Axon Axopatch 200B, Теория работы

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USE OF THE PATCH CLAMP – A TUTORIAL • 23
Chapter 3
component has just been eliminated, you may observe a small wiggle at the leading edge of the
residual transient. Continue to reduce the FAST MAG control until the leading edge of the
transient is smooth and "S-shaped". This may lead to a small (5-10%) increase in the peak
amplitude of the residual (positive-going) transient. Note that further reductions in the FAST
MAG control will cause the residual transient to grow further in amplitude; stop when the
leading edge is smooth. This is best accomplished at a sweep speed of 100-200 µs/div and a
vertical sensitivity of about 100 mV/div, assuming a 40 mV command step (Figure 6c).
Reduce the value of the SERIES RESISTANCE control setting by about 2-3%. A notch should
develop in the residual waveform and a slower positive-going component should develop at the
trailing edge of the transient. Stop when the overall transient is centered around the baseline. A
typical waveform at this point is shown in Figure 6d. If the initial direction of the waveform is
negative, the FAST MAG may need to be decreased a little more.
Slightly increase the setting of the WHOLE CELL CAP. potentiometer (1-2%) until the slow
component of the residual transient disappears. The resulting waveform should be biphasic with
positive-going initial component and a negative-going final component. In 5 kHz bandwidth its
peak-to-peak amplitude should be about 100-200 pA and its total duration about 200 µs
(Figure 6e).
Adjust the FAST
τ
of the PIPETTE CAPACITANCE COMPENSATION until the residual
transient seems to be minimized. Note that it will still be biphasic; keep the waveform as
smooth as possible. The readjustment of FAST
τ
is usually not very large. Now readjust the
FAST MAG control of PIPETTE CAPACITANCE COMPENSATION and minimize the final
transient. A few iterative adjustments of the FAST MAG and FAST
τ
may be required to
achieve best performance. If a reasonably fast (< 200 µs) component remains that can not be
compensated with the FAST MAG and FAST
τ
controls, it probably means that a very small
readjustment of the SERIES RESISTANCE potentiometer is needed. At a slower sweep speed
(
e.g. , 1-2 ms/div) make sure that there is no slow component visible; if you observe a slow
component you need to slightly readjust the WHOLE CELL CAP. potentiometer. With a little
practice it should be possible to reduce the residual transient to an amplitude of about 10 pA so
that it essentially disappears into the noise (Figure 6f ). You are now clamping the model cell
membrane in about 30 µs and have completely eliminated all the capacity current from the output
of the headstage. Similar performance can normally be achieved with real cells but the use of the
slow component of the PIPETTE CAPACITANCE COMPENSATION is likely to also be
required. Set the vertical sensitivity to 0.5 V/div and the sweep speed to 1-2 ms/div, and turn
OFF and ON the WHOLE CELL CAP. switch (turning this switch OFF also disables
PREDICTION but not CORRECTION). This is a striking demonstration of the improvement in
performance that has been achieved by the adjustment procedure. Also note that in 5 kHz