Lecture 7 Flashcards

Question 1

Q

What is a steady state response?

Answer

A

A response that has a steady amplitude and phase relationship to the stimulus
The stimulus response is on the whole time (unlike ABR, which is a transient response)
Looking at an ongoing response to a stimulus (an amplitude modulated sound)

Question 2

Q

Sometimes, all steady state responses are referred to as ____

Answer

A

Frequency following responses

Question 3

Q

What are 5 examples of steady state responses?

Answer

A

the cochlear microphonic
frequency-following responses
envelope-following responses
steady-state evoked potentials
the auditory steady-state response

Question 4

Q

Explain speech evoked responses

Answer

A

Speech also has fluctuations
Can hear the same activity going on in the brain that is in the original sound
SSRs are encoding the fluctuations that are happening in the actual sound (our brains follow the frequencies of the signal)

Question 5

Q

What is the maximum firing rate of a neuron?

Answer

A

The response gives out at 1500-2000Hz (mostly a low frequency response)
Neurons can only fire a maximum time/second

Question 6

Q

How do we look at a bunch of neurons?

Answer

A

The volley principle

Question 7

Q

Who started the work with steady state far field potentials?

Answer

A

David Regan was the first to do detailed steady-state work with scalp (far-field) potentials in the visual system
Director of the center for research in vision and hearing

Question 8

Q

What type of response is an ABR? Explain.

Answer

A

Transient: happens once after a stimulus (looking at what happens after the transient response is played)
Transient responses are triggered by an event (ABR by envelope of click or tone burst)
Once transient responses are started, they do their own thing (ABR is path up the brainstem)

Question 9

Q

What is a transient response looking at?

Answer

A

Looking at what happens after the transient response is played
Looking at travel time
Get an ABR triggered at a certain point

Question 10

Q

What do steady state responses follow?

Answer

A

Steady-state responses follow the stimulus (i.e., they have a constant amplitude and phase relationship to the stimulus)
You are getting a response that looks like the stimulus (the tone is steady and the response fluctuates with the stimulus)
Ongoing response to an ongoing stimulus

Question 11

Q

What is more difficult to determine with a steady state response?

Answer

A

More difficult to determine the timing (hard to determine where it began because there is always some delay between stimulus and response)
Whereas with ABR, timing is very important

Question 12

Q

Explain the path of a sound wave

Answer

A

In the air, we have longitudinal waves of compression (air particles pushed together) and rarefaction
As speaker diaphragm pulls back, low pressure wave approaches the ear drum, eventually pulls it out (rarefaction)
The auditory system is physically moving in motion with the sound

Question 13

Q

Explain the temporal coding of sound

Answer

A

Light green: basilar membrane pulled upwards (rarefaction)
- Tip links are stretched,
- Ion channels open

Dark green: basilar membrane pushed downwards (condensation)
- Tip links are loose
- Ion channels closed

Question 14

Q

Firing rate synchronizes with ____

Answer

A

Hair cell movement

Question 15

Q

What is the receptor potential?

Answer

A

Receptor potential: measure the potential in the IHC (receptor potential fluctuates as the cilia move back and forth)
Not a sinusoidal fluctuations and is somewhat displaced on the axis (as the tip links open you have a larger change in receptor potential than when they shut)

Question 16

Q

Receptor potentials follow the ____

Question 17

Q

How fast do the hair cells go?
- Where do you see DC potential?
- What is the DC shift?
- What is the AC shift?
- Where does the RP get smaller?

Answer

A

Start to see a DC potential at higher stimulus (less of what is going on is following the stimulus as you increase in frequency)
The DC shift is the sustained portion
The AC portion is the steady state portion (the portion fluctuating with the stimulus)
Receptor potentials get smaller at high frequencies but is still there

Question 18

Q

What is phase locking?

Answer

A

Tendency for the AN to fire at a certain phase

Question 19

Q

Explain AN rate coding and phase-locking at low frequencies

Answer

A

At LFs, the AN may fire at phases of the signal (the same timing)
The nerve has the tendency to fire at certain times (phase locking)
There is rate and phase locking happening

Question 20

Q

Explain AN rate coding and phase-locking at high frequencies

Answer

A

Phase locking breaks down at high frequencies (neurons can’t fire that fast, and there is some jitter with each firing)
Very hard to track high frequency signals
Only rate coding happening (no phase locking)

Question 21

Q

Inner Hair Cells connect to ____ Type I SG Fibres

Question 22

Q

What is the volley principle?

