COMING SOON
Life. Rewritten for the Cosmos.
Life. Rewritten for the Cosmos.
VYRONIS™ unites biology, AI, and astrophysics to turn astronaut health science into the blueprint for interplanetary survival.
VYRONIS™ unites biology, AI, and astrophysics to turn astronaut health science into the blueprint for interplanetary survival.
A VISION BEYOND EARTH
A VISION BEYOND EARTH
WHO WE ARE
WHO WE ARE
Founded by Varun Cruz, VYRONIS™ is the world’s first space-biotech company devoted to human life beyond Earth.
Founded by Varun Cruz, VYRONIS™ is the world’s first space-biotech company devoted to human life beyond Earth.
We study what the body becomes when gravity, radiation, and time change; developing health and environmental systems that let life persist in the most extreme conditions.
We study what the body becomes when gravity, radiation, and time change; developing health and environmental systems that let life persist in the most extreme conditions.
From orbital biology to Earth-derived resilience, our research turns astronaut-health science into the foundation for a new era of human adaptability.
From orbital biology to Earth-derived resilience, our research turns astronaut-health science into the foundation for a new era of human adaptability.
Based in Edinburgh and supported by Innovate UK, VYRONIS is shaping a future where survival itself becomes design.
Based in Edinburgh and supported by Innovate UK, VYRONIS is shaping a future where survival itself becomes design.
VYRONIS Missions
VYRONIS Missions
Every programme is a question we chose to answer: What keeps life alive when gravity ends? How does biology respond to the void?
These are our frontiers; missions that redefine how humans survive beyond Earth.
Every programme is a question we chose to answer: What keeps life alive when gravity ends?
How does biology respond to the void?
These are our frontiers; missions that redefine how humans survive beyond Earth.
Astronaut Health Intelligence System
Our flagship platform integrating biometric AI, onboard telemetry, and Earth-observation data to monitor and optimise astronaut physiology in real time.
Cellular and Genomic Adaptation in Microgravity
Researching how living cells respond to radiation, altered gravity, and time dilation to preserve biological integrity during long-duration missions.
Temporal Biology and Radiation Modelling
Analysing the biological effects of disrupted circadian cycles and radiation exposure — developing new countermeasures for astronaut fatigue, immunity, and DNA protection.
Atmospheric Intelligence and Respiration Research
Linking habitat air analytics, CO₂ recycling systems, and human respiratory response in controlled ecosystems — translating space data into sustainable air models for Earth.
Astronaut Health Intelligence System
Our flagship platform integrating biometric AI, onboard telemetry, and Earth-observation data to monitor and optimise astronaut physiology in real time.
Cellular and Genomic Adaptation in Microgravity
Researching how living cells respond to radiation, altered gravity, and time dilation to preserve biological integrity during long-duration missions.
Temporal Biology and Radiation Modelling
Analysing the biological effects of disrupted circadian cycles and radiation exposure — developing new countermeasures for astronaut fatigue, immunity, and DNA protection.
Atmospheric Intelligence and Respiration Research
Linking habitat air analytics, CO₂ recycling systems, and human respiratory response in controlled ecosystems — translating space data into sustainable air models for Earth.
Astronaut Health Intelligence System
Our flagship platform integrating biometric AI, onboard telemetry, and Earth-observation data to monitor and optimise astronaut physiology in real time.
Cellular and Genomic Adaptation in Microgravity
Researching how living cells respond to radiation, altered gravity, and time dilation to preserve biological integrity during long-duration missions.
Temporal Biology and Radiation Modelling
Analysing the biological effects of disrupted circadian cycles and radiation exposure — developing new countermeasures for astronaut fatigue, immunity, and DNA protection.
Atmospheric Intelligence and Respiration Research
Linking habitat air analytics, CO₂ recycling systems, and human respiratory response in controlled ecosystems — translating space data into sustainable air models for Earth.
TECHNOLOGY
TECHNOLOGY
Systems of Survival
Systems of Survival
Life cannot be sustained in the cosmos through biology alone. It demands systems that interpret, predict, and stabilize. Networks where data, molecules, and radiation physics coexist in a single feedback loop.
Life cannot be sustained in the cosmos through biology alone. It demands systems that interpret, predict, and stabilize. Networks where data, molecules, and radiation physics coexist in a single feedback loop.
Life cannot be sustained in the cosmos through biology alone. It demands systems that interpret, predict, and stabilize. Networks where data, molecules, and radiation physics coexist in a single feedback loop.
VYRONIS develops these systems: an adaptive framework integrating biological analytics, environmental telemetry, and quantum-level modelling of human response to off-world conditions.
VYRONIS develops these systems: an adaptive framework integrating biological analytics, environmental telemetry, and quantum-level modelling of human response to off-world conditions.
