Seven-Coordinate CoII, FeII and Six-Coordinate NiII Amide-Appended Macrocyclic Complexes as ParaCEST Agents in Biological Media

Olatunde, Abiola O.; Cox, Jordan M.; Daddario, Michael D.; Spernyak, Joseph A.; Benedict, Jason B.; Morrow, Janet R.

doi:10.1021/ic5006083

Cited by 43 publications

(80 citation statements)

References 29 publications

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“…This assignment is based on the lack of water ligands or other exchangeable groups, and the pH dependence of the CEST effect which is characteristic of amide proton exchange 2c,e. 9 The number of CEST peaks corresponds to the number of inequivalent amide protons which have exchange rate constants suitable for CEST and are shifted sufficiently far from the bulk water peak to be resolved. Notably, the two inequivalent protons on a single amide pendent give rise to resonances that are separated by a 50–70 ppm chemical shift difference.…”

Section: Discussionmentioning

confidence: 99%

“…For example, ligand donor groups used for transition metal ion paraCEST agents to date include aminopyridines,2c alcohols,7a benzimidazoles,2d, 8 pyrazoles2a and amides 2b,e. 9 These ligands all contain OH or NH protons that exchange with water protons to produce the CEST effect. In addition to providing exchangeable protons, macrocyclic ligands for these metal ions must produce complexes with a large degree of kinetic inertness for in vivo studies 10.…”

Section: Introductionmentioning

confidence: 99%

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Six, Seven or Eight Coordinate Fe^II, Co^II or Ni^II Complexes of Amide‐Appended Tetraazamacrocycles for ParaCEST Thermometry

Olatunde

Bond

Dorazio

et al. 2015

Chemistry A European J

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FeII, CoII and NiII complexes of two tetraazamacrocycles (1,4,8,11-tetrakis(carbamoylmethyl)-1,4,8,11-tetraazacyclotetradecane (L1) and 1,4,7,10-tetrakis(carbamoylmethyl)-1,4,7,10-tetraazacyclododecane (L2) show promise as paraCEST agents for registration of temperature (paraCEST = paramagnetic Chemical Exchange Saturation Transfer). The FeII, CoII and NiII complexes of L1 show up to four CEST peaks shifted ≤ 112 ppm, whereas analogous complexes of L2 show only a single CEST peak at ≤ 69 ppm. Comparison of the temperature coefficients (CT) of the CEST peaks of [Co(L2)]2+, [Fe(L2)]2+, [Ni(L1)]2+ and [Co(L1)]2+ showed that a CEST peak of [Co(L1)]2+ gave the largest CT (−0.66 ppm/°C at 4.7 T). NMR spectral and CEST properties of these complexes correspond to coordination complex symmetry as shown by structural data. The [Ni(L1)]2+ and [Co(L1)]2+ complexes have a six-coordinate metal ion bound to the 1-, 4- amide oxygens and four nitrogens of the tetraazamacrocycle. The [Fe(L2)]2+ complex has an unusual eight-coordinate FeII bound to four amide oxygens and four macrocyclic nitrogens. For [Co(L2)]2+, one structure has seven-coordinate CoII with three bound amide pendents and a second structure has a six-coordinate CoII with two bound amide pendents.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Six, Seven or Eight Coordinate Fe^II, Co^II or Ni^II Complexes of Amide‐Appended Tetraazamacrocycles for ParaCEST Thermometry

Olatunde

Bond

Dorazio

et al. 2015

Chemistry A European J

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“…82 Complexes 64–66 were reported for their pH sensitive CEST effects between pH 6.5 and 7.7. 83 Complexes 64–66 displayed CEST signals at 72, 59, and 92 ppm, respectively, with CEST effects ranging from 25 to 39%. 83 …”

Section: Introductionmentioning

confidence: 99%

“…83 Complexes 64–66 displayed CEST signals at 72, 59, and 92 ppm, respectively, with CEST effects ranging from 25 to 39%. 83 …”

Section: Introductionmentioning

confidence: 99%

Enhancing magnetic resonance imaging with contrast agents for ultra-high field strengths

Kuda-Wedagedara

Allen

2014

Analyst

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Contrast agents are diagnostic tools that often complement magnetic resonance imaging. At ultra-high field strengths (≥7 T), magnetic resonance imaging is capable of generating desirable high signal-to-noise ratios, but clinically available contrast agents are less effective at ultra-high field strengths relative to lower fields. This gap in effectiveness demands the development of contrast agents for ultra-high field strengths. In this minireview, we summarize contrast agents reported during the last three years that focused on ultra-high field strengths.

