Title: Multi-level Human Brain Modeling
1Multi-levelHuman Brain Modeling
- Jerome Swartz
- The Swartz Foundation
Rancho Santa Fe 9/30/06
2Multi-level Brain Modeling
- Everyone agrees there ARE multiple levels of
description - Science IS modeling
- Science is intrinsically multi-level in nature
(e.g. neurons behavior genes disease atoms
molecules etc.) - Understanding how the brain works means modeling
the dynamics of multi-level Information flow (not
so easy!) - Defining the Information processed by each brain
element at each Level is essential - Dynamic brain modelingwill increasingly suffer
- from Information overload
Successful Modeling
New Dynamics Phenomena
New Measurements
3Brain Research Must Be Multi-level
- Brains are active and multi-scale/multi-level
- The dominant multi-level model the computers
physical/ logical hierarchy (viz OSI computer
stack multi-level description) - Scientific collaboration is needed
- Across spatial scales
- Across time scales
- Across measurement techniques
- Across models
- Current field borders should not remain
boundaries Curtail Scale Chauvinism!
4Level Chauvinism is Endemic
- Dirac on discovering the positron the rest is
chemistry molecular structure is an
epiphenomenon! - Systems neuroscience neural networks the
molecular level is implementational detail
neural oscillations are epiphenomena - Genetics/Evolutionary Psychology genetic basis
for behavior - Cognitive Psychology largely ignores the brain
itself - Almost everyone quantum phenomena are irrelevant
to biology - To progress beyond this, we must ask if there are
any invariant mathematical principles underlying
biological multiple level interaction
5Multi-level Modeling Futures I
- To understand, both theoretically and
practically, how brains support behavior and
experience - To model brain / behavior dynamics as Active
requires - Better behavioral measures and modeling
- Better brain dynamic imaging / analysis
- Better joint brain / behavior analysis
- Todays (hardcore neurobiological) large scale
computational models do not (yet) explain
cognitive functions and complex behavior. Stay
tuned! - Circuit modelers mostly work on simple
physiological phenomena that dont directly
translate into behavioral performance - Theorists interested in cognition predominantly
use abstract mathematical models that are not
constrained by neurobiology
the next research frontiers
6Multi-level Modeling Futures II
- Microcircuit models of cognitive processes
(relating microscopic-to-macroscopic) to link the
biology of synapses and neurons to behavior
through network dynamics - Cognitive-type circuit models detailed enough to
account for neuronal data and high-level enough
to reproduce behavioral events correlated to EEG
and fMRI measurement and provide a unified
framework - Linear filter models are powerful for sensory
processing, but cognitive-type computations
involving nonlinear dynamical systems, multiple
attractors, bifurcations, etc., will play an
important role
7Multi-level Modeling Futures III
- How do top-down cognitive signals interact with
bottom-up external stimuli? How do signals flow
in a reciprocal loop between thalamocortical
sensory circuits and working memory/decision
circuits - Another challenge is to expand circuit modeling
to large-scale brain networks with interconnected
areas/modules
8Multi-level Open Questions I
- Is there a corresponding (comparable?) temporal
scale to our spatially-scaled Multi-level
description ? - At what time scales does Information flow between
levels (how fast up down?)? - Are local field synchronies multi-scale?
- Do local fields index shape synchronicity?
- Are there any direct relationships between these
processes and nonconscious/conscious mental
processing. e.g. Aha!/eureka REST
selective attention decision-making problem
solving etc.
9Multi-level Open Questions II
- How does Information cross spatial scales?
- Up
- Spike decision ramp-to-threshold
- Stochastic resonance?
- Avalanche behavior?
- Within between area synchronization avalanches?
- Down
- Synaptic reshaping
- Frequency nesting
- Ephaptic and neuromodulator influences
10Information Flow in the Levels-hierarchy
Organisms
behavior
Neurons
boundary condition
emergence
spikes
Membrane Protein Complexes
conformational changes
Macromolecules
11Human Multi-level (Brain Stack) Framework
Level
Components
Additional Description
Spatial Scale
(MM million)
Social Neuroscience (Neuro-anthropology)
mn (manymany) Global/Nation-States
Evolution-driven
Socio-Political (Geographical/Cyber)
1n (onemany) Regional/cities
km-MMm
Evolution/macro-plasticity
Human Interaction (Physical/Electronic)
11 (oneone) mirror neurons
Human Behavioral Levels
Evolution-driver
dm-MMm
Macroscopic
Emotion Language Decision making (Thin/thick
slices) Attention/awareness Sleep/awake
1self
Conscious sublevel (presentation sublevel)
Cognitive/ Psychological (Whole Brain)
Emotional/Rational/ Innerthought
1 m
Unconscious processing
Cortical hemispheres Cerebral cortex (ACC,PFC,
etc.) Thalamus/sensory afferents Hippocampus-worki
ng memory Sensorimotor system
Neurophysiological (Anatomical maps)
Network of Networks/CNS
1cm-dm
Information-Theoretic/System Levels
(1k neuron) Mini-columns Neo-cortical columns
(10-100k) Synfire chains
Mesoscopic
Network
Communication/System sublevels
1cm-dm
Cortical microcircuits Thalamocortical circuits
Circuit
Macrodynamics
1mm-cm
Interneuronal sublevel Synaptic/axonal/dendritic M
yelination/ganglia
Neuronal Synaptic
Cellular microdynamic level Spike time dependent
plasticity/Learning
1 µ -100 µ
Microscopic
Physical/Coding Levels
Neuromodulators Proteins Amino Acids
Neurogenetic sublevel Physical/coding sublevel
1 Ã…
Molecular
Closed System Interconnect Model