Programmable Cells as Living Medicine: The Body as Its Own Pharmacist
Designer cells that detect disease bioelectric signatures and release targeted therapies in real time — no drugs, no doctors, no waiting.
When AI Learns to Think in Bioelectric Patterns, Not Binary Code
Neuromorphic chips that mimic biological signal processing are already outperforming silicon on specific tasks. The gap is closing faster than expected.
DNA as a Storage Medium: 1 Gram Could Hold All of Humanity’s Data
The bioelectric encoding of digital information in biological polymers — and what it means when our archives become alive.
The Resting Membrane Potential: Why Your Cells Are Always Charged
Every cell in your body maintains a voltage difference across its membrane — typically around -70 millivolts. This guide explains how and why, using simple analogies and interactive diagrams.
Action Potentials: The Body’s Electrical Messaging System
How a nerve cell fires, what the all-or-nothing principle means, and how signals travel from your finger to your brain in under 20 milliseconds. With an explainer on why myelin is nature’s best conductor.
Bioelectric Fields: The Invisible Architecture Shaping Living Bodies
Beyond single cells — how entire tissues and organs use coordinated voltage patterns to guide growth, healing, and behavior. Including how disrupting these fields can cause cancer, and how restoring them might reverse it.
Bioelectric Computation: Can Living Cells Run Logic?
An advanced look at how engineered bioelectric circuits can perform Boolean logic, store memory, and respond to environmental inputs — and what this means for the future of living computers and programmable organisms.
How the Heart’s Electrical System Works — and What Happens When It Doesn’t
The sinoatrial node, the P wave, and the cascade of signals that make your heart beat 100,000 times a day. A visual walkthrough of cardiac bioelectricity and the mechanisms behind arrhythmia.