Hostname: page-component-586b7cd67f-dsjbd Total loading time: 0 Render date: 2024-11-22T00:28:42.573Z Has data issue: false hasContentIssue false

Bio-futures for transplanetary habitats: a summary and key outcomes from the 2022 symposium

Published online by Cambridge University Press:  19 September 2024

A response to the following question: Bio-futures for transplanetary habitats

Layla van Ellen*
Affiliation:
Hub for Biotechnology in the Built Environment, School of Architecture and Landscape, Newcastle University, Newcastle Upon Tyne, UK
Anne-Sofie Belling
Affiliation:
Hub for Biotechnology in the Built Environment, School of Architecture and Landscape, Newcastle University, Newcastle Upon Tyne, UK
Monika Brandić Lipińska
Affiliation:
Hub for Biotechnology in the Built Environment, School of Architecture and Landscape, Newcastle University, Newcastle Upon Tyne, UK
Paula Nerlich
Affiliation:
Hub for Biotechnology in the Built Environment, School of Architecture and Landscape, Newcastle University, Newcastle Upon Tyne, UK
Harry Azzopardi
Affiliation:
ARUP Sydney, Barrack Place, Sydney, NSW, Australia
Christina Ciardullo
Affiliation:
Yale Centre for Ecosystems in Architecture, Yale School of Architecture, New Haven, CT, USA
Martyn Dade-Robertson
Affiliation:
Hub for Biotechnology in the Built Environment, School of Architecture and Landscape, Newcastle University, Newcastle Upon Tyne, UK
Amy Holt
Affiliation:
International Space University, Illkirch-Graffenstaden, France
Paul James
Affiliation:
Hub for Biotechnology in the Built Environment, Department of Applied Sciences, Northumbria University, Newcastle Upon Tyne, UK
Aled Deakin Roberts
Affiliation:
Future Biomanufacturing Research Hub, Manchester Institute of Biotechnology, The University of Manchester, Manchester, UK
Angelo Vermeulen
Affiliation:
Systems Engineering and Simulation, Faculty of Technology, Policy and Management, Delft University of Technology, Delft, the Netherlands
Meng Zhang
Affiliation:
Hub for Biotechnology in the Built Environment, Department of Applied Sciences, Northumbria University, Newcastle Upon Tyne, UK
*
Corresponding author: Layla van Ellen; E-mail: [email protected]
Rights & Permissions [Opens in a new window]

Abstract

Bio-Futures for Transplanetary Habitats (BFfTH) is a Special Interest Group within the Hub for Biotechnology in the Built Environment that aims to explore and enable interdisciplinary research on transplanetary habitats and habitats within extreme environments through an emphasis on the biosocial and biotechnological relations. BFfTH organized the online and onsite networking symposium BFfTH to examine how emerging biotechnologies, living materials, and more-than-human life can be implemented in habitat design and mission planning. The two-day symposium aimed to serve as a catalyst in establishing an international network and to support the development of novel methodologies to move beyond discipline-specific approaches. The symposium consisted of five sessions, including Mycelium for Mars and Novel Biotechnologies for Space Habitats. This opinion paper presents key outcomes and trends from these sessions, a moderated panel, and informal discussions. The identified research trends explored the use of biotechnology and biodesign to enhance safety, sustainability, habitability, reliability, crew efficiency, productivity, and comfort in extreme environments on Earth and off-world. Beyond design and engineering, the symposium also examined sociotechnical imaginaries, focusing on desired experiences and characteristics of life and technology in transplanetary futures. Some of the specific topics included innovative material-driven processes for transplanetary habitat design, socio-political and ethical implications, and technology transfer for sustainable living on Earth. The outcomes emphasize the necessity for advancing biosocial and biotechnological research from an interdisciplinary perspective in order to ethically and meaningfully enable transplanetary futures. Such a focus not only addresses future off-world challenges but also contributes to immediate ecological and architectural innovations, promoting a symbiotic relationship between space exploration and sustainability on Earth.

Type
Impact Paper
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (https://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright
© The Author(s), 2024. Published by Cambridge University Press

Introduction

The last decade has seen a rise in biotechnological and biosocial research, expanding into fields such as material science, space exploration, architecture and design. Habitats in extreme environments on Earth and on other planetary bodies face many complex challenges due to environmental aspects (such as fluctuating extreme weather events, changes in gravity, and harmful radiation), societal aspects (such as physical and physiological comfort as well as dynamic more-than-human relations) and processes aspects (such as manufacturing and building remotely and autonomously in environments with limited resources). Novel solutions are being sought out using biomaterials and biotechnologies, and by analyzing and simulating biosocial relations occurring within these habitats.

Bio-Futures for Transplanetary Habitats (BFfTH) is a Special Interest Group (SIG) that covers all of these fields and brings together researchers from a myriad of backgrounds. The first event organized by BFfTH was a two-day networking symposium in April 2022 to pioneer the discussion and collaborations of researchers under the topic of BFfTH. The participants in the symposium have a background in and across the following fields: space architecture, architectural design, building materials, building physics, biology, microbiology, synthetic biology, social sciences, biomimicry and biodesign. This opinion paper presents a summary, trends and key outcomes of this first symposium.

Special interest group

BFfTH was formed within the Hub for Biotechnology in the Built Environment (HBBE) at the universities of Newcastle and Northumbria. HBBE (2019) was formed in 2019 with the ambition “to create a new generation of ‘Living Buildings’, which are responsive to the natural environment, grown using living engineered materials, which process their own waste, reduce pollution, generate energy and support a biological environment that benefits health”. Research is conducted under four research themes i.e. Living Construction, Metabolism, Microbial Environment and Responsible Interactions (HBBE 2019).

BFfTH is a Special Interest Group that aims to explore and enable interdisciplinary research on transplanetary habitats and habitats within extreme environments through an emphasis on the biosocial and biotechnological relations. The BFfTH objectives are:

  • Enabling interdisciplinary research through projects across the four themes of the HBBE: Initiating projects within the SIG itself as well as collaboration with other research groups.

  • Organizing networking event(s) hosted by BFfTH and HBBE to drive forward research and applications together with a global community (such as the first networking symposium).

  • Establishing a diverse network of researchers, and encouraging a move toward transdisciplinary research.

The networking symposium: summary

The symposium was organized around various emerging questions with the aim to bring together research that related to the overarching theme. Research into transplanetary habitats and habitats within extreme environments is growing exponentially. In order to understand emerging extraterrestrial futures and infrastructures, there is a need for transdisciplinary research that can investigate the implications of integrating living materials and more-than-human life into astronautics. How can emerging biotechnologies be implemented in the design and mission planning to enable or support the creation of transplanetary habitats and habitats in extreme environments? What new socio-political concerns or ethical implications should be taken into account? How can sustaining life off-Earth in the future help the transition toward a sustainable built environment on-Earth in the present? The aim of this symposium was to serve as a catalyst in building an international network of collaborators across industry, academia, and the private sector. The symposium also aimed to support the development of novel methodologies to move beyond discipline-specific approaches in order to address and interrogate these emerging questions. An abstract call invited speakers on the following topics:

  • Multi-species narratives and relations to sustain human and other-than-human life in transplanetary habitats;

  • Use of biotechnology and biodesign to ensure and support safety, sustainability, habitability, reliability, crew efficiency, productivity and comfort in extreme environments off and on Earth;

  • Speculative ethics for companionship between humanity and other-than-humans within transplanetary habitats;

  • Sociotechnical considerations in propagating and sustaining life beyond Earth’s environments;

  • Innovative material-driven processes for the design of transplanetary habitats;

  • Sustainable living on Earth through a holistic system thinking approach.

