Adjusting the HPLC Gradient Time For Changes in Column Diameter and/or Length (same particle size)

Changes to the column diameter (to scale the method up or down) can be calculated. For an established HPLC method using the same support type (same exact material and particle size) where the column dimensions and flow rate are known. Note: If only the diameter changes and the lengths remain the same (proper linear flow rates used in both cases), then the resulting gradient times will also be similar. If the column lengths change, then the gradient time will change.

Changes to the Gradient Time (Tg2) used for a second column which has a different diameter, "Dc2" and/or length, "Lc2" can be calculated if you know: 

• Tg1 [Time, of initial Gradient on Column #1];
• Tg2 [Time of second Gradient on Column #2];
  
• Fc1 [Flow Rate of Column 1] ;
• Fc2 [Flow Rate of Column 2];
• Dc1 [Diameter of Column 1]
• Dc2 [Diameter of Column 2];
• Lc1 [Length of Column 1];
• Lc2 [Length of Column 2].

        Tg2 = Tg1 x (Fc1 / Fc2) x (Dc2² / Dc1²) x (Lc2 / Lc1)

 

Example: Initial Method utilizes a 4.6 x 150 mm, 5u column run at 1.00 mL/min with a 10 minute gradient program and we wish to transfer this gradient method over to a column with a 2.1 mm diameter (ID) x 100 mm column run at 200 ul/min.

   Tg2 = 10 x (1 / 0.2) x (2.1² / 4.6²) x (100 /150)

   Tg2 = 10 x (5) x (4.41/21.16) x (0.67) 

   Tg2 =  50 x 0.208 x 0.67

   Tg2 =  6.97 minutes.

The gradient time used on the 2.1 x 100 mm column run at 0.200 mL/min would be ~ 7 minutes (vs 10 minutes on the 4.6 x 150 mm column at 1 mL/min).

 

NOTE: A note about optimized flow rates. If the Column PARTICLE SIZE changes, esp from greater than 3.5 u to less than 3.5 u, then the optimized flow rate may also change too. Please refer to my article; 

• "Speed Up HPLC Analysis Time Using Higher than "Normal" Flow Rates with SMALLER Particles" for more information.

Tips and Advice for Priming your HPLC PUMP (or similar pumps, FPLC or UHPLC Pump)

The single most important component of any HPLC system is the Pump module. We often refer to it as "the heart of the HPLC system". 

• You may have the most sensitive HPLC detector, the best column, a perfect method of analysis, but none of this will matter unless the HPLC pump(s) that provide mobile phase to the system operate perfectly, all of the time. If you have a poor quality (or poorly maintained) system, then you will spend much of your time trying to establish reliable flow through the HPLC system, not running samples. 
• Before using an HPLC system, you should prime all of the lines in your HPLC pump. This is needed to purge any air from the tubing, introduce fresh mobile phase to each line and then to VERIFY that each channel delivers the reported amount of fluid to the column (measure it).
  

• NOTE: This is a LONG, detailed article with lots of information, Hints and Tips. It is available in PDF format for download, here.

The HPLC pump's ability (stability) to provide reliable operation depends on: 

(1) The Chemical, Physical and Miscibility properties of the Liquid(s) being pumped;

(2) The Amount of dissolved gas inside the liquid (must be minimized);

(3) The Temperature of the room (or HPLC) must be stable;

(4) The Position of the mobile phase bottles (relative to the pump, above or below);

(5) The Solvent Pickup Filters used (are clean and appropriate in material & porosity);

(6) The Fittings used are correctly installed & tightened;

(7) The types of Tubing used are chemically, temperature and pressure compatible (esp. the Inside Diameter of the tubing);

(8) The Selected Flow Rate(s) and Back-pressure are within the optimal range of the pump;

(9) All mobile phase solutions are Filtered, Freshly prepared and Degassed;

(10) How often the Pump is properly Inspected, Cleaned & Serviced.

 The HPLC pump is the most important part of your HPLC system. Take care of it. Neglect or abuse it, and you may lose time and money. Almost every problem you experience using an HPLC will be related in some way to the pump. Make sure you understand the flow path of the system in detail, and have the training to setup and use it properly. Take a hands-on training class (not a video or web based tutorial) to learn how to use the pump on your specific HPLC system. Learn how to run simple verification tests to check the flow rate (best done with a graduated cylinder). Never rely on the software values, check and verify everything yourself. Priming and flushing are needed any time air bubbles are present, mobile phase solutions are changed or the system has sat unused (this includes overnight). Always flush multi-channel pumps and valves (i.e. Binary, Ternary, Quaternary...) using a setting of 100% channel composition. Run one channel at a time at 100%, not 25% or 50% to flush channels (a common novice mistake). Flush ALL channels on a regular basis.

