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In This Article

  • Summary
  • Abstract
  • Introduction
  • Protocol
  • Results
  • Discussion
  • Disclosures
  • Acknowledgements
  • Materials
  • References
  • Reprints and Permissions

Summary

The present protocol describes a simple procedure to acquire and analyze the topography of epicranial visual evoked potentials with 32-multichannel thin-film electrodes in the mouse.

Abstract

Visual evoked potentials (VEP) allow the characterization of visual function in preclinical mouse models. Various methods exist to measure VEPs in mice, from non-invasive EEG, subcutaneous single-electrodes, and ECoG to fully invasive intracortical multichannel visual cortex recordings. It can be useful to acquire a global, topographical EEG-level characterization of visual responses previous to local intracortical microelectrode measurements in acute experimental settings. For example, one use case is to assess global cross-modal changes in VEP topography in deafness models before studying its effects on a local intracortical level. Multichannel epicranial EEG is a robust method to acquire such an overview measure of cortical visual activity. Multichannel epicranial EEG provides comparable results through a standardized, consistent approach to, for example, identify cross-modal, pathological, or age-related changes in cortical visual function. The current study presents a method to obtain the topographical distribution of flash-evoked VEPs with a 32-channel thin-film EEG electrode array in anesthetized mice. Combined with analysis in the time and frequency domain, this approach allows fast characterization and screening of the topography and basic visual properties of mouse cortical visual function, which can be combined with various acute experimental settings.

Introduction

Mice are a preclinical model of degenerative processes of vision and ophthalmological diseases1,2,3,4. Visual evoked potentials (VEPs) are commonly used to measure cortical visual function and, for example, to assess visual degeneration in pathological models5,6. The VEP latency, conduction time, amplitude, multifocal characteristics, or spatial acuity of cortical visual evoked potentials provide diagnostic information on the functional integrity of the visual system7,8,9.

In mice, cortical visual evoked potentials can be measured across various spatial scales with methods of different complexity from non-invasive EEG, subdermal needle electrodes, and skull-implanted screws, to fully invasive intracranial approaches with epicortical ECoG, to intracortical electrode recordings10,11,12,13,14,15,16,17. These methods have different strengths and weaknesses. For example, a low number of electrodes only provides limited information on cortical VEP distribution, whereas subcutaneous needle electrodes often fail to ensure consistent recording locations. Moreover, implanted screws or fully invasive methods require damaging, penetrating, or removing of the skull and often provide only local information.

In acute experiments, a first global overview of cortical visual function is often desired, which is eventually followed by further experimental steps and compared to local intracortical recordings. For example, one potential use case is utilized first to investigate the EEG-level effects of visual cross-modal reorganization of deafness or hearing loss on VEP topography and cortical visual activity18,19 before studying the impacts on a local intracortical level.

Multichannel EEG recordings with thin-film multi-electrode arrays can provide a systematized VEP topography from the mouse skull20,21,22,23,24. Such epicranial recordings can have advantages over ECoG recordings by leaving the integrity of the skull intact and avoiding direct manipulation of the cortical surface. In addition, thin-film multi-electrodes provide a standardized electrode configuration, allowing the comparison of visual evoked spatio-temporal brain activity between experiments similar to a standardized EEG system in humans25. A standardized framework also facilitates using common EEG analysis toolboxes (e.g., Fieldtrip, Chronux, EEGLAB, and ERPLAB) to analyze mouse EEG in the time and frequency domain or in terms of connectivity26,27,28,29,30,31.

The present protocol describes a procedure for topographical VEP recordings in mice using a 32-channel thin-film electrode. This can be used as part of acute experiments followed by additional experimental steps, such as intracortical microelectrode recordings from specific brain areas. It is demonstrated here how to reliably record epicranial flash evoked VEPs with 32-channel thin-film electrodes from the mouse. In addition,  exemplary analysis of topographical VEP recordings in the time and frequency domain is presented. 

