Engineers have made a significant breakthrough in the development of a novel building material that integrates the root-like mycelium of fungi with living bacterial cells. This pioneering research, published on April 16 in the esteemed Cell Press journal, Cell Reports Physical Science, showcases a material that can be manufactured under low-temperature conditions while still utilizing living cells. This aspect contributes to the material’s remarkable ability to self-repair, presenting a promising alternative to conventional high-emission building materials like concrete.
In the words of Chelsea Heveran, the lead researcher and assistant professor at Montana State University, the strength of biomineralized materials is not yet sufficient to completely replace concrete in all construction applications. However, her team, along with other researchers in the field, is actively conducting experiments to enhance these materials so they can have wider utilizations in various building projects. The research marks a crucial step toward the advancement of sustainable construction materials that could substantially lessen the carbon footprint associated with traditional building substances.
The innovative materials developed by Heveran’s research team boast a lifespan of at least one month, a significant improvement over many existing biomaterials that can only be used for a limited period, generally spanning days or weeks. This longevity allows the embedded bacterial cells to execute numerous beneficial functions. Such capabilities include not only the self-repair of damaged materials but also the potential for these materials to assist in purifying contaminated environments. This multifaceted functionality points toward a future where building materials can not only serve foundational purposes but also contribute positively to environmental remediation.
The challenges faced in perfecting living-based building materials are well documented. As these materials begin to make their way into commercial markets, researchers are still grappling with issues stemming from the short viability of living organisms and their lack of intricate internal structures essential for various construction applications. The research conducted by Heveran’s team stands as a testament to innovation aimed at overcoming these hurdles.
Ethan Viles, the project’s first author, led the team’s exploration of using fungal mycelium as a foundational scaffold. This approach takes inspiration from previous applications of mycelium in the creation of sustainable packaging and insulation materials. The team worked particularly with the fungus species Neurospora crassa, which proved capable of forming materials with diverse and complex internal architectures. This breakthrough allows for the careful manipulation of the material’s internal structure, providing an opportunity to create various geometrical designs that could replicate the strength of natural materials.
One exciting facet of this research is the use of fungal scaffolds to guide the internal design of the new materials. Viles and Heveran noted that the internal geometries they were able to produce resemble those found in cortical bone. This revelation opens a door for future experimentation with different geometrical shapes and arrangements, which could result in even more advanced building materials tailored to specific needs within construction.
A critical aspect of this research centers on the quest to find alternatives to high carbon-footprint materials such as cement. Cement production alone accounts for a staggering 8% of all global carbon dioxide emissions resulting from human-related activities. Therefore, a successful shift to biomaterials that can serve similar functions while minimizing environmental impact could have far-reaching implications. Heveran’s team aims to continue this vital work by enhancing the survival rates of the living cells in the scaffolds. They are also exploring efficient manufacturing methods to scale up production, making these innovative materials more accessible for widespread use.
With the backing of the National Science Foundation, this research emphasizes the growing importance of interdisciplinary approaches combining biology with engineering principles. Such innovations may not only redefine how we construct our buildings but also underline the vital role that sustainable practices play in addressing the challenges posed by climate change and environmental degradation. The ability of these living materials to perform vital functions opens new horizons in the design and implementation of eco-conscious construction methods.
From a broader perspective, the fusion of living cells with engineered materials creates an exciting new frontier in material science. The ongoing research signifies how cross-disciplinary collaboration can result in breakthroughs that challenge traditional manufacturing processes. These innovations showcase a willingness to look beyond conventional materials and examine how nature itself can inform and inspire modern scientific endeavors.
In the framework of sustainable development, the creation of engineered living materials marks a pivotal moment in our approach to both resource use and environmental conservation. As researchers delve deeper into optimizing these materials, the potential to integrate further biocompatibility and self-sustaining features may soon redefine our landscapes and urban environments. The collective ambition of scientists, engineers, and environmentalists is directed toward realizing a future where our built environments coexist harmoniously with the natural world.
As this research continues to evolve, it may catalyze a transformation in industries beyond construction. The principles of utilizing naturally occurring organisms could resonate across various sectors, including packaging, textiles, and even waste management. This forward-thinking approach highlights how nature’s own processes can be harnessed and engineered to create materials that are both functional and environmentally responsible.
The findings presented in this research present a clarion call for further exploration in the use of biological materials in construction and other applications. By integrating living organisms within materials, the potential for enhancing both performance and sustainability grows exponentially. It’s a tribute to human ingenuity and collaborative efforts in science and engineering, and it embodies hope for a greener future where we can build in balance with the planet.
In conclusion, while the road ahead may be fraught with challenges, the promise of these engineered living materials serves as a powerful reminder of what’s possible when we merge technology with the resilience of nature. As the team at Montana State University continues to refine their approaches and expand the capabilities of their materials, we may be witnessing the dawn of a new era of sustainable building practices, one that could illuminate the path toward a healthier planet.
Subject of Research: Development of biomineralized materials using fungal mycelium and bacteria
Article Title: Mycelium as a scaffold for biomineralized engineered living materials
News Publication Date: 16-Apr-2025
Web References: Cell Reports Physical Science
References: DOI: 10.1016/j.xcrp.2025.102517
Image Credits: Not applicable
Keywords
Biomineralization, Fungi, Chemical engineering, Sustainable development, Biomaterials, Chemical structure, Cement, Carbon emissions
Tags: advanced material durabilitybiomineralized materials researcheco-friendly building materialsfungal mycelium in engineeringinnovative construction technologiesliving bacterial cells in constructionlow-emission construction alternativesmycelium-based constructionreducing carbon footprint in constructionself-healing building materialssustainable architecture innovationssustainable building solutions