In total, 24 abstracts were received, of which 14 were selected for oral presentation along with two invited keynote speakers & invited guest panelists, and five presenters from the BFfTH SIG. The presentations were divided into five topic sessions (see the appendix for the full program) following the common themes explored in the abstracts: Mycelium for Mars, Plants and Agriculture, Sustainable Habitats and Travels, Artistic Approach to Extremes Habitats, and Novel Biotechnologies for Space Habitats.

The two keynote speakers (both experts in their fields: one artist/biologist/researcher in space systems, and one architect and researcher for Ecosystems in Architecture) were also invited for a panel session at the end of the first day along with an invited guest panelist (bio futurist and multidisciplinary designer from industry). The panel session was fluid and although some questions were prepared in advance around the topic of biotechnical and biosocial advancements for transplanetary habitats, other questions and discussion topics were explored based on the presentations of the first day. The following sections gather quotes from the panel discussion as well as the main outcomes and insights from the two days of presentations and discussions which have been shared on the HBBE YouTube platform.Footnote 1

Key outcomes

At the end of the networking symposium, the organizers highlighted some trends seen in multiple presentations and discussions, crossing the original topic sessions. In total, six trends have been highlighted and this section expands on the discussion and main outcomes for each.

Biomimicry and biotechnology for space systems: from macro to micro

In space technology, engineering, and design, the concept of biomimicry – utilizing biological solutions to solve complex problems - is not a novel approach. There is ongoing research on biology-based enabling technologies for human space exploration (Rothschild Reference Rothschild2016). The V.I.N.E. group (Virtual Interchange for Nature-Inspired ExplorationFootnote 2 ) at NASA’s Glenn Research Center and the Advanced Concepts Team at the European Space Agency (ESA) (Menon et al. Reference Menon, Ayre and Ellery2006) are working on several projects using biomimicry for space applications. Some of their work explores tensegrity robots, seal whisker-inspired sensors, foldable and deployable solar panels gecko grippers and sensors based on a fly’s eye. Other examples of biomimicry in space include cyanobacteria-based life support systems (Verseux et al. Reference Verseux, Baqué, Lehto, De Vera, Rothschild and Billi2016) and the European Micro-Ecological Life Support System Alternative (MELiSSA) project (Vermeulen et al. Reference Vermeulen, Papic, Nikolic and Brazier2023). The MELISSA project is a bioregenerative ecosystem that is inspired by lake ecosystems (Walker and Granjou Reference Walker and Granjou2017).

During the symposium, many presentations included research on biomimicry particularly in the area of materials engineering. Specifically, the use of biomaterials and the concept of Engineered Living Materials (ELMs) for space applications were presented. Biomaterials as described here are grown, rather than manufactured, and examples include fungal mycelium, bacterial cellulose, plants, and animal cells. ELMs are materials inspired by nature that self-synthesize, sense, and respond to the environment and are hierarchically structured (Molinari et al. Reference Molinari, Tesoriero and Ajo-Franklin2021). ELMs contain living elements that provide the responsive function and polymeric matrices, required for scaffolding functions, and can therefore be designed as active and responsive materials (Nguyen et al. Reference Nguyen, Courchesne, Duraj-Thatte, Praveschotinunt and Joshi2018; Rodrigo-Navarro et al. Reference Rodrigo-Navarro, Sankaran, Dalby, del Campo and Salmeron-Sanchez2021).

In addition to ELMs, non-living biomaterials were also presented and discussed. For instance, biomimetic composites akin to natural seashells or pearls could be produced through the low-energy hybridization of natural biopolymers and extraterrestrial mineral deposits. These biopolymers could be generated through versatile bioreactors, where phototrophic microorganisms could be engineered to produce binders through the fixation of CO2 and N2 with sunlight. The notion of considering inhabitants as bioreactors was also discussed; here a protein from human blood (Human Serum Albumin) could be combined with urea (obtainable from urine) and regolith to produce a biological composite with compressive strengths on par with terrestrial concrete (Roberts et al. Reference Roberts, Whittall, Breitling, Takano, Blaker, Hay and Scrutton2021).

These biomaterials, and especially ELMs could potentially play a crucial role in the future of space systems due to their unique properties. These include self-replication, self-healing and self-assembly processes, without the need for high-energy or resource-intensive processing. These processes could significantly lower the costs of a mission since the desired materials and objects can be grown in situ, reducing the mass of material needed to be transported from Earth. The self-healing properties and the possibility to create on-demand materials also provide a source of reliability, flexibility and safety. The second property of note is responsiveness to the environment. As such biomaterials are able to sense changes in the environment and respond to them with minimal energy and material cost (Pawlyn Reference Pawlyn2016; van Ellen et al. Reference van Ellen, Bridgens, Burford, Crown and Heidrich2023). The third property advocating for the use of biological materials in space systems is their innate potential for multi-functionality. A variety of functions and properties can be embedded in the materials, based on the given requirements and mission needs and intrinsic weaknesses of selected materials can potentially be overcome through methods such as bioengineering and synthetic biology; techniques which could be conducted in situ to provide flexibility and reduce mission risk (Gilbert and Stephens Reference Gilbert and Stephens2018; Tang et al. Reference Tang, An, Huang, Vasikaran, Wang, Jiang, Lu and Zhong2021). Different techniques and processes were presented during the symposium including using enclosed environments and molds to grow organisms and additive manufacturing to develop bulk materials. However, notably absent from the discussions was the utilization of 3D bioprinting, an emerging technology that enables rapid assembly of tissue-engineered constructs in three dimensions (Correia Carreira et al. Reference Correia Carreira, Begum and Perriman2020). We suggest that incorporating the topic of 3D bioprinting into future symposia could enrich the discourse and enable to bridge between processing and manufacturing of bulk materials and scaffold materials with biomaterials.

The ideas discussed during the sessions on Mycelium for Mars and Novel Biotechnologies for Space Habitats of using biological materials and ELMs include growing space habitats and creating habitats as living habitation systems. For example, during one presentation it was suggested that mycelium could be embedded into the habitat structure itself and utilized as a form of biosensor in the detection of temperature, oxygen and pressure changes in the habitat. Such a solution would enable the creation of a habitat that could respond and adapt to its environment, and cohabiting astronauts (Brandić Lipińska et al. Reference Brandić Lipińska, Maurer, Cadogan, Head, Dade-Robertson, Paulino-Lima, Liu, Morrow, Senesky, Theodoridou, Rheinstädter, Zhang and Rothschild2022). Other potential research avenues discussed included the utilization of biological organisms in space for the bioproduction of essential or useful commodities, such as food, bioplastics or bespoke pharmaceuticals on demand.

