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Creative Biolabs

Neural Probe Products

Electrophysiological recordings play a pivotal role in advancing neuroscience investigations, enabling the exploration of distinct field potentials across various brain regions and the intricate transmission of electrical impulses among neurons. These recordings are of utmost significance in comprehending diverse neural circuit functions and their correlation with neurodegenerative disorders.

Revolutionizing neural research, Creative Biolabs offers comprehensive solutions for in vivo electrophysiology recordings. Our high-density neural probes stand as cutting-edge microfabricated instruments tailored for capturing neural activity from diverse depths within the brain's architecture, as well as from its surface. These sophisticated probes mark a significant stride towards unraveling the intricacies of the nervous system's functionality.

Features of our Neural Probes

  • High-density: Capture both deep and surface neural activity with high-density microfabricated probes.
  • Up to 128 Channels: Enable chronic, long-term recording through our multi-channel electrodes.
  • Lightweight and Microfabrication: Reduce animal headload with 64/128 channel electrodes designed for comfort.
  • Deep and Surface Insights: Complete recordings across 128 channels at depths of 90mm with deep-array electrodes.
  • Acute and Chronic Neural Recording: Enable both acute and chronic recording, and construct a more comprehensive understanding of neural dynamics.
  • Cost Efficiency: Maximize product value with easy operation, superior performance, and low costs.
  • Beginner Kit: Tailor your research platform while minimizing expenses using our guided Starter Kit.

Pick Your Neural Probe

Silicon Neural Probes have emerged as a game-changing technology in neurophysiological studies. They offer a unique advantage in achieving high-resolution recordings from multiple neurons simultaneously. Creative Biolabs excels in designing and producing Silicon Neural Probes that exhibit exceptional stability and biocompatibility. These probes feature microfabricated silicon shanks with integrated electrodes, enabling precise probing of neural networks.

Example Case: Researchers at Creative Biolabs utilized Silicon Neural Probes with multi-site recording capabilities to investigate the neural correlates of learning and memory in rodent models. The high spatial resolution of the probes enabled the observation of intricate firing patterns within specific brain regions during various behavioral tasks.

