Abstract
Parallel acquisition NMR spectroscopy (PANSY) is used to detect simultaneously signals from up to four nuclear species, such as H-1, H-2, C-13, N-15, F-19 and P-31. The conventional COSY, TOCSY, HSQC, HMQC and HMBC pulse sequences have been adapted for such applications. Routine availability of NMR systems that incorporate multiple receivers has led to development of new types of NMR experiments. One such scheme named PANACEA allows unambiguous structure determination of small organic molecules from a single measurement and includes an internal field/frequency correction routine. It does not require the conventional NMR lock system and can be recorded in pure liquids. Furthermore, long-range spin–spin couplings can be extracted from the PANACEA spectra and used for three-dimensional structure refinement. In bio-molecular NMR, multi-receiver NMR systems are used for simultaneous recording of H-1 and C-13 detected multi-dimensional spectra. For instance, the 2D (HA)CACO and 3D (HA)CA(CO)NNH experiments can be recorded simultaneously in proteins of moderate size (up to 30 kDa). The multi-receiver experiments can also be used in combination with the fast acquisition schemes such as Hadamard spectroscopy, computer optimized aliasing and projection-reconstruction techniques. In general, experiments that utilize multiple receivers provide significantly more information from a single NMR measurement as compared to the conventional single receiver techniques.
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Abbreviations
- COSY:
-
Correlation spectroscopy
- FID:
-
Free induction decay
- HETCOR:
-
Heteronuclear correlation
- HMBC:
-
Heteronuclear multiple-bond correlation
- HMQC:
-
Heteronuclear multiple-quantum correlation
- HSQC:
-
Heteronuclear single-quantum correlation
- INADEQUATE:
-
Incredible natural abundance double quantum transfer experiment
- IPAP:
-
In-phase anti-phase
- NMR:
-
Nuclear magnetic resonance
- NOE:
-
Nuclear Overhauser effect
- PANACEA:
-
Parallel acquisition NMR and all-in-one combination of experimental applications
- PANSY:
-
Parallel acquisition NMR spectroscopy
- PR:
-
Projection reconstruction
- RF:
-
Radio frequency
- S/N:
-
Signal-to-noise
- TOCSY:
-
Total correlation spectroscopy
- TROSY:
-
Transverse relaxation optimized spectroscopy
References
Gal M, Frydman L (2010) Multidimensional NMR methods for the solution state. In: Morris GA, Emsley JW (eds) Encyclopedia of magnetic resonance, Chap. 3. Wiley, Chichester, UK
Kupče Ē, Freeman R (2003) J Biomol NMR 27:101–113
Kupče Ē, Nishida T, Freeman R (2003) Progr NMR Spectrosc 42:95–122
Kupče Ē, Freeman R (2006) In: Arrondo JLR, Alonso A (eds) Advanced techniques in biophysics, Chap. 6. Springer, Berlin, pp 131–147
Ding K, Gronenborn A (2002) J Magn Reson 156:262–268
Hiller S, Fiorito F, Wüthrich K, Wider G (2005) Proc Natl Acad Sci USA 102:10876–10881
Fiorito F, Hiller S, Wider G, Wüthrich K (2006) J Biomol NMR 35:27–37
Brüschweiler R, Zhang F (2004) J Chem Phys 120:5253–5260
Zhang F, Brüschweiler R (2004) J Am Chem Soc 126:13180–13181
Frydman L, Scherf T, Lupulescu A (2002) Proc Natl Acad Sci USA 99:15858
