MEA60System MEA Manual

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Microelectrode Array (MEA)
Manual

Information in this document is subject to change without notice.

No part of this document may be reproduced or transmitted without the express written permission
of Multi Channel Systems MCS GmbH.

While every precaution has been taken in the preparation of this document, the publisher and the author
assume no responsibility for errors or omissions, or for damages resulting from the use of information
contained in this document or from the use of programs and source code that may accompany it. In no
event shall the publisher and the author be liable for any loss of profit or any other commercial damage
caused or alleged to have been caused directly or indirectly by this document.

© 2018 Multi Channel Systems MCS GmbH. All rights reserved.

Printed: 25.07.2018

Multi Channel Systems
MCS GmbH
Aspenhaustraße 21
72770 Reutlingen
Germany
Phone +49-71 21-909 25 - 0
Fax

+49-71 21-909 25 -11

sales@multichannelsystems.com
www.multichannelsystems.com

Microsoft and Windows are registered trademarks of Microsoft Corporation. Products that are referred
to in this document may be either trademarks and / or registered trademarks of their respective holders
and should be noted as such. The publisher and the author make no claim to these trademarks.

Microelectrode Arrays (MEAs) — Overview

Table of Contents
1

Introduction

6

1.1

About this Manual

6

2

Important Information and Instructions

7

2.1

Operator's Obligations

7

2.2

Guarantee and Liability

7

2.3

Important Safety Advice

8

3

Microelectrode Arrays (MEAs) — Overview

9

3.1

Extracellular Recording with Microelectrode Arrays

3.2

MEA Design and Production

10

3.3

Electrodes, Tracks, and Insulation

11

4

MEA Types and Layouts

12

4.1

Standard Electrode Numbering

13

4.2

Standard MEA

14

4.3

High Density MEA: 60HDMEA

15

4.4

Hexa MEA: 60HexaMEA40/10

16

4.5

Thin MEA: 60ThinMEA

17

4.6

Three dimensional MEA: 60-3DMEA

18

4.7

Eco MEA: 60EcoMEA

19

4.8

Perforated MEA: 60pMEA

20

4.9

Perforated MEAs for Use with MEA2100-32-System
and USB-MEA32-STIM4-System

21

9

4.10 MEA with 6 Wells: 60-6wellMEA

22

4.11 256MEA for Use with MEA2100-256and USB-MEA256-Systems

23

4.12 MEA with 6 Wells for Use with MEA2100-256and USB-MEA256-Systems

24

4.13 MEA with 9 Wells for Use with MEA2100-256and USB-MEA256-Systems

25

4.14 120MEA for Use with MEA2100-120-System

26

4.15 120MEA1000-1500/30iR-Ti for Use with MEA2100-120-System
4.16 Quadrant MEA: 60-4QMEA1000

28

4.17 Square MEA: 60SquareMEA

29

4.18 PEDOT-CNT MEAs: 60PedotMEA

30

4.19 FlexMEA

31

4.20 EcoFlexMEA

33

4.21 MEA Signal Generator: 60MEA-SG

35

27

3

MEA Manual

5

MEA Handling

37

5.1

Hydrophilic Surface Treatment

37

5.1.1

Plasma Cleaning

37

5.1.2

Preculturing

38

5.2

38

5.2.1

Sterilization with Ethanol and UV Light

38

5.2.2

Steam Sterilization (Autoclavation)

38

5.2.3

Dry-Heat Sterilization

38

5.2.4

Sterilization with Hot Water

38

5.3

MEA Storage

39

5.4

MEA Coating

39

5.4.1

Coating with Nitrocellulose

39

5.4.2

Coating with Polyethyleneimine (PEI) plus Laminin

40

5.4.3

Coating with Polyornithine (plus Laminin)

41

5.4.4

Coating with Poly-D-Lysine (plus Laminin)

42

5.4.5

Coating with Poly-D-Lysine (plus Fibronectin)

43

5.4.6

Coating with Fibronectin

43

5.4.7

Coating with Collagen

44

5.5

Cleaning of used MEAs

45

5.5.1

General Recommendations for Cleaning MEAs

45

5.5.2

Cleaning of pMEAs

45

5.5.3

Cleaning of EcoMEAs

45

5.5.4

Cleaning of EcoFlexMEAs

45

5.5.5

Cleaning of FlexMEAs

46

5.5.6

Removing Nitrocellulose Coating

46

5.5.7

MEA Cleaning with EDTA-Collagenase

46

5.5.8

MEA Cleaning with Terg-A-Zyme

47

6

Culture Chamber and Ring Options

49

6.1

MEA2100-CO2-C

49

6.2

Sealed MEA Culture Dish

49

6.3

MEA Culture Chamber with Lid

50

6.4

Culture Chamber for 9-Well MEAs

50

6.5

Culture Chamber for 6-Well MEAs

50

6.6

Ring Options

51

7

Recording with MEAs

52

7.1

Mounting the MEA

52

7.1.1

Cleaning the Contact Pads

52

7.1.2

Positioning the MEA

52

7.1.3

Grounding the Bath

52

General Performance / Noise Level

53

7.2

4

Sterilization

Microelectrode Arrays (MEAs) — Overview

8

Stimulation

55

8.1

Using MEA Electrodes for Stimulation

55

8.2

Capacitive Behavior of Stimulating Electrodes

56

8.3

Aspects of Electrode Size and Material

57

8.4

Recommended Stimulus Amplitudes and Durations

58

9

Troubleshooting

59

9.1

About Troubleshooting

59

9.2

Technical Support

59

9.3

Noise on Single Electrodes

60

9.4

Overall Noise / Unsteady Baseline

62

9.5

Missing Spikes or Strange Signal Behavior

63

10

Appendix

65

10.1 Contact Information

65

10.2 Safe Charge Injection Limits

66

5

MEA Manual

1

Introduction
1.1 About this Manual
The MEA manual comprises all important information about the microelectrode arrays (MEA) for use with
(USB-) MEA- or ME-Systems from Multi Channel Systems. The MEA manual focuses on general information
on the MEA design, use, and handling, and more specific information on different MEA types. It also
includes recommendations on sterilization, coating, and cleaning procedures, from scientifical papers
or from recommendations of other MEA users.
For more details on issues that refer to the amplifier, like grounding or mounting the MEA, please refer to
the manual for the MEA amplifier you use. You will find more information about the MEA-System and its
components in general in the MEA-System manual. For more details on the data acquisition and analysis
program Multi Channel Suite or MC_Rack, please refer to the respective manuals.
It is assumed that you have already a basic understanding of technical terms. No special skills are required
to read this manual.
The components and also the manual are part of an ongoing developmental process. Please understand
that the provided documentation is not always up to date. Please check the MCS web site
(www.multichannelsystems.com) from time to time for downloading up-to-date manuals.
Those parts in this manual that refer to the applications and not to the product itself, for example,
coating of MEAs, are only a summary of published information from other sources (see references) and
has the intention of helping users finding the appropriate information for setting up their experiments.
Multi Channel Systems MCS GmbH has not tested or verified this information. Multi Channel Systems
MCS GmbH does not guarantee that the information is correct. Multi Channel Systems MCS GmbH
recommends to refer to the referenced literature for planning and executing any experiments.

6

Microelectrode Arrays (MEAs) — Overview

2

Important Information and Instructions
2.1 Operator's Obligations
The operator is obliged to allow only persons to work on the device, who


are familiar with the safety at work and accident prevention regulations and have been instructed
how to use the device;



are professionally qualified or have specialist knowledge and training and have received instruction
in the use of the device;



have read and understood the chapter on safety and the warning instructions in this manual
and confirmed this with their signature.
It must be monitored at regular intervals that the operating personnel are working safely.
Personnel still undergoing training may only work on the device under the supervision
of an experienced person.

2.2 Guarantee and Liability
The General conditions of sale and delivery of Multi Channel Systems MCS GmbH always apply.
The operator will receive these no later than on conclusion of the contract.
Multi Channel Systems MCS GmbH makes no Guarantee as to the accuracy of any and all tests and data
generated by the use of the device or the software. It is up to the user to use good laboratory practice to
establish the validity of his findings.
Guarantee and liability claims in the event of injury or material damage are excluded when they are the
result of one of the following.


Improper use of the device.



Improper installation, commissioning, operation or maintenance of the device.



Operating the device when the safety and protective devices are defective and / or inoperable.



Non-observance of the instructions in the manual with regard to transport, storage, installation,
commissioning, operation or maintenance of the device.



Unauthorized structural alterations to the device.



Unauthorized modifications to the system settings.



Inadequate monitoring of device components subject to wear.



Improperly executed and unauthorized repairs.



Unauthorized opening of the device or its components.



Catastrophic events due to the effect of foreign bodies or acts of God.

7

MEA Manual

2.3 Important Safety Advice
Warning: Make sure to read the following advice prior to install or to use the device and the software.
If you do not fulfill all requirements stated below, this may lead to malfunctions or breakage of
connected hardware, or even fatal injuries.
Warning: Obey always the rules of local regulations and laws. Only qualified personnel should be
allowed to perform laboratory work. Work according to good laboratory practice to obtain best results
and to minimize risks.
The product has been built to the state of the art and in accordance with recognized safety engineering
rules. The device may only


be used for its intended purpose;



be used when in a perfect condition.



Improper use could lead to serious, even fatal injuries to the user or third parties and damage to the device
itself or other material damage.
Warning: The device and the software are not intended for medical uses and must not be used on
humans.



Malfunctions which could impair safety should be rectified immediately.



Regard the technical specifications of the various MEA types, especially the temperature range and the safe
charge injection limits for stimulation.



Do not autoclave or expose pMEAs to heat more than 50 °C.



Do not touch the electrode field in any way.



Do not use any liquids or cleaning solutions with a high pH (> 7) for a longer period of time on MEAs
of a silicon nitride insulation type. Basic solutions will damage TiN electrodes.

8

MEA Manual

3

Microelectrode Arrays (MEAs) — Overview
3.1 Extracellular Recording with Microelectrode Arrays
A microelectrode array (MEA) is an arrangement of typically 60 electrodes allowing the targeting of several
sites in parallel for extracellular recording and stimulation.
Cell lines or primary cell preparations are cultivated directly on the MEA. Freshly prepared slices can be used
for acute recordings, or can be cultivated as organotypic cultures (OTC) on the MEA.
Recorded signals are amplified by a filter amplifier and sent to the data acquisition computer. All MEAs
(except EcoFlex- or FlexMEAs) are only for use with MEA- or MEA2100-Systems or USB-MEA-Systems for
extracellular recording from Multi Channel Systems MCS GmbH. FlexMEAs may be used with components
of ME-Systems and USB-ME-Systems from Multi Channel Systems MCS GmbH. EcoFlex- and FlexMEAs are
designed for use in in vitro or in vivo studies. Please see setup manuals “Setup (USB-) MEA-Systems and
(USB-) ME-Systems” for more information.
Several MEA geometries are provided for a wide variety of applications. Almost all excitable or electrogenic
cells and tissues can be used for extracellular recording in vitro, for example, central or peripheral neurons,
cardiac myocytes, whole-heart preparations, or retina.
There are various applications for MEAs in the fields of neurobiology and cardiac electrophysiology.
Typical neurobiological applications are: Ion channel screening, drug testing, safety pharmacology studies,
current source density analysis, paired-pulse facilitation (PPF), long term potentiation (LTP) and depression
(LTD), I / O relationship of evoked responses, circadian rhythm, neuroregeneration, developmental biology,
microencephalograms (EEG), and microelectroretinograms (ERG).
Typical applications in the cardiac field are: Activation and excitation mapping, measuring of the conduction
velocity, longterm characterizations of cell types (especially stem cells), culture pacing, drug testing, safety
pharmacology studies, monitoring of QT-related prolongation and arrhythmias, cocultures and disease /
implantation model.
For more information on published applications or procedures for biological preparations, please see the
application notes on the MCS web site:
http://www.multichannelsystems.com/downloads/documentation