Answer

A

The central auditory system ‘listens’ to many neurons, so individual neurons do not need to fire on every cycle
All the neurons can’t fire every time, but enough of them will (will get a good representation of the AN)

Question 23

Q

What happens as the IHCs move back and forth? When are individual neurons more likely to fire?

Answer

A

As this hair cell moves back and forth, we will get a receptor potential that fluctuates (not a pretty sinusoid, more depolarization than hyperpolarization)
Individual neurons are more likely to fire when ion channels open

Question 24

Q

What are period histograms?

Answer

A

AN firing follows waveforms very precisely
Depolarization = the AN fires
Hyperpolarization = the AN isn’t firing

Question 25

Q

What is half wave rectification?

Answer

A

Half wave rectification = the AN doesn’t fire during hyperpolarization
This distorts the signal

Question 26

Q

Phase-locking in the AN vs CN

Answer

A

Phase-locking is more precise in the cochlear nucleus (e.g., bushy cells) than in the auditory nerve
A much cleaner representation of the frequency (more precise in the brainstem)
Why? Each AN fiber isn’t that precise, but when they work together, they are very precise

Question 27

Q

What is a frequency following response? Where does this response get better?

Answer

A

A response that follows the frequency
The response gets better as you go farther up the brainstem
A far-field (scalp) electrophysiologic response that has the same frequency components as the stimulus

Question 28

Q

Where is a FFR coming from?

Answer

A

Research suggests sources in the midbrain (IC), but there are likely contributions from the cortex (for very low frequencies), and of course, from the lower brainstem and auditory nerve

Question 29

Q

Can FFR be used to test hearing directly?

Answer

A

Unfortunately can’t be recorded near threshold (and high-levels are less place-specific)
You need fairly high levels and low frequency to get a good FFR (70 dB)
At softer levels, you will not get a good FFR

Question 30

Q

What is the highest synchronization of the cochlea?

Question 31

Q

What is the highest synchronization of the brainstem?

Question 32

Q

What is the highest synchronization of the cortex?

Answer

A

0.3kHz (but typically up to 40Hz)

Question 33

Q

What do we do about artifact and the CM with FFR?

Answer

A

Because the response looks just like the stimulus, it is hard to separate from artifact (because artifact looks just like the stimulus too)
We usually combat these by recording to alternate polarities, and averaging an even number of trials

Question 34

Q

What does alternating polarity do to the FFR?

Answer

A

Stimulus is not perfectly rectified in IHC transduction (since AN is hyperpolarized during condensation phase)
Alternating polarity should almost eliminate FFR, and double the frequency of residual activity
It’s going to fire in one half of the cycle, but not the other half (you get a smaller version of the signal at twice the frequency of the stimulus)

Question 35

Q

How useful are FFRs?

Answer

A

FFRs to the components in the stimulus spectrum have limited utility for audiology (discovered before ABR, but less useful; less useful clinically)

Question 36

Q

What are 4 cons to FFR?

Answer

A

Only reflect encoding of low frequency information
Easily confused with stimulus artefact and the cochlear microphonic
Alternating polarity eliminates artefact and CM, but also distorts the FFR
Can only get super well at high levels

Question 37

Q

What is a brilliant alternative to the FFR?

Answer

A

The auditory steady state response (ASSR)
This is a clinically useful alternative to the FFR (a clever way of getting the response that doesn’t have all the issues of the FFR)

Question 38

Q

How were SSRs discovered?

Answer

A

Galambos (1981) discovered that presenting stimuli at 40 Hz produced a large steady-state response (not 40 Hz tones, but higher frequency tones presented 40 times per second)
Presented a high frequency sound (2K) at 40 times per second (found that the response had a 40Hz shape)

Question 39

Q

What are SSRs similar too?

Answer

A

Steady state responses may be similar to transient responses… it may be a series of them, just overlapped.

