The Three Most Common HPLC Questions and How To Solve Them

The three most common HPLC related questions I am asked each week can be summarized below. Test your basic chromatography knowledge. Before reading the answers, see if you can answer them correctly on your own.

• "What Is Causing the HPLC Baseline, Pressure or Peak Retention Time(s) To: Wander, Change, Drift, Vary or be Unstable?"

• "How Should I Wash or Regenerate My HPLC Column?"

• "How Can I Tell if the Sample is Retained On the HPLC Column? or What Does It Mean When No Chromatography Took Place?"

Let us address each question in order and attempt to provide accurate answers (I have included links after each question to articles with more detailed explanations).

What Is Causing the HPLC Baseline, Pressure or Peak Retention Time(s) To: Wander, Change, Drift, Vary or be Unstable?

• Retention times must be reproducible from run to run.The causes of an unstable baseline and/or changing peak retention time(s) are often related. Common reasons include: Column temperature fluctuations, inadequate mobile phase mixing or degassing, leaks, dirty column, sample overload, lack of pH or buffering control (weakly ionizable samples can be very sensitive to changes). *Full Article link with detailed answers, here.

How Should I Wash or Regenerate My HPLC Column?

Note: Before proceeding with any column regeneration or cleaning procedures, always refer to the specific advice provided by the column manufacturer. Approved maintenance and cleaning instructions can often be found in the product guide or booklet which comes with the new column. Additional information can be found on the vendor's website or by contacting them directly.

• Two issues must be addressed to answer these types of questions. (1) Always wash your column with a specific column wash solution which is stronger than your analysis solution. The use of a stronger solution (In this context, "stronger" means better at dissolving the samples and faster at eluting them from the column) as the wash solution requires regular use to maintain the column. Failure to regularly wash your column may result in compounds accumulating on the column over time (fouling the column) resulting in poor reproducibility, higher back-pressures, contamination and/or poor peak shape. (2) Next, always wash your column after each analysis. This should be a separate step, not incorporated into your analysis method. The analysis method should not include the column re-equilibration steps at all. A second, separate wash method should always follow each analysis method which includes the rinsing of the column with a "stronger" solution for an adequate period of time, then adjustment back to initial conditions where re-equilibration can take place to get it ready for the next analysis run. These are fundamental guidelines of good method development and follow well established principles. Developing methods in this way should increase the lifetime of your columns and improve the reproducibility of results obtained (better %RSD run-to-run).

For more information on washing bound proteins off RP HPLC columns, please refer to this linked article found here.

How Can I Tell if the Sample Is Retained On the HPLC Column? or What Does It Mean When the Sample Comes Out At or Near the Column Void Volume?

• Chromatography is a tool which when used properly adds one or more additional dimensions of physical or chemical characterization information to your analysis data. It does so first by using on-column RETENTION. Samples must be run under conditions which allow the material to interact with the chromatography support for a period of time. We define this time as the retention time. A sample which does not interact at all with the column support material will elute off the column early (and not be retained) at the "column void time" (or column dead time). We refer to this void time as the "T zero" time. When a sample elutes at or near the T zero time, no chromatography has taken place and no method has been developed. It is as if the HPLC column was not used. How do you know what the "T zero" time is (it will be different for different methods)? You must first calculate the HPLC column's dead volume. Once you know the column dead volume and flow rate, you can calculate the T zero time. A scientifically valid HPLC method will include conditions which retain the sample on the column for a long enough period of time to insure that it is interacting with the support. This allows for separation from other compounds to take place and is the purpose of chromatographic resolution. Without this retention mechanism, you are just flow-injecting the sample past the column and skipping all chromatography. It would be far simpler to just place the sample in a spectrophotomer cell as no retention or additional data would be obtained using that technique.

• When first learning liquid chromatography, two of the very first calculations you must learn to use in HPLC are: Column Dead Volume (aka: Column Void Volume) and the K prime of a sample (aka: Peak Capacity Factor). Do you know how to calculate these? They are calculated and reported for each method used. You should be able to tell anyone who asks you what the values are for each method. A chromatographer must know and understand them before using an HPLC system or running a method. They are also critical to method specificity and proper validation. Here are links which after reading and practicing, should make you an expert in these two fundamental calculations. 

