The U.S. market's high prices create the large profit pool necessary to fund risky drug development. If the U.S. adopted price negotiation like other countries, the global incentive for pharmaceutical innovation would shrink, resulting in fewer new drugs being developed worldwide.

While the FDA is often blamed for high trial costs, a major culprit is the consolidated Clinical Research Organization (CRO) market. These entrenched players lack incentives to adopt modern, cost-saving technologies, creating a structural bottleneck that prevents regulatory modernization from translating into cheaper and faster trials.

The Orphan Drug Act successfully incentivized R&D for rare diseases. A similar policy framework is needed for common, age-related diseases. Despite their massive potential markets, these indications suffer from extremely high failure rates and costs. A new incentive structure could de-risk development and align commercial goals with the enormous societal need for longevity.

Responding to Wall Street pressure to de-risk, large pharmaceutical firms cut internal early-stage research. This led to an exodus of talent and the rise of contract research organizations (CROs), creating an infrastructure that, like cloud computing for tech, lowered the barrier for new biotech startups.

A massive disconnect exists where scientific breakthroughs are accelerating, yet the biotech market is in a downturn, with many companies trading below cash. This paradox highlights structural and economic failures within the industry, rather than a lack of scientific progress. The core question is why the business is collapsing while the technology is exploding.

The biotech ecosystem is a continuous conveyor belt from seed funding to IPO, culminating in acquisition by large biopharma. The recent industry-wide stall wasn't a failure of science, but a halt in M&A activity that backed up the entire system.

MIT Professor Jim Collins estimates a $20 billion investment could fund the R&D and clinical trials for 15-20 new antibiotics, solving the crisis for decades. This cost is a fraction of recent tech investments, framing an existential threat as a solvable, relatively affordable problem.

The AI-discovered antibiotic Halicin showed no evolved resistance in E. coli after 30 days. This is likely because it hits multiple protein targets simultaneously, a complex property that AI is well-suited to identify and which makes it exponentially harder for bacteria to develop resistance.

Diseases like Ebola and malaria, which primarily affect poor countries, lack market incentives for vaccine R&D. The Ebola vaccine only progressed because it was briefly on a U.S. bioterrorism list created after 9/11, highlighting how market failures require creative, sometimes accidental, incentives to overcome.