Question 40

Q

Cortical columns synchronize very well at ____Hz

Question 41

Q

Why was the birth or SSRs important?

Answer

A

You could elicit the transient response (ABR/MLR) with a tone burst at any frequency (e.g. 4 kHz) – wouldn’t get an FFR at 4K, too high
Therefore, you could elicit a 40 Hz response with repeated tone bursts at any stimulus frequency
FFR frequency limit is not an issue

Question 42

Q

A x kHz tone burst, presented 40 times per second creates…

Answer

A

Displacement primarily at the x kHz cf. of the cochlea
- The STIMULUS frequency (carrier)
Which is reflected in a 40 Hz response
- The PRESENTATION RATE
A 2000Hz tone burst will go to the 2000Hz characteristic frequency of the cochlea (carrier frequency)
What we are looking for from the brain is the presentation rate (40Hz) – you will also see it at the harmonics of that

Question 43

Q

FFR vs ASSR

Answer

A

FFR
- Follow the frequency of the stimulus (a continuous 500 Hz tone = a small 500 Hz response)

SSR
- Follow the presentation rate or the “envelope” (the turning on/off or up/down of a stimulus)
- Not following the frequency, but the presentation rate (how many times you present)

Question 44

Q

500Hz played 40 times per second gives you…

Answer

A

500Hz FFR
40Hz ASSR

Question 45

Q

What is another name for a SSR?

Answer

A

Envelope following response (EFR)

Question 46

Q

Repetition rate vs. modulation rate
- what is ASSR a response too?

Answer

A

Amplitude modulating (turning up and down) is the same as turning on and off
The ASSR is a response to the modulation rate (i.e., the envelope) or repetition rate of a stimulus… these are all the same thing
Modulation rate = envelope rate = presentation rate

Question 47

Q

Why is 40Hz SSR used?

Answer

A

Works best for infants

Question 48

Q

Noise floor goes down with increase in ____

Answer

A

Frequency

Question 49

Q

The ____ doesn’t lock well at high frequencies, but the ____ does

Answer

A

Cortex, brainstem

Question 50

Q

The cortex only locks good up to ____Hz (above this, they get smaller and you are looking at ____ responses)

Answer

A

40, brainstem

Question 51

Q

____ can be the carrier

Answer

A

Any frequency

Question 52

Q

With ASSR, the response is not to the ____, but to the ____

Answer

A

Stimulus frequency, modulation (envelope or presentation rate)

Question 53

Q

How do you make an amplitude modulated stimulus?

Answer

A

Present a short stimulus over and over again at a specific rate
- The stimulus is called the ‘carrier’ and the presentation rate is the ‘envelope’
Turn a stimulus up and down at a specific rate
- This is done by combining multiple tones
- The tones are the ‘carrier’ and the modulation rate is the ‘envelope’

Question 54

Q

What happens when two tones are presented (carrier vs modulation)?

Answer

A

130 and 140 Hz
- 130 will have 13 peaks
- 140 will have 14 peaks
- Go up and down 10 times a second because they are separated by 10Hz (it will beat at the difference frequency)
- In 100 ms (1/10th of a s), one has 13 cycles, and one has 14
These will create maximal displacement in the 130 and 140 Hz places in the cochlea
But they fall within the same critical band, so the tones will interact, creating an amplitude modulation at 10 Hz
This is a temporal pattern (a 10 Hz amplitude modulation) occurring in the 130-140 Hz region (the carrier frequencies)
e.g., 130 Hz and 140 Hz will beat at 10 Hz, but there is no 10 Hz ‘tone’—130 and 140 Hz are the only two frequencies present
The 10 Hz envelope isn’t part of the stimulus, it’s what arises when the stimulus components add together in the ear
The modulation rate doesn’t affect where it goes on the basilar membrane (the 10Hz isn’t really there but the auditory system feels it there, that is just where it is beating)

Question 55

Q

120 and 140 will fluctuate at ____Hz

Answer

A

20 Hz (it beats at that part of the cochlea 20x per second)

Question 56

Q

What introduces the envelope frequency into the nervous system?