Protocol

All animals were handled and housed according to German (TierSchG, BGBl. I S. 1206, 1313) and European Union (ETS 123; Directive 2010/63/EU) guidelines for animal research. The animal experiments were approved by German state authorities (Lower Saxony State Office for Consumer Protection and Food Safety, LAVES) and were monitored by the university animal welfare officer. A 3-month-old male C57BL/6J mouse was used for the present study.

1. Animal details

  1. Perform the VEP measures in mice adequate for the particular research question.
  2. Be aware of mouse strain peculiarities in physiology that can impact the experiment by altered anesthetic sensitivities, seizure susceptibility, age, or genetic background.
    ​NOTE: Mouse strains with different genetic backgrounds may often develop other sensory impairments (e.g., C57BL/6 progressive hearing loss), which might go unnoticed but indirectly affect visual processing (e.g., cross-modal influences19).

2. Induction of general anesthesia

  1. Prepare a surgical field at the recording site. Determine the pre-surgical weight of the mouse.
  2. Induce anesthesia with ketamine/xylazine, i.p., with a dosage of 100 mg/kg ketaminehydrochloride, 4 mg/kg xylazinhydrochloride, and 5mg/kg carprofen (see Table of Materials).
  3. Immediately after injection, place the mouse back in the cage.
  4. Place an infrared heating lamp (see Table of Materials) at an adequate distance and wait for full induction of general anesthesia for at least 5 min.
  5. Observe the stopping of spontaneous movements and loss of the righting reflex. Check for loss of the toe-pinch reflex.

3. Physiological monitoring and maintenance of general anesthesia

  1. Transfer the mouse to the recording site onto a heating pad.
  2. Use a rectal temperature probe attached to a temperature control system to keep the core body temperature at 37.6-37.8 °C.
  3. Ensure optimal body temperature of the mouse. In addition to the heating pad, minimize heat loss by increasing room temperature if required.
  4. Place two subcutaneous silver wire electrodes (0.2 mm diameter, see Table of Materials) near the right shoulder and left hind leg for ECG monitoring.
  5. Attach the silver wire ECG electrodes to the ECG amplifier.
  6. Monitor heart rate and ECG waves on an oscilloscope (see Table of Materials) during the experiment.
    NOTE: During adequate ketamine/xylazine anesthesia, heart rate can range between 160-250 bpm32,33. Heart rate can vary depending on mouse strain, age, and physiological status.
  7. Check the toe-pinch reflex and vital signs. The absence of the toe-pinch reflex response indicates a sufficient level of anesthesia.
  8. Monitor the status and quality of the eyes during the procedure closely, and apply ophthalmic drops or gel.
  9. Monitor adequate anesthesia levels by regularly checking physiological parameters, heart rate, reflexes, and EEG activity.
  10. If the general anesthesia level gets too light, apply an additional dose of ketamine/xylazine (i.p.).
  11. Proceed fast with the experimental steps to minimize the duration of general anesthesia and the number of subsequent doses of additional ketamine/xylazine used to maintain general anesthesia.

4. Electrode placement and recording setup

  1. At the recording site, reassess adequate anesthetic depth by checking the toe-pinch reflex.
  2. Shave the top of the head with an electric shaver.
  3. To allow a free visual field, do not fixate the mice in a stereotactic frame during the experiment.
  4. Apply lidocaine (if additionally required by your local institutional guidelines for animal care).
  5. Make a 1 cm midline incision of the scalp.
  6. Retract the skin to both sides using small vessel clamps to hold the skin in place and to expose the skull.
  7. Clean the surface of the skull with a cotton swab and saline NaCl (0.9%).
  8. Attach a silver wire reference electrode (diameter 0.2 mm) for the EEG subcutaneously above the nose (nose reference) or behind the ear (mastoid). 
  9. Connect the nose reference via the probe connector to the headstage (see Table of Materials) reference output.
  10. Next, attach the EEG electrode to the headstage using an adapter attached to the headstage via a probe connector and attached to an electrode holder (see Table of Materials).
  11. Place the multichannel thin-film EEG electrode (see Table of Materials) on the skull with bregma as a reference position to ensure a standardized electrode position for each experiment.
  12. Use a drop of saline to adjust the electrode's position. While the skull surface is still wet, the electrode is easily movable. Then, dry the skull carefully with a cotton swab. 
  13. Wait until the saline solution dries and the electrode firmly attaches to the skull.
  14. Cover the electrode with a small drop of silicone oil to avoid the adherence of the electrode to the overlying skin. This step helps to easily remove the electrode after the recording.
    NOTE: Be careful not to apply too much silicone oil to avoid deteriorating the contact of the electrode with the skull.
  15. Close the skin over the electrode for protection and to minimize electrical noise.
  16. Apply a small drop of tissue adhesive (see Table of Materials) to the skin to prevent the reopening of the skin incision.

