Johns Hopkins integrates nearly 200 studies and 30 million cells into a high-resolution atlas of neocortex development — turning raw biology into a programmable roadmap for the brain's computational assembly.
Evolution had 3.8 billion years. ABI gives us an afternoon. Adrian Woolfson and Eric Topol map the shift from reading DNA to authoring entire genomes — and what it means for biological computing.
Silicon that mimics the brain vs. neurons that are the brain. The neuromorphic and wetware paths diverge sharply — but their convergence may define the next era of intelligent machines.
Judah Anttila's TEDxOU talk maps the next 20 years of exponential change with rare emotional clarity. But the missing piece in his fractal mind thesis is the substrate — and wetware is already filling that gap.
Meta just open-sourced the most detailed virtual brain model ever built. It won't replace living neurons — but it could be the fastest path to making them work.
You can now buy a computer powered by living human brain cells or rent organoids in the cloud. We map the full 2026 landscape—from wetware processors to Neuralink trials and programmable cell therapies.
The real frontier of biocomputing isn't DNA — it's the proteome. Here's why intelligent organoids could crack the bottleneck and make drug discovery 100x faster.
OmicClaw lets scientists run complex genomic analysis using plain English — no code required. Here's why that matters.
The Pentagon's research arm just announced O-CIRCUIT — a program to develop biological processing units that run on living neurons, consume almost no power, and could one day navigate drones using a sense of smell.