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The steps for developing your HPLC-CAD method should follow the usual process: method scouting, optimization, robustness testing and validation.
A Charged Aerosol Detector (CAD) works by measuring particle charge and can detect all non-volatile and many semi-volatile analytes, independent of chemical structure. This detection mechanism makes the CAD response sensitive to mobile phase quality, so the presence of semi-volatile and non-volatile impurities is often the limiting factor for method sensitivity.
An important pre-requisite for any mobile phase used with the CAD is the solvent must be volatile and not contain any non-volatile components. In addition to mobile phase quality and composition, things like your lab environment, nitrogen gas supply, LC instrument usage history and column stability can also impact the detector response.
To ensure optimal performance and consistent results, you’ll want to identify sources of mobile phase impurities and other interferences and develop strategies to minimize the introduction and interference with your chromatographic analysis.
Factors | Main considerations |
---|---|
Nitrogen gas flow, mobile phase and additive purity impact baseline signal | Stable gas flow and additive-free mobile phases with no column in line should give you a background current of around 1 pA at EvapT of 35 °C |
Column bleed impacts baseline signal | Column stability can slowly deteriorate with use, especially near the pH limit and at elevated temperatures |
Analyte volatility impacts response | Use flow injection analysis to see if your analytes behave as volatiles, semi-volatiles or non-volatiles |
Evaporation temperature (EvapT) impacts response and baseline signal | Some analytes might behave as non-volatiles at lower temperatures but as semi-volatiles at higher temperatures |
Gradient elution impacts signal, noise and drift | Apply inverse gradient methods to restore the uniform response for non-volatiles |
Power function value (PFV) impacts the linear response range | An optimal PFV gives you a more accurate calculation of peak resolution and limit of detection |
Multi-detection setups can increase your detection range | Keep your fluidic connections simple and short |
Once you’ve properly set up your HPLC-CAD system in the lab, you’re ready to begin method development. Here’s some essential best practices you should follow, recommended by our experts:
Besides screening various column and eluent mixtures to select the best combinations for successful separation, you’ll need to assess if your chemicals and method conditions are compatible with the CAD.
Using a step-by-step systematic approach, you’ll see how each component affects the baseline signal or background current.
Your main goal is to get an idea of what background signal is normal for the method conditions and application.
Here are the general steps to follow for method scouting:
1. Verify your target analytes meet the CAD volatility requirements
If you do not have the numbers at hand, you can test for analyte volatility as described in our white paper: A reliable UHPLC/UV/CAD/MS multidetector method for routine quantification and library matching of extractable and leachables in pharmaceutical-grade plastics.
2. Assess the purity and stability of your nitrogen gas
This step involves running nitrogen gas through your HPLC-CAD system in the absence of a column and mobile phase flow to see if the gas flow and background signal are stable.
3. Verify your HPLC system lines and pump are free of residual salts.*
For this step, you’ll run ultra-pure lab water only, with no additives or column connected, at a flow rate of 1 mL/min and EvapT at 35 °C.
*We highly suggest having a dedicated HPLC system to use only with your CAD. If this situation is not possible, then you’ll need to flush the instrument to remove residual salts from the lines and pumps, and online degasser (if present) before connecting the CAD.
4. Check the quality of your mobile phase, without and with additives, in the absence of a column with the EvapT at 35 °C
Here, you want to track how the CAD background signal changes as the mobile phase flows, and how you can expect the signal to change with and without mobile phase additives, as well as the influence of the stationary phase.
To adequately evaluate the quality of a new batch of mobile phase, especially when using a new type or lot of solvent or additive you should establish a frame of reference and continuously monitor the performance of each application.
One approach to evaluating mobile phase quality is to first verify the detector performance using the qualification conditions described in our white paper: Getting the most out of your charged aerosol detector - factors influencing charged aerosol detector performance
5. Connect the column to ensure there is no bleed from stationary phase decomposition
Run the mobile phase with any additives through your HPLC-CAD system at your desired method conditions including gradients and column heating to verify the background signal is stable with low current.
6. Run your analysis
Again, the same rules apply here as for your general method development: stable baseline, resolved peaks and enough equilibration time.
Optimizing your HPLC-CAD method involves iterative testing of various method conditions to achieve the best resolution, speed, and reproducibility.
Robustness testing is done to determine the impact of changing parameters of the separation method and is important for both your method validation and transfer processes.
Do you have questions? Want to learn more about Charged Aerosol Detection? Speak to a solutions specialist today.