Mobile and Compact NMR

Blümich, Bernhard

doi:10.1007/978-3-319-28275-6_75-1

Cited by 6 publications

(5 citation statements)

References 242 publications

(288 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…To our knowledge, few people are involved in developing MRI hardware based on the Earthʼs magnetic field: Callaghanʼs group at Victoria University of Wellington (New Zealand) [6][7][8] and Mohorič, a member of Stepisñikʼs group at the University of Ljubljana (Slovenia) [9,10], constitute a list which is not exhaustive. We might also mention the Polymer Gel Group at the Technical University of Bremen (Germany) [11] and the groups from Aachen (RWTH and Jülich) [12,13], for their well-known instrumental development. The educational community is growing: not only are companies such as Phywe (Göttingen, Germany), dedicated to turnkey student practicals, making the 0.5 T Compact-MRTR ® , interested in such devices, but also scientific instrument manufacturers, such as Thermo Scientific (Waltham, MA, USA), selling the PicoSpin ® , also with a permanent stray field, up to 1.8 T, for NMR spectrometers, and NMReady (Calgary, AL, Canada), offering research and training solutions for the classroom, with a 1.4 T static magnet including a frequency drive lock, are now presenting competing solutions.…”

Section: The Motivation For Choosing the Efnmrmentioning

confidence: 99%

Illustrating the quantum approach with an Earth magnetic field MRI

Benli¹,

Dillmann²,

Louelh³

et al. 2015

Eur. J. Phys.

View full text Add to dashboard Cite

Teaching imaging of magnetic resonance (MR) today is still as challenging as it has always been, because it requires admitting that we cannot express fundamental questions of quantum mechanics with straightforward language or without using extensive theory. Here we allow students to face a real MR setup based on the Earthʼs magnetic field. We address the applied side of teaching MR using a device that is affordable and that proves to be sufficiently robust, at universities in Orsay, France, and San Sebastian, Spain, in experimental practicals at undergraduate and graduate levels. We specifically present some of the advantages of low field for measuring R2 relaxation rates, reaching a power of separation of 1.5 μmol on Mn(II) ions between two water bottles each of half a liter. Finally we propose key approaches for the lecturers to adopt when they are asked to pass from theoretical knowledge to teachable knowhow. The outcomes are fast calibration and the MR acquisition protocols, demonstrating the reproducibility of energy transfer during the saturation pulses, and the quantitative nature of MR, with water protons and a helium-3 sample.

show abstract

Section: The Motivation For Choosing the Efnmrmentioning

confidence: 99%

Illustrating the quantum approach with an Earth magnetic field MRI

Benli¹,

Dillmann²,

Louelh³

et al. 2015

Eur. J. Phys.

View full text Add to dashboard Cite

show abstract

“…Due to the magnetic field inhomogeneities, structural information on the chemical makeup of a sample cannot be provided. However, the NMR signal decay following excitation by a radio‐frequency (RF) pulse is useful in applications requiring information on relaxation, diffusion, or other related phenomena (Blümich, 2016). The technique has a wide range of applications in the food industry justifying the numerous review articles that have been published on the subject in recent years (Blümich, 2019; Colnago et al., 2021; Kirtil & Oztop, 2016; Ozel & Oztop, 2021; Rodríguez‐Alonso et al., 2019; Yao et al., 2022).…”

Section: Introductionmentioning

confidence: 99%

The use of time domain ¹H NMR to study proton dynamics in starch‐rich foods: A review

Riley

Nivelle

Ooms

et al. 2022

Comp Rev Food Sci Food Safe

View full text Add to dashboard Cite

Starch is a major contributor to the carbohydrate portion of our diet. When it is present with water, it undergoes several transformations during heating and/or cooling making it an essential structure-forming component in starch-rich food systems (e.g., bread and cake). Time domain proton nuclear magnetic resonance (TD 1 H NMR) is a useful technique to study starch-water interactions by evaluation of molecular mobility and water distribution. The data obtained correspond to changes in starch structure and the state of water during or resulting from processing. When this technique was first applied to starch(-rich) foods, significant challenges were encountered during data interpretation of complex food systems (e.g., cake or biscuit) due to the presence of multiple constituents (proteins, carbohydrates, lipids, etc.). This article discusses the principles of TD 1 H NMR and the tools applied that improved characterization and interpretation of TD NMR data. More in particular, the major differences in proton distribution of various dough and cooked/baked food systems are examined. The application of variabletemperature TD 1 H NMR is also discussed as it demonstrates exceptional ability to elucidate the molecular dynamics of starch transitions (e.g., gelatinization, gelation) in dough/batter systems during heating/cooling. In conclusion, TD NMR is considered a valuable tool to understand the behavior of starch and water that relate to the characteristics and/or quality of starchy food products. Such insights are crucial for food product optimization and development in response to the needs of the food industry.

show abstract

“…It relates to chain stiffness and the free volume and can be probed by measuring NMR relaxation. For such studies, compact tabletop and portable instruments are available . A portable NMR relaxometry sensor for nondestructive testing is the NMR‐MOUSE (MObile Universal Surface Explorer), which measures the NMR relaxation from a thin slice within an object exposed to the stray‐stray field of a permanent magnet (Figure ) .…”

Section: Introductionmentioning

confidence: 99%

“…By moving the sensor, different sections of the object can be probed, and discrete depth profiles can be measured with the spatial resolution determined by the slice thickness when the sensor is moved away from the object in small steps. These profiles report the stratigraphy of a layered object and the material properties of the layers in terms of the 1 H spin density, the 1 H NMR relaxation times T 1 and T 2 , and the self‐diffusion coefficient of solvents in the material …”

Section: Introductionmentioning

confidence: 99%

Aging of polymeric materials by stray‐field NMR relaxometry with the NMR‐MOUSE

Blümich

2018

Concepts Magnetic Resonance

Self Cite

View full text Add to dashboard Cite

The sensitivity of NMR relaxation to molecular motion is explored to study the aging of polymer materials and paint binder in master paintings. Polymeric materials are formulated from macromolecules with a distribution of molecular weights and low molecular weight additives. Their physical and chemical properties change with time due to exposure to temperature, mechanical stress, and solvents. These conditions lead to physical and chemical aging, which can proceed naturally over longer times or accelerated under artificial conditions in shorter times. Either procedure bears a particular signature on the molecular mobility, which can be probed nondestructively by the NMR relaxation times T1 and T2. Natural aging and accelerated temperature‐ and solvent‐induced aging are summarized for synthetic polymer materials and compared to aging of binders in the paint layers of paintings aged naturally over hundreds of years and aged artificially by solvent‐cleaning procedures during restoration or at elevated temperature during forgery.

show abstract

Mobile and Compact NMR

Cited by 6 publications

References 242 publications

Illustrating the quantum approach with an Earth magnetic field MRI

Illustrating the quantum approach with an Earth magnetic field MRI

The use of time domain ¹H NMR to study proton dynamics in starch‐rich foods: A review

Aging of polymeric materials by stray‐field NMR relaxometry with the NMR‐MOUSE

Contact Info

Product

Resources

About

Mobile and Compact NMR

Cited by 6 publications

References 242 publications

Illustrating the quantum approach with an Earth magnetic field MRI

Illustrating the quantum approach with an Earth magnetic field MRI

The use of time domain 1H NMR to study proton dynamics in starch‐rich foods: A review

Aging of polymeric materials by stray‐field NMR relaxometry with the NMR‐MOUSE

Contact Info

Product

Resources

About

The use of time domain ¹H NMR to study proton dynamics in starch‐rich foods: A review