Cycle time can affect your quantitation accuracy, dwell times can affect your sensitivity. New generation triple quadrupoles can go pretty low dwell times (i.e. 25-50 ms) without minimal effects on sensitivity. They are also much more resistant to cross-talking...
Again for older instruments and for mutliple component analysis, if the chromatography allowed it (i.e. if there was a part in the middle of the chromatogram without any peaks) you could create two events with different transitions (e.g. 10 transitions followed in the first part and 12 transitions on the second). In this way you could afford higher dwell times...
Would you mind elaborating on that a bit?
Let me try to reason it out. Cycle time affects quantitation, dwell time affects sensitivity. A dwell time leading to cycle times that are too long can cause missed data point aquisitions thus effecting sensitivity.
I'm not not seeing the relationship to cycle time relationship to quantitation except through the sensitivity loss or gain realized by longer-shorter cycle times. Shorter cycle times will capture more data points, whereby the proper cycle time will be sure to capture the maximum of a quickly changing signal.
Let me try this...I have two analytes that I am looking for with two transitions for each. At the moment I have the two transitions for the two analytes that I am looking for incorporated into one MRM function. Since, I have the two analytes nicely separated, I probably should be using separate MRM functions for each analyte to improve quantitation and sensitivity? I'm talking hypothetically at the moment since my present sensitivity and quantitation are both very good.
I have the following equation:
Cycle time = [(N transitions) * (dwell time)] + [(N transitions)*(interchannel delay)] + interscan delay
