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Kevin Gurney, Mark Humphries, Rob Stewart Adaptive Behaviour Research Group

Spiking neuron models of the basal ganglia: dopaminergic modulation of selection and oscillatory properties. Kevin Gurney, Mark Humphries, Rob Stewart Adaptive Behaviour Research Group University of Sheffield, UK. Rationale: basal ganglia and action selection.

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Kevin Gurney, Mark Humphries, Rob Stewart Adaptive Behaviour Research Group

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  1. Spiking neuron models of the basal ganglia: dopaminergic modulation of selection and oscillatory properties Kevin Gurney, Mark Humphries, Rob Stewart Adaptive Behaviour Research Group University of Sheffield, UK

  2. Rationale: basal ganglia and action selection • Aim: to understand underlying function of basal ganglia. • While learning is crucial – what is being learned? • Hypothesis: Main computational role of basal ganglia is to perform action selection • Supported by high (systems) level model • Simple leaky integrators to represent population dynamics • BUT…..

  3. Beyond the systems level • Do more realistic models support the selection hypothesis? Constraints provided by: • Specific neuronal properties • Physiological phenomena displayed by BG in toto…. • If the price of a model performing selection is its failure exhibit these phenomena, the selection hypothesis is in question • In particular, can models display oscillatory phenomena in BG? • If so, then we can use the model to explore possible function of these oscillations • Function or artifact?!

  4. Cortex (‘salience’ input) input - + Striatum STN striatum STN output output nuclei Diffuse projection • Assumes relatively diffuse projection from STN • Emphasises STN’s role as input nucleus cf, Hazrati and Parent, 1992, Mink and Thach 1993, Nambu et al 2000, Sato et al 2000 Systems level – the model architecture 3 ‘channels’

  5. Cortex/thalamus STN Striatum (D2) Striatum (D1) Interpret GP efferents as control signals for modulating selection pathway Diffuse projection EP/SNr GP Selection pathway Control pathway New functional architecture:selection and control pathways Gurney et al, 2001

  6. Oscillations in basal ganglia: matching mechanisms to phenomena • Basal ganglia display a wide range of oscillatory phenomena – from <1Hz to >100Hz • These are probably associated with a correspondingly wide range of underlying mechanisms • We focus on four BG features. • Intrinsic nature of STN-GP coupling • Dopaminergic modulation of this coupling • Rebound bursting in STN • Synaptic patterning

  7. Constructing the model

  8. Beurrier et al 1999 IK > IL burst ends IL IT IK Current Time inhibition Rebound bursting in STN

  9. cortex STN soma Proximal dendrites Distal dendrites Captured phenomenlogically: use inhibition in proximal dendrites/soma to explicitly ‘gate’ more distal input GP Importance of synaptic patterning Inhibition at soma or proximal dendrites acts divisively (rather than ‘subtractively’) 70% of GPe input is proximal or somatic (Bevan et al 1997)

  10. decreased PSP Increased PSP W = W0(1 - λ) W = W0(1 + λ) λ < 1 Dopaminergic action in striatum

  11. D2 D2 W = W0(1 – k1λ) W = W0(1 – k2λ) K1, k2 < 1 Dopaminergic action in STN Similar story in GP…

  12. Dopamine: hypotheses • Low levels of dopamine serve to couple STN and GP more tightly and to make STN more sensitive to its input • Dopamine in striatum will make channel selection easier to achieve

  13. Model neurons: summary • Leaky Integrate and Fire with • AMPA NMDA, GABA, synaptic currents • Shunting inhibition at proximal dendrites and soma • Spontaneous currents • Rebound bursting in STN, • Dopamine in striatum, STN and GP. • Inter-neuronal delays • All of the above parametrised by best estimates from the literature

  14. Network • Based on systems level model • 3 discrete channels • 64 neurons per channel, per nucleus • Probabilistic connection scheme within channels (only 25% of all possible connections made)

