Pine Research Instrumentation logo
HomeProductsElectrochemical WorkstationsWaveNeuro FSCV Series

WaveNeuro One FSCV System

Part Number
AF01FSCV1
WaveNeuro One FSCV System

The WaveNeuro® Fast Scan Cyclic Voltammetry (FSCV) Potentiostat System is a unique electrochemical instrument you will not find from other traditional electrochemical suppliers. We are excited to bring high quality, regularly available, and uniquely designed neuroelectrochemical research products to you. Created by FSCV scientists for FSCV scientists, the WaveNeuro is well-designed, of high quality construction, and supported by a company with over 40 years of history serving electrochemical researchers. The WaveNeuro seeks to fill the gap that exists for commercial fast-scan cyclic voltammetry (FSCV) systems.

Related Product Bundles

This product is available in related bundles. View related bundles in the tab below.

View Related Bundles
Login to View Prices

Customers must be logged into their account to view prices. Not all regions provide pricing online. If you do not see prices, you can obtain them from the designated sales channel in your region.

Categories
Electrochemical Workstations > WaveNeuro FSCV Series
Tags
, , ,
Applications
Fast-Scan Cyclic Voltammetry
WaveNeuro One FSCV System

The WaveNeuro® Fast Scan Cyclic Voltammetry (FSCV) Potentiostat System is a unique electrochemical instrument you will not find from other traditional electrochemical suppliers. We are excited to bring high quality, regularly available, and uniquely designed neuroelectrochemical research products to you. Created by FSCV scientists for FSCV scientists, the WaveNeuro is well-designed, of high quality construction, and supported by a company with over 40 years of history serving electrochemical researchers. The WaveNeuro seeks to fill the gap that exists for commercial fast-scan cyclic voltammetry (FSCV) systems.

More Detail
Related Bundles
References
Documents

The WaveNeuro® Fast Scan Cyclic Voltammetry (FSCV) Potentiostat System is a unique electrochemical instrument you will not find from other traditional electrochemical suppliers. We are excited to bring high quality, regularly available, and uniquely designed neuroelectrochemical research products to you. Designed by FSCV scientists for FSCV scientists, the WaveNeuro is well-designed, of high quality construction, and supported by a company dedicated to supporting the instrument, as well as you the researcher. The WaveNeuro seeks to fill the gap that exists for commercial fast-scan cyclic voltammetry (FSCV) systems.

The WaveNeuro is available in single channel (WaveNeuro One), dual channel (WaveNeuro Two), and quad multichannel (WaveNeuro Four) configurations!

The WaveNeuro Potentiostat was designed for the scientist (neuroscientist, psychologist, physician, chemist, biologist, etc.) who seeks to study the link between the brain chemistry of electroactive species (such as monoamines, catecholamines like dopamine and serotonin, oxygen, peroxide, etc.) and physiology (such as structure, function, disease, neural transmission, etc.) and behavior (such as addiction, impulsivity, decision-making, etc.). Microdialysis, still a technique used in the field, can provide high spatial resolution for detection of these chemical species but offers poor temporal resolution. FSCV, as a technique, provides both high spatial and high temporal resolution. Coupled with carbon fiber microelectrodes, FSCV provides a well-established platform for in-vivo and in-vitro experimentation.

Traditionally, the products and instrumentation required to perform FSCV have only been available through scientific connections with developing laboratories. As the technique has grown in popularity, due in part to its relative ease of use, the availability of instrumentation has not followed the same trend. We are excited to bring such FSCV instrumentation to the market, thereby providing the robust technical, service, and sales support you have come to expect in the field of research instrumentation.

