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Abstract If we assume that neuronal activity encodes a probabilistic representation of the world that optimizes free- energy in a Bayesian fashion, then.

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Presentation on theme: "Abstract If we assume that neuronal activity encodes a probabilistic representation of the world that optimizes free- energy in a Bayesian fashion, then."— Presentation transcript:

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2 Abstract If we assume that neuronal activity encodes a probabilistic representation of the world that optimizes free- energy in a Bayesian fashion, then this optimization can be regarded as evidence accumulation or (generalized) predictive coding. Crucially, both predictions about the state of the world generating sensory data and the precision of (confidence in) those data have to be optimized. In other words, we have to make predictions (test hypotheses) about the content of the sensorium and predict our confidence in those hypotheses. I hope to demonstrate the metacognitive aspect of this inference using simulations of action observation and sensory attenuation - to illustrate the nature of active inference and elucidate the computational anatomy of psychosis. The computational anatomy of psychosis Karl Friston Opening Symposium of the Translational Neuromodeling Unit Zurich, 18-20 September 2013

3 “Objects are always imagined as being present in the field of vision as would have to be there in order to produce the same impression on the nervous mechanism” - von Helmholtz Thomas Bayes Geoffrey Hinton Richard Feynman From the Helmholtz machine to the Bayesian brain and self-organization Richard Gregory Hermann von Helmholtz Ross Ashby

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5 Self organisation and Hamilton’s principle of least action The calculus of variations and the enigma of the brain: or how do we resist the second law of thermodynamics? Ergodic theorem surprisedivergence entropyenergy (precise) prediction error complexity …we minimise variational free energy or prediction error

6 How can we minimize free energy (prediction error)? Change sensations sensations – predictions Prediction error Change predictions Action Perception

7 Active inference, predictive coding and precision Precision and false inference Simulations of : Auditory perception (and omission related responses) Handwriting (and action observation) Smooth pursuit eye movements (under occlusion) Sensory attenuation (and the force matching illusion)

8 A simple hierarchy Generative models and predictions whatwhere Sensory fluctuations

9 Generative model Model inversion (inference) A simple hierarchy Expectations: Predictions: Prediction errors: Descending predictions Descending predictions Ascending prediction errors From models to perception

10 frontal eye fields geniculate visual cortex retinal input pons oculomotor signals Prediction error (superficial pyramidal cells) Conditional predictions (deep pyramidal cells) Top-down or backward predictions Bottom-up or forward prediction error proprioceptive input reflex arc Perception VTA David Mumford Predictive coding with reflexes Action Precision

11 Prediction error can be reduced by changing predictions (perception) Prediction error can be reduced by changing sensations (action) Perception entails recurrent message passing in the brain to optimize predictions Action fulfils descending predictions Both perception (attention) and action (affordance) rest on optimizing precision Precision contextualizes prediction errors though neuromodulatory gain control

12 + - De-compensation (trait abnormalities) Compensation (to psychotic state) Neuromodulatory failure (of sensory attenuation) Attenuated violation responses Loss of perceptual Gestalt SPEM abnormalities Psychomotor poverty Resistance to illusions Hallucinations Delusions

13 Active inference, predictive coding and precision Precision and false inference Simulations of : Auditory perception (and omission related responses) Handwriting (and action observation) Smooth pursuit eye movements (under occlusion) Sensory attenuation (and the force matching illusion)

14 Generative process (and model) Syrinx Neuronal hierarchy Time (sec) Frequency (KHz) sonogram 0.511.5 Frequency (Hz) percept prediction error Model inversion 500100015002000 -6 -4 -2 0 2 4 6 8 10 peristimulus time (ms) LFP ( micro-volts )

15 Reduced precision at second level Compensatory reduction of sensory precision Omission related responses, MMN and hallucinosis

16 Active inference, predictive coding and precision Precision and false inference Simulations of : Auditory perception (and omission related responses) Handwriting (and action observation) Smooth pursuit eye movements (under occlusion) Sensory attenuation (and the force matching illusion)

17 00.20.40.60.811.21.4 0.4 0.6 0.8 1 1.2 1.4 action position (x) position (y) 00.20.40.60.811.21.4 observation position (x) Heteroclinic cycle (central pattern generator) Descending proprioceptive predictions Descending proprioceptive predictions Action and agency

18 retinal input pons oculomotor signals proprioceptive input reflex arc Angular position of target in intrinsic coordinates Angular direction of gaze in extrinsic coordinates Angular direction of target in extrinsic coordinates time visual channels Generative processGenerative model Smooth pursuit eye movements

