BioNMR
NMR aggregator & online community since 2003
BioNMR    
Learn or help to learn NMR - get free NMR books!
 

Go Back   BioNMR > NMR community > News from NMR blogs
Advanced Search
Home Forums Wiki NMR feeds Downloads Register Today's Posts



Jobs Groups Conferences Literature Pulse sequences Software forums Programs Sample preps Web resources BioNMR issues


Webservers
NMR processing:
MDD
NMR assignment:
Backbone:
Autoassign
MARS
UNIO Match
PINE
Side-chains:
UNIO ATNOS-Ascan
NOEs:
UNIO ATNOS-Candid
UNIO Candid
ASDP
Structure from NMR restraints:
Ab initio:
GeNMR
Cyana
XPLOR-NIH
ASDP
UNIO ATNOS-Candid
UNIO Candid
Fragment-based:
BMRB CS-Rosetta
Rosetta-NMR (Robetta)
Template-based:
GeNMR
I-TASSER
Refinement:
Amber
Structure from chemical shifts:
Fragment-based:
WeNMR CS-Rosetta
BMRB CS-Rosetta
Homology-based:
CS23D
Simshift
Torsion angles from chemical shifts:
Preditor
TALOS
Promega- Proline
Secondary structure from chemical shifts:
CSI (via RCI server)
TALOS
MICS caps, β-turns
d2D
PECAN
Flexibility from chemical shifts:
RCI
Interactions from chemical shifts:
HADDOCK
Chemical shifts re-referencing:
Shiftcor
UNIO Shiftinspector
LACS
CheckShift
RefDB
NMR model quality:
NOEs, other restraints:
PROSESS
PSVS
RPF scores
iCing
Chemical shifts:
PROSESS
CheShift2
Vasco
iCing
RDCs:
DC
Anisofit
Pseudocontact shifts:
Anisofit
Protein geomtery:
Resolution-by-Proxy
PROSESS
What-If
iCing
PSVS
MolProbity
SAVES2 or SAVES4
Vadar
Prosa
ProQ
MetaMQAPII
PSQS
Eval123D
STAN
Ramachandran Plot
Rampage
ERRAT
Verify_3D
Harmony
Quality Control Check
NMR spectrum prediction:
FANDAS
MestReS
V-NMR
Flexibility from structure:
Backbone S2
Methyl S2
B-factor
Molecular dynamics:
Gromacs
Amber
Antechamber
Chemical shifts prediction:
From structure:
Shiftx2
Sparta+
Camshift
CH3shift- Methyl
ArShift- Aromatic
ShiftS
Proshift
PPM
CheShift-2- Cα
From sequence:
Shifty
Camcoil
Poulsen_rc_CS
Disordered proteins:
MAXOCC
Format conversion & validation:
CCPN
From NMR-STAR 3.1
Validate NMR-STAR 3.1
NMR sample preparation:
Protein disorder:
DisMeta
Protein solubility:
camLILA
ccSOL
Camfold
camGroEL
Zyggregator
Isotope labeling:
UPLABEL
Solid-state NMR:
sedNMR


Reply
 
Thread Tools Search this Thread Rate Thread Display Modes
  #1  
Old 08-21-2010, 09:12 PM
nmrlearner's Avatar
Senior Member
 
Join Date: Jan 2005
Posts: 23,713
Points: 193,617, Level: 100
Points: 193,617, Level: 100 Points: 193,617, Level: 100 Points: 193,617, Level: 100
Level up: 0%, 0 Points needed
Level up: 0% Level up: 0% Level up: 0%
Activity: 50.7%
Activity: 50.7% Activity: 50.7% Activity: 50.7%
Last Achievements
Award-Showcase
NMR Credits: 0
NMR Points: 193,617
Downloads: 0
Uploads: 0
Default Basis on qNMR: Integration Rudiments (Part II)

Basis on qNMR: Integration Rudiments (Part II)

My last post was a basic survey on different measurement strategies for peak areas. Manual methods such as counting squares or cutting and weighing, known as ‘boundary methods’ were introduced for historical reasons. These methods were first used by engineers, cartographers, etc, end then quickly adopted by spectroscopists and chromatographers.

