Tungsten Profile C, 76 mm long, 0.216 mm shaft

As low as $210.00
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Prices valid in USA, Canada, and PR only.
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Prices valid in USA, Canada, and PR only.

Tungsten, frequently used for microelectrodes, balances performance and cost.

Prices valid in USA, Canada, and PR only.

Tungsten, frequently used for microelectrodes, balances performance and cost.

  • Package of 5

 

PROS

Exceptional Rigidity

Strong, stiff metal means the probes have exceptional rigidity.

Ideal for Acute & Chronic Recording

Tungsten is biocompatibility, and its low cost make tungsten ideal for acute and chronic recording.

High Corrosion Resistance

Tungsten has a high corrosion resistance.

Long-Term Performance

These probes are offer repeatable, long-term performance.

 

CONSIDERATIONS

Are you performing microstimulation?

Platinum-iridium alloy has better electrochemical performance and stability, making it a better choice for microstimulation.

What level of stimulation current will be used?

Platinum-iridium electrodes allow for greater stimulation. Tungsten's lower charge transfer capacity results in larger, possibly unsafe interfacial potentials when you apply the same stimulation current.

What are your pH levels or stimulation options?

Tungsten may corrode when used with some pH or stimulation options.

Tungsten Profile C Comparison Chart, 76 mm long, 0.216 mm shaft


Order code
Length Insulation
Thickness
Shaft
Diameter
Nominal
Impedance
±20%
Tip
Diameter
Typical Use
TM31A10KTB 76mm 0.216 mm 1.0 MΩ 3-4µ Multi unit and single unit recording and microstimulation
TM31A10KTH 76mm 0.216 mm 1.0 MΩ Multi unit and single unit recording and microstimulation, Heat Treated Tip
TM31A20KT 76mm 0.216 mm 2.0 MΩ Multi unit and single unit recording and microstimulation
TM31A50KT 76mm 0.216 mm 5.0 MΩ Multi unit and single unit recording and microstimulation
TM31A50KTH 76mm 0.216 mm 5.0 MΩ Multi unit and single unit recording and microstimulation, Heat Treated Tip
TM33A10KT 76mm 0.216 mm 1.0 MΩ 2-3µ Multi unit and single unit recording and microstimulation
TM33A10KTH 76mm 0.216 mm 1.0 MΩ Multi unit and single unit recording and microstimulation, Heat Treated Tip
TM33A20KT 76mm 0.216 mm 2.0 MΩ 2-3µ Multi unit and single unit recording and microstimulation
 

Typical Use

Multi unit and single unit recording and microstimulation

 

Kapton tubing

Kapton tubing, indicated by “KT” in the part number, extends from the connector to within 5 mm of the tip, providing stiffness and additional insulation to the electrode shaft. Kapton-clad electrodes are recommended when the electrode is to be inserted through a cannula for extra deep penetration.

 

Quantity

Package of 5

 

See Metal Microelectrode Selection Guide

Frequently Asked Questions

More Information
SKU VAR-8079

Using Parylene Coated Metal Microelectrodes

FAQ

  • What length do I need?

The overall length of any electrode system is determined primarily on the depth of the tissue one wishes to record or stimulate and the micro-drive system being employed. Tungsten microprobes come in 76 mm or 125 mm (don’t see 125 um on WPI website) lengths or can be custom ordered in any length less than 5 inches. Platinum/Iridium typically comes in two inch lengths and stainless steel in 51 mm lengths but either can also be specified in shorter lengths or in longer lengths using stainless steel and polyimide tubing. Because of the high expense of pure iridium it is always mounted in stainless steel and polyimide tubing and is typically 50 mm long.

 

  • What is the insulation thickness?

All electrodes except the 3 inch Extra Fine-F profile tungsten microprobe, that have a 1 micron coat of Parylene-C insulation, have 3 microns of Parylene-C. It has been proven that this thickness works best for most all electrode tip profiles we offer. We selected 3 microns to provide a sufficiently small tip profile for getting close to neural elements, ease of electrode insertion and to minimize attenuation for higher impedance electrodes. Attenuation of the signal can occur as a result of capacitive shunting when recording with higher impedance microprobes in deep structures, so additional insulation maybe required in the form of WPI’s KT, polyimide microprobes. The Extra Fine profile (ex. TM31C10) for the 3 inch tungsten electrodes provides an extremely fine microprobe tip which is excellent when recording from small densely packed cell structures.

 

  • What tip impedance or exposure do I need?

Because of our unique fabrication process and the special properties of Parylene-C we are able to expose any microprobe with microscopic precision and reproducibility. Each microprobe is individually exposed under a high power microscope, inspected and electrically characterized. Our microprobes have a lower impedance value for the same tip exposure as other commercially available electrodes. It is therefore recommended that those who have not used our electrodes before specify a range of impedance in order to select the best impedance value for their application. Also since we have been providing microprobes to researchers for over 30 years, we can provide expert advice in selecting the best electrode design for your experimental paradigm. Please contact us and provide information regarding your researcher’s requirements. There is no additional charge for specifying a range of impedance values for any box of microprobes.

 

  • What tip profile is best for my application?