5. EEG recording and VEP measurement

  1. Filter EEG signals during acquisition with a wide filter between 1-9000 Hz. Use wide filter settings for the control of artifacts. Perform noise and adequate filtering later during offline processing.
  2. Check the signal quality of the ongoing EEG activity by checking for high-frequency electrical noise, 50/60 Hz artifacts, and ECG artifacts. Apply adequate ground and reference connections to the animal and equipment or apply adequate shielding.
  3. Check anesthesia depth by observing EEG activity. Try to avoid a 'too deep' anesthesia state which is characterized by the occurence of burst-suppression EEG activity. Consider the experiment's time course and ensure that anesthesia does not get too light during the recording.
  4. Use an LED stroboscope (or other types of visual stimulation) to produce ultra-short flashes (see Table of Materials) (Figure 1).
  5. Place the stroboscope at a 30 cm distance for binocular visual stimulation in front of the mouse.
    NOTE: The mouse and stroboscope are placed in a dark and soundproof chamber during the experiment.
  6. Adapt the mice to the dark for 5 min before stimulation.
  7. Elicit stroboscope flashes by triggering the stroboscope with a TTL pulse.
    NOTE: A stimulation artifact can occur due to the high voltage of the stroboscope. This can be attenuated by increasing the distance or shielding the electrode.
  8. Generate hardware TTL triggers with a multifunction I/O device (see Table of Materials) controlled by a stimulation PC to trigger the light source (i.e., stroboscope).
  9. Send TTL signal in parallel to the acquisition system to provide high-precision timestamps for the stimulus onset.
  10. Send TTL output, which is synchronized with the flash, from the LED stroboscope as feedback and as a second control for accurate stimulus onset trigger timestamps. Register this together with the recordings.
  11. Set the stimulus rate (e.g., inter-stimulus interval = 2 s). Set the number of stimulus repetitions (e.g., n = 150 repetitions)
  12. Adjust the intensities manually on the stroboscope (e.g., flash duration of 512 µs at a fixed value of 3000 lm).
    NOTE: This, however, has to be adapted to the specific experimental question.
  13. Start the stimulus presentation, record the EEG signals with recording software (see Table of Materials), and save the data on the recording PC.

6. Completion of the experiment, electrode removal, and electrode cleaning

  1. If the recording is part of a longer protocol, continue with further experimental steps.
  2. At the end of the experiment, euthanize the animal according to institutional guidelines23,34.
  3. Remove the EEG electrode with care (since they can be reused).
  4. Slowly with the application of fluid remove the electrode from the skull.
    ​NOTE: The electrodes can stick to the surface of the skull; avoid damage to the platinum sites during removal.
  5. Clean the electrode after the experiment with isotonic saline NaCl (0.9%) and immerse it in a protein remover and disinfecting solution (see Table of Materials) for 30 min.
  6. Store the electrode array in a dry, protected place.

7. Basic VEP signal processing: Time and frequency domain

  1. Import the raw data files into the analysis software (see Table of Materials).
  2. Filter EEG signals with a Butterworth bandpass zero-phase filter between 1-100 Hz.
    NOTE: Select adequate filter types and parameters depending on the respective research question27,35,36.
  3. Downsample the signals to 1000 Hz.
  4. Segment the EEG signals into trials and average the trials to yield visual evoked potentials and determine the N1 peak latency.
    NOTE: Re-referencing can be performed offline if necessary (e.g., common average referencing, bipolar referencing, local average "Laplacian" referencing)23.
  5. Determine the voltage values at specific time points of interest and plot voltage distribution maps using the analysis software.
  6. Calculate global field power37 by calculating the spatial standard deviation of all the electrode channels.
  7. Calculate a multi-taper time-frequency spectrogram with Chronux Toolbox28,31. Use a bandwidth product TW = 3 and K = 5 tapers with a 300 ms window size and 30 ms step size.