In the digital era, most common peak area measurement involves the calculation of the running sum of all points within the peak(s) boundaries or by other quadrature method (e.g. Trapezoid, Simpson, etc [1]). Obviously, the digital resolution, i.e. the number of discrete points that defines a peak is a very important factor in minimizing the integration error. Intuitively, it’s easy to understand that the higher the number of acquired data points, the lower the integration error. It’s therefore very important to avoid any under-digitalization when an FID is acquired, a problem which is unfortunately more common than many chemists realize.

As described by F. Malz and H. Jancke [2], at least five data points must appear above the half width for each resonance for a precise and reliable subsequent integration. What does this mean in practical terms? Typically, acquisition parameters are defined according to the Nyquist condition: the spectral width (SW) and the number of data points (N, total number of complex points) determine the total acquisition time AQ:

AQ = N/SW

And the digital resolution (DR) is proportional to the inverse of the acquisition time, the latter being the product of the dwell time (DW) and the number of increments:

DR = SW/N = DW x TD = 1 / AQ

If we consider a typical 500 MHz 1H-NMR spectrum with a line width at half height of 0.4 Hz (this is a common manufacturer specification) and a spectral width of 10 ppm (5000 Hz), the minimum number of acquired data points required to satisfy the five points rule should be:
5 pt x 5000 Hz / 0.4 Hz = 62500 complex points.

This number is not suitable for the FFT algorithm which requires, generally, a length equal to a power of two. This is done by zero padding the FID with zeroes until the closest upper power of two, in this case 65536 (64 Kb).

Furthermore, in order to get the most out of the acquired data points, zero filling once (adding as many zeros as acquired data points) has been found (see [3]) to incorporate information from the dispersive component into the absorptive component, and hence it is useful to zero fill at least once (which is exactly what Mnova does).. For example, as S. Bourg and J. M. Nuzillard have shown [4], even though zero-filling does not participate in the improvement of the spectral signal to-noise ratio, it may increase the integral precision by a factor up to 2^(1/2) when the time-domain noise is not correlated.

Regardless of the quadrature method, they all share the same systematic problem: in order to integrate one or several peaks it’s necessary to specify the integration limits. In qNMR assays, this is an evaluation parameter whose effect can be estimated using the theoretical line shape of an NMR signal. To a good approximation (assuming proper shimming), the shape of an NMR line can be expressed as a Lorentzian function:


Where w is the peak width at half height and H is its height value. When L(x) is integrated between +/- infinite, the total integrated area becomes:

Obviously, it’s it is unreasonable to integrate digitally from –infinite to +infinite so an approximation must be made by choosing limits. This has been studied by Griffiths and Irving [5] who have showed that for a maximum error of 1%, integration limits of 25 times the line width in both directions must be employed. If errors less than 0.1 % are desired, the integral width has to be +/-76 times the peak width. For example, in a 500 MHz NMR spectrum with a peak width of 1 Hz, the integrated region should be 152 Hz (~0.30 ppm), as illustrated in the image below


But in general, peaks are not so well separated and for example, when studying complex mixtures or impurities related to the main compound, wide integrals cannot be used. In general, integration by direct summation is not adapted to partially overlapping peaks.

For example, just consider the simple case of peak overlapping where, for instance, one peak of the double doublet overlaps within a triplet:


The theoretical relative integrals for the two multiplets should be 1:1. However, the area of the triplet calculated via the standard running sum method will be overvalued because of the contamination caused by one of the peaks of the double doublet which in turn will be underestimated. This is illustrated in the figure below where the green lines corresponds to the triplet, the blue lines to the double doublet and the red line is the actual spectrum (sum of all individual peaks)


The question is: how to overcome this problem? The answer is, of course, Line Fitting (Deconvolution) which will be the subject of my next post.

References:

[1] Jeffrey C. Hoch and Alan S. Stern, NMR Data Processing, Wiley-Liss, New York (1996)

[2] F. Malz, H. Jancke, J. Pharmaceut. Biomed. 38, 813-823 (2005)

[3] E. Bartholdi and R. R. Ernst, "Fourier spectroscopy and the causality principle", J. Magn. Reson. 11, 9-19 (1973)
doi:10.1016/0022-2364(73)90076-0

[4] S. Bourg, J. M. Nuzillard, "Influence of Noise on Peak Integrals Obatined by irect Summation", J. Magn. Reson. 134, 184-188 (1988)
doi:10.1006/jmre.1998.1500

[4] Lee Griffiths and Alan M. Irving, "Assay by nuclear magnetic resonance spectroscopy: quantification limits", Analyst 123 (5), 1061–1068 (1998)





More...

