Industrial biotech faces repeated “valleys of death” between laboratory success and commercial manufacturing, driven by a combination of technological uncertainty, scale-dependent constraints, and (mis)alignment between engineering reality and investment expectations. Promising technologies often fail not because the science is wrong, but because scale-up trajectories are built on insufficient data, optimistic assumptions, and decision-making based on the 1st product specifications from the lab that do not translate to industrial conditions. This panel returns to fundamentals, drawing on real-world experience from piloting, process engineering, and early industrialization to examine where and why scale-up breaks down. Experts will discuss how important the scale-up journey is to align technology performance with investor expectations, support sound business cases, and turn the industrial biotech toolbox into a more robust, scalable, and profitable manufacturing platform.

As biology becomes programmable and AI accelerates discovery, startups are generating breakthrough innovations at unprecedented speed. Yet translating these advances into real-world therapies still depends on effective collaboration with global pharmaceutical organizations. This session explores how the innovation ecosystem connects early-stage breakthroughs to scalable development, bringing together leaders from startup incubation, external innovation, and pharma strategy. Speakers will examine how AI-native biotech companies engage with pharma today: how startups become “pharma-ready,” how external innovation teams evaluate and structure partnerships, and what collaboration models are emerging as biology and computation converge. From early ecosystem support and venture building to strategic alliances and co-development pathways, the discussion will provide a practical look at how ideas move from discovery to patient impact in the AI era.

Scaling bio-based products to commercial production requires balancing technical readiness with market and financial realities. This session examines the capital investments, regulatory planning, and supply chain strategies necessary to move beyond the pilot stage. Experts will share lessons on aligning production capacity with demand forecasts, managing operational risk, and structuring partnerships that unlock funding and market access. Attendees will gain practical insights into navigating investor expectations, scaling efficiently without compromising quality, and making strategic decisions that ensure products can succeed commercially while meeting evolving market needs and sustainability goals.

Mining has long relied on brute force and chemistry, but biology is opening a new frontier. Biomining uses engineered microbes to extract metals and minerals with precision, efficiency, and far less environmental impact than traditional methods. From rare earth elements essential to clean energy to critical metals powering electronics, synthetic biology is reshaping how we source the building blocks of modern life. This session spotlights innovators designing bio-based recovery systems, scaling sustainable solutions, and reimagining resource extraction.

Biology is entering an era where AI agents don’t just analyze data — they co-design, plan, and execute experiments. Multi-agent systems like CRISPR-GPT demonstrate how AI can act as a true lab co-pilot: decomposing complex genome editing projects into stepwise workflows, selecting tools, troubleshooting, and even drafting protocols that allow junior researchers to perform sophisticated edits on their first attempt . Beyond CRISPR, new systems like BioMARS integrate reasoning agents with robotics, while biotech companies are testing “AI lab assistants” that monitor and adjust experiments in real time. This session explores how multi-agent copilots are making biology more reproducible, democratizing complex workflows, and pushing the boundaries of lab autonomy. The central question: when AI can plan, troubleshoot, and validate experiments end-to-end, how should scientists and institutions govern this new power?

For decades, DNA synthesis has been the limiting reagent in synthetic biology — reliable for short sequences, but increasingly error-prone and costly as designs scale. That ceiling is now cracking. New enzymatic synthesis platforms, error-correction chemistries, and assembly pipelines are extending what’s possible, opening the door to rapid construction of full pathways, microbial genomes, and even mammalian chromosomes. This session will explore how innovators are breaking past barriers, what technical and economic breakthroughs are needed next, and how longer, cheaper, and faster synthesis could fundamentally change how we design biology at scale.