9

MEA Manual

3.2 MEA Design and Production
A standard MEA biosensor has a square recording area of 700 µm to 5 mm length. In this area,
60 electrodes are aligned in an 8 x 8 grid with interelectrode distances of 100, 200, or 500 µm. Planar
TiN (titanium nitride) electrodes are available in sizes of 10, 20, and 30 µm, and three-dimensional TiN
electrodes have a diameter of > 12 µm at the base with a very fine tip. Standard MEAs are useful for
a wide variety of applications. Different geometries match the anatomical properties of the preparation.
Most MEAs are available with a substrate-integrated reference electrode replacing the silver pellet in the
bath. All electrodes can either be used for recording or for stimulation.
In principle MEA electrodes are not arranged symmetrical, so the MEA chip has to be placed inside the
amplifier in the recommended manner.
Several other MEA types and layouts that are dedicated to special applications are also available, please
see chapter “MEA Types and Layouts” for more details.
The biological sample can be positioned directly on the recording area; the MEA serves as a culture and
perfusion chamber. A temperature controller controls the temperature in the culture chamber. Various
culture chambers are available, for example, with leak proof lid or with semipermeable seal. An incubator
is not necessarily required, long-term recordings in the MEA culture chamber are possible over several
weeks or even months.
For cell or slice cultures, MEAs have to be coated with standard procedures before use to improve the cell
attachment and growth, please read chapter “ MEA Coating”.
Spike activity can be detected at distances of up to 100 µm from a neuron in an acute brain slice.
Typically, signal sources are within a radius of 30 µm around the electrode center. The smaller the distance,
the higher are the extracellular signals. The higher the spatial resolution, the lower the numbers of units
that are picked up by a single electrode, that is, the less effort has to be put into the spike sorting.
Multi Channel Systems provides MEAs with the highest spatial resolution in the market. HighDenseMEAs
have electrodes with a diameter of only 10 µm arranged in a distance of only 30 µm (center to center).
The challenge of manufacturing very small electrodes and at the same time keeping the impedance and
the noise level down has been met by introducing the electrode material Titanium nitride (TiN).
The NMI in Reutlingen, Germany (www.nmi.de), produces MEAs from very pure fine quality and highly
biocompatible materials. The NMI is a research institute, with which Multi Channel Systems has
collaborated in many projects and over many years.
Quality controls and production processes have been improved over the last years so that MEAs are always
of a fine consistent quality at very reasonable prices.

10

MEA Manual

3.3 Electrodes, Tracks, and Insulation
Microfold structures result in a large surface area that allows the formation of electrodes with an excellent
signal to noise ratio without compromising on the spatial resolution.
TiN (titanium nitride) is a very stable material that, for example, is also widely used for coating heavy
equipment. All MEAs with TiN electrodes have a long life and can be reused several times if handled with
care. If used for acute slices, MEAs can be used for approximately one year. Additionally available are
EcoMEAs equipped with gold (Au) electrodes.
Long-time experiments with cell cultures and rigid cleaning methods shorten the MEA lifetime, but you
can still reuse a MEA about 30 times, depending on the coating, cell culture, and cleaning procedure.
All MEAs (except pMEAs) show excellent temperature compatibility and are stable from 0 °C to 125 °C,
that is, they can be autoclaved.
The impedance of a flat, round titanium nitride (TiN) electrode is < 100 kfor 30 µm electrodes and
approximately 250 to 400 kfor electrodes with smaller diameters. The smaller an electrode, the higher
is the impedance. On one hand, lower impedance seems desirable, but on the other hand, a smaller
electrode and interelectrode distance results in a higher spatial resolution.
Multi Channel Systems provides MEAs with TiN electrodes with sizes of 10, 20, or 30 µm and gold
electrodes with 100 µm, which all show an excellent performance and low noise level. The average
noise level of 30 µm and 10 µm electrodes is less than 10 µV and 15 µV peak to peak, respectively.
Gold electrodes (EcoMEAs) are only available with a low spatial resolution and are useful for medium
throughput screening, where costs are a limiting factor.
All planar TiN electrodes are positioned on a round pad with a diameter of 40 µm. If you like to check
the electrodes with a light microscope, you will need an upright microscope to see the MEA from above.
With an inverse microscope, you are only able to see the (bigger) pad from below, not the electrode itself.
The electrodes are embedded in a carrier material, usually glass. Standard tracks made of titanium (Ti)
or indium tin oxide (ITO) are electrically isolated with silicon nitride (SiN). Standard contact pads are made
of titanium nitride (TiN) or indium tin oxide (ITO). ITO contact pads and tracks are transparent, for a perfect
view of the specimen under the microscope.

11

MEA Manual

4

MEA Types and Layouts
Various types of MEA biosensors are available for all kind of extracellular multi channel recordings.
Typical MEAs for in vitro applications have 60 microelectrodes arranged in an 8 x 8 layout grid
embedded in a transparent glass substrate. You can cultivate the tissue or cell culture directly on the MEA.
EcoFlex- and FlexMEAs are made for in vivo and in vitro applications.
MEA types differ in the materials used for the carrier and the recording area, and in the geometry, that is,
electrode size and interelectrode distances. The electrode size and interelectrode distances are used for
categorizing MEAs: The first number refers to the interelectrode distance, for example 200 µm, and the
second number refers to the electrode size, for example 10 µm, which results in the standard MEA type
200/10, for example.
Standard versions are available with an internal reference electrode (abbreviated “iR”) and with various
culture chamber interface options. Culture chambers are available with and without lid.
Please ask for custom layouts, that is, MEA layouts according to your specifications.
In this chapter, each MEA type is briefly described and noted.


Standard MEAs with flat round TiN electrodes in an 8 x 8 layout grid for all applications.



MEAs with 6 x 10 layout grid and 500 µm inter electrode distances.



HighDenseMEAs with the highest spatial resolution and a double recording field of 5 x 6 electrodes each.



HexaMEAs featuring a hexagonal layout, perfect for recording from retina.



ThinMEAs with a "thickness" of only 180 µm, ideally suited for high-resolution imaging.



Three dimensional MEAs, 3D-MEAs with tip sharped electrodes to penetrate the dead cell layers of a slice.



Very cost efficient and robust EcoMEAs on glass or PCB (printed circuit board) base for applications with
lower spatial resolution and higher throughput, especially for established cardiomyocyte cultures, large
slices, or whole-heart preparations.



Perforated MEAs allow perfusing the acute slice from up- and downside. For use with MEA2100
headstages equipped with perfusion element (MEA2100-PE) and MEA1060 amplifiers with perfusion
ground plate (MEA-PGP) or with.



Small perforated MEAs with 32 recording and 12 stimulation electrodes specified for use with
MEA2100-32- and USB-MEA32-STIM4-System.



6 well MEAs feature a round MEA layout, separated in six segments of 3 x 3 electrodes, like a pie-chart.
Using the 6 well MEA with macrolon triangle or round chamber ring, you have 6 separate culture chambers
on one MEA, for example, for drug application in a screening experiment.



4 quadrant 1000 MEAs with electrode layout organized in four quadrants and a center line.



256MEAs with 252 recording electrodes in a 16 x 16 layout grid for use with USB-MEA256-System.



6 well MEAs for use with USB-MEA256-System. 252 electrodes in 6 blocks of 6 x 7 electrodes in a round
layout for use with 6 well macrolon triangle or round chamber rings. You have 6 separate culture chambers
on one MEA, for example, for drug application in a screening experiment.



9 well MEAs for use with USB-MEA256-System. 256 electrodes in nine blocks of 26 recording, two
stimulation and reference electrodes each. Using the 9 well MEA with macrolon quadrant, you have
9 separate culture chambers, for example, for drug application in a screening experiment.



120MEAs and a perforated 120pMEA with 12 x 12 layout grid for use with MEA2100-120-System only.

12

MEA Manual


Square MEAs with TiN (Titanium nitride) electrodes in 50 x 50 µm square size in a 8 x 8 layout grid.



PEDOT-CNT MEAs with carbon nanotube – poly 3,4-ethylene-dioxythiophene electrodes and gold tracks
and contact pads have very low impedance values of approximately 20 kThey are ideal for stimulation
and have excellent biocompatibility and cell adhesion.



FlexMEAs made of flexible polyimide 2611 foil, perfect for in vivo and specific in vitro applications, for
example, whole-heart preparations. Available with 36 (FlexMEA36) or 72 (FlexMEA72) TiN (Titanium nitride)
electrodes.



EcoFlexMEAs made of flexible polyimide (Kapton) as well, but very cost efficient and more robust than
FlexMEAs from polyimide foil. Available with 36 (EcoFlexMEA36) or 24 (EcoFlex24) gold electrodes.

4.1 Standard Electrode Numbering

The numbering of MEA electrodes in the 8 x 8 grid (standard MEAs, ThinMEAs, EcoMEAs, pMEAs)
follows the standard numbering scheme for square grids: The first digit is the column number and
the second digit is the row number. For example, electrode 23 is positioned in the third row of the
second column.
These numbers are the same numbers that are used as channel numbers in the MCS data acquisition
software, for example the Multi Channel Suite or MC_Rack program. Using MC_Rack please make sure
that you have selected the two-dimensional MEA layout as the “Channel Layout” in “Data Source Setup”.
For more details, please refer to the MC_Rack manual or help.
Important: MEAs are not symmetrical! That is, why the writing (for example NMI, LEITER, MEA type) on
the MEA chip should be on the right side viewed from the front, with the sockets of the amplifier in the
back. MEAs with one big internal reference electrode should be placed with reference electrode to the left
side in the amplifier. Otherwise, the MEA layout will not match with the pin layout of the channel map in
the data acquisition software.
Other electrode grids are described in the next chapter, and in the Appendix.

13

MEA Manual

4.2 Standard MEA
60MEA200/30iR-Ti, 60MEA200/30iR-ITO, 60MEA200/10iR-Ti, 60MEA100/10iR-TI,
60MEA500/30iR-Ti, 60MEA500/30iR-ITO, 60MEA500/10iR-Ti
Standard MEAs have 60 electrodes in an 8 x 8 layout grid with electrode diameters of 10 µm or 30 µm,
and interelectrode distances of 100 µm, 200 µm. The MEAs with an interelectrode distance of 500 µm
have a 6 x 10 layout grid.
Versions 200/10, 200/30, 100/10 are available with an internal reference electrode as indicated by the
abbreviation iR. You connect the internal reference electrode directly to the amplifier's ground, so there
is no need for silver pellets for grounding the bath. Please refer to the MEA manual delivered with your
MEA amplifier for further information.
The flat, round electrodes are made of titanium nitride (TiN). MEAs with TiN electrodes are very stable.
Therefore, the MEAs can be reused several times and are perfect for long-time experiments (up to several
weeks and even months). The electrode impedance ranges between < 100 k for 30 µm electrodes and
250 to 400 kfor 10 µm electrodes depending on the electrode diameter. Generally, the smaller the
electrode, the higher is the impedance.
Tracks are made of titanium (Ti) and contact pads are made of titanium nitride (TiN) or indium tin oxide
(ITO); insulation material is silicon nitride. ITO contact pads and tracks are transparent, for a perfect view
of the specimen under the microscope.
Important: MEAs are not symmetrical! That is, why the writing (for example NMI, LEITER, MEA type) on
the MEA chip should be on the right side viewed from the front, with the sockets of the amplifier in the
back. MEAs with one big internal reference electrode should be placed with reference electrode to the
left side in the amplifier. Otherwise, the MEA layout will not match with the pin layout of the channel
map in the data acquisition software.
Using standard MEAs
Standard MEAs can be used for a wide variety of applications. They are robust and heat-stabilized. They can
be autoclaved and coated with different procedures for cell and tissue cultures. Generally, they can be used
for acute experiments as well as long-term cultures.

