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Comparison of 1H NMR Spectra Obtained at 42, 60, 82, and 300 MHz – Fish Oil Omega-3 Ethyl Ester Supplement Example

by Benchtop NMR, Chemistry, Chemometrics, NMR, PAT, Process NMR, qNMR

Process NMR Associates is currently developing NMR applications based on direct measurement of chemometric modeling on NMR data obtained on numerous NMR platforms. Our intention is to develop solutions that can be executed on any NMR platform. With this in mind we are currently developing a fish oil analysis application that can provide the EPA and DHA omega-3 fatty acid content of fish oil supplements manufactured by an ethyl ester esterification process. We have obtained data at 42 MHz, 60 MHz, 82 MHz and 300 MHz. The chemometric modelling yielded PLS models for all 4 field strengths that yield effectively the same result – DHA can be measured to +/- ~1.1 wt% and EPA can be measured to +/- ~2.2 wt% by a 40 second 1H NMR measurement. THe correlation is derived from a  regression of the 1H NMR variability with primary GC analysis values.

This analysis has been shown for the 300 and 60 MHz data in a previous post on this blog. The same analysis was also obtained, with similar results, on 42 and 82 MHz platforms proving that individual applications can be automated and provided at all relevant frequencies of NMR analysis whether on superconducting lab systems or permanent magnet benchtop systems.

At each field strength the relative lineshapes are pretty much the same (<1 Hz at half height). The field strength differences mean that the same spectrum is dispersed across frequency space proportionate to the magnetic field. Figure 1 below shows the frequency space spectra obtained at all 4 field strengths on the same sample.

Figure 2 shows the same spectra displayed on the usual normalized chemical shift scale (ppm). In these spectra the data is stretched in order to allow the chemical shift comparison of the data. IN effect the 42 MHz NMR is stretched by a factor of 7, the 60 MHz data by a factor of 5 and the 80.2 MHz data by a factor of 3.7. The effect of the relative size of J coupling compared to the frequency space occupied by 1 ppm is an interesting observation to see directly. In traditional NMR analysis the resolution of various peaks was always the driving force for increasing the magnetic field strength of NMR instruments. With todays powerful PC’s and advanced software information can be garnished readily from any of these spectra by way of global spectral deconvolution or multivariate statistics.It is no longer necessary to obtain baseline resolution in order to integrate a resonance and obtain quantitative information.

THough the data is more closely packed together in the low field spectra it can be acknowledged that the same information is present in all 4 spectra. Automation approaches can be developed that will allow accurate measurement of quality parameters, component quantification, or structural verification to be performed on data obtained from any of these NMR systems.

The development of readily deployable NMR benchtop systems at an affordable price point must surely lead to the development of NMR into a more widely utilized technique outside of the realms of scientific study and quality control that NMR has thus far been involved.

1H NMR at 42, 60, 82, and 300 MHz
Figure 1: Comparison of 1H NMR spectra obtained on an omega-3 fish oil supplement obtained at 42, 60, 82, and 300 MHz displayed in frequency space. These spectra show the native spectra dispersion obtained at the different magnetic field strengths of the NMR spectrometers
CHemical SHift Scale Normalization of 1H NMR spectra obtained on the same sample at 42.5, 60.3, 82.3, and 300 MHz
Chemical Shift Scale Normalization (ppm) of 1H NMR spectra obtained on the same sample at 42.5, 60.3, 82.3, and 300 MHz. In these spectra the absolute frequency of the spectrum is divided by the spectrometer frequency to obtain a normalized spectrum where the chemical shift in ppm of the various peaks in the spectrum are observed at the same position on the ppm NMR scale. In this normalized view the relative proportion of a ppm that the J couplings represent in the 1H multiplets can be plainly seen.  

 

 

 

 

Presentations at SMASH 2014

by Beer, Chemistry, Chemometrics, Herbal Supplement, Process NMR, qNMR, Reaction Monitoring

“Beer Manufacturing and Analysis by NMR”, John C. Edwards and Adam Dicaprio, Presented at the Mestrelab MNova Users, Meeting – SMASH, Atlanta, GA, September 7, 2014
Get PDF Here

“Survey of Low Field NMR Spectrometer Platforms for Successful Screening of Sexual Enhancement and Weight Loss Supplements for Adulteration with Drugs and Drug Analogs”, John C. Edwards, Kristie Adams, Anton Bzhelyansky , Presented at SMASH Conference, Atlanta, GA, September 7-10, 2014.
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John Edwards to be Guest Editor of 2 Special Issues of Magnetic Resonance in Chemistry Dedicated to Benchtop NMR

by NMR, Process NMR, qNMR, TD-NMR

I have been invited to be a guest editor for Wiley publishing to pull together 2 special issues of Magnetic Resonance in Chemistry. I am putting out a general “call for papers” but I will harass people personally. We are looking for 10-20 papers for each issue.

The deadline for submission of the papers is June 30 so no-one has an excuse that there isn’t enough time. I do ask that you email me at the contact below to let me know that you are thinking of submitting and a title would be nice also (though I won’t hold you to it). We hope to have the review and revide papers (if necessary) by late October and then publish by December 2014.

