alstom Power, Air Products, the Energy Technologies Institute (ETI), Tata Steel, SSE, RWE npower, Johnson Matthey, E.ON, CPL Industries, Clean Coal Ltd and Innospec, together with the Biomass & Fossil Fuels Research Alliance (BF2RA), a grouping of companies across the power sector. Further, we have engaged SMEs, including CMCL Innovation, 2Co Energy, PSE and C-Capture, that have recently received Department of Energy and Climate Change (DECC)/Technology Strategy Board (TSB)/ETI/EC support for CCS projects. The active involvement companies have in the research projects, make an IDC the most effective form of CDT to directly contribute to the UK maintaining a strong R&D base across the fossil energy power and allied sectors and to meet the aims of the DECC CCS Roadmap in enabling industry to define projects fitting their R&D priorities. The major technical challenges over the next 10-20 years identified by our industrial partners are: (i) implementing new, more flexible and efficient fossil fuel power plant to meet peak demand as recognised by electricity market reform incentives in the Energy Bill, with efficiency improvements involving materials challenges and maximising biomass use in coal-fired plant; (ii) deploying CCS at commercial scale for near-zero emission power plant and developing cost reduction technologies which involves improving first-generation solvent-based capture processes, developing next-generation capture processes, and understanding the impact of impurities on CO2 transport and storage; (iimaximising the potential of unconventional gas, including shale gas, 'tight' gas and syngas produced from underground coal gasification; and (iii) developing technologies for vastly reduced CO2 emissions in other industrial sectors: iron and steel making, cement, refineries, domestic fuels and small-scale diesel power generatort and These challenges match closely those defined in EPSRC's Priority Area of 'CCS and cleaner fossil energy'. Further, they cover biomass firing in conventional plant defined in the Bioenergy Priority Area, where specific issues concern erosion, corrosion, slagging, fouling and overall supply chain economics.

Fullerenes are football-shaped cages of carbon atoms, for the discovery of which the British scientist Harry Kroto won the Nobel prize in 1996. Inside the cage is an empty space. Chemists and physicists have found many ingenious ways of trapping atoms or molecules inside the tiny fullerene cages. These encapsulated compounds are called endofullerenes. A remarkable method was pioneered by the Japanese scientists Komatsu and Murata, one of whom is a project partner on the current proposal. They performed "molecular surgery". First, a series of chemical reactions was used to open a hole in the fullerene cages. A small molecule such as water (H2O) was then inserted into each fullerene cage by using high temperature and pressure. Finally, a further series of chemical reactions was used to "sew" the holes back up again. The result was the remarkable chemical compound called water-endofullerene, denoted H2O@C60. Our team has succeeded in developing a new synthetic route which requires milder conditions and has improved yield for the production of H2O@C60. In addition we will encapsulate other small molecules in the fullerene cage, including ammonia (NH3) and methane (CH4). Molecules of ordinary water have two forms, which are called ortho and para-water, which are distinguished by the way the magnetic hydrogen nuclei point: in opposite sense for para-water, and in the same sense for ortho-water. In ordinary conditions, these two forms interconvert rapidly, and cannot be isolated. However, by trapping water molecules inside fullerene cages, the two forms are isolated and may be studied separately. We recently observed that these two forms of water have different electrical properties. At low temperatures, the two forms interconvert over a period of tens of hours. We will study the interconversion of the two forms of water, and develop a theory of why this conversion changes the electrical properties. In order to understand how these molecules behave, we will use several techniques. These methods include nuclear magnetic resonance (which involves a strong magnet and radiowaves), neutron scattering (in which the material is bombarded with neutrons from a nuclear reactor) and infrared spectroscopy (which involves the absorption of low-energy light waves). By combining the information from these different techniques, we will build up a complete picture of the quantum-mechanical behaviour of the trapped molecules. Since ortho and para-water have different electrical properties, we expect to distinguish between single H2O@C60 molecules in the ortho and para states, by measuring the electrical response of single molecules. This will be done scanning over a surface loaded with the fullerenes, using a very sharp tip. In this way, we hope to observe the ortho to para transition of single molecules - something that has never been done before. Although most of this project concerns basic science, this project could lead to technological and even medical advances in the future. For example, the ortho and para states of the individual H2O@C60 molecules could allow the storage of one bit of information inside a single molecule, without damaging it in any way. This might lead to a new form of very dense data storage. Since a single gram of H2O@C60 contains about 10^19 molecules, this single gram could in principle store 1 million terabytes of information, sufficient to store the DNA sequences of everyone on the planet (although it will be very difficult to store and retrieve this information). In addition, the quantum behaviour of the encapsulated molecules is expected to give rise to greatly enhanced magnetic resonance signals, leading to the possibility of greatly enhanced MRI images, with considerable medical benefits.

