Innovating functional colour changing photonic crystals - from gas sensors to tissue scaffolds

Lead Research Organisation: Advanced Material Development
Department Name: Inks formulations

Abstract

Structurally coloured polymer-based photonic crystals enhanced with pristine graphene or other 2D related nanomaterials that can change colour upon external stimuli such as heat or mechanical pressure are promising for a range of novel and emerging sensing applications. These materials have the potential to disrupt several market sectors, yet work is still needed in developing the base technology and multidisciplinary commercial application of the resulting devices and products.

The programme of work within this Future Leaders Fellowship will focus on the executive transition of the fellow from academia to industry and her leading further multidisciplinary developments and the subsequent commercial innovation of novel photonic crystal devices. Particular aims are to produce an ionizing radiation dosimeter with an effective atomic number similar to that of human tissue for accurate tissue equivalent dosimetry, a sensing device which changes vividly in colour upon exposure to toxic gas environment in civilian first responder applications as well as a novel in vitro tissue model, consisting of heart cells on a conductive photonic crystal scaffold, to create a commercially viable, functional, electrically stimulated, physiologically relevant, heart tissue scaffold.

The economic and social impact of these will be widely felt. For example cheap and simple to use devices that can quantitatively and qualitatively detect the presence of toxic gases can save the lives of civilians and first responders responding to hazardous fire situations. A radiation dosimeter for careful radiation monitoring will protect radiation workers and patients from potential health risks, and contribute to enhancement of the health and safety standards, while the development of novel tissue scaffolds will enable easier design and testing of vaccines and drugs and significantly reduce the use of animals.

Planned Impact

The fellowship will support the development of a Polymeric Photonic Crystal Platform will provide immense long-term impact on the public and commercial sector. It will develop new products and processes at 2 UK Universities through a high growth potential SME and the High-Value Manufacturing Catapult. The product portfolio comprising of three major groups of products that include gas sensors, radiation dosimeters and tissue scaffolds. Being business hosted brings many advantages in terms of commercial freedom and the pathway for the fellow to become an inspiring female innovator.

The economic and social impact of these will be widely felt. For the gas sensor work, there are ~37,000 house fires a year in the UK and 200 fire-related deaths annually mostly caused by inhaling the toxic fumes. Long-term, photonic crystal-based gas sensors will have an immersive impact on society. Cheap and simple to use devices that can quantitatively and qualitatively detect the presence of toxic gases can save the lives of civilians and first responders responding to hazardous fire situations.

The same material system can be used as a radiation dosimeter that measures dose uptake of external ionising radiation (e.g. X-rays). X-rays are vital to helping diagnose various illnesses including cancer. However, X-rays or CT scans utilise ionising radiation can be a cause of cancer many years later. The evidence suggests that 6 in 1,000 cancers in the UK are caused by diagnostic radiation alone. Hence this project will deliver a device for careful monitoring to optimise radiation doses and protect medical radiation workers and patients from potential health risks. It will enable to contribute to enhancement of the health and safety standards, influence the policies and reduce the NHS spending.

While the development of novel tissue scaffolds, long-term, will enable to understand and consequently tackle the cardiovascular diseases such arrhythmias, coronary artery disease or heart attack which are currently the leading cause of death worldwide, results in a quarter of deaths in England costing NHS seven billion pounds annually. At the same time, the design and testing of vaccines and drugs will become more accessible, more effective and significantly reduce the use of animals.

Short-term, this project will significantly impact the Fellow who will make a transition from academia to industry - further developing her world-class skills in research into the industrial research field, her team that will be exposed an environment which is a hybrid of academia and industry. The fellowship will greatly enhance AMD itself by developing a new stream of business in partnership with UKRI and will enhance the reputation of two south-east universities by working with a high growth potential SME. It has the potential to generate new job opportunities for the company and attract additional investment through public and private means.

Through careful and targeted dissemination of results to both the academic and industrial community, the profile of this type of research and innovation will rise, and through thought leadership activities the importance of advanced manufacturing using nanomaterial enabled innovations is greatly enhanced.
 