The use of microorganisms through bioengineering and synthetic biology also provides the potential to create flexible bioreactors to sustain habitation and life on the Moon and Mars. For example, an iGEM student-led project from the Exeter team in 2018 explores if bioreactors containing specific microbial strains could be used in the production of oxygen from the Martian regolith, which in turn are also able to detoxify the regolith from the harmful perchlorates contained within.Footnote 3 Regolith is one of the most readily abundant in situ materials found on the Martian surface, and therefore one of the best candidates for the construction of off-world habitats (Liu et al. Reference Liu, Li, Sun, Guo, Harvey, Tang, Lu and Jia2022). Several methods have been proposed for the mechanical stabilization of regolith and include heat-fusion (sintering), cement composites (concrete), synthetic polymer binders, sulfur binders and fusion with ice (Naser Reference Naser2019; Naser and Chen Reference Naser and Chen2021). However, these solutions have several drawbacks, such as high energy or water use, or the need for the mining, purification and processing of specific mineral deposits – which would constrain habitat locality and add to launch mass and mission cost. By utilizing living organisms for planetary construction, it could however be possible to create regolith biocomponents, where the bound material would grow in situ. Examples include proteins and carbohydrates for the creation of regolith biocomposites (Roberts et al. Reference Roberts, Whittall, Breitling, Takano, Blaker, Hay and Scrutton2021; Roedel et al. Reference Roedel, Lepech and Loftus2014), or the use of mycelium for consolidation of the regolith into structural components. Presentations also suggested humans themselves be considered as in situ resources, as they too are able to produce, a variety of organic compounds, including urea, and Serum Albumin, both of which could be used as binders for regolith (Roberts et al. Reference Roberts, Whittall, Breitling, Takano, Blaker, Hay and Scrutton2021).

Mycelium-based materials

The use of mycelium – the vegetative, root structure of fungi – was primarily discussed during the Mycelium for Mars session. However, it was not limited to that session only, in fact, concepts or projects using mycelium for a variety of purposes in space exploration were repeated throughout the whole symposium. The Mycelium on Mars session was also not restricted to the Martian environment; it covered the wider context of using mycelium-based material for space exploration, at different feasibility levels and over varying time scales.

Mycelium is one of the emerging biomaterials that has a variety of beneficial, current, and prospective properties. It can even be bioengineered to provide additional properties and functions. Commercial applications (fashion, packaging material, acoustic panels, decorative furniture, or insulative material) are starting to gain traction on the market with the existing fabrication methods constantly being improved upon through ongoing research. Some examples were shown of mycelium products already at high technology readiness level (TRL). Companies like Ecovative, Bolt Threads, or Biohm lead the fungi food and biomaterials revolution with mycelium-based materials. Ecovative has licensed their Mushroom@Packaging technology in the US and around the world in the last few years, and more recently Stella McCartney partnered with Bolt Threads on a limited run of 100 mycelium-crafted bags that sell for up to $2950 (Biohm, n.d.; Bolt Threads, n.d.; Ecovative 2022). Because of the favorable properties and characteristics it exhibits (see the next section for detailed overview of these properties), there is extensive, ongoing research on integrating mycelium into the built environment (Elsacker et al. Reference Elsacker, Peeters and De Laet2022a, Reference Elsacker, Van Rompaey, Peeters and De Laet2022b). Consequently, it has also been proposed as a material for applications in space habitats, adding to the pallet of space-architectural solutions.

Mycelium-based materials and the idea of growing structures in situ are being considered both as a new construction approach for building space habitats and as an alternative for creating furnishings and interior elements inside the habitat, in a controlled environment.

The main properties in favor of using mycelium-based materials are its insulative, acoustic, and fire resistance properties, the ability for waste-degradation and self-healing and self-replicating potential. The use of mycelium also contributes to the efficiency of material transportation. In terms of utilizing mycelium for outer space architectures, with the possibility to grow materials in situ, there is no need to launch quantities of construction materials, decreasing the mass of the payload. Instead, what needs to be brought from Earth are spores and some nutrients, enabling the formation of components in situ.

In addition to the building efficiency, another potential advantage of utilizing mycelium for outer space architecture and living systems could address human psychological factors of sustained space travel, for example enabling astronauts to outfit their environments with mycelial components. We envisage that the different textures of various mycelium-based materials have a great level of tactility. Indeed, some studies suggest that tactility may be beneficial for the psychological comfort of astronauts (Schlacht Reference Schlacht2012).

Additionally, certain mycelium species are also edible, could have medical applications (within the development of cancer therapeutics) (Patel and Goyal Reference Patel and Goyal2012), and could also provide radiation protection (melanin-rich fungi) (Mattoon et al. Reference Mattoon, Cordero and Casadevall2021). Other species are bioluminescent and can sense temperature, pressure and other chemical and physical differences (Adamatzky et al. Reference Adamatzky, Gandia and Chiolerio2021). There are myriad possibilities for the application of mycelium-based materials in architecture and space habitats. Therefore, many visions and scenarios are being researched spanning a large feasibility scale on how fungal-based materials can benefit human habitation in space: from arrival, to resources and infrastructures, to environmental adaptation and communication. Scenario methods are discussed in more detail in Speculative approaches and scenarios section.

The Mycelium for Mars session not only discussed the opportunities and potentialities of using mycelium but also the trade-offs and challenges that would be necessary to overcome in order to develop the vision into prototypes and architectural materials and components. During the talks, it was explained that the material functionality is dictated by the fabrication process. Growing mycelium is a resource-intensive process. It needs life-supporting conditions: the presence of oxygen, stable temperature, H2O, a humid environment and nutrients (usually plant husks or cellulose-based structures). Additionally, a lot of heat is required to bake the mycelium, to prevent further, uncontrolled development and creation of fruiting bodies. Therefore, there is a trade-off in terms of the amount of equipment and resources required for processes that provide the strength and functionality of materials.

Understanding the system metabolism is critical for the development of efficiently functioning space habitats and living habitation systems. It includes mapping of the specific waste streams: gas and water quantities required for synthesis as well as the end-of-life scenario in terms of how used mycelial elements could be broken down into new components. To be able to efficiently use mycelium for space applications, we need to maximize resource efficiency within the system’s metabolism. One of the proposed solutions was the integration of waste streams into the growth process (Brandić Lipińska et al. Reference Brandić Lipińska, Maurer, Cadogan, Head, Dade-Robertson, Paulino-Lima, Liu, Morrow, Senesky, Theodoridou, Rheinstädter, Zhang and Rothschild2022) such as recycling of water from the drying process.