Cat. No. Product Name Channel Number Site Material Substrate Material Length
NRZP-0823-ZP10 iElec™ Silicon Neural Probe-128 Channels-1 128 Electroplated pedot Single crystal silicon Up to 12 mm
NRZP-0823-ZP11 iElec™ Silicon Neural Probe-128 Channels-10 128 Electroplated pedot Single crystal silicon Up to 12 mm
NRZP-0823-ZP12 iElec™ Silicon Neural Probe-128 Channels-2 128 Electroplated pedot Single crystal silicon Up to 12 mm
NRZP-0823-ZP13 iElec™ Silicon Neural Probe-128 Channels-3 128 Electroplated pedot Single crystal silicon Up to 12 mm
NRZP-0823-ZP14 iElec™ Silicon Neural Probe-128 Channels-4 128 Electroplated pedot Single crystal silicon Up to 12 mm
NRZP-0823-ZP15 iElec™ Silicon Neural Probe-128 Channels-5 128 Electroplated pedot Single crystal silicon Up to 12 mm
NRZP-0823-ZP16 iElec™ Silicon Neural Probe-128 Channels-6 128 Electroplated pedot Single crystal silicon Up to 12 mm
NRZP-0823-ZP17 iElec™ Silicon Neural Probe-128 Channels-7 128 Electroplated pedot Single crystal silicon Up to 12 mm
NRZP-0823-ZP18 iElec™ Silicon Neural Probe-128 Channels-8 128 Electroplated pedot Single crystal silicon Up to 12 mm
NRZP-0823-ZP19 iElec™ Silicon Neural Probe-128 Channels-9 128 Electroplated pedot Single crystal silicon Up to 12 mm
NRZP-0823-ZP20 iElec™ Silicon Neural Probe-16 Channels-1 16 Electroplated pedot Single crystal silicon Up to 12 mm
NRZP-0823-ZP21 iElec™ Silicon Neural Probe-16 Channels-2 16 Electroplated pedot Single crystal silicon Up to 12 mm
NRZP-0823-ZP22 iElec™ Silicon Neural Probe-32 Channels-1 32 Electroplated pedot Single crystal silicon Up to 12 mm
NRZP-0823-ZP23 iElec™ Silicon Neural Probe-32 Channels-10 32 Electroplated pedot Single crystal silicon Up to 12 mm
NRZP-0823-ZP24 iElec™ Silicon Neural Probe-32 Channels-2 32 Electroplated pedot Single crystal silicon Up to 12 mm
NRZP-0823-ZP25 iElec™ Silicon Neural Probe-32 Channels-3 32 Electroplated pedot Single crystal silicon Up to 12 mm
NRZP-0823-ZP26 iElec™ Silicon Neural Probe-32 Channels-5 32 Electroplated pedot Single crystal silicon Up to 12 mm
NRZP-0823-ZP27 iElec™ Silicon Neural Probe-32 Channels-6 32 Electroplated pedot Single crystal silicon Up to 12 mm
NRZP-0823-ZP28 iElec™ Silicon Neural Probe-32 Channels-7 32 Electroplated pedot Single crystal silicon Up to 12 mm
NRZP-0823-ZP29 iElec™ Silicon Neural Probe-32 Channels-8 32 Electroplated pedot Single crystal silicon Up to 12 mm
NRZP-0823-ZP30 iElec™ Silicon Neural Probe-64 Channels-1 64 Electroplated pedot Single crystal silicon Up to 12 mm
NRZP-0823-ZP31 iElec™ Silicon Neural Probe-64 Channels-10 64 Electroplated pedot Single crystal silicon Up to 12 mm
NRZP-0823-ZP33 iElec™ Silicon Neural Probe-64 Channels-11 64 Electroplated pedot Single crystal silicon Up to 12 mm
NRZP-0823-ZP34 iElec™ Silicon Neural Probe-64 Channels-12 64 Electroplated pedot Single crystal silicon Up to 12 mm
NRZP-0823-ZP35 iElec™ Silicon Neural Probe-64 Channels-13 64 Electroplated pedot Single crystal silicon Up to 12 mm
NRZP-0823-ZP37 iElec™ Silicon Neural Probe-64 Channels-2 64 Electroplated pedot Single crystal silicon Up to 12 mm
NRZP-0823-ZP39 iElec™ Silicon Neural Probe-64 Channels-3 64 Electroplated pedot Single crystal silicon Up to 12 mm
NRZP-0823-ZP40 iElec™ Silicon Neural Probe-64 Channels-4 64 Electroplated pedot Single crystal silicon Up to 12 mm
NRZP-0823-ZP41 iElec™ Silicon Neural Probe-64 Channels-5 64 Electroplated pedot Single crystal silicon Up to 12 mm
NRZP-0823-ZP42 iElec™ Silicon Neural Probe-64 Channels-6 64 Electroplated pedot Single crystal silicon Up to 12 mm
NRZP-0823-ZP43 iElec™ Silicon Neural Probe-64 Channels-7 64 Electroplated pedot Single crystal silicon Up to 12 mm
NRZP-0823-ZP45 iElec™ Silicon Neural Probe-64 Channels-8 64 Electroplated pedot Single crystal silicon Up to 12 mm
NRZP-0823-ZP46 iElec™ Silicon Neural Probe-64 Channels-9 64 Electroplated pedot Single crystal silicon Up to 12 mm

Understanding the deep-brain structures and their intricate connectivity patterns demands advanced technologies. Creative Biolabs introduces the Deep Array technology, a breakthrough in accessing deeper brain regions with minimal tissue damage. This array features an elongated design that penetrates the brain's layers while preserving the delicate neural architecture.