Scaling bio-based products requires integrated technical collaboration across strain engineering, fermentation, downstream processing, and analytics. Full-stack approaches—where startups, CDMOs, and platform technology providers align early on—can optimize yield, reduce variability, and lower cost of goods (COGS) at commercial scale. This session explores case studies of cross-company collaboration, from co-development of microbial strains and bioreactor designs to shared process analytics and predictive modeling. Hear how teams are breaking down technical silos to accelerate scale-up, improve reproducibility, and create competitive, sustainable manufacturing solutions that bring synthetic biology products from the lab to the market efficiently.

The next frontier of biology isn’t in predicting a single static protein structure, but in capturing how proteins move, fold, and interact across time and environments. This session explores how AI can illuminate protein conformations and dynamics, and extend those insights into virtual multi-cellular or tissue models. Experts will discuss the challenge of integrating heterogeneous datasets and instruments, and how breakthroughs in dynamic modeling could reshape drug design, disease understanding, and biomanufacturing. Can we build models that reflect the living, breathing complexity of biology—not just snapshots, but motion?

Biotech is no longer behind the scenes—it’s on our shelves, in our homes, and part of our daily routines. From sustainable haircare to household cleaning, and high-performance materials, bio-based innovations are redefining everyday consumer experiences. This session explores what drives adoption, how brands communicate the value of biology, and why trust, transparency, and performance are key to building loyalty. Join us to hear from the companies making biology irresistible, accessible, and seamlessly integrated into daily life—and learn what it takes to create bio-products consumers truly love.

For decades, pharmaceutical supply chains were optimized for cost and scale, stretching across continents to source critical active ingredients. But fragility has made resilience a strategic imperative. Synthetic biology offers a new model: onshoring the production of essential APIs by programming cells to manufacture small molecules, peptides, and novel amino acids with precision and scalability. Instead of relying on distant chemical supply networks, biology becomes the factory—flexible, distributed, and programmable. This session explores how engineered microbes and directed evolution platforms are rebuilding pharma supply chains from the molecular level up, enabling secure, responsive, and locally anchored production of the medicines the world depends on.

Meat is one of the world’s most complex biomanufacturing systems—and also one of its least optimized. For 12,000 years, we’ve cycled crops through animals to make meat. Drawing from his new book Meat, Bruce Friedrich contends that advances across science and engineering now make it possible to produce meat far more efficiently, which will reduce meat’s contribution to hunger, climate change, deforestation, antibiotic resistance, and pandemic risk. Most importantly for the success of alternative meats, these new technologies will also improve food security and add to GDP for the nations that lean in. It’s been exactly ten years since the first plant-based burgers were introduced and also exactly ten years since the first cultivated meat companies were incorporated. Bruce will reflect on how far we’ve come, how far we have to go, and what it's going to take to get there. Welcome to the next agricultural revolution—courtesy of science.

For 20+ years, the synthetic biology community has generated breakthrough targets, but too many continue to stall at the same choke points: freedom-to-operate, productivity, process robustness, CMC readiness, and the leap from “works in the lab” to “works at scale.” In this lightning talk, Ingenza will share how we’ve repeatedly helped teams cross that valley of death, turning innovative discoveries into manufacturable realities across industrial biotech and therapeutics. We’ll spotlight our inGenius® platform: a proven panel of high-performing microbial and mammalian production hosts paired with AI/ML-driven enzyme discovery and gene design optimisation (codABLE®), scalable upstream and downstream platform process workflows, and a comprehensive suite of high-end analytical tools that accelerate and de-risk the path from early discovery to market readiness. Powered by 20+ years of successful delivery, expect rapid, real, case study driven lessons from the front lines: what fails most often, what fixes it fastest, and how to design with manufacturability from day one without slowing innovation. If you’re engineering biology to improve human health or the planet, this talk is your shortcut to faster timelines and better outcomes that help SynBio move at the speed it promises.