In addition, adapting an ecosystem-based approach (material ecology), is to use the most abundant resource on the Moon or Mars – regolith. Despite the fact that mycelium-based composites have a great advantage in growing into bulk materials in a short period of time, to achieve the scale for human habitat, extra aggregates could significantly reduce the nutrient and time requirements. Although mycelium cannot grow solely on regolith, the regolith could provide a structural mass, and with minimum quantities of nutrients, mycelium can act as a binder, holding the regolith-based structure together (Brandić Lipińska et al. Reference Brandić Lipińska, Maurer, Cadogan, Head, Dade-Robertson, Paulino-Lima, Liu, Morrow, Senesky, Theodoridou, Rheinstädter, Zhang and Rothschild2022).

There is still a substantial gap between commercially ready products and current fabrication methods of mycelial products and those that are required or desired for space-architectural applications. A stepping stone is needed between our current capabilities and the future mycelium-based space habitats, that are more achievable in the coming decade. The discussion around this topic led to questions about near-term mycelium applications for space. Some research questions are:

  • Which additional applications can we research to enable us to test and validate the utility of mycelium in actual off-world conditions?

  • How can we grow (mycelium) using minimal biomass and/or water and oxygen?

  • How can we ensure the long-term robustness of the materials in extreme conditions?

  • What are the construction methods that would enable minimal interventions in the habitat construction and maintenance process?

  • Is it possible to create real self-replicating and self-healing habitats?

Relations with the natural in space

A more permanent human presence in deep space, invites crucial discussions around the role of nature in sustaining human life, as well as the impact on well-being of humans on future deep space journeys, and the creation of livable habitats on other planets that support human and nonhuman life in the long term (Imhof et al. Reference Imhof, Weiss, Vermeulen, Flynn, Hyams, Kerrigan, Rengifo, Mohanty and Armstrong2017). Human relations to the Natural are not only reflected upon within the Anthropocene, but further in relation to the nonhuman world. The nonhuman world is comprised of other-than-human living organisms (animals, microorganisms, fungi, etc.), the non-living and the various ecosystems present both on and off-world.

Diverse art, design, and science projects presented at the symposium showed the relevance of the biosocial perspectives with interdisciplinary and transdisciplinary projects that studied perspective shifts from human-centric to polycentric. Polycentric being the inclusion of humankind’s interconnectedness with the Natural, remediation of nature in the Anthropocene and in extreme environments, life-like reproducing AI systems able to create human habitats, and human-AI interdependence in future scenarios.

Humankind’s relation to nature on and off Earth has been shown to be highly influenced by human-centric perspectives (Fremaux Reference Fremaux2019). Past research into the creation of off-world human-made habitats included the design of controlled biospheres that are highly selective in choice of species and ecosystems, excluding what is considered undesirable and non-serving to humans (Tsiolkovsky Reference Tsiolkovsky and Groys2019). This thinking has been continued into the more recent MELiSSA and Lunar Base 1 projects (Walker and Granjou Reference Walker and Granjou2017). During the symposium, participants were speculating on ‘What is nature in space?’.

When humans bring living systems into otherwise controlled environments these systems have an ambiguous nature as they could either represent “nature” or the human control of it (Bringslimark et al. Reference Bringslimark, Hartig and Patil2009). What might be considered “nature” depends on the extent to which the living systems are allowed to evolve and adapt to new environments, and to what extent we adapt and control the environment itself. Therefore, questions about human relations emerged throughout the symposium during talks and discussions, some of which will lead to future research. For example, is it a human-created and/or controlled nature? Is it designed as an evolving system that develops in relation to factors such as human behavior, environmental resource availability and environmental changes? Can these evolving systems begin to create their own nature?

Research and artistic projects questioned the past perspective of a controllable nature and invited to be inspired by the human-caused Anthropocene to take new pathways toward complexity and inclusive futures of human existence also in space. Diverse artistic projects are exploring the remediation of Anthropocene environments by codesigning with living organisms. For example, mycoremediation has been shown to successfully detoxify soil through fungal metabolism (Assad et al. Reference Assad, Rafiq, Bashir, Sofi, Reshi and Rashid2021). Following that natural process, fungal-based burial suits were presented as a potential study for the use of human bodily wastes as part of a circular system that could be utilized within more extreme environments (Nai and Meyer Reference Nai and Meyer2016).

Presentations and discussions at the symposium highlighted explorations into codesigning and interfacing to drive polycentric perspectives. They showed that the nonhuman world can inform, inspire, and drive research into travel and habitation in space toward healthy systems that coexist in a sustaining and evolving modality.

Specific projects addressed these relations through collaborations such as the Human-Bacteria Interfaces which were presented during the symposium. This project, also presented in Albrecht et al. (Reference Albrecht, Boelen, Pelluchon and Weibel2023), was specifically looking at microbe-human relations and the potential for one to interface with the other, potentially leading toward mutualistic symbiotic modes of being. It aimed to de-center human agents and allow for a disassembly of established narratives of bacteria and microbes as inherently bad or harmful in their existence of highly complex, de-centered ecosystems. Ideation and prototype development were led by assessment of the ways in which microbial organisms sensorily and habitually engage with their surroundings, making potential nonhuman narratives part of the design and knowledge process. The designed interface used bacterial cellulose as a living medium to facilitate human-microbial interaction. In a modular structural system made from bacterial cellulose, textiles and glass, the interface allows for mutualistic cocreation of experimental architectural structures. The structure cohosts humans and bacterial cellulose in an ever evolving, growing manner that is activated through signaling and supply of nutrients and shelter.

Vermeulen presented that growing and evolving habitats, especially in the context of spaceships, offer the potential of using so-called emergence engineering, a form of bio-inspired engineering that translates the behavior and systems of living organisms into an evolving form (Gorochowski et al. Reference Gorochowski, Hauert, Kreft, Marucci, Stillman, Tang, Bandiera, Bartoli, Dixon, Fedorec, Fellermann, Fletcher, Foster, Giuggioli, Matyjaszkiewicz, McCormick, Montes Olivas, Naylor, Rubio Denniss and Ward2020). Self-replicating spaceship modules that are programed with rules of termite architecture in relation to human spaceship population numbers were presented as example (Imhof et al. Reference Imhof, Weiss, Vermeulen, Flynn, Hyams, Kerrigan, Rengifo, Mohanty and Armstrong2017). In a system using de-centralized swarm robotics, the modular spaceship system can source material to replicate from its environment to build an exponentially growing spaceship architecture that allows for replacement of the modules and metamorphic evolution of the overall system through a combination of growth, repair, replication and evolution. In scenarios that envision such self-replicating architectures for human habitats, a factor that needs to be considered is balancing human occupancy in relation to the dynamic habitat structure. The life-like property of self-replicating spaceships and the relation to human reproduction invites the study of a nonhuman perspective of future habitat creation and codependency.