Results

Recording visual evoked potentials with multichannel EEG allows the assessment of the topography of VEP amplitudes, latencies, or frequency components in mice. Figure 2A shows an example of a flash evoked VEP topography recorded with an epicranial 32-channel EEG from a 3-month-old male C57BL/6J mouse. The strongest visual evoked activity occurs in the occipital region above the visual cortex.

Figure 2B shows the voltage distribution o...

Discussion

This article describes a method for recording epi-cranial multichannel EEG with thin-film electrodes and how to acquire a consistent topographical representation of visual evoked potentials in the mouse. Here, we exemplarily showed binocular flash stimulation, but this approach can also be applied with other types of visual stimuli (i.e., monocular, spatial gratings, focal visual field) using, for example, a larger display.

A critical step in the protocol is the positioning of the electro...

Disclosures

The authors declare no competing financial interests or other conflicts of interest.

Acknowledgements

This work was supported by the German Research Foundation (Deutsche Forschungsgemeinschaft, Cluster of Excellence 2177 "Hearing4all", Project number 390895286).

Materials

NameCompanyCatalog NumberComments
Bepanthen 5% DexpantheolBayerOphtamic gel
Cheetah software 5.11NeuralnyxVersion 5.11Recording software for neurophysiologcal signals
Digital Lynx SXNeuralynxDigital Lynx 16SXRecording system
ECG differential amplifierOtoconsultWDA2 V1.0
Electric shaverAesculapGT420
Electrode HolderTSE Systems430005-HE
Examination lightHeineHL 5000Cold light source lamp
Heating Pad + Temperature Control systemCWETC-1000 Mouse
Histoacryl 0.5 mLB.BraunTissue adhesive
Infrared heat lamp SanitasSIL 06
Ketamine 10% WDTKetaminhydrochlorid
LED stroboscope MonarchNova Strobe PBLVisual stimulation
Matlab 2021aThe Mathworks2021aStimulus control and analysis
Moria Vessel ClampFine Science Tools18320-11
Mouse EEG electrode NeuroNexusH32 (Reticular)32-channel EEG electrode. Thickness: 20 μm; length: 8.6 mm; width 6.8 mm. Platinum sites: 500 μm diameter
Mouse Frame custom madeInformation available on request
Multifunction I/O deviceNational InstrumentsPCIe-6353 with BNC 2090AAnalog stimulus generation, output, and trigger
NaCl 0.9%B.BraunIsotonic, sterile, nonpyrogenic
Neuralynx HS36 NeuralynxHS-36Headstage
Neuronexus probe connectorNeuralynxADPT-HS36-N2T-32AElectrode connector
OscilloscopeTektronixTDS 2014B
Progent Intensive CleanerMeniconProtein remover and disinfecting solution for rigid gas permeable lenses
Recording PC HPHP Z800Recording PC
Rimadyl (Carprofen)ZoetisCarprofen
Silicon Oil M 1000Carl Roth4045.1
Silver wire Science ProductsAG-8WDiameter 203 µm; ECG and reference electrode
Sound proof chamberIAC acoustics
Stereotactic MicromanipulatorTSE Systems430005-M/PFor EEG electrode placement
Stimulation PCDellDell Precision T5810Stimulation PC
Surgical microscopeZeissOp-Mi Focus
Surgical tape3M1527-01.25 cm x 9.1 m
Thilo-Tears 3 mg/gAlcon Pharma GmbHOphtamic gel
Vaselin LichtensteinWinthropWhite vaselin ointment
Xylazin 2%  BernburgXylazinehydrochlorid
Xylocaine Spray (10 mg/puff)AspenLidocaine

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