High-Resolution Microcoil
            <sup>1</sup>
            H-NMR for Mass-Limited, Nanoliter-Volume Samples

Olson, Dean L.; Peck, Timothy L.; Webb, Andrew; Magin, Richard L.; Sweedler, Jonathan V.

doi:10.1126/science.270.5244.1967

Cited by 510 publications

(469 citation statements)

References 15 publications

Supporting

Mentioning

459

Contrasting

Unclassified

Order By: Relevance

“…This does not necessitate the acquisition of a functionalized xenon spectrum. Here we introduce a method, Figure 8a, that measures changes in the Figure 8b shows the application of the indirect assay (n = 5) to a solution containing 1.5 mM of peptide-derivatized cryptophane-A cage (17). The decrease in the integrated intensity of the solution peak by 60% reflects the presence the cryptophane-bound xenon.…”

Section: Indirect Assay For Biosensor Event By Xenon Exchangementioning

confidence: 99%

“…Steady progress is being made to incorporate NMR analysis into high-throughput and combinatorial chemistry applications. [13][14][15][16][17][18] Utilization of conventional NMR for high-throughput biosensor applications may be limited by the intrinsically low sensitivity and the complexity of spectra obtained from biomolecules and mixtures. Laser-polarization 19 of 129 Xe offers an increase in signal-tonoise by several orders of magnitude relative to the equilibrium nuclear-spin polarizations measured in normal NMR experiments.…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Development of a Functionalized Xenon Biosensor

et al. 2004

View full text Add to dashboard Cite

NMR-based biosensors that utilize laser-polarized xenon offer potential advantages beyond current sensing technologies. These advantages include the capacity to simultaneously detect multiple analytes, the applicability to in vivo spectroscopy and imaging, and the possibility of "remote" amplified detection. Here we present a detailed NMR characterization of the binding of a biotin-derivatized caged-xenon sensor to avidin. Binding of "functionalized" xenon to avidin leads to a change in the chemical shift of the encapsulated xenon in addition to a broadening of the resonance, both of which serve as NMR markers of ligand-target interaction. A control experiment in which the biotin-binding site of avidin was blocked with native biotin showed no such spectral changes, confirming that only specific binding, rather than nonspecific contact, between avidin and functionalized xenon leads to the effects on the xenon NMR spectrum. The exchange rate of xenon (between solution and cage) and the xenon spin-lattice relaxation rate were not changed significantly upon binding. We describe two methods for enhancing the signal from functionalized xenon by exploiting the laser-polarized xenon magnetization reservoir. We also show that the xenon chemical shifts are distinct for xenon encapsulated in different diastereomeric cage molecules. This demonstrates the potential for tuning the encapsulated xenon chemical shift, which is a key requirement for being able to multiplex the biosensor.

show abstract

Section: Indirect Assay For Biosensor Event By Xenon Exchangementioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Development of a Functionalized Xenon Biosensor

et al. 2004

View full text Add to dashboard Cite

show abstract

“…As is well known, miniaturised NMR detectors benefit from a favorable scaling of mass sensitivity (the absolute number of spins required for a detectable signal) with probe volume [13]. This had led to flow probes with very high sensitivity based on micro-solenoid coils wound around glass capillaries.…”

Section: Introductionmentioning

confidence: 99%

An optimised detector for in-situ high-resolution NMR in microfluidic devices

Finch

Yılmaz

Utz

2016

Journal of Magnetic Resonance

109

View full text Add to dashboard Cite

Integration of high-resolution nuclear magnetic resonance (NMR) spectroscopy with microfluidic lab-on-a-chip devices is challenging due to limited sensitivity and line broadening caused by magnetic susceptibility inhomogeneities. We present a novel double-stripline NMR probe head that accommodates planar microfluidic devices, and obtains the NMR spectrum from a rectangular sample chamber on the chip with a volume of 2 l. Finite element analysis is used to jointly optimise the detector and sample volume geometry for sensitivity and RF homogeneity. A prototype of the optimised design has been built, and its properties have been characterised experimentally. The performance in terms of sensitivity and RF homogeneity closely agrees with the numerical predictions. The system reaches a mass limit of detection of 1.57 nMol p s, comparing very favourably with other micro-NMR systems. The spectral resolution of this chipGprobe system is better than 1.75 Hz at a magnetic field of 7 T, with excellent line shape.

show abstract

“…Micro-fabricated receiver structures can be directly integrated into lab-on-achip devices, and systems with limits of detection as low as 0.025 nmol · s 1/2 have been reported in the literature 5 . Different detector geometries and microfabrication strategies for microfluidic NMR have been described, including solenoids [6][7][8] , planar spirals [9][10][11][12] , and microslots/micro striplines [13][14][15][16] . While these approaches yield similar sensitivity for a given probe volume, resolution in the vicinity of 0.01 ppm has only been achieved with very simple, linear fluidic geometries (capillar- ies).…”

Section: Introductionmentioning

confidence: 99%

Structural shimming for high-resolution nuclear magnetic resonance spectroscopy in lab-on-a-chip devices

2014

View full text Add to dashboard Cite

High-resolution proton NMR spectroscopy is well-established as a tool for metabolomic analysis of biological fluids at the macro scale. Its full potential has, however, not been realised yet in the context of microfluidic devices. While microfabricated NMR detectors offer substantial gains in sensitivity, limited spectral resolution resulting from mismatches in the magnetic susceptibility of the sample fluid and the chip material remains a major hurdle. In this contribution, we show that susceptibility broadening can be compensated even in the presence of substantial mismatch by including suitably shaped compensation structures into the chip design. An efficient algorithm for the calculation of field maps from arbitrary chip layouts based on Gaussian quadrature is used to optimise the shape of the compensation structure to ensure a flat field distribution inside the sample area. Previously, the complexity of microfluidic NMR systems has been restricted to simple capillaries to avoid susceptibility broadening. The structural shimming approach introduced here can be adapted to virtually any shape of sample chamber and surrounding fluidic network, thereby greatly expanding the design space and enabling true lab-on-a-chip systems suitable for high-resolution NMR detection.

show abstract

High-Resolution Microcoil ¹ H-NMR for Mass-Limited, Nanoliter-Volume Samples

Cited by 510 publications

References 15 publications

Development of a Functionalized Xenon Biosensor

Development of a Functionalized Xenon Biosensor

An optimised detector for in-situ high-resolution NMR in microfluidic devices

Structural shimming for high-resolution nuclear magnetic resonance spectroscopy in lab-on-a-chip devices

Contact Info

Product

Resources

About

High-Resolution Microcoil 1 H-NMR for Mass-Limited, Nanoliter-Volume Samples

Cited by 510 publications

References 15 publications

Development of a Functionalized Xenon Biosensor

Development of a Functionalized Xenon Biosensor

An optimised detector for in-situ high-resolution NMR in microfluidic devices

Structural shimming for high-resolution nuclear magnetic resonance spectroscopy in lab-on-a-chip devices

Contact Info

Product

Resources

About

High-Resolution Microcoil ¹ H-NMR for Mass-Limited, Nanoliter-Volume Samples