Our industrial economy was built on energy-intensive, centralized manufacturing. The future economy will be grown with biology—making what we need, where we need it, when we need it—with superior unit economics and seamless integration into nature. The bottleneck: biotech has largely been confined to fermenters. Switch Bioworks breaks that constraint by engineering microbes that operate directly in nature—starting with agriculture. Today, 4 billion people depend on expensive synthetic fertilizer for food security—a $200B market. Switch is replacing it with engineered microbes that colonize plant roots and “switch” on fertilizer production precisely when needed. This time-controlled switching architecture solves the tradeoffs that have limited prior biofertilizers and delivers unbeatable unit economics for farmers. Founded by Tim Schnabel, who invented the core technology at Stanford, Switch is led by a world-class team spanning microbial engineering, ag commercialization, IP, and regulatory leadership, with advisors from Corteva, BASF, Syngenta, Nutrien, and leading universities. Switch is preparing to raise a Series A to reach commercialization and lead the Biology on Demand movement. Fertilizer has opened the door, the platform is ready for more.

While Twist Bioscience may look like an overnight success, its rise reflects a decade of persistence, innovation, and platform building. In this main stage keynote, CEO and co-founder Emily Leproust shares the journey from startup vision to global leader in DNA synthesis and programmable biology, highlighting lessons learned scaling deep technology, navigating industry cycles, and building trusted infrastructure for biotech and pharma. Looking ahead, Twist is positioning itself at the forefront of the convergence between AI and biology, using DNA as an information layer to accelerate drug discovery and advance human health. This keynote explores how long-term thinking and bold ambition are shaping the next era of AI-driven therapeutics.

Biotechnology is enabling a new generation of ingredients that elevate both product performance and sustainability. In this fireside chat, leaders from Procter & Gamble will discuss how biotech is being applied across key material classes to enhance consumer products, highlighting innovations behind their latest Native launch and emerging bio-derived ingredients for hair and beauty. The conversation will also explore how biotech platforms are helping shape the future of high-performing, sustainable consumer goods.

Biology will be the center of the next industrial revolution, representing a $4 trillion economic opportunity. Yet, this value remains overwhelmingly unrealised for one fundamental reason: nature never intended to power industrial manufacturing. Biology was optimized for survival, not for the high-efficiency processes required to transform the global economy. For too long, the industry has relied on incremental improvements, essentially duct-taping enzymes and calling them industrial. At Biomatter, we believe that complete freedom to design any enzyme is the only way to realize the full potential of biomanufacturing. By combining Generative AI with rigorous physics engines, our Intelligent Architecture™ platform allows us to step outside the bounds of natural selection and build enzymes from the bottom up. We are turning the "previously impossible" into routine. From liberating enzymes of their cofactor dependencies for mRNA raw materials to designing lactases that reject the trade-off between lactose removal and high GOS fiber formation, we are proving that biology’s limits are negotiable. Join us to see how we are building the enzymes nature couldn't.

For over a century, antivenoms have relied on serum extraction from animals — a process that’s costly, inconsistent, and limited to specific snake species. Today, advances in synthetic biology and antibody engineering are pointing toward a different future: a universal antivenom capable of neutralizing toxins across the world’s deadliest snakes. This session dives into the science and story behind this breakthrough — from the man who endured more than 200 bites to generate a unique immune response, to the researchers using those antibodies to design broad-spectrum, recombinant therapies. Together, they’re charting the path from survival experiment to programmable immunity.

Drug discovery often measures biology at the cell level, while therapies must ultimately work across tissues, organs, and whole patients. This scale mismatch means that even highly accurate cellular predictions can fail to translate in the clinic. This session explores strategies to bridge that gap. How do we connect single-cell dynamics to organ-level physiology and patient outcomes? How do we preserve biological context while scaling models? And how do we ensure that virtual biology does not stop at simulation, but informs real therapeutic decisions? Speakers will discuss multiscale modeling that links molecular and cellular systems to higher-order biology; spatial and high-dimensional phenotypic data that retain context; and integrated computational–experimental loops that translate cellular signals into clinically meaningful biomarkers. Together, we ask: how do we ensure virtual biology reflects not just what cells do in isolation, but how biology behaves in the full complexity of patients?