Example Case: Through collaboration with leading neuroscientists, Creative Biolabs utilized Deep Array probes to explore the neural circuits underlying mood disorders. By precisely targeting the subregions of the amygdala in animal models, researchers gained insights into the real-time modulation of neuronal activity during stress responses.

Cat. No. Product Name Channel Number Site Material Substrate Material Length
NRZP-0823-ZP1 iElec™ Deep Array Neural Probe-128 Channels-1 128 Electroplated pedot Single crystal silicon Up to 90 mm
NRZP-0823-ZP2 iElec™ Deep Array Neural Probe-128 Channels-2 128 Electroplated pedot Single crystal silicon Up to 90 mm
NRZP-0823-ZP3 iElec™ Deep Array Neural Probe-32 Channels-1 32 Electroplated pedot Single crystal silicon Up to 90 mm
NRZP-0823-ZP4 iElec™ Deep Array Neural Probe-32 Channels-2 32 Electroplated pedot Single crystal silicon Up to 90 mm
NRZP-0823-ZP5 iElec™ Deep Array Neural Probe-32 Channels-3 32 Electroplated pedot Single crystal silicon Up to 90 mm
NRZP-0823-ZP6 iElec™ Deep Array Neural Probe-64 Channels-1 64 Electroplated pedot Single crystal silicon Up to 90 mm
NRZP-0823-ZP7 iElec™ Deep Array Neural Probe-64 Channels-2 64 Electroplated pedot Single crystal silicon Up to 90 mm

The Double-Sided Probe, a testament to Creative Biolabs' innovation, allows simultaneous recordings from opposing sides of neural tissue. This revolutionary design not only maximizes data collection but also provides valuable insights into the connectivity between neighboring neurons.

Example Case: Neuroscientists at Creative Biolabs harnessed the potential of Double-Sided Probes to study interhemispheric communication in animal models of sensory integration. By recording neural activities from both hemispheres, researchers deciphered the intricate coordination mechanisms underlying binaural processing.

Cat. No. Product Name Channel Number Site Material Substrate Material Length
NRZP-0823-ZP32 iElec™ Double Sided Silicon Neural Probe-64 Channels-10 128 Electroplated pedot Single crystal silicon Up to 12 mm
NRZP-0823-ZP36 iElec™ Double Sided Silicon Neural Probe-128 Channels-1 128 Electroplated pedot Single crystal silicon Up to 12 mm
NRZP-0823-ZP38 iElec™ Double Sided Silicon Neural Probe-128 Channels-2 128 Electroplated pedot Single crystal silicon Up to 12 mm
NRZP-0823-ZP44 iElec™ Double Sided Silicon Neural Probe-64 Channels-7 128 Electroplated pedot Single crystal silicon Up to 12 mm

Creative Biolabs has developed ultra-thin, flexible polymer electrode arrays designed for recording field potentials and spikes on the brain's surface. These arrays are employed in both short-term and long-term experiments involving various animal models, including rodents, sheep, and non-human primates. Similar to their penetrating counterparts, these electrodes are optimized for capturing high-resolution field and action potentials. This technology enables researchers to gather detailed insights into brain activity and neuronal behavior, making it a valuable tool in neuroscience research.

Cat. No. Product Name Channel Number Site Material Substrate Material Length
NRZP-0823-ZP8 iElec™ Polymer Surface Neural Probe-128 Channels-1 128 Electroplated pedot Flexible polymer N/A
NRZP-0823-ZP9 iElec™ Polymer Surface Neural Probe-64 Channels-6 64 Electroplated pedot Flexible polymer N/A

Customized Electrode Modification Services

In addition to our standard range of electrode products, we also offer customized electrode modification services tailored to meet your specific experimental needs. Our services encompass electrode sharpening, precise integration with optical genetic fibers, and alignment with EEG records for optimal performance. These specialized modifications are designed to enhance the quality and compatibility of electrodes, ensuring they align seamlessly with your research requirements.

Don't hesitate to contact us for more information.

For Research Use Only. Not For Clinical Use.

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