Lanthanide complexes as chiral probes and labels

Lead Research Organisation: Durham University
Department Name: Chemistry

Abstract

Ever since Faraday first declared that 'polarised light was a most delicate investigator of molecular condition', scientists have sought to exploit the intrinsic handedness of light. Light that is polarised in a plane is the sum of left handed and right handed circularly polarised components. The exploitation of the circular polarization of light is rare, yet it offers unique opportunities in areas such as the development of optical robes for the biosciences, in the creation of new security labelling/tagging features and in the development of image contrast, based on the relative intestines of the left and right handed components of polarised light. Circularly polarised luminescence (CPL) is the emission analogue of circular dichroism (CD), that has been used for some time to examine chiral systems by virtue of the differential absorption of left and right handed light. Intrinsically, CPL is a much more sensitive optical technique, but is has not really been used at all in life or material science applications.

In Durham very bright compounds of the rare earth element europium have been created recently, that are not only the brightest emitters of red light that have been devised but also emit light with a preferential handedness. Using these new compounds, it is much faster and easier to detect their CPL, and new instrumentation has been developed in tandem, that allows their CPL behaviour to be studied both in spectroscopy and in microscopy. The project will examine how these bright red-emitting emitters of light can be used to tag or label documents or printed labels, thereby opening up the possibility of their use in security applications for validation of true identity. Examples might include bank notes, legal documents, high end branded labels for designer clothing or official documents, such as passports.

In addition, new molecules will be designed and created that bind to a wide range of enzymes in the body that are involved in the transfer of a phosphate group. For example, the protein tyrosine phosphatases account for 0.05% of the total phosphorylation in cells, but play a key role in the regulation of critical biological functions, e.g. adhesion, cell cycle control and the ways that cells grow and differentiate. Antibodies specific to phosphorylated tyrosine sites are commonly used for many practical applications, involving monitoring enzyme activity, but their use is hampered by high cost and poor stability. Chemical probes that can directly visualise the activity of this specific range of enzymes activity are required and could be used in drug screening applications, as the inhibitors of these key enzymes are of great interest to the pharmaceutical sector. Using europium compounds that interact selectively with these sites where tyrosine has been phosphorylated, a chiral CPL signature can be observed, that identifies the site and the nature of the amino-acids around that site. Thus the europium compounds can serve as selective chemical probes to signal , by an induce CPL response, whether the tyrosine is phosphorylated and where in the biomolecule it has been modified. These properties will be studied in detail and their scope and utility evaluated.

Planned Impact

The project relates to the EPSRC Physical Science capability theme, notably in the direct involvement with synthetic coordination/supramolecular chemistry. Industry in the UK has strategic interests in developing new security tagging/labelling methodology and in promoting new chemical probe applications (e.g. GE-Amersham/ GSK). These companies will be made aware of the scientific advances defined in this work, either via academic channels of conference dissemination and primary publications, or by direct contact, once commercial confidentiality is properly protected. These cases will be handled by the University's Business and Innovations Service: n.b. Durham Chemistry was placed top for Impact in REF 2014, and the PI and Co-I was responsible for one of the 4* case studies.

The PI and co-I will continue to cooperate with research groups around Europe (e.g. PI via participation in the European Society for Molecular Imaging) exchanging information, publicising key advances and organising short-term scientific missions to selected research groups.

Nationally, the background to this project links to the EPSRC Challenge theme, Healthcare Technologies (involving Medical Imaging and Biological Chemistry), creating impact by improved predictive/diagnostic capability through the development of new types of optical probe.

The project also relates to imaging technology that relates to the 'Imaging Technologies in Healthcare', the 'Global Uncertainties' and 'Manufacturing the Future' themes. In the EPSRC 2016 Plan, the UK's connectedness is to be supported by devising "innovative cost effective ways of delivering services ... through transformational technologies that connect people things and data together in safe, smart, secure and ... trustworthy ways".

As a separate advance, the development of portable adapted cameras for use in security tagging could take advantage of differential image contrast associated with the circular polarisation of emission, in tandem with time-resolved detection.
Such a strategy is potentially of general utility and may be applicable to documents, currency, drugs, explosives and labels on high value consumer products. Contact will be made with the North of England based companies, DelaRue and Innovia , once proof-of-concept is established in both tagging and in optimising the instrumentation for rapid assessment.

Publications

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MacKenzie LE (2019) Science podcasts: analysis of global production and output from 2004 to 2018. in Royal Society open science

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MacKenzie LE (2021) Circularly polarized lanthanide luminescence for advanced security inks. in Nature reviews. Chemistry

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Parker D (2021) The design of responsive luminescent lanthanide probes and sensors. in Chemical Society reviews

 
Description We have discovered that we can use the handedness of emitted light to signal and distinguish the binding of a light emitting probe to different types of protein, thereby distinguishing for example important serum proteins like alpha-acid glycoprotein and human serum albumin. We have also constructed a new type of spectrometer and have shown proof of principle to create a new type of microscope that can each distinguish the handedness of emitted light.
Exploitation Route Greater awareness of the creation of chiral probes is expected to lead to renewed interest in this aspect of of labelling. A scientific meeting was held in London in early 2019 bringing together teams from across Europe under a Royal Society Discussion meeting to advertise these new advances. In addition, an EC ITN was funded in related work of which the Durham University team is a partner; this network runs from October 2020-March 2024 and involves labs in 7 European countries, exchanging ideas, training researchers and sharing expertise. The expertise of staff on this grant for synthesis and characterisation was passed on to a new PhD student funded by the ITN scheme
Sectors Healthcare

Pharmaceuticals and Medical Biotechnology

Security and Diplomacy

 
Description After discussion with Cisbio (France) we have field a European patent application (NB cannot be entered in the IP section as not published yet): It is a European Patent Application Number 20306296.3 dated October 28 2020, and relates to Europium Complexes as pH Sensors
First Year Of Impact 2020
Sector Pharmaceuticals and Medical Biotechnology
Impact Types Economic