VYRONIS develops these systems: an adaptive framework integrating biological analytics, environmental telemetry, and quantum-level modelling of human response to off-world conditions.
Each module - whether biometric, atmospheric, or genomic, functions as part of a living computational architecture designed to keep humans viable in microgravity, radiation, and temporal distortion environments.
Each module - whether biometric, atmospheric, or genomic, functions as part of a living computational architecture designed to keep humans viable in microgravity, radiation, and temporal distortion environments.
Each module - whether biometric, atmospheric, or genomic, functions as part of a living computational architecture designed to keep humans viable in microgravity, radiation, and temporal distortion environments.
Biometric Intelligence Layer
Biometric Intelligence Layer
Biometric Intelligence Layer
Continuous monitoring and predictive modelling of human physiology using multi-modal sensor arrays. Machine learning pipelines correlate cardiovascular, neural, and biochemical data with environmental stressors to pre-empt degradation before symptom onset.
Continuous monitoring and predictive modelling of human physiology using multi-modal sensor arrays. Machine learning pipelines correlate cardiovascular, neural, and biochemical data with environmental stressors to pre-empt degradation before symptom onset.
Continuous monitoring and predictive modelling of human physiology using multi-modal sensor arrays. Machine learning pipelines correlate cardiovascular, neural, and biochemical data with environmental stressors to pre-empt degradation before symptom onset.
Data captured from simulated microgravity trials and parabolic-flight experiments feeds directly into GENORA™, our astronaut-health analytics engine.
Data captured from simulated microgravity trials and parabolic-flight experiments feeds directly into GENORA™, our astronaut-health analytics engine.
Data captured from simulated microgravity trials and parabolic-flight experiments feeds directly into GENORA™, our astronaut-health analytics engine.
ENVIORNMENTAL TELEMETRY NETWORK
ENVIORNMENTAL TELEMETRY NETWORK
ENVIORNMENTAL TELEMETRY NETWORK
A distributed lattice of radiation, particulate, and atmospheric sensors forming a unified life-support intelligence grid.
A distributed lattice of radiation, particulate, and atmospheric sensors forming a unified life-support intelligence grid.
A distributed lattice of radiation, particulate, and atmospheric sensors forming a unified life-support intelligence grid.
The network models CO₂ flux, oxygen dynamics, ionizing radiation exposure, and micro-climate variation within confined habitats.
The network models CO₂ flux, oxygen dynamics, ionizing radiation exposure, and micro-climate variation within confined habitats.
The network models CO₂ flux, oxygen dynamics, ionizing radiation exposure, and micro-climate variation within confined habitats.
Each sensor node uses adaptive signal compression and quantum-resilient encryption to ensure data integrity across latency gaps in deep-space communication.
Each sensor node uses adaptive signal compression and quantum-resilient encryption to ensure data integrity across latency gaps in deep-space communication.
Each sensor node uses adaptive signal compression and quantum-resilient encryption to ensure data integrity across latency gaps in deep-space communication.
Adaptive Bio-Interfaces
Adaptive Bio-Interfaces
Adaptive Bio-Interfaces
Smart interfaces translating physiological feedback into actionable system control.
Smart interfaces translating physiological feedback into actionable system control.
Smart interfaces translating physiological feedback into actionable system control.
These include epidermal micro-mesh wearables and implantable biosensors capable of autonomous recalibration when encountering unknown biological or physical variables.
These include epidermal micro-mesh wearables and implantable biosensors capable of autonomous recalibration when encountering unknown biological or physical variables.
These include epidermal micro-mesh wearables and implantable biosensors capable of autonomous recalibration when encountering unknown biological or physical variables.
Data from these interfaces allows autonomous habitat systems to synchronize environmental modulation with human metabolic rhythms; effectively letting the spacecraft breathe with its crew.
Data from these interfaces allows autonomous habitat systems to synchronize environmental modulation with human metabolic rhythms; effectively letting the spacecraft breathe with its crew.
Data from these interfaces allows autonomous habitat systems to synchronize environmental modulation with human metabolic rhythms; effectively letting the spacecraft breathe with its crew.
RADIOBIOLOGICAL MODELLING & TEMPORAL STABILITY
RADIOBIOLOGICAL MODELLING & TEMPORAL STABILITY
RADIOBIOLOGICAL MODELLING & TEMPORAL STABILITY
CHRONOVA™ integrates particle-flux simulations with biological half-life decay models to predict radiation-induced cellular drift over time.
CHRONOVA™ integrates particle-flux simulations with biological half-life decay models to predict radiation-induced cellular drift over time.
CHRONOVA™ integrates particle-flux simulations with biological half-life decay models to predict radiation-induced cellular drift over time.