OK, so what can you do to make sure your HPLC pump is properly primed with fluid and operating to the best of its ability?

Start, by reading the operator's manual for your pump. Review the procedures for connecting it to the system, become familiar with the flow path and understand the procedures to prime the pump heads. Practice these procedures.

If an inline vacuum degasser is used, become familiar with the specifications, chemical compatibility (some are not compatible with solvents such as strong acids, strong bases, THF, chloroform, fluorinated additives and so on) and internal channel volume of each chamber used. It is useful to know what the degasser chamber volume is to figure out what the total channel priming volume is. This may be different for similar systems. Check, measure, verify, do not assume.

Priming Volume: The total volume contained in each channel's low-pressure line from the mobile phase bottle to the degasser + the degasser chamber channel volume + the total volume in the line from the degasser to the pump head (or multichannel valve) = the total minimum volume you must flush out before using the system. Because flushing just the minimum of volume (1x) of fluid through the channel is unreliable, flush 2x, 3x or more times this total volume, per channel (or as much fluid as it takes), to prime each channel. *If no degasser is present, then just calculate the volume contained in the low pressure tubing from the bottle to the pump head/valve. Set the pump to direct the flow to waste and use a high initial flow rate to speed up the priming process.

Use fresh mobile phase (prepared daily and filtered). Make sure the solvent pickup filters are clean. If possible, have the bottles placed higher than the pump's inlet (once flow has been established, this will allow natural siphoning to push liquid towards the pump head). Prime all of the lines used. The pumps run on liquid, not air so try and fill any of the lines with pure mobile phase before you connect them to the pump and/or degasser (If all of the lines are prefilled with fresh liquid, you can skip this part).  

There are two ways to PRIME EACH line (Flushing the Channels).

• *First, open any Prime/Purge or Waste Valve so the mobile phase is directed to waste, not the injector, column or detector. Our goal is to initially fill the lines with liquid, quickly, and we do not want these fluids to go through the entire HPLC system (i.e. column), just the HPLC pump.

(1) Wet Priming use a syringe fitted with a Luer-to-threaded fitting adapter (usually 1/4-28) to draw liquid through the tubing in the mobile phase bottle and into the pump's degasser and/or pump head's inlet. Be sure to have this type of syringe available (very useful). Never push fluid, only draw fluid through the tubing, just like the pump does. Connect the syringe to the mobile phase bottle lines, degasser ports and/or pump head multichannel valve or pump head inlet, as needed, to draw liquid through until all lines are filled.

(2) Dry Priming using the HPLC pump to draw the mobile phase out of the bottles, through the lines, degasser channels and to the pump head or multichannel valve. Note: "Dry" because the lines (low pressure tubing) are initially dry when we start. Always do this one channel at a time (e.g. A = 100%). This insures no miscibility or mixing problems and is standard procedure. Start with a modest flow rate to get the fluid moving through the lines, then increase the flow rate to speed up the process. The low pressure Teflon tubing is transparent so you can watch this process. Repeat with each channel. Note: Some HPLC pumps will struggle to perform this type of dry priming, as they will be unable to draw the liquid up from the bottle and/or pump the air out of the system. Pre-priming the lines using a syringe (as in #1 above) will help solve this. Running the pump with just air inside the lines may result in increased wear on the system (esp the piston seals) so if the system struggles to fill with liquid after one minute, discontinue and manually wet prime each line.

NOTES: 

• The back-pressure shown on the system readout should be very low during this initial  priming process (e.g. < 15 bars) as the HPLC system should not be plumbed with the column or detector inline, during the priming process (it should be by-passing those parts). Only the viscosity of the solution, the selected flow rate and the internal diameter of the tubing going into and out of the pump will contribute to the observed back-pressure, and this should be very low value.

• Once you have verified that liquid is exiting through the pump head waste port, you can increase the flow rate to speed up the priming process, but pay attention to the back-pressure. It should increase as the flow rate increases and drop as the flow rate drops. Continue to prime each channel in this way, one-at-a-time, until all channels are primed and flushed with liquid. You can gradually slow the flow rate down as you stop, to transition from one channel to another.
  