14

MEA Manual

4.3 High Density MEA: 60HDMEA
60HDMEA30/10iR-ITO

10 µm electrodes are arranged in two recording fields with 5 x 6 electrodes each. The interelectrode
spacing is only 30 µm center to center.
The very high electrode density of the two recording fields on a 60HDMEA is only possible by the special
TiN electrode material and production process. This MEA type is especially useful for applications, where
a high spatial resolution is critical, for example, for multitrode analysis.
For example, the very high spatial resolution of the high density MEAs is very useful for recording from
retina ganglia cells. The double recording field can also be used for coculturing two slices, each on one
recording field. The flat, round electrodes are made of titanium nitride (TiN).Tracks and contact pads are
made of transparent indium tin oxide (ITO); insulation material is silicon nitride.
60HDMEA30/10iR-ITO MEAs are available with internal reference electrode.
Using 60HDMEAs
The same material is used for standard MEAs and high density MEAs. Therefore, they are equally robust
and heat-stabilized. They can be autoclaved and coated with different procedures for cell and tissue
cultures.

15

MEA Manual

4.4 Hexa MEA: 60HexaMEA40/10
60HexaMEA40/10iR-ITO

Electrode layout for 60HexaMEA40/10iR-ITO.

HexaMEAs feature a hexagonal layout, perfect for recording from retina.
The specific layout of the electrodes resembles ideally the regularity of the retina's architecture.
The insulation material is silicon nitride.
Electrodes in the center have a diameter of 10 µm with an interelectrode distance of 40 µm.
This HexaMEA provides an internal reference electrode.
The electrodes of 60HexaMEA40/10iR-ITO are configured with invariable interelectrode distance
of 40 µm, and with TiN electrodes of 10 µm diameter. They include a big internal reference electrode.
The tracks and contact pads are made of ITO.
Using 60HexaMEAs
The same material is used for standard MEAs and HexaMEAs. Therefore, they are equally robust and
heat-stabilized. They can be autoclaved and coated with different procedures for cell and tissue cultures.

16

MEA Manual

4.5 Thin MEA: 60ThinMEA
60ThinMEA200/30iR-ITO, 60ThinMEA30/10iR-ITO

60ThinMEAs are only 180 µm "thick", ideally suited for high-resolution imaging. 60ThinMEAs are like
standard MEAs, but the electrodes are embedded in a very thin and delicate glass substrate on a robust
ceramic carrier. The thin glass allows the use of oil immersion objectives with a high numerical aperture.
Like standard MEAs, 59 electrodes and one reference electrode are arranged in an 8 x 8 layout grid with
electrode diameters of 30 µm and interelectrode distances of 200 µm.
60ThinMEAs are also available in a double 5 x 6 layout grid with 10 µm TiN electrodes and 30 µm
interelectrode distance like the High Dense MEA (60ThinMEA30/10iR-ITO).
The flat, round electrodes are made of titanium nitride (TiN).
Tracks and contact pads are made of transparent ITO; insulation material is silicon nitride.
Using 60ThinMEAs
60ThinMEAs are heat-stabilized and can be autoclaved. They can also be coated with different procedures
for cell and tissue cultures.
They should be handled with great care because of the thin and delicate recording area.

17

MEA Manual

4.6 Three dimensional MEA: 60-3DMEA
60-3DMEA200/12iR-Ti

60-3DMEAs are the ideal solution for acute slices, because the three dimensionally shaped electrodes are
intended to penetrate dead cell layers. Using conventional flat electrodes, the electrodes may interface with
the damaged cell layer rather than with the healthy cells. The three dimensional electrode of a 3D MEA may
be able to penetrate this cell layer and contact the healthy cells above better.
The tip-shaped electrode results in a larger surface area, etched from glass with a diameter of 100 µm.
The spatial resolution is limited. 59 electrodes and one reference electrode are aligned in an 8 x 8 grid
with interelectrode distances of 200 µm.
The Titanium nitride (TiN) electrodes are 20 µm high and have a diameter of about 12 µm at the base,
ending in a fine small tip.
Tracks and contact pads are made of Titanium (Ti); the insulation material is Silicone nitride (SiN).
Using 60-3DMEAs
The same material is used for standard MEAs and 60-3DMEAs. Therefore, they are also heat-stabilized.
They can be autoclaved and coated with different procedures for cell and tissue cultures.
Due to the production process and the fine tip, there may be more variations in the electrode impedance,
which is important for stimulation experiments, especially with current.

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4.7 Eco MEA: 60EcoMEA
60EcoMEA, 60EcoMEA-Glass
60EcoMEAs are available on opaque printed circuit board (PCB) and on transparent glass base (60EcoMEAGlass). They are low price variants for medium throughput applications like small screens where material
costs play a bigger role than in more scientific MEA applications.

60EcoMEAs are opaque and are therefore useful only for applications where you do not need a visual
control under a microscope, for example, for established cell cultures. 60EcoMEA-Glasses are transparent
all-purpose MEAs.
Due to the special production process on PCB, electrodes of 60EcoMEAs are available only with
a diameter of 100 µm and an interelectrode distance of 700 µm. The electrodes on an 60EcoMEA-Glass
also have a diameter of 100 µm and a distance of 700 µm. Thus, 60EcoMEA or 60EcoMEA-Glass are
useful for applications where a high spatial resolution is not important, but which emphasize on low price
consumables. They have proven to be especially useful for recordings from established cardiomyocyte
cultures. They are not useful for establishing a new cell culture, as the cell performance cannot be
monitored. Multi Channel Systems recommends to use standard 200/30 MEAs for establishing the cell
culture first, then switch to 60EcoMEA or 60EcoMEA-Glass.
60EcoMEAs are provided in the typical 8 x 8 layout with internal reference electrode. Custom layouts
following your personal specifications are possible at very reasonable prices. Please ask your local retailer
for details. Electrodes, tracks, and contact pads are made of pure gold. Due to the soft gold material
of the contact pads, the contact to the amplifier pins is excellent. The insulation material on EcoMEA-Glass
chips is SU-8 (photoresist, 1 - 2 μm).
Using 60EcoMEAs
Like standard MEAs, 60EcoMEAs and 60EcoMEA-Glass are very robust. They can be coated with different
procedures for cell and tissue cultures. The gold electrodes are very robust, too, and are the only MEA
electrodes that will endure more severe cleaning methods.
Important: Please do not autoclave 60EcoMEA-Glass! Rinse with 70 % Ethanol or expose the MEA to
ultraviolet light for sterilization.
New 60EcoMEAs are very hydrophobic. They should be coated with nitrocellulose or treated with a plasma
cleaner before use.

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4.8 Perforated MEA: 60pMEA
60pMEA200/30iR-Ti

60pMEA100/30iR-Ti

Acute slice recordings on common glass MEAs are done from the cells at the bottom of the slice, which are
in contact with the MEA electrodes. These cells get less oxygen and nutrients from the perfusion medium,
and therefore are likely to give smaller signals and might eventually die first. Perforated MEAs present a
solution to this problem as they allow a perfusion of the tissue from both sides at the same time, thereby
optimizing the oxygen supply of the acute slice.
Perforated MEAs are identical in size and function to the regular MEAs. The recording electrodes are
arranged in 8 x 8 standard layout grid in 60pMEA200/30iR-Ti, and in 6 x 10 layout grid in
60pMEA100/30iR-Ti. The electrodes are integrated into a thin polyimide foil. This thin foil is fixed on
a ceramic or glass waver for mechanical stability. In the middle of the waver, under the electrode field,
there is a hole that makes it possible to access the electrode field from below. The area around the
electrodes is perforated to allow a perfusion of the tissue from both sides. The total area of the holes
averages 0.8 mm, the diameters of the holes varies between 20 µm and 90 µm.
These pMEAs are designed for use with MEA2100-System headstages with perfusion element (PE) and
MEA1060 amplifier equipped with a perfusion ground plate (PGP). The PE or PGP replaces the standard
ground plate of the headstage or MEA1060 amplifier. Please note that there are different types of the
MEA-PGPs for different amplifier types (MEA1060-UP-PGP, MEA1060-UP-BC-PGP, and MEA1060-INV /
INV-BC-PGP). Additional to the use of 60pMEAs together with the MEA2100-(2x)60-System, you can use
120pMEAs with MEA2100-120-System equipped with a perfusion element (PE) integrated in the ground
plate of the headstage.
For an overview of suggested configurations to work with 60pMEAs, see the MEA Application Note
“Acute Hippocampal Slices on pMEAs”.
Using 60pMEAs
Perforated MEAs have a robust ceramic carrier or they are mounted on glass as usual, but the electrodes
are embedded in polyimide foil. Therefore they are heat stable to 50 °C only, and cannot be autoclaved.
Please do not use an ultrasonic bath for cleaning.

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4.9 Perforated MEAs for Use with MEA2100-32-System
and USB-MEA32-STIM4-System
pMEA-32S12-L1, pMEA-32S12-L2, pMEA-32S12-L3, pMEA-32S12-L4

pMEA-32S12-Lx
For the USB-MEA32-STIM4-System small perforated MEAs have been designed. Please see USB-MEA32STIM4 manual for detailed information. Additionally the MEA2100-32-System is adapted for these small
type of MEA. The pMEAs are different in size, but identical in function to the regular pMEAs. Layout 1
(pMEA-32S12-L1) of the perforated MEAs designed for the MEA2100-32- and for the USB-MEA32STIM4-System has been optimized for acute hippocampal slices.
The flat, round electrodes are made of titanium nitride (TiN) with a diameter of 30 µm for the recording
electrodes, and 50 µm for the stimulation electrodes. The stimulation electrodes cannot be used for
recording, and vice versa. The interelectrode distances vary from 150 to 200 µm. MEAs with titanium
nitride (TiN) electrodes are very stable. Therefore, the pMEA can be reused several times and is perfect
for long-time experiments (up to several weeks and even months). The electrode impedance is < 100 k.
Tracks and contact pads are made of titanium nitride (TiN), the insulation material is polyimide, respectively.
The electrodes are integrated into a thin polyimide foil. This thin foil is fixed on a ceramic waver for
mechanical stability. In the middle of the waver, under the electrode field, there is a hole that makes it
possible to access the electrode field from below. The area around the electrodes is perforated to apply
suction to the slice from below. The total area of the holes averages 0.8 mm, the diameters of the holes
varies from 20 to 90 µm. Please read chapter "Working with the USB-MEA32-STIM4 Amplifier"
in USB-MEA32-STIM4 manual or “Setting up the MEA” in the MEA2100 manual.
Using pMEAs
Perforated MEAs have a robust ceramic carrier, but the electrodes are embedded in polyimide foil.
Therefore they are heat stable to 50 °C only, and cannot be autoclaved. Please do not use an ultrasonic
bath for cleaning.

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4.10 MEA with 6 Wells: 60-6wellMEA
60-6wellMEA200/30iR-Ti

60-6wellMEAs are MEA chips with six independent culture chambers, separated by a macrolon ring. Inside
each well, in between the marked two bars coming out of the circle in the middle of the MEA, there is a
field of nine electrodes with an internal reference electrode. The electrode in the center of the MEA is for
grounding.

60-6wellMEAs are developed, for example, for safety-pharmacological screenings of drug induced
QT-prolongation. Multi Channel System MCS GmbH provides a software solution for these experimental
intentions, the QT-Screen-Lite program. The 60-6wellMEA allows running six experiments with identical
surrounding conditions at once. Two types of macrolon rings are available: Rings with six triangular
chambers and rings with round chambers.

The electrodes of the 60-6wellMEA are from titanium nitride (TiN), the isolation is made up of Silicon nitride
(SiN). Contact pads are from titanium nitride (TiN), and tracks are from titanium (Ti). The diameter of the
electrodes is 30 µm, the distance from centre to centre is 200 µm.
Using 60-6wellMEAs
60-6wellMEAs can be used for a wide variety of applications. They are robust and heat-stabilized. They can
be autoclaved and coated with different procedures for cell and tissue cultures. Generally, they can be used
for acute experiments as well as long-term cultures.