Using relativistic time-dilation data and circadian modelling, it provides a framework for maintaining genomic stability during prolonged exposure to high-energy cosmic rays.
Using relativistic time-dilation data and circadian modelling, it provides a framework for maintaining genomic stability during prolonged exposure to high-energy cosmic rays.
Using relativistic time-dilation data and circadian modelling, it provides a framework for maintaining genomic stability during prolonged exposure to high-energy cosmic rays.
The output: predictive countermeasures for DNA repair pathways and radiation-shield optimisation, validated against onboard dosimetry arrays.
The output: predictive countermeasures for DNA repair pathways and radiation-shield optimisation, validated against onboard dosimetry arrays.
The output: predictive countermeasures for DNA repair pathways and radiation-shield optimisation, validated against onboard dosimetry arrays.
Earth Integration Protocols
Earth Integration Protocols
Earth Integration Protocols
Every system designed for orbit is simultaneously a mirror for Earth.
Every system designed for orbit is simultaneously a mirror for Earth.
Every system designed for orbit is simultaneously a mirror for Earth.
Environmental telemetry algorithms repurpose into terrestrial climate-resilience platforms; biometric intelligence informs medical diagnostics and predictive healthcare.
Environmental telemetry algorithms repurpose into terrestrial climate-resilience platforms; biometric intelligence informs medical diagnostics and predictive healthcare.
Environmental telemetry algorithms repurpose into terrestrial climate-resilience platforms; biometric intelligence informs medical diagnostics and predictive healthcare.
Our philosophy: survival in the cosmos is simply survival, perfected.
Our philosophy: survival in the cosmos is simply survival, perfected.
Our philosophy: survival in the cosmos is simply survival, perfected.
" EVERY CELL THAT ADAPTS IN SPACE TEACHES US HOW TO SURVIVE ON EARTH "
" EVERY CELL THAT ADAPTS IN SPACE TEACHES US HOW TO SURVIVE ON EARTH "
Varun Cruz, Founder & Chief Executive Officer
Varun Cruz, Founder & Chief Executive Officer
RESEARCH
Life Under Gravity’s Edge
Life Under Gravity’s Edge
The biology of space is a paradox; life evolved under gravity, yet seeks to exist without it.
The biology of space is a paradox; life evolved under gravity, yet seeks to exist without it.
The biology of space is a paradox; life evolved under gravity, yet seeks to exist without it.
VYRONIS™ studies this transition: the molecular, cellular, and systemic reconfiguration that defines survival beyond Earth’s biosphere.
VYRONIS™ studies this transition: the molecular, cellular, and systemic reconfiguration that defines survival beyond Earth’s biosphere.
VYRONIS™ studies this transition: the molecular, cellular, and systemic reconfiguration that defines survival beyond Earth’s biosphere.
Our research combines radiation physics, temporal biology, and genomics to understand how humans adapt, deteriorate, and recover under altered physical laws.
Our research combines radiation physics, temporal biology, and genomics to understand how humans adapt, deteriorate, and recover under altered physical laws.
Our research combines radiation physics, temporal biology, and genomics to understand how humans adapt, deteriorate, and recover under altered physical laws.
What we learn off-world rewrites what we know on Earth; from radiation medicine to regenerative biology and planetary climate modelling.
What we learn off-world rewrites what we know on Earth; from radiation medicine to regenerative biology and planetary climate modelling.
What we learn off-world rewrites what we know on Earth; from radiation medicine to regenerative biology and planetary climate modelling.
Genomic Adaptation & Cellular Integrity
Genomic Adaptation & Cellular Integrity
Genomic Adaptation & Cellular Integrity
Using microgravity and radiation exposure simulations, VYRONIS™ decodes transcriptional changes within cellular systems to map genomic stability thresholds.
Using microgravity and radiation exposure simulations, VYRONIS™ decodes transcriptional changes within cellular systems to map genomic stability thresholds.
Using microgravity and radiation exposure simulations, VYRONIS™ decodes transcriptional changes within cellular systems to map genomic stability thresholds.
Our ASTRALIFE™ initiative investigates DNA repair kinetics, epigenetic drift, and mitochondrial dynamics under chronic space stress.
Our ASTRALIFE™ initiative investigates DNA repair kinetics, epigenetic drift, and mitochondrial dynamics under chronic space stress.
Our ASTRALIFE™ initiative investigates DNA repair kinetics, epigenetic drift, and mitochondrial dynamics under chronic space stress.
This work informs new therapeutic strategies for cancer, immune modulation, and longevity on Earth; proving that the biology of astronauts is the biology of us all.
