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Contrast Dependant Center Surround Interactions in Area V4

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Presentation on theme: "Contrast Dependant Center Surround Interactions in Area V4"— Presentation transcript:

1 Contrast Dependant Center Surround Interactions in Area V4
Kristy A Sundberg, Jude F Mitchell, John H Reynolds

2 Center Surround Receptive Field Organization
RF Center Surround region

3 Stimulus

4 V4 Example Cells Center alone Firing rate Firing rate % Contrast
30 20 Center alone 20 Firing rate Firing rate 10 10 20 1 10 85 1 10 85 % Contrast % Contrast

5 V4 Example Cells Response Gain
1 10 85 20 30 20 Center alone Firing rate Firing rate 10 20 Center + Surround 1 10 85 % Contrast % Contrast

6 V4 Example Cells Contrast Gain
Firing rate 1 10 85 20 30 % Contrast 1 10 85 20 % Contrast Center alone Center + Surround

7 Does response and contrast gain reflect different classes of cells?

8 Does response and contrast gain reflect different classes of cells?
The same neuron can show both patterns. Contrast Gain Response gain Firing rate 1 10 85 20 30 % Contrast 1 10 85 20 30 Center alone Center alone Center + 20% Surround 20 Center + 85% Surround % Contrast

9 Simple divisive normalization model
+ - Add refs

10 + - Simple divisive normalization model
Center stimulus excitation (Ecenter) + - Center stimulus inhibition (Icenter)

11 + - Simple divisive normalization model
Center stimulus excitation (Ecenter) + - Center stimulus inhibition (Icenter) Model response to center stimulus (Ecenter)/(Icenter+A)

12 + - Simple divisive normalization model
surround stimulus excitation (Esurround) + - surround stimulus inhibition (Isurround)

13 + - Simple divisive normalization model
surround stimulus excitation (Esurround) + - surround stimulus inhibition (Isurround) Model response to surround stimulus (Esurround)/(Isurround+A)

14 + - Simple divisive normalization model Model response to both stimuli
(Ecenter + Esurround)/ (Icenter+ Isurround + A)

15 Simple divisive normalization model
(Ecenter)/(Icenter+A) = center stimulus response 10 100 Ecenter Ec Icenter Ic

16 Simple divisive normalization model
(Ecenter)/(Icenter+A) = center stimulus response 10 100 Ecenter Ec Response to center stimulus Icenter Ic

17 Predictions of divisive normalization model
center stimulus response = (Ecenter)/(Icenter+A) Center alone Response 1 10 100 % Contrast

18 Predictions of divisive normalization model
Center + surround stimulus response = (Ecenter + Esurround)/ (Icenter+ Isurround + A) Weak Is (low contrast surround) Center + Surround Response 1 10 100 % Contrast

19 Predictions of divisive normalization model
Center + surround stimulus response = (Ecenter + Esurround)/ (Icenter+ Isurround + A) Weak Is (low contrast surround) Strong Is (high contrast surround) Center alone Response Center + Surround 1 10 100 1 10 100 % Contrast % Contrast

20 Predictions of divisive normalization model
Center + surround stimulus response = (Ecenter + Esurround)/ (Icenter+ Isurround + A) 10 1 100 % Contrast Response Strong Is (high contrast surround) Weak Is (low contrast surround)

21 The same neuron can show both patterns.
Firing rate 1 10 85 20 30 Center + 20% Surround Center alone 1 10 85 20 30 Center alone 20 Center + 85% Surround Weak Is (low contrast surround) Strong Is (high contrast surround) % Contrast Response 1 10 100 1 10 100 1 10 100 % Contrast % Contrast % Contrast

22 Summary Simple divisive normalization model can account for both response and contrast gain Relative strength of surround stimulus inhibitory input determines the pattern of suppression

23 V4 neurons can have peaked contrast response functions
20 50 Center alone Firing rate Firing rate 10 25 1 10 85 1 10 85 % Contrast % Contrast

24 Simple divisive normalization model
(Ecenter)/(Icenter+A) = center stimulus response 10 100 Ecenter Ec Response to center stimulus Icenter Ic

25 Prediction of divisive normalization model
(Ecenter)/(Icenter+A) = center stimulus response Center stimulus response Icenter Ecenter % Contrast

26 Prediction of divisive normalization model
(Ecenter)/(Icenter+A) = center stimulus response % Contrast Center stimulus response Ecenter Icenter Icenter Ecenter % Contrast

27 Conclusions Small gratings induce large surround modulations in V4
Surround suppression shows patterns of both response gain and contrast gain Simple divisive normalization model can account for both response and contrast gain Peaked contrast response functions are predicted when V4 inputs have saturating contrast response functions.

