Note: The total HPLC gradient system
dwell volume is different than the HPLC column’s void volume. Two different terms for two very different measurements.
When we perform gradient HPLC analysis, the mobile phase composition is changed over a period of time. The mobile phase is mixed in real time by the pump(s), mixer and/or valves, then transported to the injector and finally, on to the head of the HPLC column. The total volume of liquid contained between where the mobile phase is mixed and the head of the column helps us determine when the newly mixed solution arrives at the column head (it is not instantaneous). This delay is often referred to as the gradient delay time (or delay volume) and its value will vary for different HPLC systems due mainly to differences in tubing dimensions used, pumping system type and the design of the flow path.
When we perform gradient HPLC analysis, the mobile phase composition is changed over a period of time. The mobile phase is mixed in real time by the pump(s), mixer and/or valves, then transported to the injector and finally, on to the head of the HPLC column. The total volume of liquid contained between where the mobile phase is mixed and the head of the column helps us determine when the newly mixed solution arrives at the column head (it is not instantaneous). This delay is often referred to as the gradient delay time (or delay volume) and its value will vary for different HPLC systems due mainly to differences in tubing dimensions used, pumping system type and the design of the flow path.
For
example: If the system dwell
volume is found to be 1 ml and the flow rate used is 1.000 ml/min, then the
gradient delay time is one minute.
So how do we
know what the system dwell volume or gradient delay volume is? Well, we measure
it of course!
Measure the ‘System Dwell Volume’ (aka: Gradient
Delay Volume)*:
(1) REMOVE any
HPLC column(s) and install a Zero Dead Volume Union (*ZDV) or a restriction capillary of know volume in its place.
(2) Prepare Two
Different Mobile phase solutions:
Bottle
‘A’: HPLC grade Methanol (MeOH).
Bottle
‘B’: HPLC grade Methanol with 0.1% acetone added (v/v).
(3) Set your
UV/VIS detector to 265 nm (8 nm Bandwidth, Reference OFF).
(4) Program a
suitable system flow rate and create a simple Gradient Method (linear change)
which starts at 0.0 minutes with 100% ‘A’ (HPLC grade Methanol) and 0% B (HPLC
grade Methanol with 0.1% acetone added) and runs to 0% ‘A’ and 100% ‘B’ for about
10.0 minutes (actual times used will depend on your selected flow rate).
(5) Flush and degas
both solutions, ‘B’ first, then ‘A’ through the system until you get a nice
clean, flat baseline. Make sure their is enough backpressure on the pump (>40 bars) to obtain a stable signal (use a restrictor or back-pressure regulator if needed).
(6) No
injection should occur during this method.
(7) Start the
method (RUN) and observe the 265 nm signal over time. At some point you should
observe the signal begin to rise. When you see this signal change occur, the
acetone has finally made it from the pump head to the detector’s flow cell.
Make note of the time this occurs.
Using the known flow
rate and observed signal change time, you can now estimate the total system dwell volume.
Example:
If you observe the signal start to rise steeply at 2.00 minutes and your flow
rate was 1.000 ml/min. Your system dwell volume would be 2.000 mls.
A more accurate
system dwell volume value can be obtained by next running the same method with an
injection of acetone (e.g. 1 ul) and noting the time at which the injection
peak is first seen. That will give you the time it takes the sample (and therefore
the volume needed) to go from the injector to the flow cell. If you subtract this time
off the system dwell time you recorded in the last test, you will have the
actual measured time from the pump head (or proportioning valve) to the head of
the column (vs the flow cell). Normally the volume contained in this tubing and
flow cell are very small relative to the volume in the rest of the system, so
we can ignore them. However, when using some of the very low volume columns
(e.g. 2.1 x 50 mm), the volume contained in these areas can become significant
so when appropriate, we need to be aware of them.
Failure to take
into account changes in HPLC system dwell volumes can result in methods which
no longer work or provide different results. This is because the gradient
rate change you program in your method may not allow enough time for the new mobile
phase composition to reach and flow all the way through the column in the time
that you have programmed. A common mistake we see is when users forget to
adjust the gradient profile when changing column dimensions or program changes
using too fast a time.
BTW: One common
trick we use to improve compatibility between systems which have different
dwell volumes is to include an initial (time 0.0) isocratic hold-time into the start of each
method. If all systems used have system delay volumes under 3 mls, then add a 3
minute isocratic hold time at the start of each method (if 1.000 ml/min flow
rates are used), before any gradient starts. While not the best way to deal
with the issue, this type of “cheat” can make it possible to quickly adapt a
method for use on several different system types.
*Note: This is a generic method to determine
the system dwell volume or gradient delay volume. Detector signal buffering and flow cell volume also adds to the delay and in some cases, must also be accounted for too. There are many other methods
which can be used for this determination as well. This proposed example serves to illustrate the
concept only.