  15. Constraining phenomena 1: Low frequency oscillations in STN-GP (Magill et al, Neuroscience,106, 2001) • Low frequency oscillations (LFOs) in STN are driven by cortical slow wave under urethane anaesthesia. • GP does not oscillate in control (normal DA) conditions. Only shows oscillation under dopamine depletion (6-OHDA lesion) • Residual LFOs (with 6-OHDA lesion) in STN and GP under cortical ablation

  16. Data – STN control

  17. Model - STN control Pseudo-eeg

  18. Data – GP control

  19. Model - GP control (1)

  20. Model GP control (2)

  21. Data – STN DA-depleted

  22. Model STN DA-depleted

  23. Data – GP DA-depleted (in phase)

  24. Model - GP DA-depleted (in-phase)

  25. Data – GP DA-depleted (anti-phase)

  26. Model - GP DA-depleted (anti-phase)

  27. Data – cortical ablation and DA-depleted Most neurons do not show LFOs but residual LFO activity…

  28. Model - no cortex (DA-depleted) STN GP

  29. LFO counts Neuron is LFO if significant peak in power spectrum below 1.5Hz In DA control conditions, no GP LFOs, STN driven by cortex LFO in GP promoted by DA depletion Residual LFO in STN & GP under cortical ablation

  30. Mean firing rates

  31. LFO – mechanistic explanation • Low frequency oscillations associated with rebound bursting will be ‘unmasked’ at low levels of dopamine…. • GP more likely to generate pre-conditioning hyperpolarisation

  32. Constraining phenomena 2: gamma oscillations in STN(Brown et al., Exp Neuro. 177, 2002) There is gamma oscillation (40-80Hz) in alert rats This is increased (86% mean) by systemic D2 agonist (quinpirole) Local field potential spectrum (control)

  33. Model simulated D2 agonist 128% power increase → DA=0.2 control DA=0.8 ‘D2 agonist’ Mean power spectra (192 neurons) Peaks in power spectrum

  34. Gamma oscillations: explanation • Gamma oscillations are associated with the natural frequency of oscillation of the GP-STN circuit • determined by circuit delays • At control levels of dopamine, the presence of some LFO masks gamma • Can’t be doing gamma during quiet phase of LFO period. • At higher levels of dopamine, gamma is unmasked

  35. Selection experiments Cortical input (Mean firing rate) ch2 ch1 1 2.5 time

  36. ch1 ch3 ch2 Mean firing rate SNr Firing rate Time ctx ch2 ch1 Ctx Ch1: 20 Hz Ctx Ch2: 40 Hz time 1 2.5 Selection and switching

  37. ch1 ch3 ch2 Firing rate ctx ch2 ch1 time 1 2.5 DA depletion prevents selection Mean firing rate SNr LFOs? Time Ctx Ch1: 12 Hz Ctx Ch2: 20 Hz

  38. ch1 ch3 ch2 ctx ch2 ch1 time 1 2.5 Effects of DA depletion overcome by highly salient action Mean firing rate SNr Firing rate Time Ctx Ch1: 20 Hz Ctx Ch2: 40 Hz

  39. ch1 ch3 ch2 ctx ch2 ch1 time 1 2.5 DA increase results in simultaneous selection Mean firing rate SNr Firing rate Time Ctx Ch1: 20 Hz Ctx Ch2: 40 Hz

  40. Summary • A spiking model of BG constrained by known physiology is able to account for a range oscillatory phenomena • Oscillations are modulated under Dopaminergic control of STN and GP • The same model displays selection and switching properties, thereby supporting the selection hypothesis for BG function • Currently exploring computational role of LFOs • Perturb BG to selection in otherwise unresolved selection competition?

  41. Peter Redgrave Paul Overton The adaptive behaviour research group Kevin Gurney Tony Prescott Mark Humphries Ben Mitchinson Rob Stewart Ric Wood Jonathan Chambers Ψ Tom Stafford

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