Macrocyclic Transition-Metal Parashift Complexes for MRI at Clinical and Pre-clinical Magnetic Fields

Nicola J. Rogers; Ashok Kumar Chowan; Carlson Alexander; Daniel Bowdery; Galina Pavlovskaya; Peter Harvey

doi:10.1039/D5DT01149C

Macrocyclic Transition-Metal Parashift Complexes for MRI at Clinical and Pre-clinical Magnetic Fields

Nicola J. Rogers^*, Ashok Kumar Chowan, Carlson Alexander, Daniel Bowdery, Galina Pavlovskaya, Peter Harvey

^*Corresponding author for this work

Department of Chemistry

Research output: Contribution to journal › Journal article › peer-review

Abstract

A series of macrocyclic transition-metal complexes, including Fe(II), Co(II), Ni(II), and Cu(II) complexes, have been evaluated for parashift MRI imaging applications, by assessing their paramagnetic NMR properties, including proton chemical shifts, nuclear relaxation rates, and any exchange dynamics in solution, at magnetic fields strengths relevant to clinical and pre-clinical imaging. Among the complexes studied, Fe(II) and Co(II) systems demonstrated significant paramagnetic shifts with desirable relaxation properties, making them potential candidates for lanthanide-free parashift molecular probes for MRI. Field-dependent nuclear relaxation rate analyses provided insights into electronic relaxation times, confirming the suitability of certain complexes for parashift imaging at lower magnetic fields. Phantom imaging experiments at 9.4 T further validated the feasibility of molecular imaging using a cyclen-based macrocyclic Fe(II) complex, making a significant advance toward developing transition metal-based MRI probes using biogenic metal ions, and offer promise for future responsive imaging due to the direct signal detection.

Original language	English
Pages (from-to)	11036-11046
Number of pages	11
Journal	Dalton Transactions
Volume	54
Issue number	28
DOIs	https://doi.org/10.1039/D5DT01149C
Publication status	E-pub ahead of print - 25 Jun 2025

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title = "Macrocyclic Transition-Metal Parashift Complexes for MRI at Clinical and Pre-clinical Magnetic Fields",

abstract = "A series of macrocyclic transition-metal complexes, including Fe(II), Co(II), Ni(II), and Cu(II) complexes, have been evaluated for parashift MRI imaging applications, by assessing their paramagnetic NMR properties, including proton chemical shifts, nuclear relaxation rates, and any exchange dynamics in solution, at magnetic fields strengths relevant to clinical and pre-clinical imaging. Among the complexes studied, Fe(II) and Co(II) systems demonstrated significant paramagnetic shifts with desirable relaxation properties, making them potential candidates for lanthanide-free parashift molecular probes for MRI. Field-dependent nuclear relaxation rate analyses provided insights into electronic relaxation times, confirming the suitability of certain complexes for parashift imaging at lower magnetic fields. Phantom imaging experiments at 9.4 T further validated the feasibility of molecular imaging using a cyclen-based macrocyclic Fe(II) complex, making a significant advance toward developing transition metal-based MRI probes using biogenic metal ions, and offer promise for future responsive imaging due to the direct signal detection.",

author = "Rogers, {Nicola J.} and Chowan, {Ashok Kumar} and Carlson Alexander and Daniel Bowdery and Galina Pavlovskaya and Peter Harvey",

note = "NR thanks HKBU, the Hong Kong Jockey Club Charities Trust, and the University of Warwick for support. CAK and CA thank the Hong Kong Jockey Club for support under the Global JC STEM Professorship scheme. PH was supported by a URKI Future Leaders Fellowship [MR/X034046/1]. We acknowledge Dr Andrew Coy and Dr Bertram Manz at Magritek and Dr Alan Kenwright for assistance with NMR, Dr Guy Clarkson for support with X-ray crystallography, and Professor David Parker and Professor Thomas Meersmann for useful discussions. Publisher copyright: {\textcopyright} The Royal Society of Chemistry 2025",

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AU - Pavlovskaya, Galina

AU - Harvey, Peter

N1 - NR thanks HKBU, the Hong Kong Jockey Club Charities Trust, and the University of Warwick for support. CAK and CA thank the Hong Kong Jockey Club for support under the Global JC STEM Professorship scheme. PH was supported by a URKI Future Leaders Fellowship [MR/X034046/1]. We acknowledge Dr Andrew Coy and Dr Bertram Manz at Magritek and Dr Alan Kenwright for assistance with NMR, Dr Guy Clarkson for support with X-ray crystallography, and Professor David Parker and Professor Thomas Meersmann for useful discussions. Publisher copyright: © The Royal Society of Chemistry 2025

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N2 - A series of macrocyclic transition-metal complexes, including Fe(II), Co(II), Ni(II), and Cu(II) complexes, have been evaluated for parashift MRI imaging applications, by assessing their paramagnetic NMR properties, including proton chemical shifts, nuclear relaxation rates, and any exchange dynamics in solution, at magnetic fields strengths relevant to clinical and pre-clinical imaging. Among the complexes studied, Fe(II) and Co(II) systems demonstrated significant paramagnetic shifts with desirable relaxation properties, making them potential candidates for lanthanide-free parashift molecular probes for MRI. Field-dependent nuclear relaxation rate analyses provided insights into electronic relaxation times, confirming the suitability of certain complexes for parashift imaging at lower magnetic fields. Phantom imaging experiments at 9.4 T further validated the feasibility of molecular imaging using a cyclen-based macrocyclic Fe(II) complex, making a significant advance toward developing transition metal-based MRI probes using biogenic metal ions, and offer promise for future responsive imaging due to the direct signal detection.

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Macrocyclic Transition-Metal Parashift Complexes for MRI at Clinical and Pre-clinical Magnetic Fields

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