Information technology (IT) has penetrated all aspects of life in modern society. At the heart of IT are miniature devices that can process and store information in one or another form. Currently, the information is processed mainly within semiconductor based data architectures based on tiny "transistors". In contrast, long-term data storage is dominated by magnetic hard disk drives, within which the information is stored as direction of tiny "magnetic needles" the two opposite orientations of which represent "0" and "1" values in binary logics. However, the semiconductor industry is predicted to reach the limit of miniaturisation within the coming decade, while the energy consumption becomes increasingly important both for environmental concerns and to align with use in portable battery fed devices. In this project, we aim to demonstrate a key component of a novel device for information technology, which has the potential to lead to combined data processing and storage on the same chip. This device will be based upon 'magnonics', in which wave-like perturbations of magnetisation ('spin waves') travel through and interact in patterned magnetic tracks ('waveguides') to perform operations. We propose to construct a spin wave source such that the wave properties of many such sources are linked; technically, this is known as 'coherence'. Our proposed spin wave source consists of a magnetic nanowire antenna placed across the waveguides. Microwave radiation will create magnetic oscillations in the antennae, which in turn will induce the spin waves in the nearby waveguides. Spin waves are proposed as logic signal carriers, thereby assisting their seamless integration with existing and future magnetic data storage technologies. This integration of signal processing and storage within a single architecture promises reduced energy consumption and fast device operation. In addition, we will exploit how the spin waves interact with the magnetic configuration of the various components. The materials and geometry of the antennae and waveguides causes the magnetisation to prefer to lie along their length. However, opposite magnetisations can be engineered to meet within, say, the waveguide to create a transition region called a 'magnetic domain wall'. By selectively configuring the orientation of the magnetic waveguide and antennae, including incorporation of magnetic domain walls, we will be able to program the magnonic device functionalities. The magnetic materials we propose to use don't require power to retain their magnetisation (non-volatility), meaning our devices will store the configuration when powered off and, therefore, will be instantaneously bootable upon switch on. The multiple stable configurations of the magnetic components and associated multiple functionalities will also provide an opportunity for creating more complex devices that could replace several semiconductor transistors in conventional electronics. Apart from consumer electronics, the devices will be advantageous for use in aerospace, space and sub-marine technologies in which their non-volatility and resistance to radiation will allow vital weight and cost savings to be made. The collaborative research programme will be conducted jointly by the Department of Materials Science and Engineering at the University of Sheffield and the College of Engineering, Mathematics and Physical Sciences at the University of Exeter. The Sheffield team will contribute to the project their internationally leading expertise in nanotechnology and manipulation of magnetic domain walls, while the Exeter team will contribute their world leading expertise in dynamical characterization and theoretical modelling of magnonic devices. By joining their forces together, the two teams will ensure that UK will remain at the forefront at the magnetic logic technology, in particular opening the new interdisciplinary field of domain wall magnonics.

Doctoral Training Partnerships: a range of postgraduate training is funded by the Research Councils. For information on current funding routes, see the common terminology at https://www.ukri.org/apply-for-funding/how-we-fund-studentships/. Training grants may be to one organisation or to a consortia of research organisations. This portal will show the lead organisation only.

Chemistry is a dynamic subject that is at the centre of many different scientific advances. Organic chemistry is concerned with the reactivity of carbon in all its different forms and can be viewed as the chemistry taking place within living things. Chemists are constantly looking for new ways of designing and building molecules (synthetic chemistry is molecular architecture) and this proposal describes a short and powerful new way of making valuable molecules using a new type of catalyst. The molecules at the heart of the proposal are compounds containing a carbon-oxygen double bond (a carbonyl group) which have special properties and are the building blocks of many known pharmaceutical agents. The novel chemistry proposed here will provide a new, efficient and powerful way of making carbonyl compounds using catalysis to control all aspects of the structures of the products formed: this will be of great benefit to both academia and industry who will be able to make interesting molecules (some that were otherwise inaccessible) in new ways. Plans have also been made to screen the compounds that we make for a wide range of biological activity. Given all of the above, it is imperative that we have novel, efficient and powerful methods for making new carbonyl containing compounds so that we can study and use them. In addition, the development and application of new catalysts and catalytic systems is also important because catalysis makes chemical reactions run faster, and become cleaner with less waste: this is clearly a good thing for industry and also for the environment. The Fellowship aspect of this proposal is designed to allow the principal investigator the time to study and develop a new research direction. Plans have been made to interact and collaborate with other academics who can provide specialist knowlege and also with two project partners (one a multi-national pharmaceutical company and the other a leading academic in the United States of America) so that industrial problems and mechanistic details can be identified and addressed at all stages of the project. Three post-doctoral assistants will be employed to carry out the exprimental work, and the project will provide a thorough and comprehensive training in science and the attendant areas of communication/ presentation and creativity. This will equip them very well for the job market afterwards.

