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LOOKING FOR QUANTUM PROCESSES IN NETWORKS OF HUMAN NEURONS ON PRINTED CIRCUIT BOARD R. Pizzi*, A. Fantasia*, F. Gelain°, D. Rossetti* & A. Vescovi° *Dept of Information Technologies, University of Milan – Crema, Italy ° Stem Cells Research Institute, DIBIT S. Raffaele – Milano, Italy Our Group • The team: 3 physicists, 1 biologist, 1 electronic engineer, 1 bioengineer, 3 computer scientists • Virtual laboratory (3 IP videophones with videocamera connection) between the Living Networks Lab and the Stem Cells Research Institute • The Stem Cells Research Institute is directed by Prof. Angelo Vescovi, who has pioneered the field of neural stem cells • Recently he has described the capacity of neural stem cells to give rise to skeletal muscle and hemopoietic cells The Stem Cells • Stem cells are capable of both proliferation and differentation into specialized cells, that serve as a continuos source of new cells. • Stem cells can be transplanted to create new healthy tissues. • Using human neural stem cells allows to consider the possibility of really implantable neural devices. • Human neural stem cells can build real living networks on artificial substrate Objectives • Comparing the activity of Artificial Networks with living networks having the same architecture • Understanding learning processes in biological neurons • Developing computational functionalities on living networks • Looking for quantum processes in biological neurons Materials • Artificials Neural Networks software (Kohonen and Hopfield networks, Java source code) • Quantum computing emulator (QuCalc on Mathematica®) • Glass PCB with 100µm gold pads connected by thin nickel/gold wires • DAQ acquisition module with 2 digital 8 bit channel output ports and 10 analog input ports • Custom electronic circuit designed for maximum performance voltage in cells stimulation • Software (Delphi) interface for the input pattern set up and data acquisition The Experiments Kohonen Hopfield The Experiments • Kohonen networks • Holographic Hopfieldlike networks • Non locality basins • Control basin (culture medium) The Kohonen Network • Straightforward architecture • Analogy with neurobiological (cortical) structures • Self-organization X1 . . . Xn Input layer Competitive layer Classification of Simple Patterns Kohonen network Signal Analysis QUALITATIVE ANALYSIS Culture medium before stimulation Channel 1 Channel 2 Channel 3 Signal Analysis • The output corresponding to similar bitmaps take similar values Signal Analysis Stimulation with the “0” bitmap • The “0” bitmap is given by the electrical values “11111111” but the neurons reply with low voltage values Signal Analysis Culture medium stimulated with “0” bitmap • The culture medium behaves as a conductor and replays to the “0” with higher values Signal Analysis Neural cells after stimulation • After the end of stimulation the cells keep signals different both each others and from the signals before the stimulation Recurrence Quantification Analysis •Non linear analysis tool •Temporal series recostructed with delay-time embedding •Estimate of the distances between the series vectors •Representation by means of Recurrent Plots • Unorganized signal before the training • Unorganized signal (in evolution )during the training • Highly organized behavior during the presentation of a “learnt” pattern • Highly organized behaviour after the end of stimulation First Conclusions •After the end of stimulation the cells were healthy and alive. •The cells reply to the presentation of organized pattern with electrically specific signals. •Similar bitmaps produce similar signals without correlation with input voltages •The cell seem to be able to keep information after the end of stimulation. •High increase of self-organization in stimulate cells The Classical Hopfield network 1. Fully interconnected network 2. Hebb-like learning 3. Isomorphic to general quantum equations Classification of Simple Patterns Hopfield network The Experiment • Network training with 50 sequences of all the possibile “1” and “0” patterns (frequency 40 Hz) • Presentation of the “1” pattern, 50 lectures • Presentation of the “0” pattern, 50 lectures • Presentation of the “1” pattern affected by noise, 50 lectures • Presentation of the “0” pattern affected by noise, 50 lectures Signal Analysis During the training 0,08000 0,06000 0,04000 0,02000 -0,04000 46 41 36 31 26 21 16 11 -0,02000 6 1 