Single-Unit Recording and Action (1) Flashcards

1
Q

What is single-unit recording?

A
  • recording from single neurons using one or more microelectrodes
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2
Q

What are the safety concerns with using single-unit recording on humans?

A
  • highly invasive: requires direct access to brain (trauma to scalp and skull, infection risk, and brain tissue damage)
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3
Q

When would single-unit recording be used on humans?

A
  • if already entering the brain for medical reasons
  • if there is potential to address severe disability
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4
Q

What is the argument in favor of animal experiments?

A
  • it is always unacceptable because:
    1. it causes suffering
    2. benefits to humans are not proven
    3. human benefits could be produced in other ways
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5
Q

What is the argument against animal experiments?

A
  • it is always unacceptable because:
    1. it causes suffering
    2. benefits to humans are not proven
    3. human benefits could be produced in other ways
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6
Q

How is single-unit recording used to benefit quadriplegics

A
  • insert microelectrode arrays to left motor cortex (these detect neuron signals)
  • neuron signals pass to connectors attached to the skull
  • amplified signals are fed to a brain-machine interface which interprets them and passes on to arm
  • interface operates robotic arm
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7
Q

What types of recordings are there?

A
  • intracellular: voltage clamp, patch clamp
  • extracellular: single-unit recording, multi-electrode recording, field potentials
  • in vivo (or in vitro)
  • awake (or anaesthetized)
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8
Q

How is the spatial and temporal resolution?

A
  • very good!
  • individual action potentials in individual neurons
  • can’t get better than this
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9
Q

What are the challenges of single-unit recording?

A
  • How to find the “right” neurons
  • How does this neuron relate to the other 100 billion (what is the rest of the brain doing)
  • Do unexpected results mean that you are wrong or recording from the wrong neurons?
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10
Q

What type of electrodes and set-up is possible?

A
  • single electrode, 4 electrodes (tetrode) or multiple, or array
  • electrode can be connected to animal, feed up through a commutator that rotates
  • this allows animal to walk around
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11
Q

What happens to data after it enters the electrode?

A
  • amplify/filter
  • analogue-to-digital conversion
  • data storage
  • visualized as spike clustering
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12
Q

What are electrode tips made of?

A
  • platinum/tungsten
  • quartz glass (longer)
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13
Q

What does an implanted tetrode actually record?

A
  • tetrode will record from multiple neurons that are physically near to it
  • similarly, the signal of one neuron is likely detected by more than one electrode
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14
Q

What can the layout of multi-electrode recording look like?

A
  • array of 8 electrodes in a row at different depths
  • spread out horizontally and vertically
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15
Q

What is used to identify “units”? Why is this needed?

A
  • methods such as clustering are using to identify distinct units (hopefully individual neurons)
  • because multiple neurons recorded by electrode and single neuron may be recorded by multiple electrodes
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16
Q

What is depicted on a raster plot w/ histogram?

A
  • data from a single unit over many trials
  • indicates when conditioned stimulus is presented and when response occurred
  • trials are lined up on some time point
17
Q

What experiment was conducted to examine working memory and DLPFC?

A
  • oculomotor delayed response task with monkeys
  • monkey stares at fixation point
  • a cue appears
  • the cue disappears, the fixation point disappears and then the monkey must move it’s eyes to the cue
18
Q

What was found while examining working memory and DLPFC?

A
  • firing of some neurons at cue
  • firing of some neurons during delay
  • firing of some neurons during action
  • indicates the DLPFC maintains information and working memory
19
Q

What did responses of a single neuron reveal (for working memory and DLPFC experiment)?

A
  • individual rastors with three lines each that indicate: cue, cue leaves and response
  • this neuron fires during the delay period but only when the cue is at the bottom position
20
Q

What is a spatial tuning curve?

A
  • representation of when a neuron fires by examining all directions and firing rates
21
Q

What happens if you affect a neuron with a spatial tuning curve by lesion?

A
  • the monkey will no longer be able to remember when the cue is at the bottom
22
Q

What is cognitive map theory? What cells are needed for this?

A
  • memory for spatial relationships in environment
  • map for a specific neuron
  • place cells: fire when animal is in a particular location
23
Q

How was cognitive map theory studied?

A
  • camera facing down to keep track of where animal is
  • match up neuron firing and actual location of animal
24
Q

How was single-unit recording used to examine dopamine?

A
  • record from neuron that releases dopamine
25
Q

When did dopamine neurons fire?

A
  • if animal learns something new and you give it a reward: neurons fire
  • if sound a beep and give reward, then sound a beep: neurons fire
  • if sound a beep and no reward: neurons fire below threshold
26
Q

What does this tell us about dopamine neurons?

A
  • they signal to tell the animal when expectations are violated (good or bad)
  • record reward prediction error, not reward itself
  • often called reinforcement learning (used with AI)