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4.11 256MEA for Use with MEA2100-256- and USB-MEA256-Systems
256MEA30/8-ITO, 256MEA60/10iR-ITO, 256MEA100/30-ITO, 256MEA200/30-ITO, and 256ThinMEA

The 256MEAs have to be used with MEA2100-256- and USB-MEA256-Systems. Please refer to the
respective manual for detailed information.
The 256MEA contains 252 recording, and four ground electrodes arranged in a 16 x 16 layout grid
embedded in a transparent glass substrate. The contact to the amplifier is provided by a double ring
of contact pads around the rim of the MEA. The standard material for MEAs is also used for 256MEAs:
The electrodes are from titanium nitride (TiN) with a silicon nitride (SiN) isolator, and contact pads and
tracks are made of transparent indium tin oxide (ITO).
The spacing of the electrodes in the 16 x16 grid averages 30, 60, 100 µm or 200 µm between the
electrodes. The electrode diameter of 30 µm results in an impedance of <100 k. The electrode diameter
of 10 µm results in an impedance of approximately 250 to 400 k. The dimension of the glass carrier
is 49 x 49 x 1 mm as usual. 256MEAs are stable in a temperature range from 0 ° - 125 °C.
The 256MEA is only MEA type, which is rotationally symmetric.
256ThinMEAs are only 180 µm "thick", ideally suited for high-resolution imaging. 256ThinMEAs are like
standard MEAs, but the electrodes are embedded in a very thin and delicate glass substrate on a robust
ceramic carrier. The thin glass allows the use of oil immersion objectives with a high numerical aperture.
Like 256MEAs, 252 electrodes are arranged in a 16 x 16 layout grid with electrode diameter of 30 µm,
and interelectrode distance of 200 µm (256ThinMEA200/30-ITO).
Using 256MEAs
The same material is used for standard MEAs and 256MEAs. Therefore, they are equally robust and heatstabilized. They can be autoclaved and coated with different procedures for cell and tissue cultures.
Using 256ThinMEAs
256ThinMEAs are heat-stabilized and can be autoclaved. They can also be coated with different procedures
for cell and tissue cultures. They should be handled with great care because of the thin and delicate
recording area.

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4.12 MEA with 6 Wells for Use with MEA2100-256- and USB-MEA256Systems
256-6wellMEA200/30iR-Ti

The 256-6wellMEA200/30iR-ITO has 256 electrodes and has to be used with MEA2100-256- and
USB-MEA256-Systems. Please refer to the respective manual for detailed information.
The dimension of the glass carrier is 49 x 49 x 1 mm as usual. The MEAs with 6 wells are stable
in a temperature range from 0 ° - 125 °C.
The 256-6wellMEA contains 252 recording, 6 reference and four ground electrodes arranged in 6 electrode
blocks with a 6 x 7 layout grid for the recording electrodes. The reference electrode is around each block.
They are embedded in a transparent glass substrate. The contact to the amplifier is provided by a double
ring of contact pads around the rim of the MEA. The standard material for MEAs is also used for
256-6wellMEA: The electrodes are from titanium nitride (TiN) with a silicon nitride (SiN) isolator,
and contact pads and tracks are made of transparent indium tin oxide (ITO).
Using the 256-6wellMEA with macrolon ring, you have six separate culture chambers on one MEA,
for example, for drug application in a screening experiment.
The spacing between the recording electrodes in the 6 x 7 grid averages 200 µm between the electrodes.
The electrode diameter of 30 µm results in an impedance of < 100 k.
Using 256-6wellMEAs
The same material is used for standard MEAs and 256-6wellMEAs. Therefore, they are equally robust and
heat-stabilized. They can be autoclaved and coated with different procedures for cell and tissue cultures.

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4.13 MEA with 9 Wells for Use with MEA2100-256- and USB-MEA256Systems
256-9wellMEA300/30iR-ITO

The 256-9wellMEA300/30iR-ITO has 256 electrodes and has to be used with MEA2100-256and USB-MEA256-Systems. Please refer to the respective manual for detailed information.
The dimension of the glass carrier is 49 x 49 x 1 mm as usual. The MEAs with 9 wells are stable
in a temperature range from 0 ° - 125 °C.
The 256-9wellMEA contains 234 recording, 18 stimulation or recording, and four ground electrodes
arranged in nine electrode blocks with a 6 x 5 layout grid for the recording electrodes, two stimulation
or recording electrodes, and one reference electrode per each block. They are embedded in a transparent
glass substrate. The contact to the amplifier is provided by a double ring of contact pads around the rim of
the MEA. The standard material for MEAs is also used for 256-9wellMEA: The electrodes are from titanium
nitride (TiN) with a silicon nitride (SiN) isolator, and contact pads and tracks are made of transparent indium
tin oxide (ITO).
Using the 256-9wellMEA with macrolon quadrate, you have nine separate culture chambers on one MEA,
for example, for drug application in a screening experiment.
The spacing between the recording electrodes in the 6 x 5 grid averages 300 µm between the electrodes.
The electrode diameter of 30 µm results in an impedance of < 100 k. The dimension of the square
stimulation electrode is 50 x 200 µm.

Using 256-9wellMEAs
The same material is used for standard MEAs and 256-9wellMEAs. Therefore, they are equally robust and
heat-stabilized. They can be autoclaved and coated with different procedures for cell and tissue cultures.

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4.14 120MEA for Use with MEA2100-120-System
120MEA200/30iR-Ti, 120MEA100/30iR-Ti, 120pMEA200/30iR-Ti

120MEA200/30iR-Ti

120pMEA200/30iR-Ti (electrode field with perforation)

The 120MEA200/30iR-Ti has 120 electrodes and can only be used with the MEA2100-System connected
to a headstage HS120 with 120 electrodes. Please refer to the MEA2100-System manual for detailed
information.
The dimension of the glass carrier is 49 x 49 x 1 mm as usual. The MEAs with 120 electrodes are stable
in a temperature range from 0 ° - 125 °C.
The 120MEA200/30iR-Ti contains 120 recording, four reference and four ground electrodes arranged in
a 12 x 12 layout grid. They are embedded in a transparent glass substrate. The contact to the amplifier is
provided by a double ring of contact pads around the rim of the MEA. The standard material for MEAs is
also used for 120MEA200/30iR-Ti: The electrodes are from titanium nitride (TiN) with a silicon nitride (SiN)
isolator, and contact pads and tracks are made of titanium nitride (TiN).
The spacing between the recording electrodes in the 12 x 12 grid averages 100 or 200 µm between
the electrodes. The electrode diameter of 30 µm results in an impedance of < 100 k.
This MEA is also available as perforated 120pMEA200/30iR-Ti. The electrodes are from Titan Gold Titan,
all other MEA parameters are the same. The inner diameter around the electrodes of 3 to 4 mm2
is perforated and the total area of holes is 12 % of these area.
Using 120MEAs
The same material is used for standard MEAs and 120MEA200/30iR-Ti and 120MEA100/30iR-Ti. Therefore,
they are equally robust and heat-stabilized. They can be autoclaved and coated with different procedures
for cell and tissue cultures.
Using 120pMEA200/30iR-Ti
Perforated MEAs have a glass carrier, but the electrodes are embedded in polyimide foil. Therefore they
are heat stable to 50 °C only, and cannot be autoclaved. Please do not use an ultrasonic bath for cleaning.

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4.15 120MEA1000-1500/30iR-Ti for Use with MEA2100-120-System
120MEA1000-1500/30iR-Ti

120MEA1000-1500/30iR-Ti
The 120MEA1000-1500/30iR-Ti has 120 electrodes and can only be used with the MEA2100-System
connected to a headstage HS120 with 120 electrodes. Please refer to the MEA2100-System manual
for detailed information.
The dimension of the glass carrier is 49 x 49 x 1 mm as usual. The MEAs with 120 electrodes are stable
in a temperature range from 0 ° - 125 °C.
The 120MEA1000-1500/30iR-Ti contains 120 recording, four reference and four ground electrodes
arranged in a 12 x 120 layout grid. They are embedded in a transparent glass substrate. The contact
to the amplifier is provided by a double ring of contact pads around the rim of the MEA. The standard
material for MEAs is also used for 120MEA200/30iR-Ti: The electrodes are from titanium nitride (TiN)
with a silicon nitride (SiN) isolator, and contact pads and tracks are made of titanium nitride (TiN).
The wide spacing between the recording electrodes in the 12 x 10 grid is 1000 μm in vertical and
1500 μm in horizontal direction. The electrode diameter of 30 µm results in an impedance of < 100 k.
Using 120pMEA1000-1500/30iR-Ti
The same material is used for standard MEAs and 120MEA200/30iR-Ti and 120MEA1000-1500/30iR-Ti.
Therefore, they are equally robust and heat-stabilized. They can be autoclaved and coated with different
procedures for cell and tissue cultures.

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4.16 Quadrant MEA: 60-4QMEA1000
60-4QMEA1000iR-Ti

The 60-4QMEA1000 has 60 electrodes organized in four quadrants (13 electrodes each) with a center line
(7 electrodes). The electrode diameter is 30 µm, and the interelectrode distance varies: Inside the quadrants
the distance is 200 µm, from quadrant to quadrant the distance is 1000 µm, and to the center line it is
500 µm.
The 60-4QMEA1000 is available with an internal reference electrode.
The flat, round electrodes are made of titanium nitride (TiN). MEAs with TiN electrodes are very stable.
Therefore, the MEAs can be reused several times and are perfect for long-time experiments (up to several
weeks and even months). The electrode impedance is < 100 k.
Tracks are made of titanium (Ti) and contact pads are made of titanium nitride (TiN); insulation material
is silicon nitride (SiN).
Using 60-4QMEA1000
The 60-4QMEA1000 can be used for a wide variety of applications. They are robust and heat-stabilized.
They can be autoclaved and coated with different procedures for cell and tissue cultures. Generally,
they can be used for acute experiments as well as long-term cultures.

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4.17 Square MEA: 60SquareMEA
60SquareMEA200/50iR-Ti

60SquareMEAs have 60 electrodes in an 8 x 8 layout grid with square electrode of 50 x 50 µm size and
interelectrode distances of 200 µm. They are available with an internal reference electrode. You can
connect the internal reference electrode directly to the amplifier's ground and will not need silver pellets
for grounding the bath anymore.
The flat, square electrodes are made of titanium nitride (TiN). The electrode size of 50 x 50 µm guarantees
very low noise. MEAs with TiN electrodes are very stable. Therefore, the MEAs can be reused several times
and are perfect for long-time experiments (up to several weeks and even months). The electrode impedance
ranges about 100 k
Tracks are made of titanium (Ti) and contact pads are made of titanium nitride (TiN); insulation material
is silicon nitride.
Important: MEAs are not symmetrical! That is, why the writing (for example NMI, LEITER, MEA type) on
the MEA chip should be on the right side viewed from the front, with the sockets of the amplifier in the
back. MEAs with one big internal reference electrode should be placed with reference electrode to the left
side in the amplifier. Otherwise, the MEA layout will not match with the pin layout of the channel map in
the data acquisition software.
Using 60SquareMEAs
MEAs with square electrodes can be used for a wide variety of applications. They are robust and heatstabilized. They can be autoclaved and coated with different procedures for cell and tissue cultures.
Generally, they can be used for acute experiments as well as long-term cultures.

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4.18 PEDOT-CNT MEAs: 60PedotMEA
60PedotMEA200/30iR-Au

Carbon nanotube structure of PEDOT electrodes.

60PedotMEAs have - like standard MEAs - 59 electrodes and one reference electrode that are arranged
in an 8 x 8 layout grid with electrode diameters of 30 µm and interelectrode distances of 200 µm.
The flat, round electrodes are made of PEDOT-CNT carbon nanotube – poly 3,4-ethylene-dioxythiophene.
Contact pads and track material is made of titanium nitride (TiN) covered by a layer of gold (Au).
The insulation material is silicon nitride.
This type of MEA is characterized by very low impedance values of approximately 20 k.They are ideal
for stimulation and have excellent biocompatibility and cell adhesion.
Important: MEAs are not symmetrical! That is, why the writing (for example NMI, LEITER, MEA type) on
the MEA chip should be on the right side viewed from the front, with the sockets of the amplifier in the
back. MEAs with one big internal reference electrode should be placed with reference electrode to the left
side in the amplifier. Otherwise, the MEA layout will not match with the pin layout of the channel map in
the data acquisition software.
Using 60PedotMEAs
MEAs with PEDOT-CNT electrodes can be used for a wide variety of applications. They are robust and
heat-stabilized. They can be autoclaved and coated with different procedures for cell and tissue cultures.
Generally, they can be used for acute experiments as well as long-term cultures.

