2 research outputs found
Multimodal probes : superresolution and transmission electron microscopy imaging of mitochondria, and oxygen mapping of cells, using small-molecule Ir(III) luminescent complexes
We describe an Ir(III)-based small-molecule, multimodal probe for use in both light and electron microscopy. The direct correlation of data between light- and electron-microscopy-based imaging to investigate cellular processes at the ultrastructure level is a current challenge, requiring both dyes that must be brightly emissive for luminescence imaging and scatter electrons to give contrast for electron microscopy, at a single working concentration suitable for both methods. Here we describe the use of Ir(III) complexes as probes that provide excellent image contrast and quality for both luminescence and electron microscopy imaging, at the same working concentration. Significant contrast enhancement of cellular mitochondria was observed in transmission electron microscopy imaging, with and without the use of typical contrast agents. The specificity for cellular mitochondria was also confirmed with MitoTracker using confocal and 3D-structured illumination microscopy. These phosphorescent dyes are part of a very exclusive group of transition-metal complexes that enable imaging beyond the diffraction limit. Triplet excited-state phosphorescence was also utilized to probe the O2 concentration at the mitochondria in vitro, using lifetime mapping techniques
Sensitisation of Eu(III)- and Tb(III)- based luminescence by Ir(III) units in Ir/lanthanide dyads: evidence for parallel energy-transfer and electron-transfer based mechanisms
A series of blue-luminescent Ir(III) complexes with a pendant binding site for lanthanide(III) ions has been
synthesized and used to prepare Ir(III)/Ln(III) dyads (Ln = Eu, Tb, Gd). Photophysical studies were used to
establish mechanisms of Ir→Ln (Ln = Tb, Eu) energy-transfer. In the Ir/Gd dyads, where direct Ir→Gd
energy-transfer is not possible, significant quenching of Ir-based luminescence nonetheless occurred;
this can be ascribed to photoinduced electron-transfer from the photo-excited Ir unit (*Ir, 3MLCT/3LC
excited state) to the pendant pyrazolyl-pyridine site which becomes a good electron-acceptor when coordinated
to an electropositive Gd(III) centre. This electron transfer quenches the Ir-based luminescence,
leading to formation of a charge-separated {Ir4+}•—(pyrazolyl-pyridine)•− state, which is short-lived possibly
due to fast back electron-transfer (<20 ns). In the Ir/Tb and Ir/Eu dyads this electron-transfer pathway
is again operative and leads to sensitisation of Eu-based and Tb-based emission using the energy liberated
from the back electron-transfer process. In addition direct Dexter-type Ir→Ln (Ln = Tb, Eu) energytransfer
occurs on a similar timescale, meaning that there are two parallel mechanisms by which excitation
energy can be transferred from *Ir to the Eu/Tb centre. Time-resolved luminescence measurements
on the sensitised Eu-based emission showed both fast and slow rise-time components, associated
with the PET-based and Dexter-based energy-transfer mechanisms respectively. In the Ir/Tb dyads, the
Ir→Tb energy-transfer is only just thermodynamically favourable, leading to rapid Tb→Ir thermally-activated
back energy-transfer and non-radiative deactivation to an extent that depends on the precise
energy gap between the *Ir and Tb-based 5D4 states. Thus, the sensitised Tb(III)-based emission is weak
and unusually short-lived due to back energy transfer, but nonetheless represents rare examples of Tb(III)
sensitisation by a energy donor that could be excited using visible light as opposed to the usually required
UV excitation