Description This is a business hosted fellowship, and the fellow has made significant advancements in the development of a number of products related to the photonic crystal technology that were part of this fellowship funding. While a number of technologies is subjected to contractual confidentiality, there are a number of technologies that have been significantly advanced due to the funding and the products are being prepared for scale-up and release to the market including:
- development of novel colour changing sensors for vaccine vial monitoring applications. Our Colorimetric time temperature indicators (TTI's) based on low cost, sustainable materials can be printed onto most substrates, enabling use on food and pharmaceutical packs for deployment within the production process and supply chain.
- development of highly sensitive chemiresistive sensors for the detection of environmental pollution.
Exploitation Route By partnering with appropriate industrial partners, these technologies can be progressed through technology readiness levels (TRLs) and are projected to be deployed on the market as products within the next couple of years.
Sectors Agriculture

Food and Drink

Environment

Manufacturing

including Industrial Biotechology

Pharmaceuticals and Medical Biotechnology

 
Description We have developed a number of technologies with each of them anticipating to make a significant impact in near future. All of these innovations are in the process of being scaled-up. Radiation dosimeters: We have developed a technology that reduces the risk to radiotherapy patients from increasing exposure to radiation medicine through real-time quality assurance of radiation doses. It can long-term facilitate a change in clinical protocols and reducing treatment planning time. Chemical sensors: exposure to lethal and disabling gases is a constant danger in a wide range of settings including fires in confined spaces, industrial chemical spillages, etc. There is no easy way for first responders to assess which toxic gases are present. We have developed a passive colorimetric sensing device which changes vividly in colour upon exposure to toxic chemical environment (gases and liquids). In-vitro drug screening platform: we have developed a smart, fully synthetic, photonic crystal-based biomimetic scaffold that provides a highly biocompatible environment capable of providing a non-invasive, label-free method of detecting cell response. Rising incidence of chronic diseases such as diabetes, cancer, cardiovascular diseases, which call for tissue regeneration therapies, is major factor driving the market revenue growth. Other significant factors driving it include the rise in the elderly population and rising demand for organ transplants. laser eye protective coatings: laser eye protection is a growing area of importance for military and domestic operators. We have developed low-temperature-processable structurally coloured tunable notch filters based on PCs towards wavelength-selective rejection while maintaining off-resonance high transmittance for user operability. vaccine vial monitors: we have developed thermochromic, low-cost VVM that can undergo a simple, clear, irreversible visual colour change making them suitable for global supply chains and end-users with no language requirements nor training needed. VVMs offer important means to simplify logistics, increase the acceptability and safety of immunization.
First Year Of Impact 2023
Sector Chemicals,Environment,Healthcare,Pharmaceuticals and Medical Biotechnology
Impact Types Societal

Economic

Policy & public services

 
Description Early Career Researcher Forum on Horizon Early Career Researcher Forum on Horizon
Geographic Reach National 
Policy Influence Type Contribution to a national consultation/review
 
Description Novel tissue equivalent dosimeters to monitor ionising radiation
Amount £30,000 (GBP)
Organisation University of Surrey 
Sector Academic/University
Country United Kingdom
Start 02/2023 
End 03/2023
 
Description Validation of novel chemiresistive sensors for environmental monitoring
Amount £9,994 (GBP)
Funding ID 10022881 
Organisation Innovate UK 
Sector Public
Country United Kingdom
Start 01/2022 
End 03/2022
 
Description CPI 
Organisation Centre for Process Innovation (CPI)
Country United Kingdom 
Sector Private 
PI Contribution We are providing our expertise in the area of processing of nanomaterials and fabrication of sensor devices.
Collaborator Contribution CPI provides us with expertise in the area of printed electrodes for gas sensing applications, and more generally provides their experience in the area of product-scale up and product commercialisation. CPI provides access to the world-leading equipment and facilities that are critical for the successful delivery of this current research project.
Impact This collaboration was established less than 12 months ago, hence there are no outputs that can be clearly evidenced yet.
Start Year 2021
 
Description NPL 
Organisation National Physical Laboratory
Country United Kingdom 
Sector Academic/University 
PI Contribution development of chemiresitive sensors for air quality monitoring, we have provided sensing materials and built sensing devices
Collaborator Contribution collaborators provided their facilities for testing and their expertise in the area of air quality monitoring
Impact innovate UK report, news article
Start Year 2022
 
Description Sussex 
Organisation University of Sussex
Department School of Mathematical and Physical Sciences Sussex
Country United Kingdom 
Sector Academic/University 
PI Contribution expertise in the area of photonic crystals and jined development of various technologies
Collaborator Contribution Colleagues from the university of Sussex have a unique expertise in the area of nanomaterials processing, senaing particles which are used in the photonic crystal platform to to turn them into smart functional devices
Impact scientific publications which have been highlighted in other sections of this submission
Start Year 2021
 
Description University of Surrey 
Organisation University of Surrey
Department School of Veterinary Medicine
Country United Kingdom 
Sector Academic/University 
PI Contribution Expertise in the area of processing of nanomaterials and sensor development
Collaborator Contribution Expertise in the area of tissue engineering, toxicity of nanomaterials as well as access to their research facilities.
Impact This is a multi-disciplinary collaboration between physicists, material scientists and life scientists. The school of veterinary Medicine provides their expertise in the are of life sciences
Start Year 2021
 