Frydman L, Scherf T, Lupulescu A (2003) J Am Chem Soc 125:9204
Barna JCJ, Laue ED, Mayger MR, Skilling J, Worrall SJP (1987) J Magn Reson 73:69–77
Chen J, Mandelshtam VA, Shaka AJ (2000) J Magn Reson 146:363–368
Schmieder P, Stern AS, Wagner G, Hoch JC (1993) J Biomol NMR 3:569
Kazimierczuk K, Zawadzka A, Kozminski W, Zhukov I (2006) J Biomol NMR 36:157–168
Kazimierczuk K, Kozminski W, Zhukov I (2006) J Magn Reson 179:323–328
Kupče Ē, Freeman R (2003) J Am Chem Soc 125:13958–13959
Kupče Ē, Freeman R (2004) J Am Chem Soc 126:6429–6440
Yoon JW, Godsill S, Kupče Ē, Freeman R (2006) Magn Reson Chem 44:197–209
Schanda P, Brutscher B (2005) J Am Chem Soc 127:8014
Schanda P, Kupče Ē, Brutscher B (2005) J Biomol NMR 33:199
van de Ven FJM (1995) Multidimensional NMR in liquids. VCH, New York
Cavanagh J, Fairbrother WJ, Palmer AG III, Skelton NJ (1996) Protein NMR spectroscopy. Academic, San Diego
Moore GJ, Hrovat MI, Gonzalez RG (1991) Magn Reson Med 19:105–112
Hou T, MacNamara E, MacNaughton M, Raftery D (1999) Anal Chim Acta 400:297–305
Blaimer M, Breuer F, Mueller M, Heidemann RM, Griswold MA, Jakob PM (2004) Top Magn Reson Imaging 15:223–236
Kupče Ē, Freeman R, John BK (2006) J Am Chem Soc 128:9606–9607
Ernst RR, Bodenhausen G, Wokaun A (1997) Principles of nuclear magnetic resonance in one and two dimensions. Clarendon, Oxford
Robinson JN, Coy A, Dykstra R, Eccles CD, Hunter MW, Callaghan PT (2006) J Magn Reson 182:343–347
Kupče Ē, Wrackmeyer B (2010) Appl Organomet Chem (Spl Issue: In Memoriam Professor Edmunds Lukevics) 24:837–841
Kupče Ē, Cheatham S, Freeman R (2007) Magn Reson Chem 45:378–380
Bax A, Freeman R, Kempsell SP (1980) J Am Chem Soc 102:4849–4851
Bax A, Freeman R, Kempsell SP (1980) J Magn Reson 41:349–353
Kupče Ē, Freeman R (2008) J Am Chem Soc 130:10788–10792
Kupče Ē, Freeman SR (2010) Magn Reson Chem 48:333–336
Kupče Ē, Freeman R (2010) J Magn Reson 206:147–153
Iijima T, Takegoshi K (2008) J Magn Reson 191:128–134
Bermel W, Bertini I, Felli IC, Piccioli M, Pierattelli R (2006) Prog NMR Spectrosc 48:25
Kupče Ē, Kay LE, Freeman R (2010) J Am Chem Soc 132:18008–18011
Jeannerat D (2003) Magn Reson Chem 41:3–17
Jeannerat D (2007) J Magn Reson 186:112–122
Lescop E, Schanda P, Rasia R, Brutscher B (2007) J Am Chem Soc 129:2756–2757
Hounsfield GN (1973) Br J Radiol 46:1016
Zhi-Pei Liang, Lauterbur PC (2000) Principles of magnetic resonance imaging, Chap. 6. IEEE, New York, pp 187–216
Nagayama K, Bachmann P, Wuthrich K, Ernst RR (1978) J Magn Reson 31:133
Bodenhausen G, Ernst RR (1982) J Am Chem Soc 104:1304–1309
Kupče Ē, Freeman R (2004) Concepts Magn Reson 22A:4–11
Kupče Ē, Freeman R (2004) Concepts Magn Reson 23A:63–75
Kupče Ē, Freeman R (2004) Spectroscopy 19(10):16–20
McIntyre L, Freeman R (1992) J Magn Reson 96:425
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Kupče, Ē. (2011). NMR with Multiple Receivers. In: Heise, H., Matthews, S. (eds) Modern NMR Methodology. Topics in Current Chemistry, vol 335. Springer, Berlin, Heidelberg. https://doi.org/10.1007/128_2011_226
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DOI: https://doi.org/10.1007/128_2011_226
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