0,00000 Signal Analysis 0,08000 • 50 presentations of pattern “0” 0,06000 0,04000 0,02000 49 45 41 37 33 29 25 21 17 9 13 -0,02000 5 1 0,00000 -0,04000 -0,06000 0,04000 -0,04000 -0,06000 49 45 41 37 33 29 25 21 17 9 13 -0,02000 5 0,00000 1 • 50 presentations of pattern “0” affected by noise 0,02000 Signal Analysis 0,04000 • 50 presentations of pattern “1” 0,02000 46 41 36 31 26 21 16 11 -0,02000 6 1 0,00000 -0,04000 -0,06000 0,04000 -0,04000 -0,06000 46 41 36 31 26 21 16 11 -0,02000 6 0,00000 1 • 50 presentations of pattern “1” affected by noise 0,02000 Recurrence Quantification Analysis • Plot after presentation of pattern “0” Channel 1 Channel 3 Recurrence Quantification Analysis • Plot after presentation of pattern “1” Channel 1 Channel 3 Preliminary Results • The network answers in a selective way to different patterns • Similar patterns give rise to similar answers Preliminary Results • Organized behavior with respect to presentation of different patterns • High determinism of signals depending on the neuron channel and the presented pattern Preliminary Results • The living network can “codify” the patterns • The distribution of the 50 + 50 outputs to compare quantum and classical behaviour is underway • “On-the-fly” analysis shows irregularities in the reply to the same pattern: a quantum effect ? Quantum Network • We are developing an artificial quantum neural network to see if it could be a better model for the behaviour of real cells. • Neurons are represented by qu-bits. • Unitary evolution is achieved by a sequence of local 2-qubit unitary evolutions acting on randomly choosen couples of neurons. Quantum Network • After k 2-qubit unitary evolutions the state of the network is a classical state obtained after a “wave collapse” of the global quantum state. • Learning in this model is achieved by modifying the complex parameters that regulate quantum interaction between neurons. • The model enables the possibility of quantum tunneling between different energy levels. Quantum Network Unitary Evolutions on the 2 qubit space generates entangled global state Dynamics: Random choice of two qubits Unitary evolution k times Wave collapse Quantum tunneling in neural networks • Classical Boltzmann machines introduce thermal noise to avoid system to be trapped in local minima • The path climbs the slope of the energy gap between 2 minima • Quantum tunneling in quantum networks allows to reach the minima passing through the energy gap • This method allows faster computation in finding global minimum • The computation is robust against noise and decoherence Quantum tunneling in the quantum neural network Energy level Classical stochastic networks Quantum Tunneling Configurations space Testing quantum non-local correlations in neurons • We tried to test if EPR-like correlations may exist in neurons • EPR correlations between two systems A,B are of the kind |0A0B>+|1A1B> i.e. the whole system is in a superposition of two state |0A0B> , |1A1B> • In every state the two systems A,B present statistical correlations. Non Locality Experiment • Two dishes electrically connected • Then separated and electrically insulated • 50 electrical stimulations (40 Hz) • 50 light stimulations with 466 nm LED (near UV band) The Measures • Signals crosscorrelation before stimulations: • Signals crosscorrelation after electrical stimulation: • Signals coherence after electrical stimulation: • Signal crosscorrelation after LED stimulation: 0.304 0.184 0.47 -0.484 • Signals coherence after LED stimulation: 0.80 Experimental results • The best correlations between systems A,B have been obtained with light stimulation directed only to system A. • This doesn’t necessarily mean that EPR correlations are present in neurons. • It could be explained by some kind of communication between separated neurons. • More experiments are needed to formulate theoretical explanations. Considerations •LED stimulations should not affect the signals •The “multipower” of stem cells (even potential retinal cells) could be a reason for reaction •Reaction to LED stimulation cannot be caused by electrical interference between basins •The extremely low energy could have avoided dechoerence processes Future Developments • Accurate analysis of signals (non linear analysis, ANN analysis) • Further experiments to validate the previous ones • Accomplishment of the quantum formalism for the network training • More complex living networks to perform more complex tasks