These projects challenge design and technology interventions that aim to facilitate a world of self-sufficiency for humans from the more-than-human world; and emphasize our interdependence and interconnectedness within a complex system of nature. The projects aim to move beyond the human-centric idea of nature as an object to be controlled, tamed or mainly evaluated or included based on its value to us. The ever-evolving human relation to the natural on Earth and in space will continue to be challenged by sociocultural perceptions and ever-evolving technological possibilities. However, the presented projects drive futures that move beyond the narratives of what nature should be, based on human-centric ideas and the control of the nonhuman as humanity moves closer to establishing a permanent presence off-world (Mads Bering Christiansen et al. Reference Christiansen, Beloff, Jørgensen and Emilie Belling2020).

Systems thinking

Throughout the whole symposium, emphasis was placed on the need for interdisciplinary and transdisciplinary methods to develop bio-futures. The guest panelists also emphasized the need to work together with industrial partners and policymakers, going beyond purely academic thinking. Even though, as one panelist pointed out “people are naturally territorial about the stuff they know and the stuff they do”. However, working together is about unlocking the collective intelligence of the group (Vermeulen et al. Reference Vermeulen, Nevejan, Brazier and Boelen2018). This process will require facilitation, however, and needs to be economically viable, which is not always the case in academia.

Working across fields is difficult to achieve (Verkerke et al. Reference Verkerke, van der Houwen, Broekhuis, Bursa, Catapano, McCullagh, Mottaghy, Niederer, Reilly, Rogalewicz, Segers and Verdonschot2013) but one way to enable this transdisciplinarity is to utilize systems thinking. Systems thinking can be defined as “a practice of seeing wholes and a framework for seeing interrelationships rather than things, for seeing patterns of change rather than static snapshots” (Senge Reference Senge1994). There are different ways to approach this (and different scales) but there was an overall consensus of viewing transplanetary habitats as large dynamic systems, that encompass all subsystems within, such as the structural system, ECLSS (Environmental Control and Life Support Systems), power, logistic supply, communication, and data handling. Creating dynamic transplanetary habitats is crucial in highly unpredictable environments (Vermeulen et al. Reference Vermeulen, Goldoust, Sirenko, Hallak, Lutkewitte, Husárová, Long and Brazier2019). It increases the overall adaptability and resilience of the habitats over time. Such an approach includes conceiving the ECLSS as a bioregenerative system with dynamic and potentially evolvable properties.

During the panel session, an important distinction was mentioned: optimizing a system vs. satisficing a system (the latter being a combination of the words satisfy and suffice). Following in the tradition of the scientific method, in which we investigate variables in isolation, often subsystems are designed for optimization of a single parameter under pre-defined conditions, but at some point, we will have to satisfy a whole environment (Mankiewicz et al. Reference Mankiewicz, Hénaff and Dyson2021) in which performance variables interact with and are interdependent on each other (Levin and Emmerich Reference Levin and Emmerich2013). This means preferring a system that isn’t optimized for any one function but that has multiple pathways to solve problems at the same time, much like cell metabolism. Such redundance increases the resilience and longevity of a system.

Another important notion is that of systems integration – the consolidation of numerous distinct systems into one to simplify processes and reduce complexity. Systems integrations were presented holistically but also starting from a specific case or challenge such as using byproducts of chemical reactions. For example, fuel cells that convert hydrogen and oxygen (available as rocket propellant), into electrical power with the by-product being pure water available for drinking – is far more efficient than separate propellant, energy storage (e.g., batteries), and water storage systems. Having heavily integrated systems also reduces the need for backup systems and spare parts for redundancy, since a failure of one system could be mitigated by others. Biological systems could integrate numerous systems and provide many benefits that would reduce mission complexity, launch mass, cost, and overall risk. For instance, a versatile algae photo-bioreactor system could not only produce food and oxygen highly efficiently (negating the need for a separate oxygen production system and associated back-ups), but the organisms could also be engineered to produce bioplastics, bioadhesives, or other useful chemicals or pharmaceuticals as required. Instead of needing to take every medicine that may be needed on a mission (with resupply for long-duration missions as medicinal efficacy degrades over time), bioreactors could produce pharmaceuticals as required - in addition to their other useful functions.

Speculative approaches and scenarios

Many approaches to the presented research were speculative, and science fiction was often quoted as inspiration to imagine possible futures in space. The methods – originating from the design approach – to develop these visions and turn them into concepts (and eventually high TRL applications) are (Hyry Reference Hyry2021):

  • Scenario building and speculative design.

  • Material experimenting and rapid prototyping.

  • Observing results on the small scale before going to larger scale to avoid failing in the very early stages of the process.

  • Bottom-up approaches.

  • Computer simulation.

These speculations were sometimes more defined using scenario theory and the Futures Cone. The Futures Cone is able to define and detangle futures from each other by categorizing them into futures that are: preposterous, possible, plausible, the “projected” future, probable and finally preferable future (Voros Reference Voros2017). Speculative design critically examines the future and not only prepares for preferable futures but also the undesirable, unexpected and unbelievable futures (Voros Reference Voros2017). It is a way to open up the thinking process and suggest another way of looking at the future from various perspectives and to raise questions about them.

With the help of future scenarios, the desired future can be built with existing tools and materials. Future scenarios also prepare humans to confront the obstacles they may experience on their way to space and observe the critical turning points.

One way to develop those scenario’s is to experiment with materials and learn from those experimentations as one presenter highlighted. It was explained that material experimentation is a way to deepen the understanding of the material behavior and understand the properties which leads to exploring all the possible usages and create more in-depth future scenarios. The hands-on material exploration process is more about learning through the failures that happen during the development process as the material does not react as planned.

These scenarios were developed and presented by architects and designers showing through drawings and collages the possible future scenarios for life in space. Some presenters also tried to simulate how these futures will evolve with computer models. For example, there were talks about simulating the development and evolution of a spaceship during decades of deep space travel, but also simulations of social species interactions such as ants, bees, and termite colonies.

Considerations – biosafety and bioethics of space exploration

Space exploration, and especially human spaceflight, has always raised questions about its ethics (Chon-Torres Reference Chon-Torres2017). Do we, as a species, need to venture beyond Earth’s atmosphere? Do we have the right to settle on other planetary surfaces? And if we bring along living organisms, how do we deal with the lack of consent? Furthermore, there is the additional concern of biosafety, as organisms may manifest and evolve novel traits in space, potentially introducing unforeseen biological hazards to both human and nonhuman life forms. Synthetic biology is often touted as a solution to adapt organisms to the unique conditions of outer space, but even here on Earth there is no consensus yet on how to release such organisms in the environment.

It’s clear that in parallel with developing bio-inspired technologies, we need to equally develop a robust bioethical framework. Researchers in the emerging field of astrobioethics argue that a critical aspect of exploration is to reflect on our past and explore consciously, going beyond biological safety to include moral reflection (Chon-Torres Reference Chon-Torres2017). Some of these issues were brought up during the symposium. Ciardullo, for example, talked about whether ecosystems should only be used in service of the human species, or whether they deserve their own agency. Ciardullo highlighted that our current building industry is focused on controlling the environment which is in stark contrast to the multitudes of interactions resulting from various organisms within ecosystems. Hence, are we ready to let go of control over other life and what would that look like? The reasons to incorporate nonhuman life into space exploration can vary from the need to develop closed-loop systems to biophilia, and it is critical to be diligent in measuring and communicating these reasons alongside designing solutions for space habitats.