The WaveNeuro seeks to fill the gap that exists for commercial FSCV systems by providing systems with many novel features, such as:

  • We strive to have items in stock and ready to ship! Who can wait 8 weeks or more when your research productivity is on the line?
  • A system that breaks from the past, with an overall updated design, including: a “breakout box” built into and included with the WaveNeuro, intuitive and clearly-labeled connectors, in a small dimensional footprint.
  • Built for flexibility – includes behavioral input mapping to digital and analog input/output connections.
  • Designed with Pine Research modular headstage cable design, preventing that “pile of unknown headstage/cables” that so many labs make over time.
  • 1, 2, or 4 Channel Configurations now available!
The WaveNeuro One FSCV System is available as part of a product bundle. A product bundle is a combination of products that are compatible and often sold together for convenience and confidence. Below is a list of product bundles that contain WaveNeuro One FSCV System.
Basic System Bundle (No Additional Products Included)
Image
Bundle Name
Bundle Part #
Bundle Link
WaveNeuro One Potentiostat Basic Bundle
WaveNeuro One FSCV Potentiostat (Basic Bundle)
[NEC-WN-ONE-B]
View
Bundled with National Instruments Interface Board and Cables
Image
Bundle Name
Bundle Part #
Bundle Link
WaveNeuro One FSCV Potentiostat Plus Bundle
WaveNeuro One FSCV Workstation System Bundle, with NI Interface
[NEC-WN-ONE-P]
View
  1. Todorov, J.; McCarty, G.S.; Sombers, L.A. Mechanistic Insight into Tyrosine Oxidation at Carbon-Fiber Microelectrodes Revealed by Fast-Scan Cyclic Voltammetry. ACS Electrochem. 2025.
  2. Qi, Y.; Jang, D.; Ryu, J.; Bai, T.; Shin, Y.; Gu, W.; Iyer, A.; Li, G.; Ma, H.; Liou, J.; van der Meer, M.; Qiang, Y.; Fang, H. Stabilized carbon coating on microelectrodes for scalable and interoperable neurotransmitter sensing. Nat Commun 2025, 16, 3300.
  3. Fernández-Vega, L.; Meléndez-Rodríguez, D.E.; Ospina-Alejandro, M.; Casanova, K.; Vázquez, Y.; Cunci, L. Development of a Neuropeptide Y-Sensitive Implantable Microelectrode for Continuous Measurements. ACS Sens. 2024.
  4. Dumitrescu, E.; Copeland, J.M.; Venton, B.J. Parkin Knockdown Modulates Dopamine Release in the Central Complex, but Not the Mushroom Body Heel, of Aging Drosophila. ACS Chem. Neurosci. 2023, 14, 198-208.
  5. Li, Y.; Jarosova, R.; Weese-Myers, M.E.; Ross, A.E. Graphene-Fiber Microelectrodes for Ultrasensitive Neurochemical Detection. Anal. Chem. 2022, 94, 4803-4812.
  6. Ostertag, B.J.; Cryan, M.T.; Serrano, J.M.; Liu, G.; Ross, A.E. Porous Carbon Nanofiber-Modified Carbon Fiber Microelectrodes for Dopamine Detection. ACS Appl. Nano Mater. 2022, 5, 2241-2249.
  7. Chang, Y.; Venton, B.J. Dual-Channel Electrochemical Measurements Reveal Rapid Adenosine is Localized in Brain Slices. ACS Chem. Neurosci. 2022, 13, 477-485.
  8. Li, Y.; Weese, M.E.; Cryan, M.T.; Ross, A.E. Amine-functionalized carbon-fiber microelectrodes for enhanced ATP detection with fast-scan cyclic voltammetry. Anal. Methods 2021, 13, 2320-2330.
  9. Asrat, T.M.; Cho, W.; Liu, F.A.; Shapiro, S.M.; Bracht, J.R.; Zestos, A.G. Direct Detection of DNA and RNA on Carbon Fiber Microelectrodes Using Fast-Scan Cyclic Voltammetry. ACS Omega 2021, 6, 6571-6581.
  10. Wonnenberg, P.; Cho, W.; Liu, F.; Asrat, T.; Zestos, A.G. Polymer Modified Carbon Fiber Microelectrodes for Precision Neurotransmitter Metabolite Measurements. J. Electrochem. Soc. 2020, 167, 167507.