• If liquid has been drawn to the pump head, but the pump head still is not pumping liquid through it, it may be experiencing cavitation (air locked). If there is an outlet port on top of the pump head, the outlet fitting above the pump head can sometimes be briefly loosened with a wrench, allowing the system to push the air out (open it slightly with a wrench, then quickly close it after liquid comes out). Have a towel ready to soak up any fluid that comes out. Keep the area clean and dry. Alternatively, try drawing liquid through this port, while it is running, to gently fill the pump head chamber and remove the air.

• In some case, the inlet or especially the outlet check valve(s) can also become "stuck" open. When buffers are left in the system (they should be flushed out with water), crystals and particulate matter may deposit on the valve resulting in poor sealing, leaks or air being drawn through. Drawing liquid out of the pump head's outlet port with a syringe (or gently pushing it through the pump head) may remove the air bubble, debris and prime the valve, restoring function. Note: If needed, shut down the pump and clean/replace any contaminated or worn check valves before proceeding.
  

• In more extreme cases, you can change the mobile phase going into the pump head to a more viscous intermediate solvent to get things moving (an alcohol such as IPA might work well. If buffers have been used, then always first flush with pure water). 

• Degas all eluents / mobile phase solutions used. All of them. Degassing will help reduce the formation of bubbles inside the pump head. Failure to properly degas the solutions used may result in loss of prime, baseline and/or pressure instability. Make sure your degasser is operating properly (electronic vacuum degassers only last ~ 5 years at most. Be sure to have them professionally serviced). Sonicating fluids at the bench or using vacuum filtration to initially remove gas from the solution will only degas the solution for a short time (minutes). Gas will slowly diffuse back into the solution resulting in baseline noise, drift and pump problems (for HPLC, only use inline degassing or Helium sparging).
  

• Verify the flow rate. It may be unwise to rely on the indicated flow rate shown on the instrument screen or display. It is wise to measure the flow rate of each channel, separately, using a graduated cylinder and a timer. This is the most reliable way to determine what the actual flow rate is through the system (and is also the method we use during performance verification or qualification testing too). To check the flow, make sure the system has been primed and flushed. Install a flow restriction capillary in place of the column (to provide the required back pressure). Set the flow rate to a value which is appropriate for the pump and measure/record the volume delivered vs. time. Example: Using a flow rate of 1.000 mL/min obtain a 10 mL volume, glass laboratory grade graduated cylinder. At time zero, direct the flow from the restrictor's outlet into the graduated cylinder. Measure the volume of fluid collected in 8 minutes. *It should be 8.00 mLs.
  

If you continue to have priming problems and/or air bubbles disrupting the flow there are four more things you can check. 

1. Make sure the solvent pickup filters/frits are clean and unobstructed (these are maintenance items). If the filters are obstructed, then a vacuum may form on the line resulting in pump cavitation and loss of prime. One quick way to check if this might be a problem is to remove the suspect solvent pickup filter from the tubing, then try again. If flow is restored w/o the filter in place, then the filter may have been clogged. Install a new solvent filter as soon as possible. *Never run the HPLC without solvent filters installed. Those filters perform a very important job and protect the flow path of the system.  
2. Service the Pump Heads. Regular cleaning, inspection and replacement of worn parts must be done to maintain the function of the pump. Worn parts will result in failures, instability, lost time, plus invalid data. The pump has many mechanical parts which wear out and require replacement. Most pumps should be inspected/serviced every 6 months. Keep the pumps clean and fully serviced (replace: piston seals, pistons, frits, check valves as needed). Depending on the brand, model and applications, the types of parts needed and the frequency of repairs varies widely. *This is discussed in another article. 
3. If your HPLC system has an inline vacuum degasser (either a standalone or integrated module), it may be damaged, contaminated or broken. The typical service life of an electronic inline vacuum degasser is only five years (some models have even shorter lifespans). Degasser's with internal damage may result in contamination of the mobile phase. A failing or damaged HPLC vacuum degasser may directly contribute to analysis problems (ghost peaks, pressure instability, poor baseline stability...). Have your degasser professionally diagnostically tested and serviced often.  
4. Clean and/or replace any worn or damaged inlet or outlet pump head valves. Not flushing buffers out of the HPLC system on a regular basis or remain in contact with the solution for long periods of time can damage the valves. In some cases, cleaning is all that is needed, but in others, replacement is required to restore function. Be sure to have the system professionally serviced on a regular basis.
   