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4.19 FlexMEA
FlexMEAs are made of flexible polyimide foil, perfect for in vivo and specific in vitro applications.
Only 12 µm "thick" and weighing less than 1 g, the FlexMEA biosensor is very thin and light weight.
The FlexMEAs are available with 32 (64) recording electrodes plus two (four) indifferent reference
electrodes and two (four) ground electrodes in a 6 x 6 (8 x 9) electrodes grid. More layouts can be
provided on request. The flexible base is perforated for a better contact with the surrounding tissue.
The electrodes are from titanium nitride (TiN), contact pads and track material from pure gold.
FlexMEAs are stable at a temperature range from 10 °C to 125 °C and can be autoclaved.
Using FlexMEAs
Warning: Do not use an ultrasonic bath for cleaning. The manufacturer recommends sterilization
by rinsing with alcohol.
FlexMEAs are usually connected to a head stage preamplifier that is connected to a filter amplifier
or programmable gain amplifier (see also the ME-System product line of Multi Channel Systems).
Via provided adapters FlexMEAs can be connected to 32-channel miniature preamplifiers MPA32I
from Multi Channel Systems for in vivo experiments. There is no need for an adapter if the FlexMEA
should be connected to the 32-channel miniature preamplifier MPA32I-Flex.

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FlexMEA36

The FlexMEA36 has 32 recording electrodes plus two internal reference electrodes and two ground
electrodes in a 6 x 6 electrodes grid. The titanium nitride electrodes have a diameter of 30 µm, and
the distance between the electrodes is 300 µm. The polyimide foil is perforated with holes of 30 µm
diameter, ensuring optimal tissue contact.
When using the FlexMEA36 together with a standard 32-channel miniature preamplifier MPA32I,
you need the ADPT-FM-32 adapter to connect the FlexMEA36 to the standard MPA32I. There is no
need for an adapter if you use the FlexMEA36 specified 32-channel miniature preamplifier MPA32I-Flex.
Please read the data sheet FlexMEA36, and the MPA32I (-Flex) manual for more information.

FlexMEA72

The FlexMEA72 has 64 recording electrodes plus four internal reference electrodes and four ground
electrodes in an 8 x 9 electrodes grid. The titanium nitride electrodes have a diameter of 100 µm, and
the distance between the electrodes is either 625 µm or 750 µm. The polyimide foil is perforated with
holes of 100 µm diameter, ensuring optimal tissue contact.
When using the FlexMEA72 together with two standard 32-channel miniature preamplifier MPA32I,
you need the ADPT-FM-72 adapter to connect the FlexMEA72 to two standard MPA32Is. Please read
the data sheet FlexMEA72 or ADPT-FM-72, and the MPA32I manual for more information.

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4.20 EcoFlexMEA
EcoFlexMEAs are made of flexible polyimide (Kapton). They are less flexible as FlexMEAs, but therefore
more robust in handling and sterilization. With a thickness of 50 µm and low weight the EcoFlexMEA
is perfect for in vivo and specific in vitro applications, respectively.
The EcoFlexMEA is available with 24 or 36 electrodes, two internal reference electrodes, and two ground
electrodes. Custom layouts can be provided on request.
The electrodes, contact pads and track material are made of pure gold. EcoFlexMEAs are stable
at a temperature range from 0 °C to 125 °C and can be autoclaved.
The EcoFlexMEA can directly be connected to a standard 32-channel miniature preamplifier MPA32I,
you do not need an adapter. An additional connector on the side of the EcoFlexMEA36 can be used for
connecting a silver pellet or a silver wire for grounding the bath. Please read the data sheet EcoFlexMEA,
and the MPA32I manual for more information.
Using EcoFlexMEAs
EcoFlexMEAs are usually connected to a head stage preamplifier that is connected to a filter amplifier or
programmable gain amplifier (see also the ME-System product line of Multi Channel Systems). EcoFlexMEAs
can be directly connected to a 32-channel miniature preamplifier from Multi Channel Systems for in vivo
experiments.

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EcoFlexMEA36

The EcoFlexMEA36 has 32 recording electrodes, two internal reference electrodes, and two ground
electrodes in a 6 x 6 electrode grid. The recording electrodes have a diameter of 50 µm, the distance
between the electrodes from center to center is 300 µm. The electrodes, contact pads and track material
are made of pure gold. EcoFlexMEA36 is stable at a temperature range from 0 °C to 125 °C and can be
autoclaved.
The EcoFlexMEA36 can directly be connected to a standard 32-channel miniature preamplifier MPA32I,
you do not need an adapter. The connector on the right side of the MEA (see picture) can be used for
connecting a silver pellet or a silver wire for grounding the bath. Please read the data sheet EcoFlexMEA36,
and the MPA32I manual for more information.

EcoFlexMEA24

The EcoFlexMEA24 has 24 recording electrodes, two internal reference electrodes, and two ground
electrodes in a 2 x 10 + 4 electrode grid. The recording electrodes have a diameter of 80 µm, the distance
between the electrodes from center to center is 300 µm. The electrodes, contact pads and track material
are made of pure gold. EcoFlexMEA36 is stable at a temperature range from 0 °C to 125 °C and can be
autoclaved.
The EcoFlexMEA36 can directly be connected to a standard 32-channel miniature preamplifier MPA32I,
you do not need an adapter. Please read the data sheet EcoFlexMEA24, and the MPA32I manual for more
information.

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4.21 MEA Signal Generator: 60MEA-SG

60MEA-SG
The 60MEA-Signal Generator is a convenient tool for MEA-Systems first time users. It can replace
a MEA for learning and / or teaching purposes. The device has the same dimensions and contact pad
layout as a 60-channel MEA chip, and is compatible with all MEA1060 amplifier types and with the
MEA2100-System with 60-channel headstage, MEA2100-HS60 or MEA2100-HS2x60.
The MEA-SG produces sine waves, or replays a variety of biological signals. These signals are fed
into the MEA amplifier as analog signals. With this artificial data, you are able to test the functionality
of the hardware and software system, without the need for a biological sample on a real MEA. Please
use the 256MEA-SG for the USB-MEA256-System and the 120MEA-SG for MEA2100-System connected
to a headstage with 120 channels, the MEA2100-HS120.

256MEA-SG

120MEA-SG

For FlexMEAs, connected to ME-Systems and for wireless headstages, connected to the Wireless-System
you can use a specially adapted signal generator ME/W-SG.

ME/W-SG

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5 MEA Handling
Warning: If possible, use only liquids or cleaning solutions with a neutral pH = 7 on MEAs. Do not
expose MEAs with silicon nitride insulation or TiN electrodes to basic liquids (pH > 7) or aggressive
detergents for a longer period of time. Basic or aggressive liquids may damage TiN electrodes
irreversibly.
Warning: It is absolutely necessary to rinse the MEAs thoroughly with distilled water after treatment
with detergent, particular when using Terg-A-Zym before heat sterilization (dry heat sterilization
is not recommended). Otherwise the potential rests of the detergent may burn into the glass carrier
of the MEA and may destroy the electrodes.
Warning: Do not touch the electrode field in any way during the coating or cleaning procedure.
Keep all instruments, tissues, pipette tips, and similar at a safe distance from the recording area.
The electrodes are easily damaged (except EcoMEA electrodes).

5.1 Hydrophilic Surface Treatment
The surface of new MEAs is hydrophobic, and even hydrophilic MEAs tend to become hydrophobic again
during storage. A hydrophobic surface prevents attachment and growth of the (hydrophilic) cells. The first
step in preparing a MEA for use is therefore to ensure that the surface is hydrophilic enough for coating
and cell adhesion.
To test this without contaminating the surface, place a small drop of water on the MEA surface outside
the culture chamber. If the drop does not wet the surface, you likely need to perform one of the following
steps, in particular when using new arrays.
Literature
Ulrich Egert, Thomas Meyer (2004); Heart on a Chip — Extracellular multielectrode recordings from cardiac
myocytes in vitro, "Methods in Cardiovascular Research", S. Dhein and M. Delmar (eds.)

5.1.1

Plasma Cleaning
Laboratories with access to electron microscopy facilities are likely to have a sputter device or a plasmacleaning chamber (for example Plasma Technology, Herrenberg, Germany or PDC-32G from Harrick Plasma,
Ithaca, NY, United States). The MEA surface is exposed to a gas plasma discharge, which will make the
surface polar and thus more hydrophilic. The treatment gives a very clean and sterile surface that can be
coated readily with water-soluble molecules. Note that the effect wears off after a few days.
Plasma cleaner parameters: MEAs can be treated with low-vacuum plasma for 1 to 2 minutes at 0.2 mbar
and 50 to 100 W. Additional supply of atmospheric air or O 2 is recommended.
Protein Coating
If protein coating is acceptable in the planned experiments, there is another quick and simple way to render
the surface hydrophilic.

1. Sterilize the MEAs as described below.
2. Place approximately 1 ml of a concentrated, sterile protein solution (for example, albumin, fetal calf serum
or similar) onto the culture region for about 30 min.
3. Wash the culture chamber thoroughly with sterile water afterwards. The MEA can then be directly used for
cell culture.

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5.1.2

Preculturing
Another pragmatic method is to coat the hydrophobic MEAs and to plate the cell cultures on the MEA, and
let it grow for some days (up to weeks) until the cells have transformed the surface so that it is sufficiently
hydrophilic. The “preculture” will generally show very bad growth and viability, and needs to be discarded
before plating the culture that will be used for experiments.
Please note that the MEA and the electrode performance may suffer under cell culturing. Therefore,
the above-mentioned methods are preferable.

5.2 Sterilization
Sterilization of MEAs is not necessary for acute slices.
Glass MEAs with TiN electrodes and EcoMEAs with gold electrodes can be sterilized with standard methods
for cell culture materials using either rinsing with 70 % alcohol, UV-light (about half an hour depending
on the intensity), vapor autoclavation, or dry-heat sterilization up to a temperature maximum of
125 °C.
Warning: Do not autoclave or sterilize perforated MEAs by heat. These MEA types are not thermo-resistant,
and will be irreversibly damaged.

5.2.1

Sterilization with Ethanol and Ultraviolet Light

 Rinse MEAs with 70 % ethanol. Do not immerse the MEA into the alcohol for a longer time otherwise
the ring on the MEA will probably get off.
 Let MEAs air-dry overnight on a sterile workbench (laminar flow hood) with UV light turned on.

5.2.2

Steam Sterilization (Autoclavation)

 Autoclave MEAs at 125 °C for 15 min.

5.2.3

Dry-Heat Sterilization
Dry-heat sterilization is possible if a stream autoclave is not available, which is the better choice.
Please clean the MEA thoroughly with distilled water before using the oven, otherwise potential
rests of any material may burn into the glass carrier of the MEA and may destroy the electrodes.

 Thermally sterilize MEAs in an oven at 121 °C for 15 min.
 Thermally sterilize FlexMEAs in an oven at 121 °C for 15 min.
 Thermally sterilize pMEAs in an oven at 50 °C for 2 hours.

5.2.4

Sterilization with Hot Water

 Expose MEAs to hot water (90 °C) for 1 min.

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5.3 MEA Storage
To maintain a hydrophilic surface after hydrophilization, it is recommended to store the MEAs filled
with distilled water until use. Dry MEAs will get hydrophobic again after some time.
Store MEAs filled with sterile distilled water at 4 °C in the dark (that is, in the fridge, to prevent
microbiological contaminations) to maintain a hydrophilic surface.

5.4 MEA Coating
Coating of MEAs with various materials is used for improving the attachment and growth of cell cultures
or cultured slices. Coating is generally not required for recordings from acute slices.
Coating of MEAs has the same purpose than coating of other culture dishes. Therefore, you can generally
use the same standard protocols that you have established for coating culture dishes for your cell cultures,
provided that the involved chemicals are not aggressive and damage the electrodes (see recommendations
for the various MEA types).
In the following, some standard coating procedures are shortly described. You should try out which coating
procedure proves best for your application. The listed materials are only recommendations; you may use
any equivalent equipment. Most coatings are stable for several uses of the MEA and do not have to be
removed after use (except nitrocellulose).
Please note that the materials and procedures described in the following are only a summary of published
information from other sources (see references) or from personal communications with MEA users, and
has the intention of helping users finding the appropriate information for setting up their experiments.
Multi Channel Systems MCS GmbH has not tested or verified this information, and therefore cannot
guarantee that the information is correct. Please refer to the referenced literature for planning and
executing any experiments.