"Determination of HPLC Column Dead Volume / Dead Time (T zero)";

"K Prime (also known as: Capacity Factor or Retention Factor): One of the Single Most Important HPLC Parameters of All".

So, how did you do answering these basic questions? If you have put in the needed study time and practical experience to learn and use these fundamentals of high-performance liquid chromatography, then you should have been able to easily provide correct answers to all three questions. If not, then it is time to go back and study up on those basic liquid chromatography texts and article links, plus get more supervised hands-on time with the instruments.

Diagnosing & Troubleshooting HPLC Pressure Fluctuation Problems (Unstable Baseline)

Few things in chromatography are more frustrating than dealing with large pressure fluctuations (>1% ripple). If the pump pressure is unstable, and fluctuating up and down, then it will negatively impact your ability to analyze, measure and integrate sample peaks in a reliable manner. A smooth, flat baseline is needed to run and develop methods, collect the data (peaks), integrate and report the results which are reproducible. Baseline instability during an analysis may lead to the entire analysis being declared invalid.

So what causes the HPLC pressure to sometimes fluctuate in a wild manner up and down on your HPLC system? Unfortunately, many things... Most result from poor training, incorrect operation techniques, but some are maintenance related so be sure and keep your chromatograph in excellent condition. Maintain a logbook for each instrument and record what types of maintenance and service have been performed over-time, with the date and list of parts used/replaced. Additionally, maintain a preventative maintenance schedule (e.g. every six months) to inspect and clean the entire HPLC system to check condition, verify operation and minimize unproductive down time. 

HPLC Pump or System Pressure Fluctuation Causes and Solutions:

• Air / gas In the Liquid or Mobile phase (Failure to Degas Mobile phase OR loose fittings) --- Air gets into the system due to a leak or from gas trapped in the mobile phase. Find and correct the cause of the leak and/or degas the mobile phase (use continuous Vacuum degassing or a Helium sparging system only). Leaks are the most common cause of instability, but insufficiently degassed solution is a close second. Make sure your degasser is working 100% correctly (they require professional servicing every 5 years). HPLC pumps require degassed mobile phase for reliable operation.

• Loss of Prime. Improper Priming of the System --- Failure to flush ALL of the lines with freshly degassed mobile phase, before use (every day), will often result in all kinds of instability problems until all of the old gas-filled mobile phase has bee purged from the system. *This could take many column volumes of liquid. Make sure you account for any vacuum chamber volume too. Properly prime the pump heads before use.

• Sticking Check Valve(s) --- If air is exiting the pump outlet, the pump will not function properly. Both Inlet and Outlet valves should be inspected. Remove and clean the check valve(s). Be sure the pump is fully primed with liquid as the check valve might just have an air bubble in it (common on Waters, Thermo and Shimadzu systems). Sometimes sonication of the valve for ten minutes in a beaker containing warm solvent does the trick (e.g. MeOH or IPA/Water). Though very rare, ACN has a bad reputation for polymerizing in solution. If the system has sat unused for a long time OR was not properly flushed out when last used, it is possible that particulate matter may clog the flow path. Small sticky particles may form (ACN polymerization) and cause the check valve to stick inside the housing (use fresh, filtered solvents only to prevent these problems). Clean and inspect any suspect valve first. Replacement of the check valve may be needed in some cases to restore operation. Note, this problem of "sticking" check valves is most likely to be an issue in HPLC pumps with mechanical (gravity or spring) check valves with ruby balls, not modern style active inlet check valves ("AIV") which are electromechanical (solenoid valves) and are very reliable, much less susceptible to these problems. In any case, verify operation of all valves while under pressure (backpressure is needed for them to function correctly).
  

• Worn Pump Piston Seals --- Commonly observed as rapid up/down spiking on all channels and an inability to maintain or produce backpressure (the pump will often prime with no problem, as this is done at low-pressure). Run a formal pump high-pressure leak test at max pressure to confirm (remove the column and replace with a calibrated backpressure restriction line for all testing). Clean pistons and replace piston seals to repair (you should have spare pistons and seals on hand). *Seals are a maintenance item so expect them to wear out and need regular replacement.