Planetary protection was another topic that was discussed. Considerable effort has been dedicated to addressing planetary protection concerns within the inner Solar System exploration endeavors. Specifically, for missions targeting Mars, comprehensive internationally recognized guidelines have been established (Rettberg et al. Reference Rettberg, Antunes, Brucato, Cabezas, Collins, Haddaji, Kminek, Leuko, McKenna-Lawlor, Moissl-Eichinger, Fellous, Olsson-Francis, Pearce, Rabbow, Royle, Saunders, Sephton, Spry, Walter and Treuet2019). In order to avoid interplanetary contamination, all biological materials used for space applications would need to comply with planetary protection requirements for robotic or human missions and also with the current Committee on Space Research human mission principles and guidelines (Kminek and Conley Reference Kminek and Conley2017). In some cases (e.g. the Moon), requirements ask only for a short planetary protection plan to outline intended or potential impact targets. In other cases (e.g. Mars), detailed documentation is required including a probability of contamination analysis, a bioassay to enumerate the bioburden, and an inventory of the bulk constituent organics etc. (Kminek and Conley Reference Kminek and Conley2017). On the other hand, the issue of safety and contamination also works in reverse (backward and forward contamination). We also need to make sure that Earth is not getting contaminated by potential lifeforms from space.

Discussion

This section reflects on the talks, panel discussions and informal discussions over the two days of the symposium. The panel discussion started with a debate concerning the increased use of biomaterials in architecture, and whether this might be emerging more from a biophilic or biomimicry design standpoint. It was mentioned that in the 60’s we were embracing synthetic materials but now we have a more sensitive approach to materials (especially considering environmental safety and personal health). However, researchers are also now aware that nature has already developed a variety of solutions to complex design problems that have evolved over time through natural selection. Studying and taking inspiration from such problem-solving abilities is now well known as the biomimicry approach to design (Gamage and Hyde Reference Gamage and Hyde2012; Pawlyn Reference Pawlyn2016). All panelists agreed that the biological approach should come from a technical perspective of efficiency and redundancy and as such use frameworks (such as systems thinking and mapping described in Systems thinking section).

Moreover, if we connect the biomimicry approach to computational methods, we can start recreating and simulating natural systems and ecosystems. Some important aspects are the balance between carbon sources, sugars, and other nutrients within a system, which are being explored by many researchers at the moment and were evident across a range of presentations. However, it should also be noted that the complexity and chaotic nature of living systems cannot simply be replaced by computational systems such as Digital Twins.

To drive the field forward, the challenges that need to be overcome are biodiversity and individual health, scale-up, but also our relations with the Natural. How can we ensure these aspects (biodiversity and individual health) are maintained during deep space missions? How do we allow other things to live in symbiosis with us? Do we need to control more-than-human relations? How do we scale up whole ecosystems?

One panelist emphasized that monitoring and data gathering are vital, but creating a separate environment hosting different, less controlled systems, might be how we can “engineer” more resilient biological systems in space and on Earth. Both the MELISSA project and Biosphere II were mentioned as both being at the more extreme ends of the spectrum, and that meeting somewhere in the middle will be our next challenge.

The discussion finished with a question from the audience on building more in symbiosis with biology versus moving into a more virtual world. The discussion highlighted that it is not so dichotomous, as even in a virtual world, the devices used to interact with the virtual are indeed still very physical. It was added that moving to a virtual world or platform is also still very social as people connect with each other and with biological elements such as food. For example, food is flooding our social media platforms, creating stronger relations between biological elements and digital worlds. This raised the question that maybe virtual platforms could also be a tool to communicate with organisms and plants. This notion has been researched by Sue Thomas (Reference Thomas2013) which she called technobiophilia, where we put the essence of nature into our technology. However, another panelist argued that proper communication between humans and more-than-humans has not yet been achieved and also might not be what we want to achieve. It was suggested that aiming to design and activate interactions as the first stage of exchange toward communication is the next challenge to tackle. Thus, while communication might not be the goal, based on the discussions on relations with the Natural and systems, respect for biological elements might be a more appropriate approach.

Good quality communication across disciplinary boundaries also requires a common set of standards and methodologies, therefore a tool for gathering interdisciplinary research interests and outputs was suggested by Holt and van Ellen in the form of a database of biomaterials and their properties (van Ellen et al. Reference van Ellen, Bridgens, Burford, Crown and Heidrich2023). Such a database would help facilitate the appropriate identification of materials for a given task and allow iteration between smaller-scale scientific projects and larger-scale architectural applications.

Conclusions

To conclude, the networking symposium gathered researchers and professionals together from many different disciplines and backgrounds. Even though the field of biosocial and biotechnical futures for transplanetary habitats is highly transdisciplinary, many talks highlighted the same challenges to overcome, and similar uses of biological research to address those challenges. There was a consensus on facilitating humanity moving into space together with ecology.

To develop BFfTH, transdisciplinary research is, therefore, crucial. The fields of material science, biology, microbiology, architecture, aerospace engineering, and systems design should be encouraged to work together across academia and industry in order to maximize the exchange of ideas but also include social scientists to challenge our relations with more-than-humans and embed astrobioethics into research. A material database is one of the concrete future works that could enable this transdisciplinarity, but also events such as the BFfTH symposium to enable conversations around the topic. Further, the growth of multidisciplinary international networks such as BFfTH enables and elevates opportunities to find collaborators, support project developments and access specialized expert knowledge. The symposium was a great success as the BFfTH SIG grew with new members being enthusiastic about the topic and new project ideas being developed across fields.

Data availability statement

Data availability is not applicable to this article as no new data were created or analyzed in this study.

Acknowledgments

This research is supported by BFfTH. BFfTH would like to thank all the speakers (see appendix for full list), panelists, and participants of the symposium for their contributions and in particular Niina Hyry and Richard James MacCowan for their help in developing the first manuscript.

Author contributions

LvE, A-SB, MBL and PN organized the BFfTH symposium. LvE and MBL gathered main trends and themes from the symposium. LvE, A-SB, MBL, PN, HA, CC, MD-R, AH, PJ, ADR and AV contributed to the symposium with a talk. LvE took the lead on writing and together with A-SB, MBL and PN wrote the original draft. LvE, A-SB, MBL, PN, HA, CC, AH, PJ, ADR, MD-R, AV and MZ reviewed and edited the manuscript.

Financial support

This research is funded by Research England’s Expanding Excellence in England (E3) Fund and Northern Bridge Consortium as part of Arts and Humanities Research Council.

Competing interests

The authors declare no known conflict of interest.

Ethics statement

Ethical approval and consent are not relevant to this article type.