5.4.1

Coating with Nitrocellulose
Coating with nitrocellulose is a fast procedure that works with several cell types and tissues and that
is also successful with slightly hydrophobic MEAs. This method has the advantage that the cells stick
well to the surface. Nitrocellulose does not form a uniform layer on the MEA. The coating leaves patches
of nitrocellulose, which serve as a glue for the tissue, on the MEA surface. The tissue is not likely to get
detached even under severe mechanical disturbance (by perfusion, for example). MEAs coated with
nitrocellulose can be stored for a few days. Nitrocellulose coating has to be removed after use.
Main advantages of this method are that nitrocellulose is cheap, coating is fast and easy,
and it is also easily removed after use.
Note: Nitrocellulose solutions cannot be stored for a longer period of time. The solution forms a visible
gelatinous precipitate after extended storage of at least half a year and will not produce satisfactory
adhesive coatings anymore. Prepare a fresh solution if there are visible precipitates.
Materials



Protran or other standard nitrocellulose membrane



100 % Methanol

(Whatman, PerkinElmer)

(Carl Roth GmbH + Co. KG, UN-No. 1230)

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MEA Manual
Nitrocellulose solution
 For preparing a stock solution, dissolve a piece of 1 cm2 nitrocellulose membrane in 10 ml methanol.
Stock solutions may be stored at room temperature in polystyrene tubes. For the working solution, dilute
the stock solution 10 : 1 with methanol. You can adjust the concentration to meet your requirements.
Procedure
1. Directly before use, pipette 3 – 5 µl of the working solution onto the recording field. The recording field
should be completely covered.
2. Remove the coating solution and let the MEA air-dry. It takes just a few seconds for the methanol
to evaporate.
Literature
Ulrich Egert, Thomas Meyer (2004); Heart on a Chip — Extracellular multielectrode recordings from cardiac
myocytes in vitro, "Methods in Cardiovascular Research", S. Dhein and M. Delmar (eds.)

5.4.2

Coating with Polyethyleneimine (PEI) plus Laminin
Polyethyleneimine (PEI) has been successfully employed for dissociated cell cultures and proven to enhance
cell maturation in culture compared to polylysine coated plates. Polyethyleneimine is a positively charged
polymer and thus changes the charge on the glass surface from negative to positive. The tissue sticks even
better with this method than with the nitrocellulose method, but the polyethylenimine forms a uniform
layer that can get more easily detached from the surface, for example, by the perfusion. This coating
method can optionally be combined with laminin.
Materials



Poly(ethyleneimine) solution (PEI)

(Sigma-Aldrich, Inc., P3143)



Boric acid, crystalline

(Fisher Scientific, A73-500)



Borax (sodium tetraborate)

(Sigma-Aldrich, Inc., B0127)



1 N HCl



Laminin, 1mg/ml
Borate buffer



3.10 g boric acid



4.75 g borax

 Dissolve in 1l distilled water at 80 °C.
 Adjust pH to 8.4 with 1 N HCl.

40

(Sigma-Aldrich, Inc., L2020)

MEA Manual
PEI stock solution
0.05 – 0.1 % PEI dissolved in borate buffer.
Laminin solution
20 µg/ml laminin in plating medium.
Procedure
Note: It is necessary to thoroughly rinse off unbound PEI from the plates before use,
as dried PEI is toxic.
1. Pipette 500 µl PEI solution onto the MEA. The recording field should be completely covered.
2. Incubate at RT for 1 h, or at 4 °C over night.
3. Remove the PEI solution and thoroughly rinse 4 x with distilled water.
4. Air-dry the MEA.
5. Sterilize with UV light for at least 1 h after coating.
6. (Place a drop of sterile laminin solution onto the MEA and incubate for 30 min. Aspirate, do not rinse,
and directly seed your cells. Alternatively, mix the cells with laminin solution before plating.)
Literature
Ulrich Egert, Thomas Meyer (2004); Heart on a Chip — Extracellular multielectrode recordings from
cardiac myocytes in vitro, "Methods in Cardiovascular Research", S. Dhein and M. Delmar (eds.)
Lelong, IH, et al. (1992); J. Neurosci. Res. 32:562-568

5.4.3

Coating with Polyornithine (plus Laminin)
Poly-D-lysine can be used as an alternative for polyornithine.
Materials



Polyornithine



Laminin, 1mg/ml

(Sigma-Aldrich, Inc., L2020)

Polyornithine solution
 500 µg/ml polyornithine in distilled water
Laminin solution
 5 µg/ml laminin in plating medium or PBS (phosphate buffered saline).

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MEA Manual
Procedure
1. Incubate the MEA with polyornithine solution at RT for 2 – 3 hours or overnight at 4 °C.
2. Aspirate the polyornithine solution and rinse the MEA 3 x with distilled water before direct use or before
the following coating with laminin. MEAs coated with polyornithine can be stored at 4 C for several
weeks.
3. Incubate pre-coated MEA with laminin solution for at least 1 h.
4. Aspirate the laminin solution and directly plate cells.
Literature
Cellular Neurobiology, A practical approach, ed. By Chad and Wheal, IRL Press, Oxford

5.4.4

Coating with Poly-D-Lysine (plus Laminin)
Poly-D-lysine has been used by several groups. Results seem to be equivalent to a coating with
polyornithine. Some users complained about cell clumping and resulting cell death when using
poly-D-lysine and had better results when using polyethylenimine (PEI).
Materials



Poly-D-lysine 5 mg / 10 mL (= 0.05 % w/v) stock solution

(Sigma-Aldrich, Inc., P7280)



Laminin solution 1 mg/ml

(Sigma-Aldrich, Inc., L2020)

Laminin solution
 20 µg/ml laminin in plating medium or PBS (phosphate buffered saline).
Procedure
1. Incubate the MEA with poly-D-lysine solution and incubate at 4 °C over night.
2. Rinse MEA with sterile distilled water 3x to remove toxic unbound lysine and let the MEAs air dry under
sterile conditions (laminar flow) before plating the cells, or before the following coating with laminin.
MEAs can be stored at 4 °C for up to two weeks.
3. Incubate pre-coated MEA with laminin solution at 4 °C over night.
4. Aspirate the laminin solution and directly plate the cells.
Literature
Goslin et al. 1988, Nature 336, 672-674
Maeda et al. 1995, J.Neurosci. 15, 6834-6845
Gross et al. 1997, Biosensors & Bioelectronics 12, 373-393

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MEA Manual

5.4.5

Coating with Poly-D-Lysine (plus Fibronectin)
This coating method is used, for example, for culturing dissociated suprachiasmatic nucleus (SCN) neurons
(on standard 60MEA200/30). It is very stable and therefore especially useful for long-term cultures.
Materials



Poly-D-lysine 5 mg / 10 mL (= 0.05 % w/v) stock solution (Sigma-Aldrich, Inc., P7280)



Fibronectin (BD BioCoat™ Fibronectin Cellware)

(BD Biosciences)

Fibronectin solution
 Prepare a stock solution of 25 µg/ml fibronectin in distilled water or PBS (phosphate buffered saline) and
store it at 4 °C.
Poly-D-Lysine plus fibronectin solution
 Prepare a 0.01 % (w/v) poly-D-lysine solution, and add fibronectin 1:1 (resulting in a final concentration
of 12.5 µg/ml).
Procedure
1. Pipette 10 µl of the poly-D-lysine plus fibronectin solution onto the recording field. Pipette about 50 µl
of sterile distilled water near the rim of the culture chamber.
2. Incubate for 1 h in an incubator set to 35 °C, 65 % relative humidity, 9 % O 2, 5 % CO2; or 37 °C,
100 % humidity, 5 % CO2. To avoid a dry out of the liquid, place the MEA in a big Petri dish with lid on.
3. Rinse 2 x with sterile distilled water.
4. Let MEAs air-dry overnight on a sterile workbench (laminar flow) with UV light turned on.

5.4.6

Coating with Fibronectin
Fibronectin is a more biological coating alternative, especially used for heart tissues. The adhesion tends
to be very stable, which allows longer cultivation times.
Materials



Fibronectin (BD BioCoat™ Fibronectin Cellware)

(BD Biosciences)

Fibronectin solution
 Prepare a stock solution of 1 mg/ml fibronectin in distilled water or PBS (phosphate buffered saline) and
store it at 4 °C. The stock solution is diluted with water or PBS to a final concentration of 10 µg/ml before
use.

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MEA Manual
Procedure
1.

Cover the MEA surface with 300 µl fibronectin solution and incubate the MEA at 37 °C
for at least 1 h.

2.

Aspirate the solution and rinse the MEA 2 x with PBS (phosphate buffered saline).

3.

Plate the cells onto the MEA immediately after coating.

Literature
Ulrich Egert, Thomas Meyer (2004); Heart on a Chip — Extracellular multielectrode recordings from
cardiac myocytes in vitro, "Methods in Cardiovascular Research", S. Dhein and M. Delmar (eds.)

5.4.7

Coating with Collagen
Coating with collagen is useful for short-term cultures. It tends to detach from the surface if used
for long-term cultures.
Materials



DMEM Dulbecco’s Modified Eagle Media (DMEM) / F12



N Hydrochloric acid, pH 3.0



Acid-soluble type I collagen solution

(Gibco/Invitrogen, 21331-020)

(3 mg/ml, pH 3.0) Cellmatrix Type I-A (Nitta Gelatin Inc.)

Preparation buffer
 200 mM HEPES in 0.08 N NaOH
Collagen solution
 Add 1 ml of 10 x DMEM/F-12 medium to 8 ml Cellmatrix Type I-A and stir gently.
 Add 1 ml of preparation buffer and stir gently.
 Incubate the mixture at 4 °C for 30 min to remove any air bubbles, if necessary.
 Store at 4 °C until use.
Procedure
1.

Sterilize the MEA before the coating with collagen and perform all following steps under sterile
conditions.

2.

Incubate the MEA at 4 °C for at least 1h.

3.

Fill the MEA with collagen solution until the bottom of the culture chamber is completely covered.
Immediately remove the collagen solution with a glass pipette. The solution can be reused.

4.

Incubate the MEA in a CO2 incubator for 30 min. Rinse the MEA with sterile distilled water. Fill the
MEA with culture medium and keep it sterile in a CO 2 incubator until use (for up to one week).
Check for contaminations before use.

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5.5 Cleaning of used MEAs
5.5.1

General Recommendations for Cleaning MEAs
The cleaning procedure depends on the kind of coating and on the kind of biological preparation. In the
following, a few general considerations are listed.



If you have recorded from an acute slice without coating, you can simply rinse the MEA with distilled water
and the MEA should be fine.



If necessary, the MEA can then be cleaned with any cleaning agent, for example, a standard dish-washing
detergent. When cleaning coated MEAs, parts of the coating may go off. You have to recoat a MEA when
the coating is not sufficient anymore, that is, when you observe problems with cell attachment or
recording.



If more severe methods are needed, the MEA can also be cleaned in an ultrasonic bath for a short moment.
But this method is a bit dangerous, because there are ultrasonic baths that are too strong and will destroy
the MEA. The behavior should be tested with an older MEA first. Generally is using an ultrasonic bath not
recommended.



EcoMEAs are easier to clean, because the golden electrodes are not so easily damaged.

5.5.2

Cleaning of pMEAs
Perforated MEAs have a robust ceramic or glass carrier, but the electrodes are embedded in polyimide foil.
Therefore, they are heat stable to 50 °C only and cannot be autoclaved.
Please do not use ultrasonic bath for pMEAs!

 Rinse with distilled water first, then apply 1% Terg-A-Zyme solution (Sigma) for several hours. Rinse
the pMEA again with distilled water and dry them directly before use. Sterilization via rinsing with 70 %
ethanol is possible. Do not immerse the pMEA into the alcohol for a longer time otherwise the ring may
probably get off!