The proposed UK Consortium on Turbulent Reacting Flows will perform high-fidelity computational simulations (i.e. Reynolds Averaged Navier-Stokes simulations (RANS), Large Eddy Simulation (LES) and Direct Numerical Simulations (DNS)) by utilising national High Performance Computing (HPC) resources to address the challenges related to energy through the fundamental physical understanding and modelling of turbulent reacting flows. Engineering applications range from the formulation of reliable fire-safety measures to the design of energy-efficient and environmentally-friendly internal combustion engines and gas turbines. The consortium will serve as a platform to collaborate and share HPC expertise within the research community and to help UK computational reacting flow research to remain internationally competitive. The proposed research of the consortium is divided into a number of broad work packages, which will be continued throughout the duration of the consortium and which will be reinforced by other Research Council and industrial grants secured by the consortium members. The consortium will also support both externally funded (e.g. EU and industrial) and internal (e.g. university PhD) projects, which do not have dedicated HPC support of their own. The consortium will not only have huge intellectual impact in terms of fundamental physical understanding and modelling of turbulent reacting flows, but will also have considerable long-term societal impact in terms of energy efficiency and environmental friendliness. Moreover, the cutting edge computational tools developed by the consortium will aid UK based manufacturers (e.g. Rolls Royce and Siemens) to design safe, reliable, energy-efficient and environmentally-friendly combustion devices to exploit the expanding world-wide energy market and boost the UK economy. Last but not least, the proposed collaborative research lays great importance on the development of highly-skilled man-power in the form of Research Associates (RAs) and PhD students of the consortium members, who in turn are expected to contribute positively to the UK economy and UK reacting flow research for many years to come.

Doctoral Training Partnerships: a range of postgraduate training is funded by the Research Councils. For information on current funding routes, see the common terminology at https://www.ukri.org/apply-for-funding/how-we-fund-studentships/. Training grants may be to one organisation or to a consortia of research organisations. This portal will show the lead organisation only.

One in three people in the UK population will develop cancer during their life time. The incidence of cancer continues to increase world-wide and healthcare providers are facing increasing challenges in the management of this expanding group of patients. However, new imaging technologies allow detection of tumours at earlier stages and now more cancer patients than ever can be successfully treated by surgery. Tissue conserving surgery is an advanced surgical procedure that tries to only remove cancerous tissue and leave healthy tissue in place. In skin conserving surgery (also known as Mohs micrographic surgery), one layer after another of tissue is cut away and examined under the microscope to make sure that all the cancer is out. This process is stopped when only healthy tissue is left. Successful removal of all cancer cells is the key to achieving lower rates of the cancer returning. There is always a balance to be struck between making sure that all the cancer is removed and preserving as much healthy tissue as possible in order to reduce scarring and disfigurement. The real challenge however is to know where the cancer starts and ends when looking at it during an operation so that the surgeon knows when to stop cutting. Although Mohs surgery provides the highest cure rates for basal cell carcinoma, the most common type of cancer in humans with ~60,000 new patients each year in the UK, it takes around 1-2 hours per layer to prepare and diagnose under the microscope. The high costs and the need for highly specialized surgeons, has limited the availability of Mohs surgery in the UK and led to "post-code" treatment variability. Compared to Mohs surgery, breast conserving surgery (more than 10,000 procedures per year) is considerably more complex and for practical reasons, the traditional methods of diagnosis by preparing thin tissue specimens cannot be performed during surgery. As a consequence, in England more than 2,000 patients per year require a second operation, usually complete removal of the breast. Recently, my research group has developed a new method to diagnose cancer cells in tissue layers removed during surgery. The main advantage of this technique is that the time consuming steps of tissue fixation, staining, and sectioning are eliminated. This new diagnosis method uses a combination of two techniques called auto-fluorescence imaging and Raman scattering, that can measure the molecular composition of tissue and provide objective diagnosis of cancer. However, this breakthrough is just the beginning and further work is required to take these successes forward and improve patient care. In the short and medium term, I will focus on reducing the diagnosis time for skin cancers to only a few minutes by developing a method to measure Raman spectra from eighteen regions of the tissue simultaneously. In collaboration with cancer surgeons, we will expand this new technology to diagnosis of other cancers, such as breast and lung. This will be achieved by optimizing the auto-fluorescence imaging and Raman scattering to take into consideration the chemical make up of these tissues. In the longer term, I plan to develop novel hand-held medical devices based on multimodal spectral imaging that could be used by the surgeons to diagnose the tissues directly on the body and remove tissue only if cancerous cells are detected. These methods for tumour diagnosis can revolutionise the surgical treatment of cancers, by providing a fast and objective way for surgeons to make sure that all cancer cells have been removed whilst at the same time preserving as much healthy tissue as possible. To achieve these ambitious objectives I will work in close partnership with other scientists, engineers, doctors, surgeons and industry. Such collaborations will ensure that cutting-edge science and engineering is exploited to develop leading healthcare technologies for the benefit of patients.