Answer

A

Nonlinearities in cochlear movement and in inner hair cell transduction

Question 57

Q

The tones have to be fairly close to ____

Answer

A

Beat together

Question 58

Q

What happens when we use 3 tones?

Answer

A

Sinusoidal amplitude modulation (SAM)
Just like a beat, except there is one tone above and below the carrier frequency (each at half amplitude of center component)
480+500+520 is a 500 Hz tone that is modulated at 20 Hz
Carrier = 500 Hz
Modulation = 20 Hz (getting a SSR at 20Hz)
Will also see a beat at 40Hz (diff between 480 and 520)
Will also get an FFR at the frequencies
Will also see a beat at the harmonics
All of the sound energy is at 480, 500 and 520 (a FFR could be recorded at these frequencies)
an ASSR will be recorded at 20 Hz

Question 59

Q

What is so good about SAM?

Answer

A

Carrier frequency determines where on BM (what frequencies are being tested) e.g., 500 or 4000 Hz
Modulation frequency/rate is the frequency that we record at the scalp
A sinusoidal modulation gives us a bigger response (modulation goes up and down a little sharper)

Question 60

Q

an amplitude modulation that occurs when ____

Answer

A

Tones interact

Question 61

Q

Explain playing 1008, 1082, and 934Hz

Answer

A

Its 3 steady pure tones, the combination goes up and down 76 times per second (that’s the difference between the tones) because they add together in your ear
Its like turning 1008Hz up and down 76 times per second
The sum of the components is modulated (the sum isn’t present in the signal, it is just 3 tones)

Question 62

Q

The carrier frequency is the ____

Answer

A

Frequency of the tone itself

Question 63

Q

The modulation frequency is the ____

Answer

A

Difference between the tones

Question 64

Q

Why is ASSR better than FFR?
- no problem with what?
- where are responses larger?
- how does artifact affect them?

Answer

A

No problem with the 1500 Hz limit in the brainstem
Responses are larger at low frequencies (this is where the brain loves to time lock)
Easy to separate from artefact!

Answer 60

A

These non-linearities induce energy at the modulation frequency (when they overlap on the basilar membrane)
Because of the distortion that the ear is doing

Answer 61

A

Tone bursts
Beats
SAM
SIN3

Answer 62

A

There is a lot of splatter with each tone burst

Answer 63

A

A beat is very focused in frequency, but has a very small response

Answer 64

A

SAM (3 tones) gives a larger response, but is less focused in frequency

Answer 65

A

SIN^3 gives a larger response, but is less focused in frequency

Answer 66

A

Response, frequency

Answer 67

A

Frequency focused, response

Answer 68

A

SIN3 or tone bursts (poor frequency focused)

Answer 69

A

Beats (highly frequency focused)

Answer 70

A

Tone bursts or SIN3

Answer 71

A

AM Rate (or Frequency)
- “80 Hz AM”
AM Depth
- 100% AM (signal goes completely off an on) – this is what we use for thresholds
- 50% AM (signal goes to half its amplitude) – diagnostic measure
Shape of modulation
- Exponential (rises and falls more quickly)
- Sinusoidal (rises and falls smoothly)

Answer 72

A

FM Rate (or Frequency)
- “80 Hz FM” (it goes up and down in FREQUENCY 100 times/sec)
FM Depth
- 10% FM (signal goes up and down in frequency by 10%)
- A larger depth gives a bigger response

Answer 73

A

Both AM and FM
- Mixed = AM and FM at same rate
- IAFM = independent AM and FM (different rates)
Described by
- AM Rate /Frequency
- AM Depth
- FM Rate /Frequency
- FM Depth

Answer 74

A

Sound goes in
Activation at 1kHz region of the basilar membrane
SSR at 81Hz
If we get 81Hz it tells us that they encoded 1kHz

Answer 75

A

Brainstem and cortex

Answer 76

A

Mostly brainstem (loss of what is coming from the cortex)
Once you go above 40 Hz, the cortex isn’t involved very much

Answer 77

A

a) Carrier = 500 Hz
b) Modulation rate = 80 Hz
c) FFR at 420, 500, 580 Hz
d) ASSR at 80 Hz
e) Primary source brainstem
f) Slow the modulation rate (460, 500, 440 Hz) – modulation rate around 40Hz (from cortex and brainstem)