Description University of Surrey/Physics 
Organisation University of Surrey
Department Department of Physics
Country United Kingdom 
Sector Academic/University 
PI Contribution Expertise in the area of processing of nanomaterials and sensor development as well as expertise in business development and product scale up activities
Collaborator Contribution expertise in the area of soft matter physics and polymer physics as well as access to the research facilities
Impact no outputs yet
Start Year 2021
 
Title Optical Filters 
Description This present invention relates to transparent films that are able to block predetermined wavelengths of light, the films being formed from colloidal crystals of latex particles and 2D nanomaterials. The invention also relates to methods of making such films, their applications, as well as substrates onto which the films have been deposited. 
IP Reference 23180534.2 
Protection Patent / Patent application
Year Protection Granted 2023
Licensed No
Impact a number of commercial partners are interested in developing and licencing this technology from us,
 
Title POLYMERIC OPAL 
Description The present disclosure provides a polymeric opal comprising a polymer and an additive. The additive comprises a two-dimensional (2D) material and/or a carbon nanotube and the weight ratio of the polymer to the additive is between 100:0.001 and 00:0.1. 
IP Reference US2022017719 
Protection Patent application published
Year Protection Granted 2022
Licensed Yes
Impact This patent application is the main base of all the advances in the fellowship. Patent owned by the University of Surrey but is exploited by Advanced Material Development Ltd.
 
Title Photonic Nanodiagnostic Platform for Biomarker Detection 
Description In accordance with a first aspect of the invention, there is provided a kit for detecting a biomarker in a sample, the kit comprising: a photonic crystal comprising a plurality of mesoscopic particles and an additive, wherein the additive comprises a zero-dimensional (0D) material, a one-dimensional (1D) material and/or a two-dimensional (2D) material; and a moiety specific to the biomarker. Advantageously, the photonic crystal will change colour if exposed to the biomarker. Furthermore, the degree of colour change will vary depending upon the concentration of the biomarker. Accordingly, the kit of the first aspect may not only be used to 10 determine the presence or absence of a biomarker in a sample but may also be used to determine the concentration thereof. 
IP Reference 2403261.7 
Protection Patent / Patent application
Year Protection Granted 2024
Licensed No
Impact this will be licenced within the next 12 months
 
Title Photonic Platform for Detection of a Biothreat 
Description colorimetric detection platform based on photonic crystal technology for identification of biothreats 
IP Reference 2403261.7 
Protection Patent / Patent application
Year Protection Granted 2024
Licensed No
Impact this invention has an opportunity to be licenced in the next 12 months
 
Title vaccine vial monitors 
Description we have developed thermochromic, low-cost VVM that can undergo a simple, clear, irreversible visual colour change making them suitable for global supply chains and end-users with no language requirements nor training needed. This innovation is undergoing scale up activities , UKRI FLF funded 
Type Preventative Intervention - Physical/Biological risk modification
Current Stage Of Development Refinement. Non-clinical
Year Development Stage Completed 2023
Development Status Under active development/distribution
Impact Our VVMs prevent heat-damaged vaccines to be used and good vaccines to be thrown out; enable the health workers know whether the vaccine can be safely used for immunization, can save the global community millions of dollars per year, enables to extend the reach of immunization programs by taking the vaccine beyond the cold chain (e.g. for polio-eradication efforts in war-torn and inaccessible regions of the world). 
 
Description AkzoNobel's Paint the Future bootcamp 
Form Of Engagement Activity A formal working group, expert panel or dialogue
Part Of Official Scheme? No
Geographic Reach International
Primary Audience Industry/Business
Results and Impact AMD has been chosen as one of 'the world's brightest startups' as they join AkzoNobel's Paint the Future finalists Bootcamp
The Paint the Future global startup challenge has invited 11 finalists from hundreds of global applicants to take part in a three-day bootcamp taking place in Amsterdam on November 16-18 (delayed until March 2022). The startups and AkzoNobel experts mmet face-to-face to explore potential collaborations together.
Year(s) Of Engagement Activity 2022
URL https://amdnano.com/news-release.php?id=3
 
Description Denbies workshop 
Form Of Engagement Activity Participation in an activity, workshop or similar
Part Of Official Scheme? No
Geographic Reach Regional
Primary Audience Industry/Business
Results and Impact 30 people attended the workshop. This meeting was intended to disseminate the most recent findings arising from the fellowship and also do some brainstorming of ideas to further enhance the project advances
Year(s) Of Engagement Activity 2021
 
Description NanoteC 
Form Of Engagement Activity A talk or presentation
Part Of Official Scheme? No
Geographic Reach International
Primary Audience Postgraduate students
Results and Impact Nanomaterials conference, 80 people attended the conference, two postdoctoral researchers funded by this award gave scientific presentations
Year(s) Of Engagement Activity 2023