Recently, an influential American business magazine, Forbes, chose Quantum Engineering as one of its top 10 majors (degree programmes) for 2022. According to Forbes magazine (September 2012): "a need is going to arise for specialists capable of taking advantage of quantum mechanical effects in electronics and other products." We propose to renew the CDT in Controlled Quantum Dynamics (CQD) to continue its success in training students to develop quantum technologies in a collaborative manner between experiment and theory and across disciplines. With the ever growing demand for compactness, controllability and accuracy, the size of opto-electronic devices in particular, and electronic devices in general, is approaching the realm where only fully quantum mechanical theory can explain the fluctuations in (and limitations of) these devices. Pushing the frontiers of the 'very small' and 'very fast' looks set to bring about a revolution in our understanding of many fundamental processes in e.g. physics, chemistry and even biology with widespread applications. Although the fundamental basis of quantum theory remains intact, more recent theoretical and experimental developments have led researchers to use the laws of quantum mechanics in new and exciting ways - allowing the manipulation of matter on the atomic scale for hitherto undreamt of applications. This field not only holds the promise of addressing the issue of quantum fluctuations but of turning the quantum behaviour of nano- structures to our advantage. Indeed, the continued development of high-technology is crucial and we are convinced that our proposed CDT can play an important role. When a new field emerges a key challenge in meeting the current and future demands of industry is appropriate training, which is what we propose to achieve in this CDT. The UK plays a leading role in the theory and experimental development of CQD and Imperial College is a centre of excellence within this context. The team involved in the proposed CDT covers a wide range of key activities from theory to experiment. Collectively we have an outstanding track record in research, training of postgraduate students and teaching. The aim of the proposed CDT is to provide a coherent training environment bringing together PhD students from a wide variety of backgrounds and giving them an appreciation of experiment and theory of related fields under the umbrella of CQD. Students graduating from our programme will subsequently find themselves in high-demand both by industry and academia. The proposed CDT addresses the EPSRC strategic area 'Quantum Information Processing and Quantum Optics" and one of the priority areas of the CDT call, "Towards Quantum Technologies". The excellence of our doctoral training has been recognised by the award of a highly competitive EU Innovative Doctoral Programme (IDP) in Frontiers of Quantum Technology, which will start in October 2013 running for four years with the budget around 3.8 million euros. The new CDT will closely work with the IDP to maximise synergy. It is clear that other high-profile activities within the general area of CQD are being undertaken in a range of other UK universities and within Imperial College. A key aim of our DTC is inclusivity. We operate a model whereby academics from outside of Imperial College can act as co-supervisors for PhD students on collaborative projects whereby the student spends part of the PhD at the partner institution whilst remaining closely tied to Imperial College and the student cohort. Many of the CDT activities including lectures and summer schools will be open to other PhD students within the UK. Outreach and transferable skills courses will be emphasised to provide a set of outreach classes and to organise various outreach activities including the CDT in CQD Quantum Show to the general public and CDT Festivals and to participate in Imperial's Science Festivals.