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A. Sher1, E. J. Chichilnisky2, W. Dabrowski3, A. A. Grillo1, M

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1 Large Scale Multielectrode Recording and Stimulation of Neural Activity
A. Sher1, E. J. Chichilnisky2, W. Dabrowski3, A. A. Grillo1, M. Grivich1, D. Gunning4, P. Hottowy3, S. Kachiguine1, A. M. Litke1, K. Mathieson4, D. Petrusca1. 1Santa Cruz Institute for Particle Physics, University of California, Santa Cruz, CA 2Systems Neurobiology, Salk Institute, La Jolla, CA 3AGH University of Science and Technology, Kraków, Poland 4University of Glasgow, Glasgow, UK

2 Extracellular Multielectrode recording of neural activity
Action Potential Cell Membrane Potential in ref out => network of ~100 billion neurons or not… Extracellular Multielectrode recording of neural activity - Simultaneous activity of many neurons - Best spatial resolution: single neuron - Best time resolution: single action potential

3 System Overview Hundreds of electrodes and readout channels
Interelectrode distance of tens of microns Signal amplification (input ~ hundreds of μV) Low noise DAQ system for digitizing and saving the data Data analysis

4 Electrode Array S. Kachiguine (SCIPP) Previous state-of-the-art Now
0.93mm Silicon Nitride Glass Indium Tin Oxide Platinum Black 61 Electrodes 1.92mm 60μm 512 Electrodes S. Kachiguine (SCIPP)

5 Platchip 64 channels; 120 μm pitch; die size = 3.3 x 7.8 mm2
AC coupling: 150 pF Platinization current: μA (controlled by 5 bit DAC) Stimulation current: μA (controlled by external analog signal with gain set by 5 bit DAC) Connection to electrode 64 channels stimulate Output (to Neurochip) platinize -2.5 V Common external stimulation signal Design by W. Dabrowski et al., Krakow

6 Neurochip 64 channels; 120 μm pitch; die size = 4.8 x 7.8 mm2
bandpass filter: Hz (typical); equivalent rms input noise ~5 μV (~7 μV for complete system with saline; signal amplitude range = 50 – 800 μV) sampling rate/channel = 20 kHz (typical); multiplexer freq. = 1.3 MHz (typical) input S&H Analog multiplexer output 64 channels preamp bandpass filter amp reference Design by W. Dabrowski et al., Krakow

7 to reference electrode
512 electrode Readout System chamber Fan-in 512-electrode array to reference electrode 64-channel Neurochip Platchip SCIPP 64:1 multiplexing. Gain: ~1000. Bandpass: 80Hz – 2kHz. Input noise: <10μV. DAQ: NI PCI ADC cards; 20kHz sampling of each channel; 15MB/s data rate.

8 Retina Retina ~100 million photoreceptors ~1 million axons

9 Retina Dacey, 2004 How is visual information (patterns, color, motion) encoded by different ganglion cell classes? Collaboration with E.J. Chichilnisky (Salk Institute, San Diego) Cajal, 1900

10 Retina ON Parasol Midget OFF

11 Retina Results: Ongoing work: Characterization of new cell types
E.S. Frechette, A. Sher, M.I. Grivich, D. Petrusca, A.M. Litke, E.J. Chichilnisky, “Fidelity of the ensemble code for visual motion in primate retina,” J Neurophysiol., 94(1), pp , 2005 J. Shlens, G.D. Field, J.L. Gauthier, M.I. Grivich, D. Petrusca, A. Sher, A.M. Litke, E.J. Chichilnisky, “The structure of multi-neuron firing patterns in primate retina,” J Neurosci., 26(32), pp , 2006 Ongoing work: Characterization of new cell types Color processing in the retina

12 Retinal Development How is retinal architecture and its connectivity to the brain formed? Molecular cues Activity dependent “wiring” 512 electrode readout system: best tool to Characterize mouse retina functional properties Characterize changes of these properties in genetically modified mice First step: Spontaneous activity in the developing mouse retina (“retinal waves”) Collaboration with D. Feldheim (UC Santa Cruz)

13 Retinal Stimulation Millions of people have photoreceptor degenerative diseases (Retinitis Pigmentosa, Macular Degeneration) Possible solution: electrical stimulation of retinal ganglion cells. Current state-of-the-art: Human trials Array of 16 electrodes of ~500μm diameter Credit: DOE Dense electrode arrays + Simultaneous stimulation (Platchip) and recording (Neurochip): For the first time showed that safe and reliable stimulation with <10μm diameter electrodes is possible C. Sekirnjak, P. Hottowy, A. Sher, W. Dabrowski, A.M. Litke, E.J. Chichilnisky, “Electrical stimulation of mammalian retinal ganglion cells with multielectrode arrays,” J Neurophysiol., 95(6), pp , 2006

14 New Stimulation Chip Arbitrary stimulation current patterns on all electrodes Stimulation artifact suppression Pad to Neurochip Pad to electrode Stimulation circuit holding capacitor Stimulation data bus Ref Real-time stimulation data Design by P. Hottowy et al., Krakow

15 Neural network Activity in brain slices
Current 512 electrode readout and future 512 electrode Stimulation systems => Recording of network activity on unprecedented scale: Detailed characterization of the neural network properties Simultaneous Stimulation and Recording: Study of neural plasticity through active interaction with the neural network Collaboration with J. Beggs (Indiana University)

16 Recording of brain neural activity of freely behaving animals
Current: New 64 channel NeuroPlat chip (built-in AC coupling, digitally controlled gain and bandpass) Digital logic circuitry to set gain and bandpass on power-up, and to provide continuous multiplexer commands Battery operated “Spy” FM transmitter and receiver Future: Addition of electrical stimulation with the new StimChip Some applications (and advantages over the existing wired systems): Study of brain activity in rats (larger scale of movement; 3D; more natural environment; better scales to larger number of electrodes) Study of navigation system in barn owls (IN FLIGHT) Collaboration with M. Meister (Harvard U.), T. Siapas (Caltech)

17 Successfully tested on a rat two weeks ago!
Recording of brain neural activity of freely behaving animals Prototype system: 64 channels 20kHz per channel sampling rate Noise: <15μV FM signal transmission: up to 60m Weight: 80g Operation time: 10hours Successfully tested on a rat two weeks ago!

18 Future Directions: Technology
Develop a stimulation system based on the new Stimchip. (retinal prosthesis, brain slices). Further develop the in-vivo system, increasing the number of readout channels and adding stimulation capabilities. 519 electrode arrays with larger (120μm) spacing. Continue work on 30μm spacing 519 electrode array (K. Mathieson, et al., University of Glasgow). 30μm 120μm 519 electrodes 30μm prototype

19 Future Directions: Biology and Medicine
Ongoing: Study of new cell types and color processing in primate retina. Retinal development. Retinal prosthesis. Study of network activity in the brain slices. Study of brain activity in freely-behaving animals Some of the potential: Wireless recording of brain activity in epilepsy patients Screening for neural toxicity

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