19 eye (reduced precision) 50010001500200025003000 -2 0 1 2 Angular position displacement (degrees) 50010001500200025003000 -20 -10 0 10 20 30 40 50 time (ms) velocity (degrees per second) Angular velocity eye target Eye movements under occlusion – and reduced precision

20 1002003004005006007008009001000 -2 0 1 2 target and oculomotor angles time (ms) displacement (degrees) 1002003004005006007008009001000 -30 -20 -10 0 10 20 30 target and oculomotor velocities time (ms) velocity (degrees per second) eye (reduced precision) eye target Paradoxical responses to violations

21 Active inference, predictive coding and precision Precision and false inference Simulations of : Auditory perception (and omission related responses) Handwriting (and action observation) Smooth pursuit eye movements (under occlusion) Sensory attenuation (and the force matching illusion)

22 Generative process Generative model Making your own sensations

23 motor reflex arc thalamus sensorimotor cortex prefrontal cortex ascending prediction errors descending modulation descending predictions descending motor predictions descending sensory predictions

24 Self-made acts

25 and psychomotor poverty

26 102030405060 -0.5 0 0.5 1 1.5 2 hidden states Force matching illusion 102030405060 -0.5 0 0.5 1 1.5 2 prediction and error Time (bins) Sensory attenuation 102030405060 -0.5 0 0.5 1 1.5 hidden causes Time (bins) 102030405060 -0.5 0 0.5 1 1.5 Time (bins) perturbation and action Intrinsic and extrinsic

27 00.511.522.53 0 0.5 1 1.5 2 2.5 3 External (target) force Self-generated(matched) force External (target) force Self-generated(matched) force SimulatedEmpirical (Shergill et al) Failures of sensory attenuation, with compensatory increases in non-sensory precision Normal subjects Schizophrenic subjects

28 Failure of sensory attenuation and delusions of control? 102030405060 -0.5 0 0.5 1 1.5 2 2.5 3 3.5 prediction and error Time (bins) 102030405060 -0.5 0 0.5 1 1.5 2 2.5 3 3.5 hidden states Time (bins) 102030405060 -0.5 0 0.5 1 1.5 2 2.5 3 3.5 hidden causes Time (bins) 102030405060 -0.5 0 0.5 1 1.5 2 2.5 3 3.5 Time (bins) perturbation and action

29 + - Neuromodulatory failure (of sensory attenuation) Signs (of trait abnormalities) Attenuated violation responses Loss of perceptual Gestalt SPEM abnormalities Psychomotor poverty Resistance to illusions Symptoms (of the psychotic state) Hallucinations Delusions

30 Bleuler E. Dementia Praecox oder Gruppe der Schizophrenien, 1911: Disintegration – of conscious processing (the psyche) Wernicke C. Grundrisse der Psychiatrie. 1906: Sejunction – disruption of associative connectivity Anatomical disconnectionFunctional disconnection Dysconnection in schizophrenia: from abnormal synaptic plasticity to failures of self-monitoring. Schizophr Bull. 2009 May;35(3):509-27. Klaas E. Stephan, Karl J. Friston and Chris D. Frith

31 What is the functional deficit? What is the pathophysiology? How can we measure it? What is the aetiology? What is the therapeutic intervention? Summary and a Hilbert list for schizophrenia False inference due to aberrant encoding of precision A neuromodulatory failure of postsynaptic excitability: Aberrant DA/NMDAr subunit interactions Aberrant synchronous gain and fast (gamma) dynamics Aberrant cortical gain control and E-I (GABAergic) balance Aberrant dendritic integration (neuromorphology) Biophysical modelling of non-invasive brain responses dynamic casual modelling of recurrent inhibition …

32 V5 V1 IT PC Visual input Prefrontal input control subjects - predictable control subjects - unpredictable schizophrenia - predictable schizophrenia - unpredictable V1R V5L V5R ITL ITR PCL PC -2 -1.5 -0.5 0 0.5 1 1.5 cortical source log modulation Effects of predictability on recurrent inhibition control subjects schizophrenics Noa Fogelson et al., The functional anatomy of schizophrenia: a DCM study of predictive coding

33 Thank you And thanks to collaborators: Rick Adams Andre Bastos Sven Bestmann Harriet Brown Jean Daunizeau Mark Edwards Xiaosi Gu Lee Harrison Stefan Kiebel James Kilner Jérémie Mattout Rosalyn Moran Will Penny Lisa Quattrocki Knight Klaas Stephan And colleagues: Andy Clark Peter Dayan Jörn Diedrichsen Paul Fletcher Pascal Fries Geoffrey Hinton James Hopkins Jakob Hohwy Henry Kennedy Paul Verschure Florentin Wörgötter And many others

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