The first will be on high resolution benchtop NMR in which I would like to include all permanent magnet systems capable of obtaining a spectrum. This is an open invitation to all the vendors and their customers of (in no particular order) Anasazi, Nanalysis, One Resonance Sensors, Magritek/ACT, Aspect, Qualion, Picospin, Resonance Systems, Oxford Instruments, Bruker, home built devices, I would also make the exception that HTS systems be included as they are also cryogen free.

Any papers on spectrometers, magnets, educational, industrial, academic applications, chemometrics, automated approaches, reaction monitoring, online/at-line utilization, 2D NMR, combined spectral/relaxation applications.

The second will be on low resolution benchtop NMR but I would like to exclude applications that have been around for decades (H content, SFC, oil content, spin finish). I would like to encourage new applications to be submitted and they should include hardware, magnets, spectrometers, probes, 1D/2D Laplace inversion (I’d love a review/overview of that software aspect), applications. Again – all vendors and all users of commercial and home grown benchtop TD-NMR systems please submit.

We’re looking for articles on FPGA spectrometers, software approaches (1D/2D Laplace, chemometrics), magnet design and construction, dedicated rheology analysis instruments, field cycling NMR, unilateral NMR, core analyzers, applications of all whether educational, academic, industrial.

The types of articles can be Reviews, Mini-Reviews, Tutorial, Historical, Spotlight, Perspective, Communication, Article, Application Note, Case Report, Spectral Assignments, Correspondence.

Here is the official word on the use of color (note you can have all the color figures you wish in the online version but the print version is restricted): two colour illustrations per submission are allowed free of charge, however further colour illustrations are allowed at the Editors discretion and where they are justified. Authors can have as much colour as they like in the online version as the restrictions are just for the print version.

Please contact me directly if you would like to make a submission of your work to either of the two issues: john@process-nmr.com

I have posted the authors instructions for special Issues that I was given on my website at:
https://process-nmr.com/pdfs/MRC_Submission_instrux.pdf

The MRC author guidelines can be found at:
http://onlinelibrary.wiley.com/journal/10.1002/%28ISSN%291097-458Xa/homepage/ForAuthors.html

Special Issue on Benchtop NMR systems in Wiley Journal “Magnetic Resonance in Chemistry” – please consider submitting a technical or review paper

by Chemistry, Chemometrics, NMR, PAT, Process NMR, qNMR, Reaction Monitoring, TD-NMR

I was just asked by Roberto Gil (Carnegie Mellon) to pull together a special issue if Magnetic Resonance in Chemistry” on the topic of Benchtop NMR. I will personally be hitting up everyone I know who is working in this area to provide technical papers on their work in this area. I also wanted to extend an invitation to the members of this group to submit a paper for this special issue.

All topics will be considered but I would like to stay away from “traditional” 1H TD-NMR and restrict 1H TD-NMR applications to new approaches. On the high resolution side (45, 60, 80 MHz) I am hoping that applications with some real meat might be submitted rather than brochure type papers with just spectra of solvents and small molecules.

Please feel free to contact me directly if you have ideas on submissions. My contact information is listed below.

Sincerely,

John C. Edwards, Ph.D.
Manager, Process and Analytical NMR Services
Process NMR Associates, LLC
87A Sand Pit Rd, Danbury, CT 06810, USA
Tel: +1 (203) 744-5905 Cell: +1 (203) 241-0143
Skype: jcepna
e-mail: john@process-nmr.com

Register to Attend PANIC 2014 ! Deadline for Poster Submissions is December 20

by Chemistry, Chemometrics, Herbal Supplement, NMR, Process NMR, qNMR, Reaction Monitoring, TD-NMR

The 2nd Annual Practical Applications of NMR in Industry Conference (PANIC) will be held February 3-5 in Charlotte, NC. An excellent scientific agenda has been put together (see here). The Brochure is available here. Take note of the early registration (January 10, 2014) and poster submission (December 20, 2013) deadlines.

John Edwards of Process NMR Associates is on the organizing committee of PANIC and has been appointed as Treasurer of the Conference company.

John will be presenting an oral presentation in the one of the Nutraceutical Session:                NMR-Based Authentication of Nutraceuticals, Herbal Supplements, and Food Additives: Economic- and Efficacy-Driven Adulteration of Aloe Vera, Herbal Erectile Dysfunction Supplements, and Acacia Gum                                                                                                 John Edwards, Ph.D., Process NMR Associates, LLC – Biography

