How Isha's Paper Helped Launch the Cultured Meat Industry
by Rachel Nuwer
Ten years ago, cultured meatΒ seemed like the stuff of science fiction. The idea of growing meat outside an animalβs body existed only in the minds of a few niche visionaries scattered around the world. There were no labs dedicated to developing it and no funding streams to support such research. People interested in cultured meat (not to be confused withΒ plant-based meat) found each other by chance, through internet searches and word of mouth. Now, a decade later, those first imaginative ventures have exploded into a booming real-world industry, complete with a conference circuit and a Washington-facing industry coalition. What accounts for this rapid transformation?
A Long Time Coming
The idea of producing meat in a lab is not new. In 1931, Winston Churchill, for example, wrote that the βabsurdityβ of raising a whole chicken just to eat its breast or wing could soon be avoided by βgrowing these parts separately under a suitable medium.β However, by the mid-aughts, when Datar was an undergraduate, astonishingly few researchers had seriously pursued this possibility or even thought about it.A biology major in search of a calling, Datar signed up for Bettiβs meat science class, where she learned about the environmental impact of the meat industry. A brief mention of cellular agriculture was enough to pique the undergradβs interest, and she decided to focus on the topic for her senior thesis. She surveyed the existing literature on tissue engineering and culture techniques to see how those tools could be applied to food production, and then presented her findings in neat methodological steps. This, it turned out, would be a roadmap for the future of cultured meat production, including possible obstacles.Her research eventually led her to New Harvest and its founder Jason Matheny, whose groundbreaking paperΒ βIn Vitro-Cultured Meat ProductionβΒ had been foundational to the very concept of cultured meat. At the time, the companyβs website was just a landing page linking to a few articles about Matheny, who had become interested in artificial meat while touring Indian poultry farms as part of his graduate research in public health. Datar emailed her thesis to him, and he responded enthusiastically, ccβing a number of other interested researchers. The scientists encouraged Datar to publish her findings, and she followed their advice, soon bringing in Betti as co-author.
βIt is definitely not common for an undergraduate student to publish a manuscript in an internationally-recognized scientific journal,β Betti says now. βMost importantly, the paper critically addressed the engineering and nutritional challenges to producing meat thatβs as similar as possible to real meat."Others in the field quickly took notice, includingΒ Luke MacQueen, a research associate at Harvard University who specializes in tissue engineering and lab-grown meat. βThis paper was among the first ten that ever discussed this subject at all, so it was pioneering, by definition,β MacQueen says. βAnyone who was in the field at the time was often misunderstood or dismissed a little bit, so Ishaβs paper was really encouraging. It gave hope to people, and it cleared the path for others to follow.βThe support Datar received from the cellular agriculture community convinced her to keep working in the field. βIt seemed so exciting to start my career focusing on something very few people were interested in,β she says. βI liked the idea of being on the cutting edge of this crazy idea with a few other quirky people. I felt very at home in that space.βIn 2013, after completing a masterβs degree in biotechnology from the University of Toronto, Datar became New Harvestβs executive director. She has since led the non-profitβs efforts to build a community around cellular agriculture, funding promising research and bringing like minded scientists together at an annual conference. βAcademia is where innovation really begins, and where real exploratory discovery starts,β she says.
New Harvest is one of the few sources of funding for such projects. Cellular agriculture is still considered a sort of in-between discipline, Datar says. Itβs not traditional agriculture or classic food science, and itβs not typical health-focused biomedical engineering, making it ineligible for government grants from the likes of the US Department of Agriculture or the National Institute of Health. βI know firsthand that funding for projects like this used to be next to impossible,β MacQueen says. βI struggled myself, and Iβm not the only one.β
Toward sustainable eating habits
There is a real urgency to get cultured meat on shelves, thanks to the devastating impact the meat industry is inflicting on the planet, and the growing demand for its products. Most people in the world still choose to eat meat on a regular basis, if they can afford it. Meat consumption has increased exponentially over the past 50 years. As the worldβs population has doubled and countries have grown more prosperous, livestock production has quadrupled. Factory farming, meanwhile, has continued to lower costs and made meat more affordable than ever. Today, the average person consumesΒ 95 pounds of meat perΒ year, though some countries consume much more than others. Americans are among the most voracious carnivores, averaging overΒ 222 pounds of meat per person, annually.As production ramps up to meet this demand, so, too, does the industryβs carbon footprint. Livestock currently account forΒ 14.5 to 18 percent ofΒ global greenhouse gas emissions. The industry also contributes to global warming indirectly, through the land it takes up. AroundΒ 80 percent ofΒ the worldβs farmland is used to raise animals, and all that land provides just 18 percent of the calories consumed globally from farmed food. Compounding the matter,Β land allocated to livestock is oftentimes clear-cut forest,which otherwise could be conserved or restored to serve as a vitalΒ natural carbon sinkβa key to mitigating global warming.Whatβs more, the meat industryβs footprint is growing at a deleterious rate. Only last month, researchers from Harvard University published a paper warning that the livestock sector alone will account forΒ nearly half of global emissions by 2030, if current growth and operational trends persist. The studyβs authors have called for countries to set near-future dates for hitting βpeak meatβ production, and to start scaling back from there. Scaling back, the researchers write, could mean replacing livestock with crops, or taking a more environmentally friendly agroforestry approach to raising animals.Cellular agriculture could be a significant part of that solution, if a few things align. To make the product viable and competitive, the costs of production need to be even further reduced. In order to accomplish that, the industry requires more public funding and investment. Time is of the essence, because climate change wonβt wait.
A Support Network
There are reasons to be optimistic. Over the past 10 years, thanks to New Harvestβs support, cultured meat has made huge strides. Advances in stem cell technologyΒ have inspired a further breakthrough inΒ the field, allowing researchers to reprogram cells into distinct forms, including muscle cells.MacQueen and his colleagues at Harvard can already produce small pieces of tissue that resemble meat. They are now working on techniques to introduce textures that lend their meat a natural mouthfeel. Another 30 or so start-up companies are also working to produce their own cultured meat or dairy products. βThe technology is finally becoming practical,β MacQueen says. βThe extraordinary is becoming ordinary.β
Datarβs contribution has long outgrown her famous undergraduate paper, which helped kick off so many careers in the field, including her own. She is driven by a desire to create space for scientific advancement through the joint efforts of many people, institutions and companies. βThis is a huge project,β she says. βItβs about community building.βIf successful, cultured meat will help solve a multitude of problems. It will help lessen the amount of needless animal suffering. It will reduce greenhouse gas emissions by displacing a portion of the traditional meat industry, and it could help reduce food insecurityβa looming threatΒ in the face of climate change. It also has the potential to ward off antibiotic resistance, a major growing problem in livestock production. Breakthroughs in the industryβs tissue engineering research could potentially funnel back to the medical field as well.These are the possibilities that drive Datar to double down on her mission to fund more academic research. She is passionate about training students who are just as curious and talented as she was as an undergrad, and to bringing their talent into this potentially transformative industryβjust as others welcomed and encouraged her.βIt feels like a win-win-win solution,β Datar says. βSo much positivity comes from this kind of innovation. Iβm excited to be part of such a long game.β This article was produced for New Harvest byΒ Massive Science, a community of scientists telling fascinating, true stories about the science thatβs happening now.