Living in a house made of fungi and bacteria may sound like the stuff of science fiction, but researchers are now one step closer to eventually making it a reality, according to a new study. A research team in Montana grew dense, spongy tangles of mycelium — the rootlike structure that connects fungal networks underground — as a framework to create a living, self-repairing building material. The ability to create durable, load-bearing structures with living material is still many years away. However, this discovery is an important step toward creating a sustainable alternative to cement, the binding agent in concrete, said Chelsea Heveran, senior author of the study published April 16 in the journal Cell Reports Physical Science. More than 4 billion metric tons (4.4 billion tons) of cement is manufactured annually, contributing about 8% of global carbon dioxide emissions, according to London-based think tank Chatham House. This means if cement production were a country, it would rank third after China and the United States based on 2023 emissions. “We asked ‘what if we could do it a different way using biology?’ That’s the vision,” said Heveran, who is an assistant professor of mechanical and industrial engineering at Montana State University Bozeman. The study authors introduced bacteria capable of producing calcium carbonate — the same chemical compound found in coral, eggshells and limestone — to the fungal mycelium, which served as scaffolds. Through a process called biomineralization, the calcium carbonate hardened the gooey, flexible mycelium into a stiff, bonelike structure. “We’re not the first ones to biomineralize something and call it a building material. … But if you want to keep (the bacteria) alive for longer so that you can do more with them, there’s been some challenges involved to extend that viability,” Heveran said. “So that’s why we gave them fungal mycelium scaffolds, because the mycelium is really robust, and in nature, sometimes it biomineralizes (itself).” The team experimented with letting the fungus, called Neurospora crassa, biomineralize on its own but found that killing it and then adding the microbes helped achieve a stiffer material in less time. The bacteria, called Sporosarcina pasteurii, created crystalline nets of calcium carbonate around the fungal threads after metabolizing urea, which is like food for the bacteria. While other biomineralized building materials are only considered “living” for a few days, Heveran said her team was able to keep the microbes active for at least four weeks, and eventually, that period could extend to months or even years. “We’re really excited in our next work to ask the questions ‘could we seal a crack in the material?’ Or ‘could we sense something using these bacteria?’ Like, imagine you had poor air quality in your building, and these bricks were your walls. Could they light up to (indicate) that?” Heveran said. “Before, we couldn’t do any of that because the microbes weren’t alive enough, but they’re very alive now.” There’s still mush-room for improvement Before being used for homes, fences or other construction, a lot more testing is needed to find a living building material to replace cement, said Avinash Manjula-Basavanna, a bioengineer who was not involved in the study. “These kinds of experiments are done on a small scale. … They are not necessarily a reflection of the bulk material properties,” said Manjula-Basavanna, who is senior research scientist at Northeastern University in Boston. “It’s not stiffness that people are interested in when it comes to construction materials. It is the strength, (the) load-bearing ability.” While the strength and durability of living building materials is not on par with concrete yet, Heveran said mycelium is still a promising base. Thanks to its flexibility, the sticky substance could be shaped to include vascular-like channels within beams, bricks or walls. Much like blood vessels in the human body, cells within living building materials need structures capable of delivering nutrients to stay alive. However, adding these structures into the design of building materials could make them weaker, presenting a challenge for future studies, Manjula-Basavanna said. “I think in the future, they could be useful for single-story buildings, these smaller structures — it’s very much feasible,” Manjula-Basavanna said. “It might be five to 10 years down the line.” Fungus is also a potential respiratory hazard, and though killing the mycelium reduces its allergen-producing ability, more research should be done before it’s considered safe to inhabit, Heveran said. “It’s very clear to conceptualize a test framework by which the materials need to be strong enough, because those kinds of standards exist already,” Heveran said. “But we don’t have regulatory standards for my bricks that have cells in them.” Looking ahead It’s safe to say you won’t see fungus bricks sold at your local home improvement store any time soon. Heveran’s team is just one of many in the country exploring the possibilities of mycelium, which has been used for other, softer items such as packaging and insulation. Several government agencies are already interested in the possible use cases of living building materials, Heveran said. “There’s a lot of ‘ifs’ that would have to come into play for the average household to have a cost benefit from this,” Heveran said. “But for society, it might be a lot cheaper when you’re trying to build infrastructure for a community that really needs it, or if you’re trying to build infrastructure in space, this might be a lot easier than carting cement and concrete up there,” she explained. “The possibilities are really exciting to me.”