Footnotes

2 The V.I.N.E. webpage shows an overview of these projects and the researchers involved: https://www1.grc.nasa.gov/research-and-engineering/vine/external-resources

3 The project page is available here: https://2018.igem.org/Team:Exeter

References

Connections references

Belling, A, Brandić Lipińska, M, van Ellen, L, Nerlich, P, Rothschild, L, and Maurer, C (2023). Bio-futures for transplanetary habitats. Research Directions: Biotechnology Design, 1, E8. doi: https://doi.org/10.1017/btd.2023.2 Google Scholar

References

Adamatzky, A, Gandia, A and Chiolerio, A (2021) Towards fungal sensing skin. Fungal Biology and Biotechnology 8(1). https://doi.org/10.1186/s40694-021-00113-8 Google ScholarPubMed
Albrecht, KBB, Boelen, J, Pelluchon, C and Weibel, P (2023) Driving the Human: Seven Prototypes for Eco-Social Renewal (1st ed.). Mousse Publishing.Google Scholar
Assad, R, Rafiq, I, Bashir, I, Sofi, IA, Reshi, ZA and Rashid, I (2021) Mycoremediation of pollutants in aquatic environs. Freshwater Pollution and Aquatic Ecosystems (Issue December). https://doi.org/10.1201/9781003130116-10 CrossRefGoogle Scholar
Biohm. (n.d.) Biohm. https://www.biohm.co.uk/ (accessed 1 September 2022)Google Scholar
Bolt Threads. (n.d.) Bolt Threads. https://boltthreads.com/ (accessed 1 September 2022)Google Scholar
Brandić Lipińska, M, Maurer, C, Cadogan, D, Head, J, Dade-Robertson, M, Paulino-Lima, IG, Liu, C, Morrow, R, Senesky, DG, Theodoridou, M, Rheinstädter, MC, Zhang, M and Rothschild, LJ (2022) Biological growth as an alternative approach to on and off-Earth construction. Frontiers in Built Environment 8(September), 117. https://doi.org/10.3389/fbuil.2022.965145 Google Scholar
Bringslimark, T, Hartig, T and Patil, GG (2009) The psychological benefits of indoor plants: a critical review of the experimental literature. Journal of Environmental Psychology 29(4), 422433. https://doi.org/10.1016/j.jenvp.2009.05.001 Google Scholar
Chon-Torres, OA (2017) Astrobioethics. International Journal of Astrobiology 17(1), 5156. https://doi.org/10.1017/S1473550417000064 Google Scholar
Correia Carreira, S, Begum, R and Perriman, AW (2020) 3D bioprinting: The emergence of programmable biodesign. Advanced Healthcare Materials 9(15), 114. https://doi.org/10.1002/adhm.201900554 CrossRefGoogle ScholarPubMed
Ecovative. (2022) Made from Mycelium. Available at https://www.ecovative.com/ (accessed 17 June 2023)Google Scholar
Elsacker, E, Peeters, E and De Laet, L (2022a) Large-scale robotic extrusion-based additive manufacturing with living mycelium materials. Sustainable Futures 4(May), 100085. https://doi.org/10.1016/j.sftr.2022.100085 CrossRefGoogle Scholar
Elsacker, E, Van Rompaey, L, Peeters, E and De Laet, L (2022b) Fungal bioremediation of plastic waste into building materials. Proceedings of the Fifth International Conference on Structures and Architecture.CrossRefGoogle Scholar
Fremaux, A (2019) For a Post-Anthropocentric Socio-Nature Relationship in the Anthropocene. In After the Anthropocene. Cham: Palgrave Macmillan, pp. 119163 https://doi.org/10.1007/978-3-030-11120-5_4 CrossRefGoogle Scholar
Gamage, A and Hyde, R (2012) A model based on Biomimicry to enhance ecologically sustainable design. Architectural Science Review 55(3), 224235. https://doi.org/10.1080/00038628.2012.709406 CrossRefGoogle Scholar
Gilbert, JA and Stephens, B (2018) Microbiology of the built environment. Nature Reviews Microbiology 16(11), 661670. https://doi.org/10.1038/s41579-018-0065-5 CrossRefGoogle ScholarPubMed
Gorochowski, TE, Hauert, S, Kreft, JU, Marucci, L, Stillman, NR, Tang, TYD, Bandiera, L, Bartoli, V, Dixon, DOR, Fedorec, AJH, Fellermann, H, Fletcher, AG, Foster, T, Giuggioli, L, Matyjaszkiewicz, A, McCormick, S, Montes Olivas, S, Naylor, J, Rubio Denniss, A and Ward, D (2020) Toward engineering biosystems with emergent collective functions. Frontiers in Bioengineering and Biotechnology 8(June), 19. https://doi.org/10.3389/fbioe.2020.00705 CrossRefGoogle ScholarPubMed
HBBE. (2019) World first research hub to create Living Buildings. Available at http://bbe.ac.uk/index.php/press/ (accessed 10 September 2022)Google Scholar
Hyry, N (2021) Life on Mars? Speculative approach on a material exploration in the context of a Mars habitation. Aalto University.Google Scholar
Imhof, B, Weiss, P, Vermeulen, A, Flynn, E, Hyams, R, Kerrigan, C, Rengifo, M and Mohanty, S (2017) Space Architectures. In Armstrong, R. (ed.), Star Ark. Springer Nature, pp. 287340. https://doi.org/10.1007/978-3-319-31042-8 CrossRefGoogle Scholar
Kminek, G and Conley, C (2017) COSPAR’s planetary protection policy. Space Research Today 200(Figure 1), 1225. https://doi.org/10.1016/j.srt.2017.11.010 Google Scholar
Levin, H and Emmerich, S (2013) Dissecting interaction among indoor environmental quality factors. ASHRAE Journal, 55(9), 6672.Google Scholar
Liu, J, Li, H, Sun, L, Guo, Z, Harvey, J, Tang, Q, Lu, H and Jia, M (2022) In-situ resources for infrastructure construction on Mars: a review. International Journal of Transportation Science and Technology, 11(1), 116. https://doi.org/10.1016/j.ijtst.2021.02.001 Google Scholar
Christiansen, MB, Beloff, L, Jørgensen, J and Emilie Belling, A-S (2020) Soft robotics and posthuman entities. Journal for Artistic Research, 22. https://doi.org/10.22501/jar.549014 Google Scholar
Mankiewicz, P, Hénaff, E and Dyson, A (2021) Indoor Environmental Parameters: Considering Measures of Microbial Ecology in the Characterization of Indoor Air Quality. ASHRAE, IAQ2020 Indoor Environmental Quality Performance Approaches. Google Scholar
Mattoon, ER, Cordero, RJB and Casadevall, A (2021) Fungal melanins and applications in healthcare, bioremediation and industry. Journal of Fungi, 7(6). https://doi.org/10.3390/jof7060488 CrossRefGoogle Scholar
Menon, C, Ayre, M and Ellery, A (2006) Biomimetics – A new approach for space system design Biomimetics – A new approach for space system design Biomimetics Technology Tree. ESA Bulletin, 125.Google Scholar