28 Thanks Go To C. Williams J. Reyes

29 Contrast Dependant Center Surround Interactions in Area V4
Kristy A Sundberg, Jude F Mitchell, John H Reynolds

30

31 90 90 90 80 80 80 70 70 70 60 60 60 50 50 50 40 40 40 30 30 30 20 20 20 10 10 10 10 -2 10 -1 10 10 -2 10 -1 10 10 -2 10 -1 10

32 Simple divisive normalization model (Ec+Es)/(Ic+Is+A) = V4 Response
Ec = excitatory input from center stimulus Ic = Inhibitory input from center stimulus Es = excitatory input from surround stimulus Is = inhibitory input from surround stimulus A = small constant leak term

33 Physiology

34 Simple divisive normalization model
(Ec)/(Ic+A) = V4 center stimulus response Ec Response to center stimulus Ic

35 Simple divisive normalization model
(Ec)/(Ic+A) = V4 center stimulus response Ec Response to center stimulus Ic

36 Stimulus

37 Stimulus

38 Stimulus

39 V4 neurons can have peaked contrast response functions
20 50 Firing rate Firing rate 10 25 1 10 85 1 10 85 % Contrast % Contrast

40 Response Gain Example Center alone Firing rate % Contrast 30 20 10 1
1 10 85 % Contrast

41 Response Gain Example Center alone Firing rate Center + 85% surround
1 10 85 20 30 Center alone Firing rate Center + 85% surround % Contrast

42 Response Gain Example Center alone Firing rate Center + 85% surround
1 10 85 20 30 Center alone Firing rate Center + 85% surround % Contrast

43 Response Gain Example Center alone 30 20 Firing rate 10
Center + 85% surround 1 10 85 % Contrast

44 Response Gain Example Center alone 30 20 Firing rate 10
Center + 85% surround 1 10 85 % Contrast

45 Contrast Gain Example Center alone 15 Firing rate 10 5 1 10 85
1 10 85 % Contrast

46 Contrast Gain Example Center alone 15 Firing rate 10 5
Center + 85% surround 1 10 85 % Contrast

47 Contrast Gain Example Center alone 15 Firing rate 10 5
Center + 85% surround 1 10 85 % Contrast

48 Summary- Part 1 Large surround modulation induced by small grating stimuli Surround suppression shows patterns of both response gain and contrast gain

49 + - Simple divisive normalization model
Center stimulus excitation (Ecenter) + - Center stimulus inhibition (Icenter)

50 + - Simple divisive normalization model
Center stimulus excitation (Ecenter) + - Model response to center stimulus (Ecenter)/(Icenter+A) Center stimulus inhibition (Icenter)

51 + - Simple divisive normalization model
Center stimulus excitation (Ecenter) + - Model response to center stimulus (Ecenter)/(Icenter+A) Center stimulus inhibition (Icenter)

52 surround stimulus excitation (Es) surround stimulus inhibition (Is)
Simple divisive normalization model surround stimulus excitation (Es) + - surround stimulus inhibition (Is)

53 surround stimulus excitation (Es) surround stimulus inhibition (Is)
Simple divisive normalization model surround stimulus excitation (Es) Model response to surround stimulus (Es)/(Is+A) + - surround stimulus inhibition (Is)

54 + - Simple divisive normalization model
Model response to both stimuli (Ec+Es)/(Ic+Is+A) + -

55 Predictions of divisive normalization model
(Ec)/(Ic+Is+A) = V4 Response Weak Is (low contrast surround) Response 1 10 100 % Contrast

56 The same neuron can show both patterns.
30 30 Center alone Center alone 20 20 Firing rate Firing rate 10 Center % surround 10 Center + 85% surround 1 10 85 1 10 85 % Contrast % Contrast Weak Is (low contrast surround) Strong Is (high contrast surround) % Contrast % Contrast % Contrast % Contrast

57 Simple divisive normalization model
(Ec)/(Ic+A) = V4 center stimulus response 10 100 Ec Ec Response to center stimulus Ic Ic

58 Summary Simple divisive normalization model predicts peaked contrast response functions when inhibitory input saturates at lower contrasts than excitatory input.

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