  11. Regan, S.L.; Cryan, M.T.; Williams, M.T.; Vorhees, C.V.; Ross, A.E. Enhanced Transient Striatal Dopamine Release and Reuptake in Lphn3 Knockout Rats. ACS Chem. Neurosci. 2020, 11, 1171-1177.
  12. Walters, S.H.; Levitan, E.S. Vesicular Antipsychotic Drug Release Evokes an Extra Phase of Dopamine Transmission. Schizophr Bull 2020, 46, 643-649.
  13. Walters, S.H.; Shu, Z.; Michael, A.C.; Levitan, E.S. Regional Variation in Striatal Dopamine Spillover and Release Plasticity. ACS Chem. Neurosci. 2020, 11, 888-899.
  14. Delong, L.M.; Li, Y.; Lim, G.N.; Wairegi, S.G.; Ross, A.E. A microfluidic electrochemical flow cell capable of rapid on-chip dilution for fast-scan cyclic voltammetry electrode calibration. Anal Bioanal Chem 2020, 412, 6287-6294.
  15. Shin, M.; Friedman, D.A.; Gordon, D.M.; Venton, B.J. Measurement of natural variation of neurotransmitter tissue content in red harvester ant brains among different colonies. Anal Bioanal Chem 2020, 412, 6167-6175.
  16. Meunier, C.J.; McCarty, G.S.; Sombers, L.A. Drift Subtraction for Fast-Scan Cyclic Voltammetry Using Double-Waveform Partial-Least-Squares Regression. Anal. Chem. 2019, 91, 7319-7327.
  17. Calhoun, S.E.; Meunier, C.J.; Lee, C.A.; McCarty, G.S.; Sombers, L.A. Characterization of a Multiple-Scan-Rate Voltammetric Waveform for Real-Time Detection of Met-Enkephalin. ACS Chem Neurosci 2019, 10, 2022-2032.
  18. Lim, G.N.; Ross, A.E. Purine Functional Group Type and Placement Modulate the Interaction with Carbon-Fiber Microelectrodes. ACS Sens. 2019, 4, 479-487.
  19. Smith, S.K.; Gosrani, S.P.; Lee, C.A.; McCarty, G.S.; Sombers, L.A. Carbon-Fiber Microbiosensor for Monitoring Rapid Lactate Fluctuations in Brain Tissue Using Fast-Scan Cyclic Voltammetry. Anal. Chem. 2018, 90, 12994-12999.
  20. Wilson, L.R.; Panda, S.; Schmidt, A.C.; Sombers, L.A. Selective and Mechanically Robust Sensors for Electrochemical Measurements of Real-Time Hydrogen Peroxide Dynamics in Vivo. Anal. Chem. 2018, 90, 888-895.
  21. Lee, K.H.; Lujan, J.L.; Trevathan, J.K.; Ross, E.K.; Bartoletta, J.J.; Park, H.O.; Paek, S.B.; Nicolai, E.N.; Lee, J.H.; Min, H.; Kimble, C.J.; Blaha, C.D.; Bennet, K.E. WINCS Harmoni: Closed-loop dynamic neurochemical control of therapeutic interventions. Sci. Rep. 2017, 7, 46675.
  22. Kang, S.; Park, J.; Jeong, Y.; Oh, Y.; Choi, J. Second-Derivative-Based Background Drift Removal for Tonic Dopamine Measurement in Fast-Scan Cyclic Voltammetry. Anal. Chem. , 94, 11459-11463.
  23. Wilson, L.R. Studying Oxidative Stress: Real-Time Detection of Hydrogen Peroxide and Dopamine in the Brain. Ph.D. Dissertation, North Carolina State University, .
  24. Smith, S.K. Advancing Microbiosensor Development for Real-Time Electrochemical Detection of Multiple Analytes in Rat Brain Tissue. Ph.D. Dissertation, North Carolina State University, .
  25. Mauterer, M...; Estave, P.M.; Holleran, K.M.; Jones, S.R. Measurement of Dopamine Using Fast Scan Cyclic Voltammetry in Rodent Brain Slices. , 8, e2473.
  26. Hirabayashi, M. Glassy Carbon Neural Probes for Cortical and Spinal Electrochemical and Electrophysiological Sensing and Stimulation. Ph.D. Dissertation, University of California - San Diego, .
  27. Cryan, M.T.; Ross, A.E. Subsecond detection of guanosine using fast-scan cyclic voltammetry. , 144, 249-257.
