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research
brain science

integrated cell physiology

establishing connections between morphoelectric characteristics and transcriptomic-defined cell types
Advanced optical research equipment with multiple laser apparatus and measurement instruments on laboratory bench

goals and approach

The Integrated Cell Physiology team in the brain science accelerator conducts Patch-seq experiments using a whole-cell patch clamp technique to establish connections between morphoelectric characteristics and transcriptomic-defined cell types. This research helps to bridge the gap between genotype and phenotype.

The efficient and automated pipeline developed by this team is generating high-quality large-scale data at rates previously deemed impractical for electrophysiology experiments. Investigators on the Integrated Cell Physiology team utilize animal models and human tissue specimens acquired through neurosurgical procedures in combination with state-of-the-art genetic tools to identify rare cell types.

Lab technician wearing purple gloves working at computer station with multiple monitors in laboratory.

recent news

explore more news
news 
Unraveling the Complexity of the Mammalian Brain
Scientists used advanced, single-cell genomics and spatial mapping technologies to reveal this complex and rich cellular landscape.
news 
Scientists unveil first complete cellular map of adult mouse brain
High-resolution atlas charts neural neighborhoods for more than 5,300 cell types
news 
What makes us human? Detailed cellular maps of the entire human brain reveal clues
You have 3,000+ different kinds of brain cells, and more insights from the largest human brain cell atlases created to date
news 
How do our neurons connect? New study probes the details of human and mouse synapses
‘Multipatch’ technique catalogs more than 1700 connections between neurons in publicly released dataset

projects

in-vitro single cell characterization project

The “In-Vitro Single Cell Characterization Project (IVSCC)” employs a method called patch-seq to establish a direct link between the anatomical and electrical properties of individual cells and their genetic characteristics. This research is conducted using both animal models and human subjects.

gene therapy

The Integrated Cell Physiology department at the Allen Institute plays a crucial role in supporting gene therapy research. They provide important information about the effects of gene therapy interventions by conducting physiological assays that directly relate to gene function. These assays allow researchers to understand how the introduced genes are influencing the cellular behavior and function. By analyzing these physiological readouts, scientists gain valuable insights into the success and impact of the gene therapy interventions, which helps in advancing the field of gene therapy and its potential applications for various medical conditions.

PatchLink

The PatchLink project, supported by the National Institutes of Health (NIH), aims to create valuable tools that connect types of brain cells, defined by their genetics, to comprehensive brain circuit diagrams. The goal is to gain a deeper understanding of how different cell types are wired together. To achieve this, the project will develop cutting-edge automation technologies that allow us to measure shared features between genetic and circuit data sets at scale.

data and tools/

Data:

  1. Synaptic Physiology – Brain Map Portal
  2. Cell Types – Brain Map
  3. Specimens – Brain Map Knowledge

Tools:

  1. Acq4
  2. ipfx – Allen Institute GitHub
  3. MIES – Allen Institute GitHub
  4. Patchseqtools – Allen Institute GitHub

integrated cell physiology team

Luke Campagnola
Scientist III
Tamara Casper
Research Associate Sr. Supervisor
Nick Dee
Sr. Manager, Tissue Processing
Tim Jarsky
Associate Director, Electrophysiology
Megan Koch
Research Associate I
Rachel A McCue
Research Associate II
Kamiliam Nasirova
Research Associate II
Stephanie Seeman
Scientist III
Jessica Trinh
Research Associate III
we acceleratedevelopcatalyzeimpact

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brain science

Mapping every cell, connection, and circuit in the brain—openly shared with the world.

cell science

Decoding how cells become tissues, then programming that knowledge into powerful new research tools.

neural dynamics

Revealing the brain's hidden algorithms that transform neural activity into real-world behavior.

immunology

Creating the deepest open reference for the healthy human immune system ever built.

synthetic biology

Engineering cells to record their own histories, transforming how we understand disease over time.

research

Big questions, open answers, and science built to be shared.

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Inspiring the next generation of scientists through open science resources.

impact

Our science is empowering researchers and advancing health worldwide.
advancing science through open, collaborative research
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