Answer 78

A

40 Hz response
- Unreliable in infants
- Smaller in sleep

80 Hz
- Reliable in infants
- About ½ or third size of adult in first few months
- No significant changes afterwards
- Not affected by sleep

Answer 79

A

Amplitude decreases
Latency increases

Answer 80

A

4 stimuli presented simultaneously to one ear
All modulated at a slightly different rate
You know have different modulation frequencies in the brain response so you can test them at the same time

Answer 81

A

4 stimuli to the left ear and 4 stimuli to the right ear
Can also test both ears at the same time (but use different modulation frequencies in the ears)

Answer 82

A

This is only true at soft levels (< 60 dB)
At high levels, the tones interact on the basilar membrane, and the 4 or 8 frequency response is less than the individual responses
They start to overlap on the basilar membrane at high levels

Answer 83

A

Peaks measured from the averaged brain waveform (after averaging the response many many times in a very short window)

Answer 84

A

Frequencies measured from the averaged brain waveform
Since we’re looking at frequencies, we need to record a longer time window… why? Better frequency resolution

Answer 85

A

Frequency resolution is equal to 1/T, where T is the length of the time window, in seconds
- 1 second time window = 1/1 = 1 Hz resolution (80 from 81)
- 2 second time window = ½ = .5 Hz resolution (80 from 80.5 and 79.5)
- 10 second time window = 1/10 = .1 Hz resolution

Answer 86

A

Interstimulus interval (75ms for 13.3s)
Recording window (10ms)
Click (100us)
Average = 2000 clicks (about 150s or 2.5min)

Answer 87

A

Epoch length (1s for rejecting noisy epochs)
Sweep length (16s; 1/16Hz)
Modulated tone(s) on the entire time
Average = 10 sweeps (160s or 2.6min)

Answer 88

A

Averaging (noise decreases with more averaging)
Improving frequency resolution (noise decreases with more bins)

Answer 89

A

How long you record

Consider switching from 240 one-second to 80 three-second averages
Improved resolution decreases noise in each bin to 58%
Decreased number of averages increases noise in each bin by 73%
i.e., they cancel: .58 ×1.73=1

Answer 90

A

Short sweeps 15 frequencies (-7 & + 7) vs long sweeps 120 frequencies (-60 & + 60)
Noise is random, so should be distributed across many frequencies
What determines how wide the frequency resolution is? The length of the sweep that is analyzed. Longer sweeps, more narrow frequencies.
Direct trade-off between length of sweep (frequency width) and number of averages

Answer 91

A

Accurate recording: 6-7 minutes (asymptotes after this)
Fast recording: 3.5 minutes

Answer 92

A

Averaging

Answer 93

A

High frequencies (low frequencies are harder to test)

Answer 94

A

SNR = response level (corrected) / noise level

Answer 95

A

Response occurs at a known frequency
Noise is usually average level in adjacent frequency ‘bins’
Typically, the noise level is the area with no stimulus

Answer 96

A

Hotelling’s T2 test
F test

Answer 97

A

If a response is related to the stimulus, there should be a relatively consistent phase lag between the two
If a response is not related to a stimulus, the phase relationship should be random
Plot the 95% confidence interval of the mean

Answer 98

A

F test for hidden periodicity
F is a ratio of variances (or power)… both are mean-squared values
Power of response at modulation frequency to average power of response in adjacent frequency bins

Answer 99

A

F test is equivalent to the T2 test when you have one more adjacent frequency bin than the number of T2 data points
They are the same

Answer 100

A

Found BC ASSR thresholds to be lower (better) in infants than adults
Use age-specific normative thresholds

Answer 101

A

Use alternating polarity
Use sharp anti-aliasing filters (to reject the noise) – remember, we only need to record frequencies < 100 Hz, so the LP filter can be placed above this

Answer 102

A

High correlations between thresholds were found (higher correlation in the high frequencies)
Especially high correlations in the high frequencies
On average, less time needed for ASSR (can get more frequencies faster)

Answer 103

A

Stimulus modulation

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Lecture 7 Flashcards

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