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bit.bio

bit.bio is an award-winning human synthetic biology company whose mission is to code cells for novel cures. They have developed an end-to-end platform for the creation of any human cell type. With their cutting-edge and patent-protected opti-ox precision cell programing technology, bit.bio can deterministically program human induced pluripotent stem cells (iPSCs) into a chosen cell identity with unprecedented biological consistency at an industrial scale and approximately 10 times faster than conventional methods. Their platform has the potential to unlock a new generation of medicines.

Latest bit.bio Content

Images of the two speakers sit underneath the webinar title. To one side, red-labelled cells are shown.
Webinar

Powering a New Generation of Physiologically-Relevant CRISPR Screens

On-Demand
CRISPR-Cas9 gene editing is an essential functional genomics tool, facilitating the cataloging of genomic variations linked to human diseases for the discovery and validation of novel drug targets.
iPSC-derived astrocytes, human astrocytes, glial cells, opti-ox technology
Product
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ioAstrocytes - Human iPSC-Derived Astrocytes

ioAstrocytes offer a solution to researchers who are searching for easy-to-use, highly characterised human cells that are designed for co-culture and effectively recapitulate astrocyte functions within CNS models in vitro
Microscopic view of fluorescently labeled cells showing green cell bodies with blue nuclei connected by thin, bridge-like structures
App Note / Case Study

Studying the Link Between Cell Migration and Neurodegenerative Disease With iPSC-derived Microglia

In this application note, researchers from Medicines Discovery Catapult (MDC) evaluated the suitability of iPSC-derived microglia as a model for studying the mechanics of microglia activation, shedding light on their role in neurodegeneration and the potential for therapeutic targets.
A doctor writing on a clipboard next to a brain, examining medical records and analyzing brain functions
App Note / Case Study

Improving Physiological Relevance in Neurological Disease Drug Development

This app note explores the use of human iPSC-derived microglial cells as a more reliable model for neurobiological drug development.
Colorful pattern of DNA strands interwoven in a complex structure
Poster

Improving Physiological Relevance in Functional Genomics Screens

This poster describes the use of CRISPR-ready iPSCs, which are engineered to constitutively express Cas9, enabling the rapid generation of high-efficiency gene knockouts and CRISPR screens in a functional, physiologically relevant cell background.
TMI10
Video

How To Accelerate Research and Drug Discovery in Motor Neuron Disease: A Deep Dive Into Precision Reprogrammed Human iPSC-Derived Motor Neurons

In the Teach Me in 10 video, Dr. Marcos Herrera-Vaquero, bit.bio discusses motor neurons and their critical role in Motor Neuron Diseases (MNDs) such as amyotrophic lateral sclerosis (ALS) and spinal muscular atrophy (SMA).
Neuro Research
App Note / Case Study

Speeding Up Neuroscience Research

Delve into this case study to explore how a research lab at King’s College London used hiPSC-derived neurons to shed light on synaptic biology and potential treatments for psychiatric conditions.
Neuro Program
App Note / Case Study

Precision Reprogrammed iPSC Models for High-Throughput Drug Discovery

This app note delves into the role of TDP-43 protein aggregates in the disease's progression. Charles River Laboratories and bit.bio present a breakthrough in ALS research with genetically matched ioGlutamatergic Neurons, providing a crucial in vitro model.
bit.bio webinar technologynetworks 2nd May 2024
Webinar

Uncovering the Glioma Microenvironment With In Vitro Neuronal Models

On-Demand
In this webinar, you’ll hear from Dr. Brian Gill about his research into neuron–glioma interactions and how they contribute to seizures and tumoral growth.
Innovations in Disease Modeling 2024
Online Event

Innovations in Disease Modeling 2024

On-Demand
Explore the tools and techniques being used to study diseases in the lab. Discover how advances in cell culture and disease modeling are supporting diagnostic and therapeutic development.
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