Current NMR Strategies for Biomarker Discovery - Proteomic and Metabolomic Approaches to Biomarker Discovery

Biology Reference

In-Depth Information

in the 1 H NMR spectra of urine. Metabolomics 2008;

17. Robosky LC, Reily MD, Avizonis D. Improving NMR

sensitivity by use of salt-tolerant cryogenically cooled

probes. Anal Bioanal Chem 2007;

328 e 36.

387

:529 e 32.

32.

Jiang LM, Huang J, Wang YL, et al. Eliminating the

dication-induced intersample chemical-shift variations

for NMR-based bio

18. de Swiet TM. Optimal electric

fields for different

sample shapes in high resolution NMR spectroscopy.

J Magn Reson 2005;

uid metabonomic

analysis.

:331 e 4.

19. Spraul M, Hofmann M, Ackermann R, et al. Flow

injection proton nuclear magnetic resonance spec-

troscopy combined with pattern recognition methods:

implications for rapid structural studies and high

throughput biochemical

174

:4209 e 19.

33. Diaz SO, Pinto J, Graca G, et al. Metabolic biomarkers

of prenatal disorders: an exploratory NMR metabo-

nomics study of second trimester maternal urine and

blood plasma. J Proteome Res 2011;

Analyst 2012;

137

:3732 e 42.

34. Hall JE, Guyton AC. Guyton and Hall Textbook of

Medical Physiology. 12th ed. Philadelphia: Saunders/

Elsevier; 2011. p. 380.

35. Xiao CN, Hao FH, Qin XR, et al. An optimized buffer

system for NMR-based urinary metabonomics with

effective pH control, chemical shift consistency and

dilution minimization. Analyst 2009;

screening. Anal Commun

:339 e 41.

20. Gavaghan CL, Nicholson JK, Connor SC, et al. Directly

coupled high-performance liquid chromatography and

nuclear magnetic resonance spectroscopic with che-

mometric studies on metabolic variation in Sprague-

Dawley rats. Anal Biochem 2001;

1997;

291

:245 e 52.

:916 e 25.

36. Van QN, Issaq HJ, Jiang QJ, et al. Comparison of 1D

and 2D NMR spectroscopy for metabolic pro

134

21. Olson DL, Norcross JA, O

Neil-Johnson M, et al.

Micro

ow NMR: concepts and capabilities. Anal Chem

ling.

:2966 e 74.

22. Norcross JA, Milling CT, Olson DL, et al. Multiplexed

NMR: an automated capNMR dual-sample probe.

Anal Chem 2010;

2004;

:630 e 9.

37. Stolzenburg S, Lauridsen MB, Toft H, et al. Improved

quality of 1 H NMR spectroscopic data for enhanced

metabolic pro

J Proteome Res 2008;

:7227 e 36.

23. Gökay O, Albert K. From single to multiple microcoil

ling of low molecular weight metabo-

lites in human serum. Metabolomics 2011;

:270 e 7.

38. Duportet X, Aggio R, Carneiro S, et al. The biological

interpretation of metabolomic data can be misled by the

extraction method used. Metabolomics 2012;

flow probe NMR and related capillary techniques:

a review. Anal Bioanal Chem 2012;

:647 e 69.

24. LauridsenM, Hansen SH, Jaroszewski JW, et al. Human

urine as test material in 1 H NMR-based metabonomics:

recommendations for sample preparation and storage.

Anal Chem 2007;

402

:410 e 21.

39. Tiziani S, Einwas AH, Lodi A, et al. Optimized

metabolite extraction from blood serum for 1 H nuclear

magnetic resonance spectroscopy. Anal Biochem 2008;

377

:1181 e 6.

25. Beckonert O, Keun HC, Ebbels TMD, et al. Metabolic

pro

:16 e 23.

40. Sheedy JR, Ebeling PR, Gooley PR, et al. A sample

preparation protocol for 1 H nuclear magnetic reso-

nance studies of water-soluble metabolites in blood

and urine. Anal Biochem 2010;

ling, metabolomic and metabonomic procedures

for NMR spectroscopy of urine, plasma, serum and

tissue extracts. Nat Protoc 2007;

:2692 e 703.

26. Saude EJ, Sykes BD. Urine stability for metabolomic

studies: effects of preparation and storage. Metab-

olomics 2007;

:263 e 5.

41. Teng Q, Huang WL, Collette TW, et al. A direct cell

quenching method for cell-culture based metab-

olomics. Metabolomics 2009;

398

:19 e 27.

27. Hani EK, Chan VL. Expression and characterization of

campylobacter-jejuni benzoylglycine amidohydrolase

(hippuricase) gene in escherichia-coli. J Bacteriol 1995;

177

:199 e 208.

42. Salek R, Cheng KK, Grif

n J. The study of mammalian

metabolism through NMR-based metabolomics. In:

Jameson D, Verma M, Westerhoff HV, editors. Methods

in System Biology. Methods in Enzymology, volume 500.

San Diego: Elsevier Academic Press; 2011. p. 337 e 51.

43. Dietmair S, Timmins NE, Gray PP, et al. Towards

quantitative metabolomics of mammalian cells:

Development of a metabolite extraction protocol. Anal

Biochem 2010;

:2396 e 402.

28. Drider D, Bekal S, Prévost H. Genetic organization

and expression of citrate permease in lactic acid

bacteria. Genet Mol Res 2004;

:273 e 81.

29. Lenz EM, Wilson ID. Analytical strategies in metabo-

nomics. J Proteome Res 2007;

:443 e 58.

30. Somashekar BS, Ijare OB, Gowda GAN, et al. Simple

pulse-acquire NMR methods for the quantitative

analysis of calcium, magnesium and sodium in human

serum. Spectroc Acta Pt A-Molec Biomolec Spectr 2006;

:155 e 64.

44. Le Belle JE, Harris NG, Williams SR, et al. A

comparison of cell and tissue extraction techniques

using high-resolution 1 H NMR spectroscopy. NMR

Biomed 2002;

404

:254 e 60.

31. Asiago VM, Gowda GAN, Zhang S, et al. Use of EDTA

to minimize ionic strength dependent frequency shifts

:37 e 44.

45. Martineau E, Tea I, Loaec G, et al. Strategy for choosing

extraction procedures for NMR-based metabolomic

Proteomic and Metabolomic Approaches to Biomarker Discovery

Search WWH ::

Custom Search

Home