             EXERCISES TO ACCOMPANY THE NEURON TUTORIAL

The simulation loads with a number of defaults set. You should see six graph
windows on your screen. For purposes of this assignment, the upper left window
is #1. We will number the rest of the windows COUNTER-CLOCKWISE so that the
window in the upper right corner is #6. Window number #6 will not always be
present. Under the graph windows are a bunch of "buttons" and dialogue boxes.
Move the mouse cursor to the button labeled "Step". This button starts the
simulation. Click the left mouse button on "Step". (Normally you will click on
"Reset" first.) The default simulation will begin.

In window #1, there are three stimuli: one long square pulse and two strings
of impulses. From the top they are: "Source B", "Source A" and the "soma
injection current". In a dialogue box below you will see that the injection
current is set to 0.0002. To the right of that you will see that synaptic
weights for all the sources and dendrites are set to 0.0. Therefore, only the
injection current is currently stimulating the cell. (Call up help and click
on "neuron inputs" for a drawing of the model cell.) Study windows #2
through #5 until you understand what is going on.

QUESTION 1: In 20 words or less, what is the relationship between what you see
in window #4 and window #3?

Move the mouse cursor into the dialogue box for the soma injection current.
Backspace (key) once. This should delete the "2" and leave only "0.000" show-
ing. Hit "return". (NOTE: you must hit "return" after changing the contents
of a dialogue box. If you don't, the number will show as changed, but the new
value will not be installed and you will get an incorrect simulation.)
Click on "Reset" and then "Step". You should get a lot of straight lines.
Make sure you understand what you've just done.

Leave the soma injection current set to zero. Set the synaptic weight for
dendrite #1 excitatory input to 10 and make sure it is toggled to "Source A".
Click on the button labeled "inputs". This will bring up a menu of dialogue
boxes for some input parameters. Look at the parameters and relate them to the
plots in window #1. Note that the "Source A interval" is set to 10. Put the
menu away and "Step" the simulation (Click on "Reset" first). Study what you
see. Open the "input" menu and change "Source A interval" to 8 (Don't forget
to hit "return". Click on "Done". Toggle "overlay mode" on. Click on "Reset"
then "step". You should get the result of the second simulation overlayed on
the first. Leave overlay on and repeat for "Source A intervals" of 6, 4, 3,
and 2. Watch each set of curves form so that you know where each tracing came
from. If you screw up or need to run the simulations again, just toggle over-
lay off, hit reset and begin again.

QUESTION 2: In 10 words or less (two should be enough), what does the over-
layed plot in window #2 demonstrate?

QUESTION 3: Make a plot of the input-output transfer function. That is, plot
input rate vs output spikes rate.

Now set the "Source A interval" back to "3", keeping it connected to the
excitatory input of dendrite #1 with a synaptic weight of 10.  Set the
synaptic weight for dendrite #1 inhibitory input to 10 and make sure that it
is toggled to "Source B".  Leave everything else as it was. "Reset" and
"Step" for a new simulation.  You should note that the inhibitory input has
little effect upon the generation of action potentials.

QUESTION 4: Using only the "synaptic weight for dendrite #1 inhibitory input"
and the three "Source B" parameters (delay, width and interval, inhibit
(suppress) the middle of the three action potentials produced by "Source A"
input. You may not modify any "Source A" parameters, and both the first and
last action potentials must remain. Answer the question by stating the
parameter values you had to use and by submitting hard copy of window #2 if
your system allows you to make prints of the screen.

Toggle "Plot Soma" to "Plot Dendrite 2". Move the inhibitory input ("Source
B") to Dendrite #2.

QUESTION 5: For the above configuration, is the inhibitory synapse more or
less effective at suppressing the middle action potential?  Defend your
answer with numbers by varying the synaptic weights used in this
configuration and the previous one.  Explain what is happening.

Reverse the inputs. That is, place the excitatory input on dendrite #2 and the
inhibitory input on dendrite #1.

QUESTION 6: For the above configuration, is the inhibitory synapse more or
less effective at suppressing the middle action potential?  Defend your
answer in the same manner as in QUESTION 5, and explain the differences
between this situation and the previous one.


There is a button called "Add Cable". It lets you add a number of cable seg-
ments between dendrites 2 and 1. Apply a sub-threshold epsp to one of the
dendrites.

QUESTION 7: Using various numbers of inserted segments, estimate the length
constant, "lambda", for this dendrite.  Express your answer in units of
"number of segments" and compare your result with the predictions of theory.
