839 research outputs found
Cryogen-Free dissolution Dynamic Nuclear Polarization polarizer operating at 3.35 T, 6.70 T and 10.1 T
Purpose: A novel dissolution dynamic nuclear polarization (dDNP) polarizer
platform is presented. The polarizer meets a number of key requirements for in
vitro, pre-clinical and clinical applications. Method: It uses no liquid
cryogens, operates in continuous mode, accommodates a wide range of sample
sizes up to and including those required for human studies, and is fully
automated. Results: It offers a wide operational window both in terms of
magnetic field, up to 10.1 T, and temperature, from room temperature down to
1.3 K. The polarizer delivers a 13C liquid state polarization for
[1-13C]pyruvate of 70%. The build-up time constant in the solid state is
approx. 1200 s (20 min), allowing a sample throughput of at least one sample
per hour including sample loading and dissolution. Conclusion: We confirm the
previously reported strong field dependence in the range 3.35 to 6.7 T, but see
no further increase in polarization when increasing the magnetic field strength
to 10.1 T for [1-13C]pyruvate and trityl. Using a custom dry magnet, cold head
and recondensing, closed-cycle cooling system, combined with a modular DNP
probe, automation and fluid handling systems; we have designed a unique dDNP
system with unrivalled flexibility and performance.Comment: 16 pages, 8 figure
A Hyperpolarizable 1H Magnetic Resonance Probe for Signal Detection 15 Minutes after Spin Polarization Storage
Nuclear magnetic resonance (NMR) and magnetic resonance imaging (MRI) are two extremely important techniques with applications ranging from molecular structure determination to human imaging. However, in many cases the applicability of NMR and MRI are limited by inherently poor sensitivity and insufficient nuclear spin lifetime. Here we demonstrate a cost-efficient and fast technique that tackles both issues simultaneously. We use the signal amplification by reversible exchange (SABRE) technique to hyperpolarize the target1H nuclei and store this polarization in long-lived singlet (LLS) form after suitable radiofrequency (rf) pulses. Compared to the normal scenario, we achieve three orders of signal enhancement and one order of lifetime extension, leading to1H NMR signal detection 15 minutes after the creation of the detected states. The creation of such hyperpolarized long-lived polarization reflects an important step forward in the pipeline to see such agents used as clinical probes of disease
Electron and nuclear spin dynamics in the thermal mixing model of dynamic nuclear polarization
A novel mathematical treatment is proposed for computing the time evolution
of dynamic nuclear polarization processes in the low temperature thermal mixing
regime. Without assuming any a priori analytical form for the electron
polarization, our approach provides a quantitative picture of the steady state
that recovers the well known Borghini prediction based on thermodynamics
arguments, as long as the electrons-nuclei transition rates are fast compared
to the other relevant time scales. Substantially different final polarization
levels are achieved instead when the latter assumption is relaxed in the
presence of a nuclear leakage term, even though very weak, suggesting a
possible explanation for the deviation between the measured steady state
polarizations and the Borghini prediction. The proposed methodology also allows
to calculate nuclear polarization and relaxation times, once specified the
electrons/nuclei concentration ratio and the typical rates of the microscopic
processes involving the two spin species. Numerical results are shown to
account for the manifold dynamical behaviours of typical DNP samples.Comment: 11 pages, 11 figure
Cluster formation restricts dynamic nuclear polarization of xenon in solid mixtures
During dynamic nuclear polarization (DNP) at 1.5 K and 5 T, (129)Xe nuclear magnetic resonance (NMR) spectra of a homogeneous xenon/1-propanol/trityl-radical solid mixture exhibit a single peak, broadened by (1)H neighbors. A second peak appears upon annealing for several hours at 125 K. Its characteristic width and chemical shift indicate the presence of spontaneously formed pure Xe clusters. Microwave irradiation at the appropriate frequencies can bring both peaks to either positive or negative polarization. The peculiar time evolution of (129)Xe polarization in pure Xe clusters during DNP can be modelled as an interplay of spin diffusion and T(1) relaxation. Our simple spherical-cluster model offers a sensitive tool to evaluate major DNP parameters in situ, revealing a severe spin-diffusion bottleneck at the cluster boundaries and a significant sample overheating due to microwave irradiation. Subsequent DNP system modifications designed to reduce the overheating resulted in four-fold increase of (129)Xe polarization, from 5.3% to 21%
<i>In Vivo</i> phenotyping of tumor metabolism in a canine cancer patient with simultaneous <sup>18</sup>F-FDG-PET and hyperpolarized <sup>13</sup>C-Pyruvate magnetic resonance spectroscopic imaging (hyperPET):mismatch demonstrates that FDG may not always reflect the Warburg effect
In this communication the mismatch between simultaneous 18F-FDG-PET and a 13C-lactate imaging (hyperPET) in a biopsy verified squamous cell carcinoma in the right tonsil of a canine cancer patient is shown. The results demonstrate that 18F-FDG-PET may not always reflect the Warburg effect in all tumors
Long-lived States to Sustain SABRE Hyperpolarised Magnetisation
The applicability of the magnetic resonance (MR) technique in the liquid phase is limited by poor sensitivity and short nuclear spin coherence times which are insufficient for many potential applications. Here we illustrate how it is possible to address both of these issues simultaneously by harnessing long-lived hyperpolarised spin states that are formed by adapting the Signal Amplification by Reversible Exchange (SABRE) technique. We achieve more than 4 % net 1H-polarisation in a long-lived form that remains detectable for over ninety seconds by reference to proton pairs in the biologically important molecule nicotinamide and a pyrazine derivative whose in vivo imaging will offer a new route to probe disease in the futur
Hyperpolarized (6)Li as a probe for hemoglobin oxygenation level.
Hyperpolarization by dissolution dynamic nuclear polarization (DNP) is a versatile technique to dramatically enhance the nuclear magnetic resonance (NMR) signal intensity of insensitive long-T1 nuclear spins such as (6)Li. The (6)Li longitudinal relaxation of lithium ions in aqueous solutions strongly depends on the concentration of paramagnetic species, even if they are present in minute amounts. We herein demonstrate that blood oxygenation can be readily detected by taking advantage of the (6)Li signal enhancement provided by dissolution DNP, together with the more than 10% decrease in (6)Li longitudinal relaxation as a consequence of the presence of paramagnetic deoxyhemoglobin
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