Current bioprocess monitoring is limited to basic environmental proxies like pH and dissolved oxygen. Schmidt Sciences is changing this paradigm by adapting advanced physics for biology. This talk introduces three cutting-edge sensing platforms currently in development: fluorescent nanodiamonds, single-cell Raman spectroscopy, and non-invasive optical frequency combs. Join us to learn how these high-dimensional data streams are being integrated with machine learning to predict campaign outcomes and revolutionize how we monitor cell health at scale.

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The PURE system, invented 25 years ago, established a fully reconstituted approach to cell-free protein synthesis. What began as a system to better understand translation has evolved into a versatile platform for engineering biology. This talk highlights how PURE-derived platforms such as PUREfrex® enable rapid prototyping, high-throughput screening, and AI/ML-driven optimization, accelerating synthetic biology and next-generation biologics development.

Food is no longer just sustenance—it’s becoming a programmable interface with human biology. Advances in synthetic biology and foodtech are enabling the design of bioactive molecules that target specific health outcomes: regulating glucose and lipid metabolism, strengthening cardiovascular resilience, and even enhancing cognitive performance. From engineered microbes that secrete beneficial metabolites to programmable synbiotics tuned to the gut, this session will explore how programmable biology is transforming food into a therapeutic platform. Panelists will ask: what if the next breakthroughs in managing obesity, dementia, and heart disease don’t come from pharmaceuticals, but from intelligently designed foods and functional ingredients?

AI-enabled, self-driving labs are still emerging, but their foundations are already transforming how teams design, run, and interpret experiments. This session offers a practical guide for scientists and R&D leaders who want to understand what can be done today — from tightening design–test–learn loops to reducing manual error and capturing early benefits of autonomous experimentation. Rather than presenting an unrealized future, speakers will focus on practical, real-world steps that give organizations a competitive edge as SDL capabilities evolve and mature. Speakers will explore what’s working, what’s not, and how autonomous lab systems are reshaping protein engineering, pathway optimization, and therapeutic design.

Biology has long relied on a limited molecular vocabulary shaped by natural evolution. Today, that alphabet is expanding. Advances in expanded genetic codes, non-canonical amino acids, macrocycles, de novo design, and AI-guided protein engineering are enabling scientists to create biomolecules with properties and functions that nature never evolved. This session explores the rise of programmable biomolecules at the intersection of biology, chemistry, and computation. Rather than simply optimizing existing proteins, researchers are building entirely new classes of functional molecules with novel architectures, chemistries, and therapeutic potential. From next-generation biologics to hybrid molecular scaffolds, the discussion will examine how the field is moving beyond nature’s defaults and toward a future where biomolecules can be designed with increasing precision, flexibility, and intent.

Why do so many in silico models fail when moved to the lab or clinic? Too often, they’re trained on incomplete, non-human, or non-representative datasets. This session tackles the “data gap” head-on: from interoperability bottlenecks and the black box problem to the limits of current virtual cell simulations (~50 million perturbations vs. the billions biology demands). Panelists will explore how to create “human-first” datasets that reflect real biology, unlock mechanistic interoperability, and close the discovery–development divide. The goal: build AI tools that can directly identify viable drug candidates instead of stalling in silico.

Standard bioreactors often lack the instrumentation required to rapidly monitor cell physiology, leaving critical gaps in our understanding of scale-up dynamics. This session presents active projects from the Schmidt Sciences’ Sensors for Biomanufacturing Program designed to address this challenge through novel sensing modalities. Spanning from near real-time intracellular measurements to non-invasive off-gas fingerprinting, the panel brings together technology developers and industrial bioprocess experts to discuss the translation of these tools from the lab to the plant floor. Together, we will critically evaluate the utility of high-dimensional metabolic data and explore the engineering requirements for integrating physics-based sensors and machine learning into existing biomanufacturing workflows.