To permanently access this App Note for free, fill out the short form below. Cerebral organoids, derived from human pluripotent stem cells (hPSCs), have emerged as powerful three-dimensional (3D) in ...

This article is based on a poster originally authored by Bo Wang, Lu Zhang, Yufang Yan, Hongchun Zhang, Yuwei Zhao, Wenqi Zhang, Xiaopan Nie, Liyuan Zhang, Ruixiu Wang, and Jingqi Huang. Human ...

A new study of prion diseases, using a human cerebral organoid model, suggests there is a substantial species barrier preventing transmission of chronic wasting disease (CWD) from cervids—deer, elk ...

Grab your cup of coffee and join us for the Multiomics Coffee Break with a presentation from The Network Biology Collaborative Centre at Mount Sinai Hospital, Olink Certified Service Provider. With ...

Could putting a tiny brain inside a larger brain help study disease? As far-fetched as the idea might sound, the approach could allow scientists to investigate human microglia in near-physiological ...

This photo shows one of the new CAMEO sensors, holding a human cerebral organoid. Researchers have demonstrated that CAMEO -- a low-cost, scalable sensor -- can be used to monitor electrical activity ...

In a recent study published in Nature, researchers develop the clustered regularly interspaced short palindromic repeats (CRISPR)-human organoids-single-cell ribonucleic acid (RNA) sequencing (CHOOSE) ...

Research on conditions like autism, schizophrenia and even brain cancer increasingly relies on clusters of human cells called brain organoids. These pea-size bits of neural tissue model aspects of ...