• Additional Troubleshooting Info can be found here:

Diagnosing & Troubleshooting HPLC Pressure Fluctuation Problems (Unstable Baseline)

Do your HPLC Methods Meet Good Chromatography Fundamentals? HPLC Training: RETAIN, SEPARATE and RESOLVE

When an HPLC or LC-MS method is not developed properly, it may not be selective for the sample and may not show any retention on the column. When this happens, everything injected may elute out at the same time and appear to be 100% pure . *These types of errors are easy to spot by anyone with formal training and experience in chromatography concepts (note: "years" on the job are not the same thing as years of practical knowledge and/or formal training in the technique. We routinely provide consulting services to clients with 10 or more years on the job performing chromatography analysis, but whom have not received any formal training during this time and make errors of this type).

Developing HPLC Methods which follow good chromatography guidelines and fundamentals should be key goals of HPLC method development. When developing an HPLC ("UHPLC") method, you must develop an analysis method which is selective for the compound of interest. 'Selectivity' is the most important variable to focus on when developing methods. Your method must demonstrate that it can: (1) Retain; (2) Separate and (3) baseline Resolve all peaks present (and any possible impurities or related substances), in a reliable and repeatable way. Failure to demonstrate that your HPLC method meets these basic requirements AND is selective for the sample being analyzed means your method is invalid.  

*You may be surprised to know that many HPLC methods (including some published papers and "Validated" Methods) do not meet these basic requirements. In this case, knowledge is truly power. If you have the practical knowledge and understanding of this technique, you will be able to easily spot these invalid methods. Make sure you review other methods as part of your training. Never assume because someone else published it or "did it that way", that it is valid. It may not be. An average of 20% of the methods I review do not meet these basic requirements and are invalid.

• Do your HPLC methods meet these requirements? 
• Can you demonstrate to others, who are knowledgeable in the technique, that your method follows good fundamentals? 

You should be able to demonstrate knowledge of these basic principles and have confidence in them.

Proper HPLC method development training must include and stress the following three practical, fundamental concepts of Retain, Separate and Resolve:

• Demonstrate that using your HPLC Method, that the sample is RETAINED on the Column. *Screen many columns to find the best one, early in the process. For most modes of chromatography, you do this by first estimating then measuring the column void volume. How do you know if it is retained long enough? Next, you calculate the K prime (Capacity Factor) of your sample to insure it meets basic chromatography guidelines (or regulations). * K prime > 1.5 (or > 2.0 for most regulated environments). Note: While retention is required, K prime is not applicable to SEC modes of chromatography.

• When satisfactory retention is achieved (K prime), begin optimizing the method to SEPARATE and baseline RESOLVE all compounds. This is achieved using proper HPLC Method Development techniques plus the practical knowledge and experience which comes from good training. Please refer to these two linked articles for more information; "Modern HPLC Method Development Tips (PART I)" and "Modern HPLC Method Development Tips (PART II)".

A Case of Changing Solution pH. Formic Acid Stability in Solution (Methanol)

Real life examples help to better illustrate problems that I am called in to troubleshoot for clients. As a professional scientific consultant, many of my clients have spent months (sometimes years) trying to solve an analytical problem on their own before I am brought in to make the diagnosis and propose a solution. Many years of working in a wide range of scientific fields allows me to identify problems quickly and efficiently saving clients the most money and allowing them to resume work on their projects.

This was the case during a recent consult for a major cannabis testing laboratory. They were having a great deal of difficulty obtaining reproducible results for their analytical testing screens (14 compounds in their analysis with a need for repeatable and accurate results). Variations from 25% to 50% were observed run-to-run over the course of seven days. They assured me they were doing everything in the same way. To begin the troubleshooting process, we started by looking at the actual data gathered and the actual method(s) used to acquire the data. These were evaluated to see if they followed good practices and techniques, also to make sure they had SOP's in place which were clear. Good SOP's must include enough detail to allow anyone reviewing them to prepare samples, standards and/or solutions in the exact same way. Additionally, the HPLC instrumentation was checked and tested to verify it was performing as designed.