Fungi could be used to build homes one day. Meet the researchers trying to make it possible
TruthLens AI Suggested Headline:
"Researchers Explore Mycelium and Bacteria as Sustainable Building Materials"
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TruthLens AI Summary
Researchers at Montana State University are making strides toward developing a building material derived from fungi and bacteria, a concept that may seem futuristic but is becoming increasingly feasible. The team has successfully cultivated dense, spongy structures of mycelium, the underground root-like network of fungi, which serves as a sustainable alternative to traditional cement. In their study published in the journal Cell Reports Physical Science, the researchers introduced bacteria that produce calcium carbonate, the same compound found in coral and eggshells, to the mycelium, allowing it to harden into a robust material through a process called biomineralization. This innovative approach aims to address the environmental impact of cement production, which accounts for approximately 8% of global carbon dioxide emissions. The study's lead author, Chelsea Heveran, emphasized the potential of biological materials to offer a different method of construction that could significantly reduce carbon footprints in the future.
Despite the promising developments, researchers acknowledge that there are still substantial challenges to overcome before mycelium-based materials can be used in construction. While the current experiments have demonstrated the feasibility of keeping bacteria alive within the mycelium for up to four weeks, further research is required to enhance the strength and durability of the resulting materials. Experts like Avinash Manjula-Basavanna note that the materials need to meet existing construction standards, particularly regarding load-bearing capabilities. Although mycelium shows potential, its current strength does not yet match that of concrete. Concerns over safety, particularly regarding the allergenic properties of fungi, also necessitate additional investigation. Looking ahead, the researchers envision applications for these materials in low-rise buildings and possibly in specialized environments, such as space, where transporting traditional building materials proves challenging. The ongoing exploration of mycelium as a building material opens up exciting possibilities for sustainable construction practices in the future.
TruthLens AI Analysis
The article presents a groundbreaking concept that combines biology and building materials, exploring the potential of fungi and bacteria in creating sustainable homes. This innovative approach reflects a growing trend in environmental consciousness, aiming to address significant issues related to traditional construction methods and their impact on climate change.
Purpose of the Publication
The intention behind this article appears to be highlighting advancements in sustainable construction technology while also raising awareness about the environmental ramifications of cement production. By emphasizing the potential of mycelium and biomineralization, the researchers aim to inspire interest and investment in eco-friendly building practices.
Public Perception Goals
The narrative is likely designed to foster a sense of hope and excitement about the future of sustainable living. By showcasing innovative research, the article seeks to engage a broader audience in discussions regarding climate change solutions and the role of technology in addressing these challenges.
Information Omission
While the article focuses on the potential benefits of using fungi as building materials, it does not delve deeply into the potential challenges, including scalability, cost-effectiveness, and the long-term durability of such materials. This omission may lead to an overly optimistic perception of the feasibility of these alternatives.
Manipulation Assessment
The manipulation level of this article can be considered low. It presents scientific findings in a positive light but does not engage in fearmongering or alarmist rhetoric. However, some readers might perceive the enthusiasm for fungi as a building material as potentially misleading if they expect immediate practical applications without acknowledging ongoing research hurdles.
Authenticity of the News
The information appears credible as it references research published in a peer-reviewed journal, Cell Reports Physical Science. The credentials of the researchers involved lend further validity, suggesting that the findings are based on empirical data and scientific inquiry.
Societal Implications
The potential societal impacts include increased public interest in sustainable building practices and greater investment in green technologies. As awareness grows, there may be a shift in building regulations and incentives for using environmentally friendly materials, influencing the construction industry's future.
Target Audience
The article likely appeals to environmentally conscious individuals, students, researchers, and professionals in the fields of engineering, architecture, and sustainability. It seeks to engage communities interested in innovative solutions to climate challenges.
Market Impact
This news could impact industries related to construction materials, especially those exploring sustainable options. Companies involved in eco-friendly materials may see increased interest from investors and consumers, potentially affecting their stock performance and market positioning.
Global Balance of Power
While the article primarily addresses environmental issues, it subtly connects to broader global discussions on sustainability and climate change, which are increasingly critical in international relations and policy-making. The move towards sustainable materials reflects a shift in power dynamics, where countries and companies that prioritize green technologies may gain a competitive edge.
Artificial Intelligence Involvement
It is possible that AI tools assisted in the crafting or research aspects of this article, particularly in analyzing data or generating content. AI language models might have been used to structure the article or to summarize complex scientific information for a general audience, thus enhancing accessibility.
Conclusion on Reliability
Overall, this article presents a credible and relevant exploration of innovative building materials derived from fungi. While it emphasizes the positive aspects of this research, a balanced view would also consider the existing challenges. The article serves as an intriguing glimpse into the future of sustainable construction, motivating readers toward a more environmentally conscious mindset.