Molinari, S, Tesoriero, RF and Ajo-Franklin, CM (2021) Bottom-up approaches to engineered living materials: challenges and future directions. Matter 4(10), 30953120. https://doi.org/10.1016/j.matt.2021.08.001 CrossRefGoogle Scholar
Nai, C and Meyer, V (2016) The beauty and the morbid: Fungi as source of inspiration in contemporary art. Fungal Biology and Biotechnology, 3(1), 15. https://doi.org/10.1186/s40694-016-0028-4 Google ScholarPubMed
Naser, MZ (2019) Extraterrestrial construction materials. Progress in Materials Science, 105(June), 100577. https://doi.org/10.1016/j.pmatsci.2019.100577 Google Scholar
Naser, MZ and Chen, Q (2021) Extraterrestrial Construction in Lunar and Martian Environments. 17th Biennial International Conference on Engineering. https://doi.org/10.1061/9780784483374.111 CrossRefGoogle Scholar
Nguyen, PQ, Courchesne, NMD, Duraj-Thatte, A, Praveschotinunt, P and Joshi, NS (2018) Engineered living materials: prospects and challenges for using biological systems to direct the assembly of smart materials. Advanced Materials 30(19), 134. https://doi.org/10.1002/adma.201704847 Google ScholarPubMed
Patel, S and Goyal, A (2012) Recent developments in mushrooms as anti-cancer therapeutics: a review. 3. Biotech, 1. https://doi.org/10.1007/s13205-011-0036-2 Google Scholar
Pawlyn, M (2016) Biomimicry in Architecture. Riba Publishing.Google Scholar
Rettberg, P, Antunes, A, Brucato, J, Cabezas, P, Collins, G, Haddaji, A, Kminek, G, Leuko, S, McKenna-Lawlor, S, Moissl-Eichinger, C, Fellous, JL, Olsson-Francis, K, Pearce, D, Rabbow, E, Royle, S, Saunders, M, Sephton, M, Spry, A, Walter, NTreuet, JC (2019) Biological contamination prevention for outer solar system moons of astrobiological interest: what do we need to know? Astrobiology 19(8), 951974. https://doi.org/10.1089/ast.2018.1996 CrossRefGoogle ScholarPubMed
Roberts, AD, Whittall, DR, Breitling, R, Takano, E, Blaker, JJ, Hay, S and Scrutton, NS (2021) Blood, sweat, and tears: extraterrestrial regolith biocomposites with in vivo binders. Materials Today Bio 12(September). https://doi.org/10.1016/j.mtbio.2021.100136 CrossRefGoogle ScholarPubMed
Rodrigo-Navarro, A, Sankaran, S, Dalby, MJ, del Campo, A and Salmeron-Sanchez, M (2021) Engineered living biomaterials. Nature Reviews Materials 6(12), 11751190. https://doi.org/10.1038/s41578-021-00350-8 Google Scholar
Roedel, H, Lepech, MD and Loftus, DJ (2014) Protein-Regolith composites for space construction. Earth and Space 2014: Engineering for Extreme Environments - Proceedings of the 14th Biennial International Conference on Engineering, Science, Construction, and Operations in Challenging Environments, 291300. https://doi.org/10.1061/9780784479179.033 CrossRefGoogle Scholar
Rothschild, LJ (2016) Synthetic biology meets bioprinting: enabling technologies for humans on Mars (and Earth). Biochemical Society Transactions 44(4), 11581164. https://doi.org/10.1042/BST20160067 CrossRefGoogle ScholarPubMed
Schlacht, IL (2012) Space Habilitability - Integrating Human Factors into the Design Process to Enhance Habitability in Long Duration Missions. 295. http://nbn-resolving.de/urn:nbn:de:kobv:83-opus-34070 Google Scholar
Senge, PM (1994) The Fifth Discipline: The Art and Practice of the Learning Organization, Currency Doubleday.Google Scholar
Tang, TC, An, B, Huang, Y, Vasikaran, S, Wang, Y, Jiang, X, Lu, TK and Zhong, C (2021) Materials design by synthetic biology. Nature Reviews Materials 6(4), 332350. https://doi.org/10.1038/s41578-020-00265-w Google Scholar
Thomas, S (2013) Technobiophilia: nature and cyberspace. Bloomsbury Academic.Google Scholar
Tsiolkovsky, K (2019) the future of earth and mankind. In Groys, B. (Ed.), Russian Cosmism. e-flux and MIT Press, pp. 113132. https://doi.org/10.5325/utopianstudies.30.2.0355 Google Scholar
van Ellen, L, Bridgens, B, Burford, N, Crown, M and Heidrich, O (2023) Adaptability of space habitats using the rhythmic buildings strategy. Acta Astronautica 211(July), 764780. https://doi.org/10.1016/j.actaastro.2023.06.045 CrossRefGoogle Scholar
Verkerke, GJ, van der Houwen, EB, Broekhuis, AA, Bursa, J, Catapano, G, McCullagh, P, Mottaghy, K, Niederer, P, Reilly, R, Rogalewicz, V, Segers, P and Verdonschot, N (2013) Science versus design; comparable, contrastive or conducive? Journal of the Mechanical Behavior of Biomedical Materials 21(September 2020), 195201. https://doi.org/10.1016/j.jmbbm.2013.01.009 CrossRefGoogle Scholar
Vermeulen, ACJ, Goldoust, F, Sirenko, M, Hallak, D, Lutkewitte, B, Husárová, L., Long, KF and Brazier, F (2019) Simulating the construction of conceptual space architecture to explore the potential of combined asteroid mining and space-based 3D manufacturing. 70th International Astronautical Congress (IAC).Google Scholar
Vermeulen, ACJ, Nevejan, C and Brazier, F (2018) Seeker: co-creating diversified futures. In Boelen, J. (ed.), Studio Time: Future Thinking in Art and Design. Z33, pp. 172182.Google Scholar
Vermeulen, ACJ, Papic, A, Nikolic, I and Brazier, F (2023) Stoichiometric model of a fully closed bioregenerative life support system for autonomous long-duration space missions. Frontiers in Astronomy and Space Sciences, 10(August). https://doi.org/10.3389/fspas.2023.1198689 CrossRefGoogle Scholar
Verseux, C, Baqué, M., Lehto, K, De Vera, JPP, Rothschild, LJ and Billi, D (2016) Sustainable life support on mars – the potential roles of cyanobacteria. International Journal of Astrobiology 15(1), 6592. https://doi.org/10.1017/S147355041500021X Google Scholar
Voros, J (2017) Big history and anticipation. In Handbook of Anticipation. Springer, pp. 140.Google Scholar
Walker, J and Granjou, C (2017) MELiSSA the minimal biosphere: human life, waste and refuge in deep space. Futures 92, 5969. https://doi.org/10.1016/j.futures.2016.12.001 CrossRefGoogle Scholar