Achieving a flat baseline which does not exhibit spikes, ghost peaks, drift or wander in an unpredictable manner should be a primary goal when performing HPLC analysis or developing methods. Methods which result in flat baselines and have well defined, sharp peaks allow for accurate sample area integration. Integration algorithms perform poorly in quantifying peaks on sloped, drifting or noisy baselines. Excessive baseline noise contributes to many problems, including poor quantitation, high %RSD errors, peak identification errors, retention time variation and many other critical problems. Properly developed HPLC methods are reproducible methods which apply and utilize good chromatography fundamentals. Note: "Noise" is a relative term, often w/o meaning. You should always describe it scientifically, measure and compare the signal to noise ration (S/N) of the baseline vs the peak plus note any cyclical patterns (useful in troubleshooting).
Note: A lack of proper training in the operation of the HPLC system, improper start-up or poor
quality maintenance of the chromatograph (Examples: failure to degas and purge the system lines before use; poor mixing; an air bubble stuck in a
check valve, a bad detector lamp or a leak will often result in baseline noise) are the main causes of noise. Your
HPLC system must be optimized for your specific application. Be sure
and allow time for the mobile phase to reach full equilibration with the
system before starting any analysis. Do not start an analysis until the baseline is stable.
In this article, we will discuss how temperature fluctuations, inadequate mixing, inadequate degassing and flow cell contamination can result in excessive baseline noise. We will provide suggestions on how to reduce or eliminate these problems. Troubleshooting should be done on-site, not over the web or telephone.
In this article, we will discuss how temperature fluctuations, inadequate mixing, inadequate degassing and flow cell contamination can result in excessive baseline noise. We will provide suggestions on how to reduce or eliminate these problems. Troubleshooting should be done on-site, not over the web or telephone.
TEMPERATURE FLUCTUATIONS:
To
reduce temperature fluctuations, you must control the temperature of
the column and mobile phase (if applicable) during the analysis. This is
most commonly done by: (a) using equilibrated mobile phase at the start
of the day or analysis, (b) keeping the interconnecting lines as short
as possible (esp. any which exit the column and go to detectors/flow
cells), (c) insulating any stainless steel lines with plastic tubing to
reduce heat loss and (d) using a thermostatted column compartment to
maintain the column at a single set temperature throughout the day.
Control of the column temperature will remove 'temperature' as a
variable from your analysis. Temperature should be a constant run to
run, not a variable. Be sure and document the temperature selected as
part of your method.
INADEQUATE MOBILE PHASE MIXING:
The associated noise and ripple of incomplete mixing can
reduce the limit of detection (LOD) and increase integration error. Both
high pressure (with separate pumps) and low pressure pumping (one pump
with a multi-channel proportioning valve) systems depend on efficient mixing to
reduce noise. For gradient analysis, failure to completely mix the
mobile phase solution before it enters the HPLC column often results in
excessive baseline noise, spikes and poor reproducibility. "Mixing" is
often initially accomplished by combining the flow paths of more than one solvent channel together, using a multi-channel gradient valve or tubing. Mixing also performed directly in a mixer installed in the flow path of an
HPLC pump. This
mixer is often a static mixer (a simple 'Tee', a tube filled with
baffles, a frit or beads, valve orifice or microfluidic device) of low
volume design for chromatography use, but allows adequate mixing of the
liquids within a prescribed flow rate range. The best mixers incorporate
longitudinal and radial mixing in-line. A mixer with too low a volume
or of insufficient design can result in poor mixing of the mobile phase
(note: incorrect solvent compressibility settings can also cause mixing
and noise problems too). To reduce mixing problems, first insure that
the mobile phases used are fully soluble with each other. Next, make
sure that any mixer used is appropriate for the flow rates and volumes
you will be using. If needed, run a gradient valve test to insure that each valve channel is working properly, not leaking or introducing any cross-flow leakage to another channel. Monitor the baseline for pressure stability (% ripple), drift and artifacts (e.g. spikes)
in real time to spot problems and make adjustments to correct them.
INADEQUATE MOBILE PHASE DEGASSING:
For the best results, continuously degas your mobile phase. Reducing the amount of gas will also improve signal to noise levels of detection, reduce drift and reduce pump cavitation. If you are using an electronic vacuum degassing module, make sure it is maintained and working 100%. A faulty degasser may cause more damage (contamination) to your system and methods. Maintain and Repair them just as you do for your other instrument modules. Gas
bubbles may cause check valves to malfunction (get stuck), baseline
noise spikes to appear randomly, flow rates and/or pressures to become irregular,
detector outputs to show high levels of noise (from air in the flow
cell) and also cause the loss of prime or cavitation in pumps. To
achieve the best balance of low noise levels and high reliability, both
aqueous and organic mobile phases should be fully degassed before and during use. This can be
accomplished through stand-alone inline vacuum degassing modules or through
gentle continuous helium gas sparging (*Helium makes an excellent choice of gas as it is not soluble in the mobile phase. Never use Nitrogen or Argon gas, they are soluble in the liquid!). In all cases, degassing must be continuous
(not just done one time). Continuous degassing reduces cyclical noise and signal variations. For this reason, I do not recommend using
ultrasonic baths to degas mobile phase solutions as these are not used in a continuous mode. The mobile phase solution starts to re-absorb gas as soon as you stop sonicating the solution. This results in continuous baseline drift (up and down).
Removal
of gasses is critical to the function of a modern HPLC pumping system.
The liquids used are compressed to very high levels which forces out
solubilized gas from the solutions. This is best accomplished before the
liquid is transferred into the pump. These gas bubbles must be
minimized to achieve desirable baselines. *Even if you use a high pressure pumping system, an inline degassing system reduces the amount of noise and baseline drift. Properly maintain and service your degasser to insure compliant operation. IOW: Whichever method you use, always degas your mobile
phase solutions.
FLOW CELLS:
Many other types of problems not mentioned in this short article can also cause baseline noise. For example, a sticking inlet or outlet valve on the pump, worn piston seals, worn out detector lamp(s) or detector electrode (EC) can induce noise. In all cases, the cause must be investigated in a logical, step-wise manner. Demonstrate what is working and rule out items one-by-one.
Reference: http://hplctips.blogspot.com/2014/01/diagnosing-troubleshooting-hplc.html
thank you very much this is very helpful
ReplyDeleteIt is very useful for the freshers , thankyou so much
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