Source: NMR-analysis blog
Reply With Quote


Did you find this post helpful? Yes | No

Reply
Similar Threads
Thread Thread Starter Forum Replies Last Post
[NMRpipe Yahoo group] Integration of Peaks using NMR Draw
Integration of Peaks using NMR Draw Hello, Using scripts I have created my .ft2 file to visualize my 1D 13C data in nmrDraw. I would like to integrate the area for the carbonyl's and the spinning More...
NMRpipe Yahoo group news News from other NMR forums 0 12-21-2011 04:59 PM
2. NMR spectroscopy - Integration
2. NMR spectroscopy - Integration http://i.ytimg.com/vi/ZrVv7VaRjYs/default.jpg 2. NMR spectroscopy - Integration Visit www.chemistry.jamesmungall.co.uk for notes on this topic. Thanks for watching! This video explains how integration tells you the number of hydrogen atoms each peak corresponds to. Discussion of how this can be useful in determining structure. Part of a set of videos giving an introductory course on proton NMR, aimed at around A-level or International Baccalaureate standard. Includes dicussion of integration, chemical shift and coupling. From:jamesmungall Views:9428...
nmrlearner NMR educational videos 0 07-12-2011 08:26 PM
[NMR analysis blog] Basis on qNMR: Integration Rudiments (Part I)
Basis on qNMR: Integration Rudiments (Part I) First a quick recap. In my last post I put forward the idea that integration of NMR peaks is the basis of quantitative analysis. Before going any further, I would like to mention that, alternatively, peak heights can also be used for quantitation, but unless some special pre-processing is employed (see for example P. A. Haysa, R. A. Thompson, Magn. Reson. Chem., 2009, 47, 819 – 824, doi) measurement of peak areas is generally the recommended method for qNMR assays. In this post I will cover some very basic rudiments of NMR peak areas...
nmrlearner News from NMR blogs 0 08-21-2010 09:12 PM
[NMR analysis blog] Basis on qNMR: Intramolecular vs Mixtures qNMR
Basis on qNMR: Intramolecular vs Mixtures qNMR A bit of historical background NMR has won its reputation as a powerful tool for structure determination of organic molecules. In addition to the information provided by chemical shifts and coupling constants, the quantitative relationships existing between the peaks (or groups of peaks - multiplets) arising from the various nuclides in the sample has proven pivotal for the assignment and interpretation of NMR spectra. Despite the fact that the concept of quantitative NMR (qNMR) has been coupled to NMR since the early 1950, shortly...
nmrlearner News from NMR blogs 0 08-21-2010 09:12 PM
[NMR analysis blog] Basis on qNMR: Rudiments
Basis on qNMR: Rudiments http://3.bp.blogspot.com/_-MfflvAgRls/SwgqmEW0Y2I/AAAAAAAAAgs/kvnVoDo_Cms/s400/Intro1.jpgWhen I started playing drums, so many years ago, I kept hearing about so-called "Drum Rudiments". By that time, I was too young to realize how important they were and to me, they appear just as boring and repetitive exercises. However, rudiments (basic building blocks or "vocabulary" of drumming) are absolutely essential to master drums (something I have to admit I never achieved :-) ) In the last few years I’ve had the opportunity to meet and interact with many chemists...
nmrlearner News from NMR blogs 0 08-21-2010 09:12 PM



Posting Rules
You may not post new threads
You may not post replies
You may not post attachments
You may not edit your posts

BB code is On
Smilies are On
[IMG] code is On
HTML code is Off
Trackbacks are Off
Pingbacks are Off
Refbacks are Off



BioNMR advertisements to pay for website hosting and domain registration. Nobody does it for us.



Powered by vBulletin® Version 3.7.3
Copyright ©2000 - 2024, Jelsoft Enterprises Ltd.
Copyright, BioNMR.com, 2003-2013
Search Engine Friendly URLs by vBSEO 3.6.0

All times are GMT. The time now is 06:37 AM.


Map