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“…Three recent dedicated CEST workshops (3rd, 4th, and 5th international CEST workshops in Annapolis, 2012, Torino, 2014, and Philadelphia 2016) drew about 90-200 registrants. The last decade has shown major developments for paraCEST agents, 14,15,20,89,90,119,[135][136][137][138][139][140][141][142][143][144][145][146][147][148] diaCEST agents, 12,13,17,42,43,68,72,88,102,116,125,128,[149][150][151][152][153][154][155][156][157][158][159][160] and even hyperpolarized (hyperCEST) agents. 161,162 This is not surprising in view of the number of potential applications including pH imaging, metabolite detection, ion detection, cellular protein and peptide imaging, cell labeling, temperature i...…”

Section: Potential and Clinical Translation Of Cest Methodsmentioning

confidence: 99%

Proton Chemical Exchange Saturation Transfer (CEST) MRS and MRI

Zijl

Sehgal

2016

eMagRes

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Proton magnetic resonance spectroscopy ( 1 H MRS) of biological systems has higher specificity than MRI because resonances of multiple metabolites can be distinguished, reflecting chemistry and physiology in situ. Unfortunately, this approach has very low sensitivity as the metabolites are typically at millimolar concentrations compared to the molar signal strength of water-based MRI. As a consequence, even though 1 H MRS is a powerful and common research tool, its inroad into daily clinical practice has been limited. Until very recently, 1 H MRS applications have focused on the resonances upfield (i.e., at lower frequency) of the water resonance. This article deals with protons that are generally not observed in a typical water-suppressed spectrum, namely, the exchangeable protons found predominantly downfield from water. These can usually be detected by MRS only if the transfer of water proton saturation (established during water suppression) is not a confounding factor, or by using water exchange (WEX) spectroscopy, in which RF labeling of the water protons is transferred to the exchangeable protons and subsequently detected. More importantly, it has recently become clear that the presence of such exchangeable protons on low concentration solute molecules can be detected via the water signal by RF labeling of these protons and subsequent transfer of this label to water protons. This process, leading to saturation of the water signal and enhancement of the effect through repeated exchange, can be used for the imaging of metabolite signals or exchangeable-proton-based contrast agents with enhanced sensitivity. This has given rise to the field of chemical exchange saturation transfer (CEST) MRI, which has greatly increased the potential for translating spectroscopic methods to the clinic. Examples include the measurement of pH, temperature, and enzyme activity as well as detection of cellular metabolites, ions, and proteins and peptides. In addition, bio-organic compounds can now be used for contrast agents, cell and nanoparticle labeling, and reporter genes.

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Seven-Coordinate Co^II, Fe^II and Six-Coordinate Ni^II Amide-Appended Macrocyclic Complexes as ParaCEST Agents in Biological Media

Cited by 43 publications

References 29 publications

Six, Seven or Eight Coordinate Fe^II, Co^II or Ni^II Complexes of Amide‐Appended Tetraazamacrocycles for ParaCEST Thermometry

Six, Seven or Eight Coordinate Fe^II, Co^II or Ni^II Complexes of Amide‐Appended Tetraazamacrocycles for ParaCEST Thermometry

Enhancing magnetic resonance imaging with contrast agents for ultra-high field strengths

Proton Chemical Exchange Saturation Transfer (CEST) MRS and MRI

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Seven-Coordinate CoII, FeII and Six-Coordinate NiII Amide-Appended Macrocyclic Complexes as ParaCEST Agents in Biological Media

Cited by 43 publications

References 29 publications

Six, Seven or Eight Coordinate FeII, CoII or NiII Complexes of Amide‐Appended Tetraazamacrocycles for ParaCEST Thermometry

Six, Seven or Eight Coordinate FeII, CoII or NiII Complexes of Amide‐Appended Tetraazamacrocycles for ParaCEST Thermometry

Enhancing magnetic resonance imaging with contrast agents for ultra-high field strengths

Proton Chemical Exchange Saturation Transfer (CEST) MRS and MRI

Contact Info

Product

Resources

About

Seven-Coordinate Co^II, Fe^II and Six-Coordinate Ni^II Amide-Appended Macrocyclic Complexes as ParaCEST Agents in Biological Media

Six, Seven or Eight Coordinate Fe^II, Co^II or Ni^II Complexes of Amide‐Appended Tetraazamacrocycles for ParaCEST Thermometry

Six, Seven or Eight Coordinate Fe^II, Co^II or Ni^II Complexes of Amide‐Appended Tetraazamacrocycles for ParaCEST Thermometry