Introduction to Electrophysiology

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Transcription:

Introduction to Electrophysiology Dr. Kwangyeol Baek Martinos Center for Biomedical Imaging Massachusetts General Hospital Harvard Medical School 2018-05-31s

Contents Principles in Electrophysiology Techniques in Electrophysiology Electrophysiological basis of Functional MRI

Principles in Electrophysiology

Electrophysiology To investigate the electrical properties of biological cells and tissues. Nervous system, Heart (ECG), Muscle (EMG), etc. Usually measuring electrical potential (in mv or μv). Electrophysiology study in neuroscience In vitro : cultured neurons or brain slice. In vivo : living animal.

Electrophysiology of Neuron Membrane potential: Electrical potential difference across the cell membrane.

Electrophysiology of Neuron Post-synaptic potential Synaptic input Neurotransmitter-gated ion channels Varying amplitude and shape Threshold Action potential ( Spike ) Cellular output Voltage-gated ion channels Fixed response

Electrophysiology of Neuron Synaptic inputs are summed at cell body (axon hillock). Action potential occurs when the membrane potential reached the threshold. (All-or-nothing behavior) Action potential propagated to axon terminal, and then neurotransmitter is released to next neurons.

Intracelluar vs. Extracelluar recording Intracelluar recording Electrode is placed into a single cell. Measuring voltage or current across the membrane of a cell. Extracelluar recording Measuring ionic current and voltage in extracellular space. Summed activity from many neurons.

Intracellular recording Placing the electrode into a single cell. Direct measurement of the membrane potential.

Extracellular recording Measuring electrical potential or current around the cell.

Techniques in Electrophysiology

Techniques in Electrophysiology Intracellular recording single cell Extracellular recording Single unit activity Multi-unit activity (MUA) Local field potential (LFP) neuronal population EEG / EcoG cortical areas

Intracellular recording Glass micropippet Tip diameter of 50~500 nm Impedence of 10~500 MΩ Intracellular amplifier DC-amplifier with a large input resistance (~10 11 Ω)

Extracellular recording < 200 Hz > 500 Hz

Extracellular recording Extracellular recording = (fast) spike acivity + (slow) field potential Both types of activity were simulataneoulsy acquired and separated with bandpass filters. Spike acitivity: Action potential in neurons (~ 1 ms = 1000 Hz) Single unit activity: Identification of individual neurons with features in the spike shape. Multi-unit activity: Unidentified sum of spike activity from nearby population of neurons. Local field potential: Synchronized synaptic inputs (< 300 Hz) Electrical field potential in local extracellular celluar space generated by slow synchronized currents (mostly from post-synaptic current)

Single unit activity Identifying individual neurons: Tetrode + Spike sorting

Single unit recording Tetrode a bundle of four microwire electrodes. Impedence of 50-500 kω. Spike sorting Size and shape of the spike events are depending on relative position of neurons. 10 μm

Single unit activity Data: Spike trains from multiple neurons. Neuron 1 Neuron 2

Multi-unit activity (MUA) Spike activity from many unidentified neurons. level of spiking rate in local neuronal population (neural output). Rectification and downsampling of the bandpass-filtered signal.

Local field potential (LFP) Slower frequency bands in extracellular recording (0.5~200 Hz): micro EEG synchronized synaptic input (postsynaptic current) in local area is a major source of LFP. Data is analyzed as spectral power (bands) or evoked potential.

Local field potential (LFP) Linear electrode array recording of LFP 1 st spatial derivative: current flow density 2 nd spatial derivative: current source density Current sink: excitatory synaptic input

EEG/EcoG EEG records extracellular potential generated with synchronous synaptic inputs as same as LFP. Skull and dura matter work as volume conductor, and worsen spatial resolution. EcoG (electro-cortico-graphy) has a better sensitivity. Same data analysis scheme can be applied for both LFP and EEG

Neural oscillation in LFP/EEG Frequency bands in LFP/EEG Delta wave (0.5~4 Hz) Theta wave (4~8 Hz) Alpha wave (8~13 Hz) Beta wave (13~30 Hz) Gamma wave (30~100 Hz)

Comparison of electrophysiological recording EEG, LFP, MUA and single unit activity are closely interrelated. Somatosensory cortex Entorhinal cortex EEG LFP MUA Single unit

Electrophysiological basis of fmri

Neurovascular coupling What type of electrophysiolgical activity explains BOLD fmri?

Neural basis of BOLD fmri Synaptic input Local Field Potential (LFP) Neuronal output ( Spikes ) Multi-unit activity (MUA) Single unit activity

Neural basis of BOLD fmri Logothetis et al. (2001) Simultaneous electrophysiological recording with BOLD fmri. (Monkey visual cortex)

Neural basis of BOLD fmri Logothetis et al. (2001) LFP was more well matched with BOLD fmri than MUA.

Neural basis of resting state fmri Spontaneous BOLD fluctuation in fmri: 0.01~0.1 Hz

Neural basis of resting state fmri Shmuel & Lepold (2008) Spike activity MUA Gamma band power modulation (BLP)

Neural basis of resting state fmri Hemodynamic response was conserved in resting state activity.

Thank you for listening! kwangyeol.baek@gmail.com

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