Researchers in Prof. Mark Schnitzer's laboratory have developed a robotic optical microscopy system which enables users to simultaneously view and record separate areas of a single three-dimensional sample.
Over 1 in 3 people are affected by neurological conditions worldwide. Pharmacological and surgical treatment options may be limited due to access, side effects, and reduced therapeutic efficacy.
Stanford scientists have discovered that theta oscillations in the anterior cingulate cortex can detect empathic states, and that targeting the upstream orexin circuit can modulate empathy-related behaviors.
Researchers at Stanford have developed a novel endoscopic system for electrical stimulation and signal recording of olfactory tissue through a minimally invasive nasal approach.
Stanford researchers have developed a neuromonitoring-guided cognitive intervention that enhances working memory by dynamically identifying and reinforcing engagement of individualized brain networks in real time.
Stanford researchers have developed the Large-scale Electrophysiology Amplification Platform (LEAP), a wireless, label-free optical system for monitoring the electrical activity of neurons and heart cells.
Stanford researchers have developed a system that addresses a critical challenge in brain-computer interface (BCI) technology: the need for tedious and lengthy recalibration procedures that disrupt daily use.
Fiber photometry, a measurement technique that aggregates fluorescence signal using a fiber optic, is a highly pervasive approach in the field of systems neuroscience to study in vivo brain tissue dynamics during ecologically relevant behavior.
Stanford researchers have created a novel wearable device and system to assess fatigue on the user based on electrical activity associated with an eye blink of the subject.
Stanford researchers at the Lee Lab have developed a new system and method for measuring pathology then applying a novel algorithm to optimize neurostimulation therapy for altering pathology for treatment of neurodegenerative diseases.
Stanford researchers at the Lee Lab have developed a method to understand whole-brain circuit mechanisms underlying neurological disease and its application to predict the outcome of therapeutic interventions.
Researchers in Prof. Karl Deisseroth's laboratory have combined optogenetics with functional magnetic resonance imaging (fMRI) to enable highly specific in vivo analysis of brain circuits.
Researchers in Dr. Karl Deisseroth's lab have developed a selective approach to treat anxiety. Anxiety is characterized by several features that are coordinately regulated by diverse neuronal system outputs.