• Flow rate too low (may be inappropriate for system). Running at a flow rate that is below the optimum range of the specific instrument (i.e. System rated for 200 to 2,000 uL/min, but run at 100 to 200 uL/min or at the limit of the range) may result in an unstable baseline. The cause may be due to pump cavitation, loss of prime, non-optimized piston stroke volume.

• HPLC System Back-pressure too low to maintain prime in system. Most types of analytical HPLC systems require a minimum system back-pressure of 40 or more bars to maintain enough pressure (mechanical compression) on the component parts to run in a reliable fashion (*Water's Article number: 32564 states the back-pressure must be at least 1000 psi for their Alliance systems). Too low a pressure often results in a loss of prime, cavitation, mixing problems, turbulence and poor reproducibility. Correct sizing of column, particle size, flow rate and mobile phase composition should all take into account achieving enough back-pressure on the system to maintain a stable baseline throughout the entire analysis. Monitor the system back-pressure at all times for stability. High quality research grade HPLC systems are often capable of maintaining stable isocratic flows with less than 1% ripple and 0.2% ripple common ("ripple" is a term we often use to describe the pump's pressure output over time relative to the baseline (S/N)).

• Mixing Problem (gradient or isocratic online mixing) --- If your active mixer or proportioning valve (AKA: Gradient valve) is defective or dirty, then one or more of your mobile phase channels may not be getting to the pump. Air would most likely be mixing with the mobile phase causing the unstable flow. Clean or replace the valve. Note: Always try flushing the gradient valve with pure IPA, then DH20 for about twenty minutes. This sometimes restores operation by wetting and flushing the internal seals (which may dry out).

• Wrong Pump Solvent Compressibility Settings --- In HPLC we routinely subject different liquids to very high pressures which can result in measurable liquid compression. The degree of actual compression for each liquid varies, but the modern HPLC pump can compensate for this to improve the accuracy of the mixing and flow delivery.  Most pumps provide for user adjustable solvent compressibility values. If the value input varies a great deal from the actual liquid in the system, then it can result in pressure fluctuations. Example: Water has a value of 46, but Methanol 120. Using the wrong value can cause instability.  

• Poor Solubility, Mobile Phase  --- Sometimes the mobile phase which has been prepared (or mixed online) is not 100% soluble. This could be due to an inorganic salt additive which has not gone into solution or failure to fully mix and filter the mobile phase before use. Ultrasonication, a bit of heat and stirring for 20 minutes can help to get everything dissolved. 

• Dirty inline filter --- A fouled or partially plugged filter can disrupt the normally smooth flow into a turbulent one. Some are installed as part of the pump (i.e. HP/Agilent brand pumps) and should be changed out every month (Yes, for the PTFE frit, replace it once a month with a new one). Other systems use these pre-filters downstream of the pump before the injector. Clean or replace all filters frequently. If used in your system, these are regular maintenance items and should be part of a general 'PM' program.

• Dirty Solvent Pickup Inlet Filters: These can become obstructed or fouled over time (esp. if used with aqueous solutions!). Just as with any built-in filter, the multiple solvent inlet pickup filters should be cleaned or replaced on a regular basis to prevent particulate or any material which may contaminate or restrict the flow path from entering the system. Mobile phase pickup filters are often 10 to 20 um and connect to the bottom of the low pressure (e.g. Teflon) solvent lines in each bottle. If you use 316 Stainless steel filter (recommended for organic solvents), they should be removed, cleaned in an ultrasonic bath, rinsed and replaced monthly. If you use sintered glass or other disposable type filters (often used with aqueous solutions), they should be disposed of on a regular basis and replaced with new ones (replacement, not cleaning is recommended because sintered glass can not be sonicated and should be disposed of to prevent bacterial, mold or fungal contamination). A quick way to check if one filter is causing the pressure to fluctuate is to remove the filter from the one line, then re-test the system. If the problem goes away, then returns when you re-install the filter back on the line, the filter may be obstructed (replace it),

The above list includes some of the most common reasons for unstable baselines. Other non-pump related causes would include a bad / old detector lamp(s) or contaminated mobile phase. To find the cause, test and verify the operation of each component part of the HPLC. Troubleshooting Advice: Test one part at-a-time, before moving to the next part. Never assume anything, test, re-test and verify or prove at each step.