This work informs new therapeutic strategies for cancer, immune modulation, and longevity on Earth; proving that the biology of astronauts is the biology of us all.
This work informs new therapeutic strategies for cancer, immune modulation, and longevity on Earth; proving that the biology of astronauts is the biology of us all.
TEMPORAL BIOLOGY & CIRCARDIAN RECALIBRATION
TEMPORAL BIOLOGY & CIRCARDIAN RECALIBRATION
TEMPORAL BIOLOGY & CIRCARDIAN RECALIBRATION
Through the CHRONOVA™ framework, we examine how time dilation, light cycles, and radiation flux distort circadian and hormonal regulation.
Through the CHRONOVA™ framework, we examine how time dilation, light cycles, and radiation flux distort circadian and hormonal regulation.
Through the CHRONOVA™ framework, we examine how time dilation, light cycles, and radiation flux distort circadian and hormonal regulation.
We model neuroendocrine oscillations, metabolic adaptation, and cognitive impacts across prolonged microgravity exposure.
We model neuroendocrine oscillations, metabolic adaptation, and cognitive impacts across prolonged microgravity exposure.
We model neuroendocrine oscillations, metabolic adaptation, and cognitive impacts across prolonged microgravity exposure.
Findings contribute to improved mission architecture, psychological health models, and the emerging discipline of chrono-astrophysiology.
Findings contribute to improved mission architecture, psychological health models, and the emerging discipline of chrono-astrophysiology.
Findings contribute to improved mission architecture, psychological health models, and the emerging discipline of chrono-astrophysiology.
Environmental Response & Astrobiological Modelling
Environmental Response & Astrobiological Modelling
Environmental Response & Astrobiological Modelling
VYRONIS™ integrates Earth-Observation data with in-situ habitat telemetry to study environmental-biological coupling.
VYRONIS™ integrates Earth-Observation data with in-situ habitat telemetry to study environmental-biological coupling.
VYRONIS™ integrates Earth-Observation data with in-situ habitat telemetry to study environmental-biological coupling.
By merging atmospheric analytics, radiation mapping, and biosystem modelling, we construct predictive frameworks for life-support ecosystems on other worlds.
By merging atmospheric analytics, radiation mapping, and biosystem modelling, we construct predictive frameworks for life-support ecosystems on other worlds.
By merging atmospheric analytics, radiation mapping, and biosystem modelling, we construct predictive frameworks for life-support ecosystems on other worlds.
These datasets inform both exoplanetary habitability assessments and terrestrial climate-resilience systems.
These datasets inform both exoplanetary habitability assessments and terrestrial climate-resilience systems.
These datasets inform both exoplanetary habitability assessments and terrestrial climate-resilience systems.
QUANTUM BIOPHYSICS & RADIATION COUNTERMEASURES
[EMERGING DIVISION]
QUANTUM BIOPHYSICS & RADIATION COUNTERMEASURES
[EMERGING DIVISION]
QUANTUM BIOPHYSICS & RADIATION COUNTERMEASURES
[EMERGING DIVISION]
In collaboration with UK and EU partners, our Quantum Biophysics unit investigates how quantum coherence and spin dynamics affect biological stability under cosmic radiation.
In collaboration with UK and EU partners, our Quantum Biophysics unit investigates how quantum coherence and spin dynamics affect biological stability under cosmic radiation.
In collaboration with UK and EU partners, our Quantum Biophysics unit investigates how quantum coherence and spin dynamics affect biological stability under cosmic radiation.
Early data suggest radiation-resistant quantum states may be inducible within biomolecular structures; a foundation for next-generation shielding and therapeutic design.
Early data suggest radiation-resistant quantum states may be inducible within biomolecular structures; a foundation for next-generation shielding and therapeutic design.
Early data suggest radiation-resistant quantum states may be inducible within biomolecular structures; a foundation for next-generation shielding and therapeutic design.
VYRONIS™ | LIFE
VYRONIS™ | LIFE
VYRONIS™ | LIFE
REWRITTEN FOR THE COSMOS
REWRITTEN FOR THE COSMOS
REWRITTEN FOR THE COSMOS
Phone: +44 (0) 20 3432 2640
Phone: +44 (0) 20 3432 2640
Phone: +44 (0) 20 3432 2640
Email: hq@vyronis.co
Email: hq@vyronis.co
Email: hq@vyronis.co
In collaboration with global research partners including the European Space Agency (ESA) and supported by Innovate UK.
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Our Founder
Varun Cruz | vcruz@varune.co
Headquarters: 13 Hanover Square, Mayfair, London W1S 1HN, United Kingdom
Research & Laboratory Address: The Higgs Centre for Innovation, Royal Observatory, Blackford Hill, Edinburgh EH9 3HJ, United Kingdom
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