Non-uniform sampling (NUS) is a popular way of reducing the amount of time taken by multidimensional NMR experiments. Among the various non-uniform sampling schemes that exist, the Poisson-gap (PG) schedules are particularly popular, especially when combined with compressed-sensing (CS) reconstruction of missing data points. However, the use of PG is based mainly on practical experience and has not, as yet, been explained in terms of CS theory. Moreover, an apparent contradiction exists between the reported effectiveness of PG and CS theory, which states that a â??flatâ?? pseudo-random generator is the best way to generate sampling schedules in order to reconstruct sparse spectra. In this paper we explain how, and in what situations, PG reveals its superior features in NMR spectroscopy. We support our theoretical considerations with simulations and analyses of experimental data from the Biological Magnetic Resonance Bank (BMRB). Our analyses reveal a previously unnoticed feature of many NMR spectra that explains the success of â??blue-noiseâ?? schedules, such as PG. We call this feature â??clustered sparsityâ??. This refers to the fact that the peaks in NMR spectra are not just sparse but often form clusters in the indirect dimension, and PG is particularly suited to deal with such situations. Additionally, we discuss why denser sampling in the initial and final parts of the clustered signal may be useful.
[NMR paper] NMR solution structure of DNA featuring clustered 2'-deoxyribonolactone and 8-oxoguanine lesions.
NMR solution structure of DNA featuring clustered 2'-deoxyribonolactone and 8-oxoguanine lesions.
NMR solution structure of DNA featuring clustered 2'-deoxyribonolactone and 8-oxoguanine lesions.
Biochemistry. 2016 Jun 20;
Authors: Zalesak J, Constant JF, Jourdan M
Abstract
Ionizing radiations, free radicals and reactive oxygen species lead to hundreds of different DNA lesions. Clustered lesions are typical for ionizing radiations. They compromise the efficiency of the base excision repair pathway (BER) and as a consequence,...
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06-21-2016 01:30 PM
[U. of Ottawa NMR Facility Blog] Non-uniform Sampling (NUS)
Non-uniform Sampling (NUS)
Collecting 2D or 3D NMR data can be very time consuming. The indirect dimension of a 2D experiment is sampled linearly via the t1 increments in the pulse sequence. An FID must be collected for every single linearly spaced t1 increment. In the interest in collecting 2D or 3D NMR data in a more time efficient manner, a great deal of effort is made towards faster data collection techniques. While some of these methods are based on spatial selectivity, others are based on sparse sampling techniques in the indirect dimensions of nD NMR sequences. One such sparse...
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05-11-2016 08:04 PM
Sensitivity of nonuniform sampling NMR
From The DNP-NMR Blog:
Sensitivity of nonuniform sampling NMR
This is not an article directly related to DNP, however, non-uniform sampling is another great technique to enhance sensitivity in a NMR experiment. The concept can easily combined with DNP to yield even higher sensitivity enhancement factors.
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07-17-2015 03:02 PM
[NMR analysis blog] Non Uniform Sampling (NUS) NMR Processing
Non Uniform Sampling (NUS) NMR Processing
Background
In the last few years, Non-Uniform Sampling (NUS) has emerged as a very powerful tool to significantly speed up the acquisition of multidimensional NMR experiments due to the fact that only a subset of the usual linearly sampled data in the Nyquist grid is measured.
Unfortunately, this fast acquisition modality introduces a new challenge as the normal Fourier Transform will fail and consequently, special processing techniques are required.
A number of sophisticated methods have been proposed for reconstructing sparsely sampled 2D...
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12-21-2013 03:15 PM
Application of iterative soft thresholding for fast reconstruction of NMR data non-uniformly sampled with multidimensional Poisson Gap scheduling
Application of iterative soft thresholding for fast reconstruction of NMR data non-uniformly sampled with multidimensional Poisson Gap scheduling
Abstract The fast Fourier transformation has been the gold standard for transforming data from time to frequency domain in many spectroscopic methods, including NMR. While reliable, it has as a drawback that it requires a grid of uniformly sampled data points. This needs very long measuring times for sampling in multidimensional experiments in all indirect dimensions uniformly and even does not allow reaching optimal evolution times that would...
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02-16-2012 05:24 AM
NMR solution structures of clustered abasic site lesions in DNA: structural differenc
NMR solution structures of clustered abasic site lesions in DNA: structural differences between 3'-staggered (-3) and 5'-staggered (+3) bistranded lesions.
Related Articles NMR solution structures of clustered abasic site lesions in DNA: structural differences between 3'-staggered (-3) and 5'-staggered (+3) bistranded lesions.
Biochemistry. 2010 Oct 19;49(41):8978-87
Authors: Hazel RD, de los Santos C
Ionizing radiation produces a distinctive pattern of bistranded clustered lesions in DNA. A relatively low number of clustered lesions may be lethal...
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11-04-2010 10:07 AM
NMR Solution Structures of Clustered Abasic Site Lesions in DNA: Structural Differenc
NMR Solution Structures of Clustered Abasic Site Lesions in DNA: Structural Differences between 3?-Staggered (-3) and 5?-Staggered (+3) Bistranded Lesions
http://pubs.acs.org/appl/literatum/publisher/achs/journals/content/bichaw/0/bichaw.ahead-of-print/bi101021e/aop/images/medium/bi-2010-01021e_0010.gif
Biochemistry
DOI: 10.1021/bi101021e
http://feeds.feedburner.com/~ff/acs/bichaw?d=yIl2AUoC8zA
http://feeds.feedburner.com/~r/acs/bichaw/~4/GNgtLWuPbdM
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Clustered sparsity and Poisson-gap sampling
Linear Mode