We offer a variety of different tip alternatives for those that prefer a specialized electrode profile for their research. The tip selection can provide subtle yet important changes to the performance of the electrode, as described below. It is recommended that first time users consider experimenting with different tip profiles to determine which works best for their recording or stimulation protocols. A-Standard Our standard tip profile features a sharp yet robust point that offers versatile performance and an effective balance between penetration and durability. The most widely used tip profile, we recommend our standard tip for most neural recording applications, though it is also effective for most stimulation protocols. We employ an arc exposure method that provides precise and consistent performance as well as a very wide range of available impedances. While this method results in a small variability in impedance from electrode to electrode, most researchers find it very acceptable for their application. For those that need a more exact tip exposure, we offer a laser exposure service for a small premium. Please contact us if you feel this service is right for you. B-Blunted Our blunted electrodes are engineered to have a more rounded, bullet-shaped tip. For many applications the blunted tip can offer superior stimulation performance, as its shorter profile can lead to the electrode acting more as a point source and providing improved isolation. Many investigators feel that this profile both provides greater selectivity than the conventional sharper tip profiles and is more appropriate for higher-intensity stimulation protocols. Some investigators have also reported observations that the use of blunted tips leads to fewer occurrences of punctured cells. F-Extra fine Our extra-fine tip profile features a significantly sharper taper as well as a thinner insulation layer. This type of electrode is commonly used for shallow preparations where it is necessary to record from small tightly-packed cell populations, such as the striate layers of the visual and auditory cortices. Due to the very delicate nature of these tips, they are only available in tungsten electrodes, in 3-inch (76mm) length and both 0.003" and 0.005" (75 and 125 micron) shaft diameter. For penetrations greater than 4 mm in which the tip impedance is greater than 1.5 MΩ, we recommend that an additional layer of polyimide tubing be specified to reduce capacitive shunting and to increase the stiffness of the electrode. H-Heat Treated Our heat-treated electrodes are intended for those investigators who must penetrate their probes through tough membranes, such as the dura mater of larger mammals. By applying a heat source near the electrode tip under a microscope, we have the ability to provide an electrode with a more gradual tapering tip than our standard profile, while also toughening the polymer insulation near the tip. These modifications allow the electrode to be pushed through tough membranes easier and with less risk of tip and insulation damage.

 

  • Problems reading the impedance of your metal microelectrodes?
  1. Check your impedance tester, maybe you are testing the impedance values at a different frequency than the 1 Kilohertz.
  2. Check if your impedance tester doesn’t have a sample and hold circuit in which case the impedance is measured immediately upon pressing the test button and the impedance does not have a chance to stabilize.
  3. Usually the impedance will drop after a few minutes of the electrode being in the saline solution.
  4. Sometimes the electrodes can oxidize increasing the impedance in which case we recommend passing about negative 3 to 4.5 volts across the electrode in saline to clean and de-oxidize the electrode.

 

  • What electrode configuration do I need?

We presently offer three different electrode configurations at this time, although we have fabricated many custom designs for customers in the past. As you observe what our part numbers look like for our probes, as seen under our Product section, you will notice they have a part number like WE30031.0A5. The 00 portion of the part number specifies the microprobe configuration. Monopolar Electrodes - 00 Implies no special mounting with the sharpened probe being insulated with Parylene-C, having the length, width, tip profile and impedance as specified in the tables for ordering your electrodes. Polyimide Tubing - PT Electrodes which have been mounted into polyimide tubing in order to increase the stiffness and provide additional insulation thickness. This mounting is typically recommended when fairly high impedance electrodes must penetrate deeper layers of the brain or spinal cord. ST Specifies our bipolar or stereotrodes. These electrodes when ordered with impedances less than 0.5 meohms are excellent for localizing stimulation current fields. Higher impedance stereotrodes are excellent for enhancing the isolation of single neural elements by simultaneous recording of multiple units on two closely spaced microelectrodes. The tip spacing is typically equal to the shaft diameter of one of the electrodes used in making the stereotrode. Different tip spacing is available upon request.

 

  • What type of connectors are used with our electrodes?

The 5482, 5483 pin connectors are attached to the distal end of our electrodes. You can purchase these connectors as well as the mating connector, M202, by clicking here and going to our Accessory Page. Many users prefer to use our electrodes without any connector, which is fine. We will simply remove the connectors for you if requested. There is no discount for this since the connectors are attached at the beginning our fabrication process.

 

  • What are the tip exposures for different electrode impedance values?

Tip exposures for Heat Tapered "H" tip profiles have approximately 15 to 20 percent MORE exposure. Tip exposures for Blunted "B" tip profiles have approximately 15 to 20 percent LESS exposure. Tip exposures for Extra Fine "F" tip profiles have approximately 10 to 15 percent MORE exposure.

 

  • Problems reading the impedance of your metal microelectrodes?
  1. Check your impedance tester, maybe you are testing the impedance values at a different frequency than the 1 Kilohertz.
  2. Check if your impedance tester doesn’t have a sample and hold circuit in which case the impedance is measured immediately upon pressing the test button and the impedance does not have a chance to stabilize.
  3. Usually the impedance will drop after a few minutes of the electrode being in the saline solution.
  4. Sometimes the electrodes can oxidize increasing the impedance in which case we recommend passing about negative 3 to 4.5 volts across the electrode in saline to clean and de-oxidize the electrode.

 

A. Zellphusiologie "Boosting of Action Potential Backpropagation by Neocortical Network Activity In Vivo" J of Neuroscience 27. 2004: 11127-11136

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