- Please do not confuse this specific software feature ("Reference Wavelength") with the initial reference scan ('zero') which the detector takes at the start of the analysis and is subtracted from your desired signal to show only one initial signal plot (and which is used as the initial signal value to compare to the measured signal during the rest of the analysis run. This is usually known as "zeroing" the detector and occurs just once, at the start of each run. When you manually press the 'Auto-zero', you are adjusting the displayed signal plot to a know reference point (often 0.0 volts). This is a one-time zero of the signal and has nothing to do with the special software feature we discuss in this article.
Allow me to provide a brief explanation of the “Reference Wavelength” software feature as seen and used with many DAD and/or PDA detectors (e.g. HP/Agilent and Waters brand HPLC systems).
If you are running a gradient analysis, then the change in solvent properties (RI and light absorption/transmission) and temperature over time can cause noticeable baseline drift during the run. This drift up or down relative to the starting baseline reference point is normal, but may cause a number of quantification problems with the analysis reporting software (as flat baselines are more easily and accurately integrated than sloped ones).
Using the concept of Method # 2 described above, many HPLC manufactures added a software feature known as a the ‘Reference Wavelength’ to their systems. This feature allowed a chromatographer to include with each signal choice, 'A', a second wavelength value, 'B', (and bandwidth) as part of the method which would be used to subtract out raw data from the primary wavelength during the analysis. This subtraction occurs in real-time, on your raw data gathered from the detector and the resulting data reported to the user is in fact the result of the subtraction only. The original signal data is destroyed. You will never know what the original data looked like before the reference wavelength was subtracted from it (it has been destroyed). Only the newly manipulated (subtracted) result is provided, 'C'. If any sample peak(s) or impurities appeared in the region where you selected a reference wavelength/bandwidth, then the resulting data would have been subtracted from your actual sample and you would never know it happened or have any record of it! This brings up a serious validation issue as you are modifying the original data with no way of knowing (or documenting) how you have changed it. It is for this reason alone that we teach chromatographers to always turn this feature 'OFF' by default. If they want to make use of the feature, then we suggest that they simultaneously collect data from a second, separate wavelength channel such that the two raw data streams are preserved for validation purposes (Method # 2). IOW: To acquire scientifically useful data, turn 'OFF' the Reference Wavelength software feature and record all of the signal data. The separate signals can be compared, subtracted or manipulated as needed for integration and reporting purposes, but the original signal sample data, 'A', is left unchanged and secure. This allows you to monitor for contamination, impurities, problems or changes during the run. It also allows others to verify your method for accuracy.
Observational Notes: I am often called in to diagnose what the client's refer to as 'a strange problem' where the area of a known sample peak changes in an unexpected way. That "way" often includes going NEGATIVE, below the baseline. Or even increasing in area, mass or decreasing in mass.The column is clean, pumps work fine, retention times are stable and everything appears to be working fine. *This anomaly is due to the reference wavelength software feature being turned 'ON' and another compound (peak) absorbing in the user selected Reference bandwidth region. Its absorption contributes to the final signal. If the data collected (area) for the 'reference peak' is larger than the sample peak the resulting chromatogram will show a negative peak (this tends to be noticed by most users as it is illogical and indicates a serious problem!), whereas if the reference peak is smaller than the sample peak, the resulting area signal decreases, which may or may not be noticed (incorrectly interpreted as a lower concentration sample). You can see the obvious danger posed by this situation. Companies can be put in a situation where all of their past data is found to be invalid and product recalls may result from this finding. The cause is directly related to a lack of understanding and proper training in the use of the software and/or HPLC system.
How to Solve The Problem: The reason we see this feature cause so many problems in laboratories appears to be due to the fact that the Reference Wavelength software feature is being turned 'ON' by default in the software for most DAD/ PDA modules (The real default value for "Reference Wavelength" should always be: 'OFF', not on). To make matters worse, the default values for the wavelength and bandwidths often supplied by the manufacturers are actually used by most chromatographers (what are the odds that the random values placed in the system are even relevant to your analysis? Why would you use them?). We suggest using a ‘canned’ method template in most laboratories which includes a new default value for this feature... 'OFF' for all analysis methods. Most importantly of all, please obtain formal training in the use of a specialty detector such as a diode-array detector before using one for sample analysis.
Notes
- The bandwidth chosen for each wavelength is also very important and if chosen poorly, can result in adding noise to your signal, reducing it or even enhancing it. Please refer to this article for more info: http://hplctips.blogspot.com/2011/09/uv-vis-hplc-detector-signal-bandwidth.html
- If you are still running HPLC methods with the “Reference Wavelength” turned 'ON' while awaiting approval to turn it 'OFF', then you can ADD additional signals to your method with the same primary settings as before, but with “Reference Wavelength” now set to 'OFF'. Adding the same signal w/o the “Reference Wavelength” will provide you with the original signal data for future comparison to the "collected/modified" signal (allowing you to see if the data was changed). Make sure you configure these extra channels to be saved with the analysis.