After reviewing their training and methodologies on-site, a number of areas of concern were quickly identified. One of the most likely reasons for the variation in values over time was found to be caused by a common mistake in the preparation of mobile phase solutions for the HPLC system. To save time, the client's scientists prepared all organic solvent solutions in advance (~ one month or more), then filtered and stored them at room temperature. For example, their solutions of 0.1% formic acid in HPLC grade Methanol were pre-mixed and stored in glass one liter bottles. These bottles were then put aside, for an average of one month before use. This finding proved key as someone with proper HPLC training would be aware of a well known problem when formic acid is left in pure organic solvent, especially methanol, over time (less so with ACN). Briefly, the formic acid content degrades quickly over time and is often found to be only half of what it was initially after just three or four days (If you have not done so already, this is a simple and useful experiment to run in your lab, monitoring the acid level by titration, not with a pH meter, over time at room temperature in methanol)! This degradation continues over time reducing the amount of acid in solution. If the acid is added to the solution to enhance ionization (i.e. LC-MS; LC-MS/MS) or provide acidification to maintain the sample in a fully ionized form, then as the level of acidification decreases, so does the solution's ability to maintain it. In other words, your HPLC method may change over time (resulting in an in-valid method).

•  I have always promoted the importance of making and using freshly prepared mobile phase solutions (daily), especially where any aqueous solutions are used (to prevent degradation of additives and/or bacterial or fungi growth). However, this precaution does not normally apply to many pure organic solvents, but there are a few very important exceptions to this, formic acid and methanol in this example. 

Changes were made to their SOP's to insure that future solutions of formic acid in methanol were not prepared in advance, but instead, fresh on the day needed only. This coupled with a few basic improvements to their column washing, equilibration and overall training resulted in %RSD of only 0.3% for future analysis runs.

 
As a side note, I have been asked why solutions of formic acid in methanol are sold commercially for HPLC use? I have no answer to this, but respectfully remind everyone that just because something is offered for sale, does not mean it should be purchased. Ask yourself if the item is appropriate for your application? It may not be suitable for your use or application. 

BTW: Please be sure to flush your HPLC system of all organic acids (e.g. acetic, formic) after use and do not leave them in the HPLC system overnight. Even 1% levels of organic acids may be corrosive to stainless steel. 

HPLC to UHPLC Conversion Notes (Gradient Time Program Adjustment)

In an earlier article we discussed how to adjust the flow rate, injection volume and column dimensions when scaling an HPLC method UP or Down. The formula's needed to do this are fairly simple. If we adjust for changes in the column dimensions or flow rate, what types of changes are needed to adjust the gradient time? The formula to make this adjustment is also very simple. Here is the information you need.

Terms Used in Formula:

Time in minutes, Gradient (Initial): Tg1

Time in minutes, Gradient (New):   Tg2

Flow Rate in mL/min, Column (Initial): Fc1

Flow Rate in mL/min, Column (New): Fc2

Column Diameter, mm (Initial): Dc1

Column Diameter, mm (New): Dc2

Column Length, mm (Initial): Lc1

Column Length, mm (New): Lc2

• Tg2 = Tg1 x (Fc1/Fc2) x ((Dc2²) / (Dc1²)) x (Lc2 x Lc1)

Here is an example problem to solve for. 

If we start with a flow rate of 1.000 mL/min (Fc1) on a 4.6 x 250 mm column with 5 micron support (Dc1 & Lc1) and have an initial Gradient Time of 10 minutes (Tg1), then what would the new gradient time be if we switched to a sub 2 micron support in a 2.1 x 50 mm column (Dc2 & Lc2) at 0.200 mL/min (Fc2)? 

To solve the equation we will plug-in the values for each part of the equation separately, then multiply them to obtain the result.

  (Fc1/Fc2):    1.000/0.200 = 5

  (Dc2²) / (Dc1²)  4.41/21.16 = 0.21

   (Lc2 x Lc1) = 50/250 = 0.20

  Tg2 = 10 x 5 x 0.21 x 0.20 

  Tg2 = 2.10 (or 2.10 minutes)

If a 2.1 x 50 mm column was substituted for the 4.6 x 250 mm AND the flow rate was changed from 1.000 mL/min to 0.200 mL/min, then the initial programmed gradient time of 10 minutes would be changed to 2.1 minutes

UHPLC TIP: Reducing the Column Temperature to Offset Frictional Heating Effects (Causing Poor Resolution)

HPLC column temperature is a critical variable that we adjust and optimize during method development. We use it as a variable during the method development process to improve solubility, optimize peak shape and increase resolution. Once established, it must be carefully controlled during the method analysis to provide reliable and reproducible analysis results. Change the column temperature and you may also change the results obtained. This is a fundamental method development tool and must not be forgotten.