5.5.3

Cleaning of EcoMEAs
The gold electrodes of EcoMEAs are very robust and are the only MEA electrodes that will endure more
severe cleaning methods. You can check the need for cleaning under a stereo microscope: The electrodes
should be shiny and look golden. If they are gray, or if they show a film, you should clean them.

 Carefully clean the electrodes with a swab and distilled water under microscopic control.

5.5.4

Cleaning of EcoFlexMEAs
EcoFlexMEAs made of polyimide (Kapton) have a temperature range from 0 – 125 °C. They can
be sterilized by autoclavation.

 If necessary, carefully clean the electrodes with a swab and distilled water under microscopic control.

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MEA Manual

5.5.5

Cleaning of FlexMEAs
FlexMEAs made of polyimide foil have a temperature range from 10 – 125 °C. They can be sterilized
by autoclavation.
Please do not use an ultrasonic bath for FlexMEAs!

 Rinse with distilled water first, optional with ethanol 70 %.

5.5.6

Removing Nitrocellulose Coating
Note: It is very important that you clean MEAs that have been coated with nitrocellulose and remove
all biological material first before removing the coating. If you applied methanol on an uncleaned MEA,
you would rather fix the cell debris on the MEA than actually remove the coating.
1. Directly after usage, biological material is rinsed off under running water and the MEA is cleaned
with pH-neutral cleaning agents or enzymatically if necessary.
2. Rinse the MEA 2 x with methanol. If nitrocellulose is not sufficiently removed by rinsing, incubate
the MEA filled with methanol for 15 to 30 min to dissolve the cellulose nitrate.
3. Rinse the MEA with distilled water.

5.5.7

MEA Cleaning with EDTA-Collagenase
Materials:



Collagenase Type I



0.5 mM EDTA



Phosphate buffered saline (PBS)

(Sigma-Aldrich, Inc., C0130)

(Gibco/Invitrogen, 14190-144)

Collagenase solution:
 Dissolve collagenase type I in PBS at 20 U/ml.
Method:
1.

Fill the MEA culture chamber with 0.5 mM EDTA and incubate for 30 min.

2.

Rinse the chamber 3 times with PBS.

3.

Fill the MEA with collagenase solution and incubate for at least 30 min at 37 °C.

4.

Discard the collagenase solution and rinse the MEA with distilled water at least 3 times.

5.

Air dry the MEA, preferably under a laminar flow hood.

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MEA Manual

5.5.8

MEA Cleaning with Terg-A-Zyme
Materials:



Terg-A-Zyme



Distilled water

(Sigma-Aldrich, Inc., Z273287)

Terg-A-Zyme solution:
 Prepare a 1 % solution of Terg-A-Zyme in distilled water.
Method:
1. Place the MEA in 1 % Terg-A-Zyme solution overnight at room temperature.
2. Apply gentle shaking or rocking, if possible.
3. After Terg-a-Zyme treatment, rinse the MEA thoroughly with distilled water. (Terg-A-Zyme solution
can be stored at 4 °C and reused for about a week).
4. Dry the MEA and apply hydrophilic surface treatment, if necessary (Please see above).
5. If the MEA is going to be used for cell or tissue culture, autoclave the MEA at 121 °C for 30 min.
6. Do not fix cells or tissues on a MEA. Detergent treatment will not remove fixed tissues.

Important: NEVER wipe the electrode field or touch it otherwise!

Warning: It is absolutely necessary to rinse the MEAs thoroughly with distilled water after treatment
with detergent, particularly when using Terg-A-Zyme before heat sterilization (dry-heat sterilization
is not recommended). Otherwise the potential rests of the detergent may burn into the glass carrier
of the MEA and may destroy the electrodes.

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Recording with MEAs

6

Culture Chamber and Ring Options
You have several options regarding culture chamber interface rings (without ring, glass ring, plastic ring
without and with thread) and culture chambers, which are especially useful for long-term cultures or
experiments. For more details or pricing information, please ask your local retailer.

6.1 MEA2100-CO2-C
The MEA2100-CO2-C is a climate chamber for MEA2100-Systems. Connect the chamber via magnetic
forces on the lid of a MEA2100 headstage to create a 5 % CO2 atmosphere (humid or non humid)
around the biological probe. Connect a tube with an inner diameter of +/- 2.3 mm to the tube connector.

6.2 Sealed MEA Culture Dish
In order to allow long-term cultivation and recording, Multi Channel Systems recommends the use of teflon
membranes (fluorinated ethylene-propylene, 12.5 microns thick) developed by Potter and DeMarse (2001).
The ALA-MEA-MEM membrane is produced in license by ALA Scientific Instruments Inc., and distributed via
the worldwide network of MCS distributors.

The sealed MEA culture chamber with transparent semipermeable membrane is suitable for all MEAs with
glass ring. A hydrophobic semipermeable membrane from Dupont that is selectively permeable to gases
(O2, CO2), but not to fluid and H2O vapor, keeps your culture clean and sterile, preventing contaminations
by airborne pathogens. It also greatly reduces evaporation and thus prevents a dry-out of the culture.
Reference


Reference: Potter, S. M. and DeMarse, T. B. (2001). "A new approach to neural cell culture for long-term
studies." J Neurosci Methods 110(1-2): 17-24.

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MEA Manual

6.3 MEA Culture Chamber with Lid
Another possibility is to use a MEA culture chamber with lid (available from Multi Channel Systems), which
is suitable for all MEAs with plastic ring and thread. It can be adapted by inserting metal perfusion cannulas
for setting up a continuous perfusion.

6.4 Culture Chamber for 9-Well MEAs
The culture chamber ring 9well-CC for 256-9wellMEAs is suitable for the 9well macrolon quadrat (available
from Multi Channel Systems). To use the macrolon quadrat in combination with the 9well-CC as a culture
chamber, please insert a foil between macrolon quadrat and 9well-CC ring.

9well-CC for 256-9wellMEA300/30iR-ITO

6.5 Culture Chamber for 6-Well MEAs
The 6well-CC culture chamber is suitable for 6well macrolon rings on 60-6wellMEAs (available from
Multi Channel Systems). The removable membrane cover for 60-6wellMEAs is available for triangle
and round chamber rings.

6well-CC
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Recording with MEAs

6.6 Ring Options
The following table shows all available ring options. Glass rings (-gr) are available in two heights
of 6 or 12 mm. Plastic rings (-pr) are available in four heights and without or with thread (-pr-T).
The triangle (-tcr) and round (-rcr) chamber rings are suitable for the MEAs with 6 wells, the macrolon
quadrates (-mq) for the 256MEAs with 9 wells.

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7

Recording with MEAs
7.1 Mounting the MEA

7.1.1

Cleaning the Contact Pads
You should always clean the contact pads with alcohol before placing it into the MEA amplifier. Even
if you do not see any contaminations, a very thin grease layer from touching the pads with bare fingers,
for example may be present and results in a bad contact between the pads and the amplifier pins. A bad
contact will result in an increased noise level on the affected channel. This is the most prominent handling
error.

 Carefully wipe the MEA contact pads with a clean and soft tissue moistened with pure alcohol.

7.1.2

Positioning the MEA
Important: MEAs are not symmetrical! That is, why the writing (for example NMI, LEITER, MEA type) on
the MEA chip should be on the right side viewed from the front, with the sockets of the amplifier in the
back. MEAs with one big internal reference electrode should be placed with reference electrode to the left
side in the amplifier. Otherwise, the MEA layout will not match with the pin layout of the channel map in
the data acquisition software.
When placing a special MEA into the amplifier, for example 120MEA, HighDense MEA, 4Q1000 MEA
or HexaMEA, please make sure that the orientation of the MEA is correct, respectively.

7.1.3

Grounding the Bath
Make sure that the bath is connected to the amplifier's ground.

 Attach the provided silver wire or Ag/AgCl pellet to the amplifier's ground and place it into the bath.
 — OR — If you use a MEA with internal reference electrode, connect the ground to the reference electrode
socket (pin 15) with the provided connector.
Please see the manual of the respective MEA amplifier for more information about mounting MEAs and
grounding.

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Recording with MEAs

7.2 General Performance / Noise Level
You can test a MEA before use by filling it with a standard saline buffer, for example PBS (phosphate
buffered saline), and recording the noise level of the MEA and the amplifier.
MEA amplifiers have a maximum noise level of +/– 8 µV. The noise level on the MEA depends on the
electrode size and material. The smaller the electrode, the higher is the noise level. TiN electrodes have a
larger surface area due to their microfold structures, and therefore they have generally a lower impedance
and a lower noise level than electrodes of the same size that are made from other materials (for example,
Pt electrodes).
The total maximum noise level for a MEA and the amplifier should be about +/– 40 µV peak to peak
for 10 µm TiN electrodes and +/– 10 µV for 30 µm TiN electrodes.
The initial noise level may be higher if the MEAs are hydrophobic. New MEAs should be made hydrophilic
before use.
Typical noise level of a used standard 60MEA200/30iR-Ti (round 30 µm Tin electrodes)

This picture shows the typical noise level of a standard 60MEA200/30iR-Ti on most electrodes,
recorded with a MEA1060-BC amplifier.

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MEA Manual

Electrodes 43, 52, 53, and 84 show an increased noise level after a longer cycle of use. The bath
was grounded with the internal reference electrode 15. Time axis: 1000 ms, voltage axis: 50 µV.
You should ground some of the electrodes if you want to use this MEA for recording.

Same MEA, zoom to single channel # 22. Time axis: 500 ms, voltage axis: 20 µV.

Same MEA after grounding defective electrodes. Time axis: 1000 ms, voltage axis: 100 µV.
Typical noise level of a standard 60MEA200/10iR-Ti (round 10 µm Tin electrodes)

Noise level of a new standard 60MEA200/10iR-Ti. Bath grounded with the internal reference
electrode 15. Time axis: 1000 ms, voltage axis: 100 µV.

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Stimulation

8

Stimulation
8.1 Using MEA Electrodes for Stimulation
You can use any MEA electrode(s) for stimulation. Simply connect the stimulus generator outputs to
the MEA amplifier. In the MEA2100-System the stimulator is integrated in the headstage. The stimulation
electrodes are selected via software. Please see the manual for the respective MEA amplifier and stimulus
generator for more details. This and the following chapters are intended for helping you to optimize the
stimulation with MEA electrodes.
All electrodes suffer under electrical stimulation, especially under long-term stimulation. The wear depends
on the stimulus and on the electrode type. When stimulating via MEA electrodes and with standard MEA
amplifiers, you will see a stimulus artifact on all amplifier channels during stimulation due to the high
charge that is injected into the circuit, and the following saturation of the filter amplifiers. The time
constant of the stimulus artifact depends on the amplifier bandwidth; if the lower cutoff frequency is quite
low, for example, 1 Hz, the stimulus artifact will be longer than with 10 Hz, for example. In most cases, it
will not be possible to record true signals that are close to the stimulus pulse. This can be avoided by using
a MEA amplifier with blanking circuit. The stimulating electrode can generally not be used for recording in
parallel to stimulation, because the injected charge is so high, and the time constant for discharging so low.

The screen shot shows a prominent stimulus artifact on all channels, followed by a response.
The stimulating electrode No. 61 has been grounded.
The next pictures demonstrate the blanking feature. On the left screen shot, you see the stimulus artifacts
on a non-stimulating electrode without blanking. On the right, you see the same electrode and stimulation
pattern, but with blanking. The stimulus artifacts have been completely avoided, making it possible to
detect signals shortly after the stimulus.

55

MEA Manual

8.2 Capacitive Behavior of Stimulating Electrodes
Regarding the generally used stimulus pulses, stimulating electrodes behave as plate capacitors. The charge
cannot flow back to the stimulus generator due to the high output resistance and thus is kept in the
electrode. The electrode needs a quite long time to discharge itself after stimulation. As a result, stimulus
artifacts interfere with the recording, and electrodes deteriorate over time due to electrolysis. You can avoid
that by choosing an appropriate stimulus protocol that actively discharges the electrode after the pulse.
When using voltage driven stimulation, the electrodes are discharged when the voltage level is set to zero
at the end of the (monophasic) pulse. Not so in current mode. When applying a negative current pulse,
the electrode is charged and needs to be actively discharged by applying an inverted pulse with a matching
product of current and time that is you need to stimulate with biphasic pulses for current driven stimulation
to reduce both the stimulus artifact and to avoid an electrode damage. The easiest way is to use the same
signal amplitude and the same duration with an inverse polarity. For voltage driven stimulation, monophasic
pulses are fine.
The following illustration shows the effect of a biphasic current pulse on the discharge of the stimulation
electrode. As you can see, the first monophasic pulse is followed immediately by a pulse of the opposite
polarity and the same product of current and time.