  28. Ardabili, N.G. Carbon Fiber Microelectrodes as Amino Acide Sensors using Fast Scan Cyclic Voltammetry. Master's Thesis, American University, .
  29. He, X. Different Morphological Gold Nanoparticle-Modified Carbon Fiber microelectrodes for Enhanced Neurochemical Detection. Master's Thesis, American University, .
  30. Liu, F.A.; Ardabili, N.; Brown, I.; Rafi, H.; Cook, C.; Nikopoulou, R.; Lopez, A.; Zou, S.; Hartings, M.R.; Zestos, A.G. Modified Sawhorse Waveform for the Voltammetric Detection of Oxytocin. J. Electrochem. Soc. , 169, 017512.
  31. Keller, A.L.; Quarin, S.M.; Strobbia, P.; Ross, A.E. Platinum Nanoparticle Size and Density Impacts Purine Electrochemistry with Fast-Scan Cyclic Voltammetry. J. Electrochem. Soc. , 169, 046514.
  32. Dunham, K.E.; Venton, B.J. SSRI antidepressants differentially modulate serotonin reuptake and release in Drosophila. J. Neurochem. , 162, 404-416.
  33. Borgus, J.R.; Puthongkham, P.; Venton, B.J. Complex sex and estrous cycle differences in spontaneous transient adenosine. J. Neurochem. , 153, 216-229.
  34. Sato, N.; Ohta, Y.; Haruta, M.; Takehara, H.; Tashiro, H.; Sasagawa, K.; Jongprateep, O.; Ohta, J. Electrochemical activities of Fe2O3-modified microelectrode for dopamine detection using fast-scan cyclic voltammetry. , 13, 025026.
  35. Cho, W.; Liu, F.; Hendrix, A.; McCray, B.; Asrat, T.; Connaughton, V.; Zestos, A.G. Timed Electrodeposition of PEDOT:Nafion onto Carbon Fiber-Microelectrodes Enhances Dopamine Detection in Zebrafish Retina. J. Electrochem. Soc. , 167, 115501.
  36. Mendoza, A.; Asrat, T.; Liu, F.; Wonnenberg, P.; Zestos, A.G. Carbon Nanotube Yarn Microelectrodes Promote High Temporal Measurements of Serotonin Using Fast Scan Cyclic Voltammetry. , 20, 1173.
  37. Nimbalkar, S.; Castagnola, E.; Balasubramani, A.; Scarpellini, A.; Samejima, S.; Khorasani, A.; Boissenin, A.; Thongpang, S.; Moritz, C.; Kassegne, S. Ultra-Capacitive Carbon Neural Probe Allows Simultaneous Long-Term Electrical Stimulations and High-Resolution Neurotransmitter Detection. Sci. Rep. , 8, 6958.
  38. Hensley, A.L.; Colley, A.R.; Ross, A.E. Real-Time Detection of Melatonin Using Fast-Scan Cyclic Voltammetry. Anal. Chem. , 90, 8642–8650.
  39. Pyakurel, P.; Shin, M.; Venton, B.J. Nicotinic acetylcholine receptor (nAChR) mediated dopamine release in larval Drosophila melanogaster. Neurochem. Int. , 114, 33–41.
  40. Lee, S.; Venton, B. Regional Variations of Spontaneous, Transient Adenosine Release in Brain Slices. , 9, 505–513.
  41. Shin, M.; Copeland, J.M.; Venton, B.J. Drosophila as a Model System for Neurotransmitter Measurements. ACS Chem. Neurosci. , 9, 1872-1883.
  42. Castagnola, E.; Winchester Vahidi, N.; Nimbalkar, S.; Rudraraju, S.; Thielk, M.; Zucchini, E.; Cea, C.; Carli, S.; Gentner, T.Q.; Ricci, D.; Fadiga, L.; Kassegne, S. In Vivo Dopamine Detection and Single Unit Recordings Using Intracortical Glassy Carbon Microelectrode Arrays. , 3, 1629–1634.
Document #
Title
Type
Download
DRU10120
WaveNeuro One FSCV System User Guide
Download
Login
Register
Lost Password

Please enter your username (email address) and password below.

Confirm Logout

Are you sure you want to log out?

Yes, Logout Cancel

Request a Quote for this Cart

Below is the billing data we have on file. These details will be used on your quotation, so please update them here if you require any changes. Changing any details here updates them for your account.