Relevance of electron spin dissipative processes to dynamic nuclear polarization via thermal mixing

Serra, Sonia Colombo; Filibian, Marta; Carretta, P.; Rosso, Alberto; Tedoldi, Fabio

doi:10.1039/c3cp52534a

Cited by 26 publications

(18 citation statements)

References 27 publications

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“…The EPR line of the trityl was already effectively homogeneous (fast spectral diffusion). However, the electron spin T1 of the radical was dramatically shortened by Gd from about 1 s to 0.1 s. The data suggests that the ratio of nuclear to electron T1 is a critical parameter [28,29]. The addition of Gd or another paramagnetic transition metal to enhance the solid state DNP efficiency, is to eliminate or minimize the relaxation effect in the liquid state post dissolution.…”

Section: How Do We Reach Unity Polarization Fast?mentioning

confidence: 98%

On the present and future of dissolution-DNP

Ardenkjær‐Larsen

2016

Journal of Magnetic Resonance

213

324

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Dissolution-DNP is a method to create solutions of molecules with nuclear spin polarization close to unity. The many orders of magnitude signal enhancement have enabled many new applications, in particular in vivo MR metabolic imaging. The method relies on solid state dynamic nuclear polarization at low temperature followed by a dissolution to produce the room temperature solution of highly polarized spins. This work describes the present and future of dissolution-DNP in the mind of the author. The article describes some of the current trends in the field as well as outlines some of the areas where new ideas will make an impact. Most certainly, the future will take unpredicted directions, but hopefully the thoughts presented here will stimulate new ideas that can further advance the field.

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Section: How Do We Reach Unity Polarization Fast?mentioning

confidence: 98%

On the present and future of dissolution-DNP

Ardenkjær‐Larsen

2016

Journal of Magnetic Resonance

213

324

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“…40–42 The common perception is that the reduction of electron T 1 of the polarizing agent brought about by the addition of paramagnetic agent is responsible for the increase in polarization. 33,41 This is corroborated by measurements of the electron T 1 for samples doped with the various paramagnetic agents that have been shown to enhance 13 C DNP. 32,35,36,38 In each case, the electron T 1 was shortened by about one order of magnitude.…”

Section: Introductionmentioning

confidence: 68%

“…While there are other possible mechanisms that could be responsible for polarization, there is a wealth of evidence that suggests thermal mixing is dominant under the conditions used herein. 9,22,41,56,57 In the most current models of thermal mixing, the shape of the EPR spectrum as well as the electron T 1 of the radical used largely determine both the shape of the DNP spectrum and the maximum achievable polarization. 56,58,59 Though there is an only minimal change in trityl’s EPR spectra with the addition of transition metal (Figure 4a), the electron T 1 measurement is more demonstrative.…”

Section: Resultsmentioning

confidence: 99%

Transition Metal Doping Reveals Link between Electron T₁ Reduction and ¹³C Dynamic Nuclear Polarization Efficiency

Niedbalski¹,

Parish²,

Wang³

et al. 2017

J. Phys. Chem. A

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Optimal efficiency of dissolution dynamic nuclear polarization (DNP) is essential to provide the required high sensitivity enhancements for in vitro and in vivo hyperpolarized 13C nuclear magnetic resonance (NMR) spectroscopy and imaging (MRI). At the nexus of the DNP process are the free electrons which provide the high spin alignment that are transferred to the nuclear spins. Without changing DNP instrumental conditions, one way to improve 13C DNP efficiency is by adding trace amounts of paramagnetic additives such as lanthanide (e.g. Gd3+, Ho3+, Dy3+, Tb3+) complexes to the DNP sample which has been observed to increase solid state 13C DNP signals by 100–250%. Herein, we have investigated the effects of paramagnetic transition metal complex R-NOTA (R=Mn2+, Cu2+, Co2+) doping on the efficiency of 13C DNP using trityl OX063 as the polarizing agent. Our DNP results at 3.35 T and 1.2 K show that doping the 13C sample with 3 mM Mn2+-NOTA led to a substantial improvement of the solid-state 13C DNP signal by a factor of nearly 3-fold. However, the other transition metal complexes Cu2+-NOTA and Co2+-NOTA complexes, despite their paramagnetic nature, had essentially no impact on solid-state 13C DNP enhancement. W-band electron paramagnetic resonance (EPR) measurements reveal that the trityl OX063 electron T1 was significantly reduced in Mn2+-doped samples but not in Cu2+- and Co2+-doped DNP samples. This work demonstrates, for the first time, that not all paramagnetic additives are beneficial to DNP. In particular, our work provides a direct evidence that electron T1 reduction of the polarizing agent by a paramagnetic additive is an essential requirement for the improvement seen in solid-state 13C DNP signal.

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“…The efficiency of a given mechanism often depends on the magnetic field strength and temperature. Recent approaches to gain a better understanding of this dependence were reported by Wenckebach, Vega and co‐workers, and Rosso and co‐workers . Two families of PAs have been intensively used in d ‐DNP, namely nitroxide and triarylmethyl (trityl) radicals, with the former group being especially effective for the polarization of nuclei with large gyromagnetic ratios (γ; e.g.…”

Section: Dissolution Dynamic Nuclear Polarizationmentioning

confidence: 99%

Hyperpolarized NMR Spectroscopy: d‐DNP, PHIP, and SABRE Techniques

Kovtunov

Pokochueva

Salnikov

et al. 2018

Chemistry An Asian Journal

210

237

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The intensity of NMR signals can be enhanced by several orders of magnitude by using various techniques for the hyperpolarization of different molecules. Such approaches can overcome the main sensitivity challenges facing modern NMR/magnetic resonance imaging (MRI) techniques, whilst hyperpolarized fluids can also be used in a variety of applications in material science and biomedicine. This Focus Review considers the fundamentals of the preparation of hyperpolarized liquids and gases by using dissolution dynamic nuclear polarization (d-DNP) and parahydrogen-based techniques, such as signal amplification by reversible exchange (SABRE) and parahydrogen-induced polarization (PHIP), in both heterogeneous and homogeneous processes. The various new aspects in the formation and utilization of hyperpolarized fluids, along with the possibility of observing NMR signal enhancement, are described.

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Relevance of electron spin dissipative processes to dynamic nuclear polarization via thermal mixing

Cited by 26 publications

References 27 publications

On the present and future of dissolution-DNP

On the present and future of dissolution-DNP

Transition Metal Doping Reveals Link between Electron T₁ Reduction and ¹³C Dynamic Nuclear Polarization Efficiency

Hyperpolarized NMR Spectroscopy: d‐DNP, PHIP, and SABRE Techniques

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Relevance of electron spin dissipative processes to dynamic nuclear polarization via thermal mixing

Cited by 26 publications

References 27 publications

On the present and future of dissolution-DNP

On the present and future of dissolution-DNP

Transition Metal Doping Reveals Link between Electron T1 Reduction and 13C Dynamic Nuclear Polarization Efficiency

Hyperpolarized NMR Spectroscopy: d‐DNP, PHIP, and SABRE Techniques

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Product

Resources

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Transition Metal Doping Reveals Link between Electron T₁ Reduction and ¹³C Dynamic Nuclear Polarization Efficiency