Multinuclear NMR spectroscopy offers an outstanding ability to perform targeted and non-targeted analysis of nutraceuticals, herbal supplements, and food additives. Economic adulteration of these materials with lower value adulterants and the addition of pharmaceuticals to herbal supplements in order to obtain the expected efficacy of a product is surprisingly common in the marketplace today. The development of official test methods utilizing NMR spectroscopy will allow the detailed unequivocal chemical fingerprinting of the NMR spectrum to be combined with qNMR methods to quantify active components and prove authenticity from either direct observation of adulterants or by non-targeted methods such a principal component analysis. We will discuss in detail a method developed on aloe vera juice and powder products to quantify the active components as well as identify the presence of whole leaf or inner gel material in the manufacturing process. The presence of preservatives, degradation products, additives, and adulterants can also be readily identified and quantified by 1H NMR. Statistical analysis can be performed to define the range of concentrations expected in naturally produced materials as well as determine the presence of adulterated material. The utilization of erectile dysfunction pharmaceuticals in herbal supplements to deliver the expected efficacy to the herbal products will described. Finally, the use of 13C NMR to define the authenticity of gum Arabic (acacia Senegal) used as an emulsifier in the beverage industry compared to chemically similar but inferior/cheaper gum products.

and in the poster session he has 3 posters being presented:

Development of an Automated Quantitative Chemical Mixture Analysis Method within Metrelab Research MNova – Internal Standard qNMR Measurements on Aloe Vera Raw Materials, Aloe Containing Products, Finished Beer and Samples from the Different Points in the Brewing Process

John C. Edwards, Adam J. Dicaprio, Process NMR Associates, Michael A. Bernstein, Mestrelab Research

Small Molecule Chemistry of Spontaneously Fermented Coolship Ales

Adam J. Dicaprio, John C. Edwards, Process NMR Associates

John will also chair a session on Online/At-Line NMR

ONLINE/AT LINE NMR – Wednesday, February 4

3:20 Session Chair’s Remarks – John Edwards, Ph.D., Process NMR Associates, LLC – Biography

3:25: A Compact, Portable 4.7 T Driven NMR System for Reaction Monitoring

Mark Zell, Ph.D., Senior Principal Scientist & Technical Leader, Structure Elucidation Group, Pfizer – Biography

We have been using a newly developed 4.7T (200 MHz 1H operating frequency) cryogen-free NMR system which utilizes a high-temperature (~14K) superconducting magnet cooled by a standard helium compressor, driven by a high stability power supply, and utilizing a new state-of-the-art single board spectrometer. The system is designed to be portable, allowing for rapid cooling and ramping of the magnet to field without the need for expensive cryogens or a trained engineer. We have been using this system, coupled with a microcoil flow probe to investigate a multitude of samples, ranging from traditional organic compounds to complex reaction mixtures. To date, primarily 1D 1H NMR data on these samples has been acquired. We are working toward utilizing more sophisticated multi-dimensional gradient-based experiments on this system to provide additional information on reaction mixtures in both a “stop-flow” and flow-through mode. This system works well for reaction monitoring, as it provides intermediate resolution between lower resolution 60 MHz spectrometers and traditional higher-field superconducting spectrometers at 400 MHz and above. This poster will provide an overview of this new technology and demonstrate the data we are able to achieve, in comparison to that obtained at both 60 and 400 MHz.

3:55 NMR Well Logging and Downhole Fluid Characterization

Martin Hürlimann, Ph.D., Scientific Advisor, Schlumberger-Doll Research – Biography

Over the last decade, NMR well logging has matured into a significant new commercial application of nuclear magnetic resonance. In this method, an NMR sensor is moved through a borehole to continuously measure the fluids inside the surrounding earth formation. The environmental conditions are exceptionally challenging for NMR measurements. The whole sensor and associated electronics have to fit into the borehole (with a typical diameter of 20 cm) and able to withstand high temperatures and pressures that can reach 175o C and 140 MPa. The sample is located outside the sensor and the applied magnetic fields are necessarily grossly inhomogeneous. Furthermore, the measurements have to be sufficiently robust so that they can be performed in a highly automated manner without the assistance of an NMR specialist and in a wide range of environments, from the arctic to the tropics. In this talk, I will review how these challenges can be overcome with novel hardware design and new measurement techniques. Current state-of-the-art well logging measurements enable the extraction of a wide range of important physical and chemical properties that include the porosity, the distribution of pore size, and estimate of the permeability, the identification and quantification of the different fluid phases occupying the pore space (water brine, crude oil, gas…), the fluid compositions, and the fluid viscosities. I will highlight new relaxation and diffusion measurements to determine two-dimensional relaxation-diffusion distribution functions. These techniques are well suited for other applications in fields beyond the oil field, including process control or the characterization of food products.

4:25 Characterizing a Hydrogenation Reaction: In situ NMR and Mechanistic Modeling

Jonas Buser, NMR Structural Characterization Group, Eli Lilly and Company – Biography

The development of a robust manufacturing process typically involves a joint effort between engineering, mathematical modeling, process chemistry, and analytical chemistry. This presentation describes the optimization of a hydrogenation reaction observed to have variable reaction completion times at manufacturing scale. On-line flow NMR (ReactNMR) was employed to characterize a detailed reaction mechanism and kinetics. Variables of pH and hydrogen pressure were examined to see how they affected the dynamic mechanism and kinetics of the reaction. A mathematical model was developed to gain further understanding of the process kinetics as well as mass transfer limitations. The model was used to predict experimental conditions capable of minimizing the hydrogenation time. This problem solving approach is being broadly adopted to solve complex reaction problems where traditional means don’t provide a comprehensive understanding of the process.