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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
![Webinar - Neurodegenerative Disease](https://assets.technologynetworks.com/production/dynamic/images/content/392583/human-ipsc-based-models-of-glial-cells-for-studying-neurodegenerative-disease-392583-640x360.jpg?cb=13060276)
Human iPSC-Based Models of Glial Cells for Studying Neurodegenerative Disease
![Collection of mammalian cells derived from brain tissue on a black background. Astrocytes have been stained green, nuclei have been stained red (neurons) and blue (all cells).](https://assets.technologynetworks.com/production/dynamic/images/content/392166/exploring-human-ipsc-derived-astrocytes-for-advancing-cns-research-392166-640x360.jpg?cb=13041224)
Exploring Human iPSC-Derived Astrocytes for Advancing CNS Research
![TMI10 image](https://assets.technologynetworks.com/production/dynamic/images/content/391567/leveraging-human-ipsc-derived-astrocytes-for-neurological-research-and-therapy-391567-640x360.jpg?cb=13068654)
Leveraging Human iPSC-Derived Astrocytes for Neurological Research and Therapy
![Images of the two speakers sit underneath the webinar title. To one side, red-labelled cells are shown.](https://assets.technologynetworks.com/production/dynamic/images/content/389101/powering-a-new-generation-of-physiologically-relevant-crispr-screens-389101-640x360.jpg?cb=12979385)
Powering a New Generation of Physiologically-Relevant CRISPR Screens
![iPSC-derived astrocytes, human astrocytes, glial cells, opti-ox technology](https://assets.technologynetworks.com/production/dynamic/images/content/388101/ioastrocytes-human-ipsc-derived-astrocytes-388101-640x360.jpg?cb=13012689)
ioAstrocytes - Human iPSC-Derived Astrocytes
![Microscopic view of fluorescently labeled cells showing green cell bodies with blue nuclei connected by thin, bridge-like structures](https://assets.technologynetworks.com/production/dynamic/images/content/387949/advancing-neurodegenerative-disease-research-with-ipsc-derived-microglia-387949-640x360.jpg?cb=13088813)
Studying the Link Between Cell Migration and Neurodegenerative Disease With iPSC-derived Microglia
![A doctor writing on a clipboard next to a brain, examining medical records and analyzing brain functions](https://assets.technologynetworks.com/production/dynamic/images/content/387946/improving-physiological-relevance-in-neurological-disease-drug-development-387946-640x360.jpg?cb=13031215)
Improving Physiological Relevance in Neurological Disease Drug Development
![Colorful pattern of DNA strands interwoven in a complex structure](https://assets.technologynetworks.com/production/dynamic/images/content/387945/overcoming-challenges-in-functional-genomics-screening-387945-640x360.jpg?cb=12960588)
Improving Physiological Relevance in Functional Genomics Screens
![TMI10](https://assets.technologynetworks.com/production/dynamic/images/content/385552/how-to-accelerate-research-and-drug-discovery-in-motor-neuron-disease-a-deep-dive-into-precision-385552-640x360.jpg?cb=12766528)
How To Accelerate Research and Drug Discovery in Motor Neuron Disease: A Deep Dive Into Precision Reprogrammed Human iPSC-Derived Motor Neurons
![Neuro Research](https://assets.technologynetworks.com/production/dynamic/images/content/385441/speeding-up-neuroscience-research-385441-640x360.jpg?cb=12764649)