56

Stimulation

8.3 Aspects of Electrode Size and Material
Titanium nitrite (TiN) electrodes are generally more robust than electrodes from other materials, for
example platinum (Pt). In the Appendix, you find safe charge injection limit curves that document maximum
current and stimulus durations for standard TiN electrodes. Please note that these curves document the
limits. Stimulus pulses should be kept safely below these limits. The safe charge injection limit of platinum
(0.4 mC/cm2) is much smaller than for TiN (23 mC/cm 2). This fact results in a considerably lower charge that
you can inject into the electrode before faradic reactions occur that will lead to electrolysis of the electrode.
Please note that, when using voltage driven stimulation, the current flow to the electrode depends on the
electrode impedance. The lower the impedance, the higher is the current. Please make sure to obey the
safe charge injection limits always. Generally, TiN electrodes have lower impedances than Pt electrodes, and
larger electrodes also have lower impedances than smaller.
When using TiN electrodes, it is extremely important to not charge the electrodes positively, as this will
lead to electrolysis. (This is not an issue for Pt electrodes.) Therefore, when using voltage driven stimulation,
it is important to apply negative voltages only. Positive voltages will shortly charge the electrodes positively,
even though the electrode is discharged at the end of the pulse. As a consequence, biphasic voltage driven
stimulation is not recommended. When using current stimulation, it is required to use biphasic stimulation,
and to apply the negative phase first, to avoid a positive net charge on the electrode.

57

MEA Manual

8.4 Recommended Stimulus Amplitudes and Durations
The higher the amplitude and the longer the stimulus, the higher is the impact on the electrode
performance. Therefore, the amplitude and duration should be as low as possible. It is advisable to start
with a low amplitude and duration, and then increase it slowly until responses are evoked.
The allowed product of amplitude and duration is directly proportional to the electrode surface. The higher
the amplitude, the shorter is the maximum duration of the pulse, and vice versa. Do not apply pulses with
a higher amplitude or for a longer time than is recommended for the electrode type. TiN electrodes have
a rough surface structure and therefore have a larger surface than electrodes of the same size but made
of a different material. The safe-charge injection limits in the appendix describe the relationship between
maximum pulse amplitude and time for TiN electrodes.
As a consequence of the points discussed above, Multi Channel Systems recommends using negative
monophasic voltage pulses or biphasic voltage pulses to make sure that the voltage level of the
stimulating electrode is zero, and thus the electrode is discharged, at the end of the pulse.
According to the experience of MEA users, voltage pulses should be < 1 V (–100 mV to –900 mV) for
neuronal applications to avoid damage to electrode and cells. Generally, pulse durations between 100
to 500 µs are used. (See also Potter, S. M., Wagenaar, D. A. and DeMarse, T. B. (2005). “Closing the Loop:
Stimulation Feedback Systems for Embodied MEA Cultures.” Advances in Network Electrophysiology Using
Multi-Electrode Arrays. M. Taketani and M. Baudry, Springer; Wagenaar, D. A., Madhavan, R., Pine, J. and
Potter, S. M. (2005). "Controlling bursting in cortical cultures with closed-loop multi-electrode stimulation."
J Neurosci 25(3): 680-8.)
For pacing cardiomyocytes, higher voltages and durations are generally required, for example, –2 V
for 2 ms. As these pulses are not supported by standard MEA electrodes, the use of larger stimulating
electrodes is recommended.
Warning: When using MEA electrodes of TiN material, use only negative voltages pulses or biphasic current
pulses applying the negative phase first. Always regard the safe-charge injection limits as described in
the appendix of this manual. Otherwise, electrodes can be irreversibly damaged by electrolysis.

58

Troubleshooting

9

Troubleshooting
9.1 About Troubleshooting
The following hints are provided to solve special problems that have been reported by users. Most problems
occur seldom and only under specific circumstances. Please check the mentioned possible causes carefully
when you have any trouble with the product. In most cases, it is only a minor problem that can be easily
avoided or solved.
If the problem persists, please contact your local retailer. The highly qualified staff will be glad to help you.
Please inform your local retailer as well if other problems that are not mentioned in this documentation
occur, even if you have solved the problem on your own. This helps other users, and it helps Multi Channel
Systems to optimize the instrument and the documentation.
Please pay attention to the safety and service information (chapter “Important Information and
Instructions”). Multi Channel Systems has put all effort into making the product fully stable and reliable,
but like all high-performance products, it has to be handled with care.

9.2 Technical Support
Please read the Troubleshooting part of the user manual first. Most problems are caused by minor handling
errors. Contact your local retailer immediately if the cause of trouble remains unclear. Please understand
that information on your hardware and software configuration is necessary to analyze and finally solve the
problem you encounter.
Please keep information on the following at hand


Description of the error (the error message text or any other useful information) and of the context in which
the error occurred. Try to remember all steps you had performed immediately before the error occurred.
The more information on the actual situation you can provide, the easier it is to track the problem.



The serial number of the MEA. You will find it on the MEA case.



The amplifier type and serial number. You will find it on the device.



The operating system and service pack number on the connected computer.



The hardware configuration (microprocessor, frequency, main memory, hard disk) of the connected
computer. This information is especially important if you have modified the computer or installed new
hard- or software recently.



The version of the recording software. On the “Help” menu, click “About” to display the software version.

59

MEA Manual

9.3 Noise on Single Electrodes
The noise level on single electrodes is significantly higher than expected or you see artifact signals.
In the following example (60MEA200/30, filled with PBS (phosphate buffered saline), silver pellet
as bath electrode, shielded), electrodes No. 53, 63, 73, 45, 55, 48, 58 show a high noise level.

Possible causes:
?

The electrode or the contact pin of the amplifier may be defective. To test this, do the following.

1. Open the amplifier and turn the MEA by 90 degrees.
2. Close the amplifier again and start the recording.
If the same electrode in the MEA layout is affected, the amplifier's contact is not ok. If another electrode
is now affected and the previously affected electrode is ok now, the MEA electrode is not ok, but the
amplifier is fine. The following screen shot shows the same MEA than above that has been turned
clocise by 90 degrees. You see that different channels are now affected, which indicates that the
amplifier is fine but some electrodes on the MEA are defective.

— OR —


60

Use the test model probe to test the amplifier. If the noise level is fine without the MEA, bad MEA
electrodes cannot be the cause.

Troubleshooting
MEA is defective
MEAs wear out after multiple uses or over a longer time of use, for example for long-term cultures.
This is considered a normal behavior. MEAs are also easily damaged by mishandling, for example
if wrong cleaning solutions or too severe cleaning methods are used or if the recording area is touched.
If you observe a bad long-term performance of MEAs, consider a more careful handling.
Possible causes:
?

The contact pads are contaminated.

 Clean the contact pads carefully with a swab or a soft tissue and pure (100 %) alcohol.
?

The contact pads or the electrodes are irreversibly damaged. You could have a look at the electrodes
under a microscope: If they appear shiny golden, the titanium nitride is gone and the electrode is
irreversibly damaged. Electrodes may be damaged without changing their visual appearance, though.

 Pick one of the bad channels after the other and ground it. See the MEA amplifier's manual for more
information on grounding channels. In most cases, only one of the electrodes that appear bad is actually
defective, and the other ones are only affected by the single defective electrode. Ground as many
electrodes as you need for a good general performance.
In the following example, all defective electrodes have been grounded.

Grounded electrodes show a noise level that is lower than that of good electrodes.

 If too many electrodes are defective, use a new MEA.
Contact pin is defective
Please see the manual for the respective MEA amplifier.

61

MEA Manual

9.4 Overall Noise / Unsteady Baseline
The baseline is unstable, signals are jumping or drifting.
Possible causes:
?

Bath electrode is not connected to ground.

 Connect the internal or external bath electrode to one of the ground inputs of the amplifier.
?

AgCl bath electrode needs is not well-chlorided.

 Rechloride the electrode or use a new one.
?

50 Hz hum: 50 Hz is the frequency of mains power in Europe. If the shielding and grounding of the setup
is not sufficient, electrical signals are picked up from the environment.

 Use a proper shielding. For example, you can place aluminum foil over the amplifier that is connected to
any metal part of the MEA amplifier. You can also use special shielding equipment like a Faraday cage.
The following screen shot shows a recording of a 60MEA200/30 without bath electrode and without
shielding. You see that the signals are so high that the amplifier gets saturated, and you see a very strong
50 Hz hum.

The next pictures show the same MEA with bath electrode (silver pellet), but without shielding.
The baseline is very unsteady and oscillates with a frequency of 50 Hz.

62

Troubleshooting

The next screen shot shows the effect of shielding: The noise level is neglectable, and the baseline
is steady. The shielding has been achieved with a metal plate connected to the metal part of the
68-pin MCS high grade cable connector and placed above the amplifier. You could also use aluminum
foil or a Faraday cage for the same effect, for example.

9.5 Missing Spikes or Strange Signal Behavior
MEAs wear out after multiple uses or over a longer time of use, for example, for long-term cultures.
The insulation layer gets thin over time. This is considered a normal behavior.
Possible causes:
?

The insulation layer is too thin. As a result, the MEA gets the behavior of a low pass filter. This means,
that the signal frequency may be shifted to a lower frequency, and spikes are missing.

 Optically control the MEA with a microscope. If concentric colored rings (Newton rings) are visible
(due to light interference), the insulation layer is too thin and you should use a fresh MEA.
?



The insulation layer has been abraded and is missing in parts. This will result in a short circuit between
the electrodes or tracks and the bath. You will still see signals, but as an unspecific smear over the
complete array.
Use a fresh MEA.

63

Appendix

10

Appendix

10.1 Contact Information
Local retailer
Please see the list of official MCS distributors on the MCS web site.
User forum
The Multi Channel Systems User Forum provides an excellent opportunity for you to exchange your
experience or thoughts with other users worldwide.
Mailing List
If you have subscribed to the newsletter, you will be automatically informed about new software releases,
upcoming events, and other news on the product line. You can subscribe to the mailing list on the contact
form of the MCS web site.

www.multichannelsystems.com

65

MEA Manual

10.2 Safe Charge Injection Limits

66

Safe Charge Injection Limits of Micro Electrode Arrays with TiN Electrodes (diameter: 30 µm)
s af e c harg e in je c tio n lim its

m ax. p uls e am p litud e [µ A ]

2000

1500

1000

500

0

0

50

100

150

250
300
tim e [µ s ]

350

400

450

500

s a f e c h a rg e in je c tio n lim its

400
m a x. p uls e am p litu d e [µ A ]

200

350
300
250
200
150
100
50
0
500

1000

1500

2000

2500

3000

s af e c harg e in je c tio n lim its

60
m ax. p uls e am p litud e [µ A ]

tim e [µ s ]

50
40
30
20
10
0
3000

4000

5000

6000
7000
tim e [µ s ]

8000

9000

10000

Safe Charge Injection Limits of Micro Electrode Arrays with TiN Electrodes (diameter: 10 µm)
s a f e c h a rg e in je c tio n lim its

m a x. p uls e am p litu d e [µ A ]

2000

1500

1000

500

0

0

5

10

15

25
tim e [µ s ]

30

35

40

45

50

s af e c harg e inje c tio n lim its

400
m ax. p uls e am p litud e [µ A ]

20

350
300
250
200
150
100
50
0

50

100

150

200

250

300

s af e c harg e in je c tio n lim its

60
m ax. p uls e am p litud e [µ A ]

tim e [µ s ]

50
40
30
20
10
0
300

400

500

600
700
tim e [µ s ]

800

900

1000



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