I just came across this while trying trying to understand exactly what the reference spectrum is for. Thank you for posting this, it will undoubtably help with my current analysis and many future analyses. I'm even considering giving a technical presentation on this very topic so others in my company who take reference spectra for granted will be enlightened. Thank you thank you thank you!
ReplyDeleteGlad to hear you found it useful. The reference wavelength feature (not reference spectrum which is something else) results in a lot of collected data which is of no scientific value. Always turn the feature 'OFF' and consider using a separate channel of data to collect the 'reference' run for subtraction after the analysis is complete.
ReplyDeleteMy mistake, I meant reference wavelength. Thanks again.
ReplyDeleteTHANK YOU, thank you for this information! For many weeks our API std has shown too low a concentration/area and we could not figure out why this was happening. We even brought in an "expert" in method development from the instrument manufacturer to help us. They told us to always set the Reference Wavelength to 'ON' and use 360nm (100) for all samples. We modified the settings as they suggested and things have gotten even worse. Now our peaks sometimes go negative. THEN I found your great post which explains how this feature works and why we should not use it at all. Our problem dissappeared once we turned OFF the Reference wavelength feature and ignored the very bad advice given to us by the "expert". You clearly are the real expert and now that we understand how this feature works, we will never use it for method development again. Thank you as your great blog has saved our company and made us all aware of how important it is to ask questions and understand feature before we use them.
ReplyDeleteI am having a problem which is making me feel very stupid..... I have 2 peaks partly coeluting that have sort of similar UV spectra. When I try to 'subtract out' one of the peak's UV to get a better match for the other peak, the other peak's UV is inverted (upside down) compared to the library match. Why is this and how do I stop it?
ReplyDeleteThanks
Sarah
This does not sound like a Reference wavelength issue. You can not perform scientifically correct Library peak matching comparisons on HPLC peaks which are not first, fully resolved apart. By definition, co-eluting peaks will have mixed spectra and the computer software used to report this data is not capable of accurately "separating" the two apart. It will add/subtract spectral data which may or may not be part of the desired peak. The result will be unpredictable and of little value chromatographically.
DeleteThe correct solution to the problem described is to develop an HPLC method which results in Gaussian peak shapes which have at least an R of 1.5. Proper method development and related techniques will allow you to obtain reliable and reproducible data.
how do you turn off the reference wavelength in the software?
ReplyDeleteThe answer depends on which CDS software you are using.
DeleteFor ChemStation/OpenLAB, just click on the down arrow next to 'nm' where is says "REFERENCE" and it will change to 'OFF' for the wavelength selected. For many EMPOWER systems, just click on 'OFF' or leave the Reference Wavelength field empty. Make sure you select 'OFF' for all wavelengths.
Thanks for this post. it not only gave me idea what the reference wavelength is for but how this actually work.
ReplyDeleteCheers
Thank you for your valuable information. By default, does the reference wavelength get applied only to wavelengths that you indicated you wanted to collect on the software, or does that get applied to the whole scanned spectrum as well? On Chromeleon I am able to do post-run processing, and if I delete the channel that was collected because it was normalized against 360 nm, and extract new data from that same wavelength off the spectrum, will that solve the issue? Thank you again!
ReplyDeleteI'm facing a challenge with a negative peak in my analysis, and I'm hoping you might have some insights on how to overcome this. Your expertise would be greatly appreciated.
ReplyDeleteI am analyzing carotenoids. The internal standard and target carotenoids are analyzed in two channels, A and B, at 325 nm and 450 nm, respectively. The problem I am having is that even though the IS and carotenoids are detected at two different wavelengths, this is generating a negative peak in the retention time of beta-cryptoxanthin (7.8 min) (The IS also elutes at 7.8 min but 325nm). I have tried several ways to eliminate the negative peak, such as making sure the equipment is adequately purged (I don't think it is a back pressure problem) and turning off the reference wavelength, but the problem persists.
It seems that the negative peaks at 450 nm are the results of the peaks detected at 325 nm.
The method appears to be invalid. Two serious problems: (1) You can not use an internal standard (IS) that elutes at the same time as your sample. They must have different retention times to demonstrate that your method is selective. This is a basic requirement of of good chromatography and also of a valid method (method selectivity based on retention time, not wavelength alone); (2) Using sample data obtained at the same retention time, but two different wavelengths may result in some UV/VIS signal overlap. This may result in inaccurate signal integration data and even negative peaks from the contributing bandwidth values in each signal (esp from concentration changes). This is similar to the problems observed when clients use the "Reference Wavelength", but in this case it is not at all related to that issue.
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