Automated Electrographic
Analysis
Automated Electrographic
Analysis
Automated Electrographic
Analysis
Go Back
Go Back
Outcome
Outcome
Our organoid research and analysis has shown that patient-derived organoids retain the cross-frequency coupling patterns that resemble the original patient brain and disease states. This gives us powerful insight into how new therapeutics change the underlying disease on a functional level.
Our organoid research and analysis has shown that patient-derived organoids retain the cross-frequency coupling patterns that resemble the original patient brain and disease states. This gives us powerful insight into how new therapeutics change the underlying disease on a functional level.
Our organoid research and analysis has shown that patient-derived organoids retain the cross-frequency coupling patterns that resemble the original patient brain and disease states. This gives us powerful insight into how new therapeutics change the underlying disease on a functional level.
Technique
Technique
Phase-amplitude cross-frequency coupling (PAC) is a method used in neuroscience research to study the interactions between different frequency components of neural oscillations in the brain. In the context of understanding mood disorders and depression, PAC analysis can provide valuable insights into the underlying neural mechanisms.
Phase-amplitude cross-frequency coupling (PAC) is a method used in neuroscience research to study the interactions between different frequency components of neural oscillations in the brain. In the context of understanding mood disorders and depression, PAC analysis can provide valuable insights into the underlying neural mechanisms.
Phase-amplitude cross-frequency coupling (PAC) is a method used in neuroscience research to study the interactions between different frequency components of neural oscillations in the brain. In the context of understanding mood disorders and depression, PAC analysis can provide valuable insights into the underlying neural mechanisms.