If you are developing a new UHPLC method OR perhaps scaling an HPLC method to utilize 2.5 micron or smaller support particles, then you may observe a loss of resolution or poor peak shape in the new method. There are many reasons why this may occur, and the most common ones relate to not optimizing all of the method parameters correctly when scaling the method (e.g. dwell volume too large, flow cell volume too large, injection volume too large, sample rate too slow, flow rate not optimized, mobile phase composition changes not in scale with the gradient...). But there is another reason...

Resolution may be reduced or lost when all of the initial scaling and instrument set-up parameters are optimized. What is the most likely reason for this? In many cases the use of substantially higher flow rates (relative to linear flow rates) and the use of smaller diameter particles results in much higher backpressures (you may recall that if you halve the particle size, the backpressure increases 4x). The resulting backpressure might be 2, 3 or even 4 times higher than observed in the original method. While these higher backpressures were well within the operating parameters of the HPLC system used, the results obtained were poor. The possible cause? The much higher backpressure increased the amount of frictional heating inside the column, raising the actual analysis method temperature and changing the separation conditions. 

Pushing mobile phase (liquid) through a chromatography column generates heat and pressure. The heat generated increases the actual temperature of the column and reduces the viscosity of the fluid. In conventional columns (i.e. 4.6 x 150 mm, 5u) at 1.00 ml/min, this heating effect is minimal, but at much greater column pressures, > 400 bars, the frictional effects may be substantial. These types of very high pressures may be seen with methods which utilize columns containing the smallest particles (1.9 to 2.5 micron). Enough to change the temperature in the column by several degrees (e.g. >5 degrees C) and result in different method conditions. So, what can you do about this? The most direct way to address the problem is to run the same method at a lower temperature (perhaps decrease by 5 C to start with). This will slightly raise the backpressure (lower temperature equals higher viscosity), but it should cool the column and restore the original temperature conditions used. Additionally, we suggest that you always start column equilibration using a flow ramp to gradually increase the flow over time and reduce the overall heating effect and resulting "shock" placed on the column. An initial delay at equilibration may help reduce these effects (gradually ramp up to the regular flow rate and hold). You may need to try several temperatures and this may be easiest to do if your HPLC has a column compartment with heating and COOLING capabilities. Optimizing the temperature and internal pressures may increase the column lifetime and result in better overall data reproducibility.

LC-MS Contamination? Another Possible Cause. Are your Mobile Phase Bottles and Pick up Filters Clean ?

One of the more common LC/MS problems I am asked to help solve deals with contaminated LC-MS or LC/MS/MS systems. Over time, many systems will become contaminated with a wide variety of plasticizers, detergents, salts, metals and ion pairing agents that routine source cleaning will not remove. Often, these compounds are introduced to the system through the tools used (e.g. pipettes) chemicals, solvents, mobile phase additives or even the samples themselves. "Dirty" samples sometimes persist inside the system long after the analysis work is complete, leaving material in poorly maintained injection valves but also through the use of poorly washed / contaminated and fouled HPLC columns. Even the modern inline HPLC vacuum degasser has proven to be a source of contamination. 

In addition to the above mentioned sources of contamination, another more obvious source of contamination should always be addressed early in the process of cleaning the system. Specifically, the glass mobile phase bottles and the associated solvent pickup tubing and solvent pickup filters used with them. Contamination in these areas may directly infuse the system with undesirable material. Good cleaning and maintenance practices must be maintained to reduce this source of potential contamination. 

As a general guideline, we shall not place our mobile phase reservoir bottles in any type of dishwasher or wash them using any dish soaps. These may leave a residue easily detected by even the weakest mass spectrometer. Avoid contamination by purchasing high quality glass bottles with vented caps to keep dust out. If rinsing with organic solvents (and/or freshly prepared and filtered high resistance water) does not clean them, you can try a Nitric Acid rinse (up to 30%) followed by a neutralizing wash in 2M Sodium hydroxide. Follow-up with many rinses of HPLC Grade water (or LC/MS grade), oven drying, then re-fill with an appropriate mobile phase. Don't forget to replace those solvent pickup filters too. While many 316 SS pickup filters can be cleaned, most of the sintered glass style filters are designed to be disposed of (not cleaned or put in an ultrasonic cleaner!). So periodically dispose of the glass types and install new filters and fresh mobile phase into those recently cleaned bottles (before you start looking for the source of contamination in the more expensive parts of the instrument, clean or replace the filters). - Please don't re-contaminate an expensive HPLC or LC/MS system and invalidate your methods and data because you skipped replacing a $10 part. Keep commonly used spare parts in-stock and always maintain a clean system.

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.