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Perspectives / neural coding

Averaging is a convenient fiction of neuroscience

But neurons don't take averages. This ubiquitous practice hides from
us how the brain really works.

By Mark Humphries
23 September 2024 | 7 min read
 
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Illustration of distorted lines of different colors being pulled into
a box where they are smoothed in a single multicolored line.
Mathematical masking: Whenever most of us average neural activity
over trials, over neurons or both, we are implicitly assuming that
the resulting signal is what the rest of the brain sees.
Illustration by John Han
Headshot of Mark Humphries.
Mark Humphries
Chair in computational neuroscience
University of Nottingham
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Tags:
neural coding, Electrophysiology, modelling, Neural dynamics

At any social gathering of neuroscientists, the conversation can turn
to what's holding back the field. "Funders," some grumble, lamenting
the amount of money thrown at microbiology instead. "Journals,"
others chip in, grousing at the gatekeeping editors who stop new
ideas from flourishing. "The tyranny of old-timers," some newly
minted principal investigator often mutters, cursing the difficulty
of challenging entrenched ideas.

"Averaging," I say, and everyone moves slightly farther away from me
down the bar. But really, it is a problem: Averaging is
ubiquitous--and hides from us how the brain works.

A major goal of neuroscience is to understand the signals sent by
neurons. Those signals--their spikes--underpin the brain's functions,
whether they be seeing, deciding or moving. To understand, say, how
we make a decision, many argue we need to understand the spikes that
underlie it: how they convey information about the options available,
how they convey the process of a decision between those options, and
how they convey that decision into action.

Averaging is everywhere in our attempts to understand the spiking of
neurons. A good example is that fundamental workhorse of sensory
neuroscience, the tuning curve. Imagine that you want to know what
frequency of sound a neuron most prefers. You play that neuron tones
in a range of frequencies and count the number of spikes it emits for
each. Repeat that a bunch of times, average the number of spikes
emitted for each frequency, and voila, you've built yourself a tuning
curve: a plot that tells you the average number of spikes the neuron
sends for each frequency. It may well show you that the neuron sends
more spikes, on average, to 100 hertz tones than to 10 or 1,000 hertz
tones, suggesting the neuron is tuned to that specific frequency of
sound.

"

Averaging over time hides what a neuron actually sees, what it
actually gets to compute with.

--
-- Mark Humphries

The natural extension of this idea is to look across time, creating a
"peri-stimulus time histogram." This shows nothing more than the
average number of spikes a neuron sends just before and after some
significant event. When an animal repeatedly gets a reward, for
example, we look at how a neuron responds to that reward by seeing
how many more or fewer spikes it sends, on average, after a reward
than before it.

Neuroscientists use these kinds of averaging for good reasons. A
neuron typically emits just a few spikes around significant events,
so only by averaging over many repeats of a tone, reward or movement
can we have enough spikes to pull the signal out and see what event
the neuron responds to most reliably. Neurons also typically emit
different numbers of spikes to the same event, so only by averaging
over many repeats of the same event can we seemingly extract the
reliable signal the neuron uses to encode it. Averaging undoubtedly
helps us to wrap our heads around the complexity of the brain's
activity; we even use the average response of neurons as the starting
point for some of our most sophisticated analyses of population
activity, such as the many variants of principal component analysis.

But neurons don't take averages. All a neuron gets to work with is
the moment-to-moment spikes sent by its inputs. Those inputs carry
few, if any, spikes. Each input likely varies its response to the
same significant event. Averaging over time hides what a neuron
actually sees, what it actually gets to compute with.

T

he way averaging hides the actual moment-to-moment signals of neurons
becomes a problem when we consider how much deep theory is based on
averaged neural activity. A striking example is the theory for how
neurons represent evidence used to make decisions. The theory says
there exist cortical neurons, especially those in the lateral
intraparietal area, that act as evidence accumulators, ramping up
their spiking in proportion to how much incoming sensory information
supports the option they represent. One option wins out when this
ramping activity reaches a threshold.

This theory was based on a body of work that looked at recordings
from individual cortical neurons as monkeys watched dots moving
randomly on a screen and reported if the majority were moving left or
right. Cortical neurons that favored, say, the leftward option
increased their spiking when the majority of dots were moving left.
They ramped up their activity in proportion to the ramping up of
evidence for their option, looking just like they were accumulating
that evidence. The problem, of course, is that these ramps were
averages: averaged over trials and averaged over neurons.

When researchers used more advanced statistical tools to take a
closer look at single cortical neurons, they found that most didn't
ramp their activity while the dots were moving: Some increased their
activity at seemingly arbitrary moments; others seemed to decrease
their activity, even though the dots were moving in those neurons'
apparently preferred direction.

When some of the same team took a closer look at single trials of the
moving dots, they reported that even the neurons that did increase
their activity seemed to step up their activity at some point while
the monkeys were dot-watching, not gradually increase it. With just a
handful of spikes on each trial, distinguishing a step from a ramp in
spiking requires some fancy computational models that try to infer
the underlying implied firing rate. An argument raged back and forth
about how well we can tell during a single trial if a single neuron
steps rather than gradually increases its spikes.

The final answer eludes us: On single trials, some neurons' spikes
seem more step-like, other neurons' spikes more ramp-like. But
irrespective of how many neurons increased their rates or how many
stepped or ramped in single trials, the problem of averaging is
clear: Many single neurons do not look like the average "ramping"
response and do not fit theory based on it.

Does that matter? After all, if the aggregate signal across those
cortical neurons in the current moment is accumulating evidence, then
maybe that's enough. Maybe that's all the brain cares about. The
problem is that we don't know.

Whenever most of us average neural activity over trials, over neurons
or both, we are implicitly assuming that the resulting signal is what
the rest of the brain sees. We're hoping that all the variation of
individual neurons is distributed across the whole population of
neurons in such a way that their aggregate moment-to-moment signal is
approximately the same as the signal we get by averaging the output
of each neuron.

It's weird that we don't know if this assumption is true. Averaging
is ubiquitous, central to our tools and part of the language. But we
also know in our hearts that it is a matter of convenience, an easier
way to think about the brain. Indeed, averaging spikes may just be an
accident of history rather than a rational approach to understanding
the brain, an artifact from the days when just getting a different
response from a neuron to lines of different orientations was an
amazing insight into how the brain worked. Before computer-generated
graphics existed, a simple histogram of a neuron's averaged response
was the simplest thing to draw.

We now have the tools we need to find out if averaging is showing us
something about the brain's signals or is a misleading historical
accident. With recordings of spikes from hundreds of neurons at the
same time, we can ask whether the aggregate moment-to-moment signal
of these neurons looks like the signal we get when we average over
trials, neurons or both. Then we will know quite how much averaging
is a convenient fiction of neuroscience, holding back our
understanding of the brain.

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tags:
neural coding, Electrophysiology, modelling, Neural dynamics

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