Cullen lab is hiring!!! The postdoctoral researcher will manage aspects of the studies that will include iPSC derived neural and skeletal myocyte culture, bioprinting, optogenetic transduction and functional assessment in vitro and in vivo. Check this out for more details -

Group photo of inaugural Multi-Area, high-Density, Laminar Neurophysiology (MaDeLaNe) workshop Vanderbilt University. Thanks Martin Vinck Kari Hoffman @[email protected] Shailaja Akella Jake Westerberg Kianoush Banaie Boroujeni Thilo Womelsdorf Alex Maier, students and tutors! LFPs and spikes making a cameo - see them!?? ;)

Diagnostic Biochips (Diagnostic Biochips) is manufacturing its own neural probes and cloud-based software, reimagining the world of electrophysiology. Their work is helping to find therapies, and hopefully cures, for neurological disorders. #MdLifeSciences business.maryland.gov/blog/diagnosti…

This past November, DBC sponsored a webinar titled, "Unveiling the Primate Brain: Advanced Insights through Ultra-Dense Electrophysiology". Watch the webinar recording and learn about how DBC's Deep Array enables researchers to gather relevant data: hubs.ly/Q02Dbt1N0

A study from the Wang lab at JHU employs advanced imaging techniques to map the tonotopic organization of the auditory cortex in awake marmosets. This research provides insights into the functional architecture of the primate auditory cortex. hubs.ly/Q02DKSHF0 #DBCInside

🎆 🇺🇸 Happy 4th of July from all of us at DBC! 🇺🇸 🎆 Enjoy the fireworks, BBQs, and time with loved ones.

Excited to share that the latest Kari Hoffman @[email protected] paper is published in Cell Reports. We describe the dynamics of superficial and deep CA1 pyramidal cells and identified putative groups of inhibitory cells in freely moving, thinking, and sleeping macaques. 1/n

We used high-density deep array probes from Diagnostic Biochips and Freelynx from Neuralynx to wirelessly record layer-resolved LFP and spiking activity in macaque CA1 across a contextual memory task and sleep states. We used a semi-supervised approach to cluster cell groups.5/n

📢The latest from talented Saman Abbaspoor 's PhD is out in @cellreports! You into ensembles (Diagnostic Biochips DA or #neuropixels in #nhp)? ❤️CA1 microcircuits? Wonder why we don’t know how they support #memory or behavior in #primates? Like inhibitory cell types? Cell Assemblies in😴?

Cell Press published the research from Kari Hoffman @[email protected] where Sam Abbaspoor and Kari Hoffman utilized the DBC Deep Array to uncover the macaque hippocampus's unique circuit dynamics govern navigation, memory, and social behaviors across species. hubs.ly/Q02H7G2d0 #DBCInside

Our customers and many other neuroscience labs aim to understand Parkinson's at the cellular level with hopes to apply their findings to drug development and possible cures. Link to Parkinson's Foundation: hubs.ly/Q02JgwhF0

New research shows that norepinephrine spikes in the brain after unexpected events help segment and shape memories. This highlights the importance of how our brains organize after new experiences, paving the way for future studies on memory and attention. hubs.ly/Q02KGhjx0

New study using DBC Deep Array from Chris Fetsch's lab at Johns Hopkins University reveals how monkeys form decisions and confidence simultaneously. This research offers valuable insights into the neural mechanisms of metacognition. #DBCInside hubs.ly/Q02LXMsD0

Cornell researchers found BARRs, special events during non-REM sleep that stabilize brain activity after learning by silencing overactive neurons. Disrupting BARRs leads to memory issues—showing their key role in healthy brain function. hubs.ly/Q02MNgbw0 #DBCInside #Ephys

🧪📚 With school back in session, now’s the perfect time to stock up on DBC probes for your research students! Equip your lab with the best tools for success and explore our most competitive pricing yet. Order in bulk and save even more! hubs.ly/Q02NDyr30 #Ephys #Neuro

Did you know your brain simulates movements and interactions while you sleep? During REM sleep, your brain issues motor commands, shifting your internal sense of direction as if you were awake. The Scanizani Lab at UCSF determines how it works: hubs.ly/Q02PJjdq0 #DBCInside