🔬 ABOUT ASTERPHYSIOLOGY
Welcome to AsterPhysiology, your comprehensive research platform dedicated to revolutionizing worker health and safety across all industries through artificial intelligence, IoT-powered monitoring systems, and evidence-based decision support. From aerospace medicine to manufacturing, construction to healthcare, we develop intelligent solutions that protect and enhance human performance in every work environment.
🚀 OUR MISSION
AsterPhysiology emerged from a vision to transform worker health and safety across all industries through artificial intelligence, IoT technology, and evidence-based research. Our mission encompasses developing AI-driven systems that enhance human performance, prevent workplace injuries, and enable real-time health monitoring from the factory floor to the final frontier of space.
We specialize in integrating AI and IoT into occupational health practices across industries. Recent comprehensive reviews demonstrate that AI-powered predictive analytics and IoT-based monitoring systems significantly reduce workplace accidents and enable proactive health interventions across manufacturing, construction, healthcare, and aerospace environments [PMC, 2025] [PMC, 2024].
Through advanced human-in-the-loop AI systems and IoT sensor networks, we enable real-time health monitoring, environmental hazard detection, and predictive safety analytics. Our research shows measurable reductions in incident rates across industries deploying such integrated systems, from reducing ergonomic risks by 45% in manufacturing to preventing fatigue-related accidents in aerospace operations [Inseer, 2025].
OUR VISION
We envision a future where every worker, regardless of industry or environment, benefits from intelligent health and safety systems that predict, prevent, and respond to occupational hazards in real-time. Our vision encompasses AI-driven occupational health across manufacturing, construction, healthcare, mining, agriculture, and aerospace - creating safer workplaces through continuous monitoring, predictive analytics, and adaptive safety interventions [Frontiers in Public Health, 2024].
OUR COMMITMENT TO PREVENTION
At AsterPhysiology, we are fundamentally committed to improving health through prevention - being proactive and predictive in safety and health management systems. Our approach integrates IoT devices and biosensor monitoring for comprehensive prevention and surveillance of health risks due to high-risk exposures across all occupational environments.
Our evidence-based prevention strategies leverage continuous monitoring and real-time analytics to identify health threats before they manifest into injuries or illnesses. Research demonstrates that IoT-enabled biosensor systems reduce unplanned hospitalizations related to occupational exposures by up to 40%, while achieving >90% sensitivity for detecting critical health threats in industrial and aerospace workers [Healthcare Basel, 2022] [Scientific Reports, 2023].
PROACTIVE HEALTH SURVEILLANCE
Real-time biosensor networks provide continuous physiological monitoring, enabling early detection of heat stress, hypoxia, chemical exposure, and fatigue before critical thresholds are reached [PubMed, 2024].
PREDICTIVE ANALYTICS
AI-driven analysis of continuous physiological data predicts health deteriorations before symptom onset, reducing lost-time injuries and acute health incidents by 25-50% in pilot deployments [Scientific Reports, 2023].
INTEGRATED IoT ECOSYSTEMS
Wireless sensor networks integrated into smart garments and PPE provide granular real-time surveillance, decreasing emergency response times from hours to minutes [ACS Sustainable Chemistry, 2024].
EVIDENCE-BASED INTERVENTIONS
Connected devices enable evidence-based prevention strategies through aggregate sensor data, guiding targeted interventions such as hydration protocols, rest optimization, and exposure-limiting workflows.
📊 CORE RESEARCH AREAS
IoT HEALTH MONITORING
Real-time physiological monitoring systems using networked sensors and smart wearables across industries, enabling continuous tracking of vital signs, fatigue, and environmental exposures [PMC, 2024].
PREDICTIVE SAFETY ANALYTICS
AI-powered analysis of multimodal occupational datasets to predict workplace hazards, equipment failures, and health risks before they cause harm across manufacturing, construction, and aerospace [PMC, 2025].
SMART ERGONOMICS
AI-driven ergonomic assessment systems that optimize workplace layouts and monitor worker movements, achieving up to 45% reduction in ergonomic risks and 30% drop in injury incidents [Inseer, 2025].
ENVIRONMENTAL MONITORING
IoT-based systems for detecting chemical exposure, air quality hazards, and environmental risks in industrial settings, with >90% accuracy in hazardous exposure detection and automated safety responses.
OCCUPATIONAL HEALTH ACROSS INDUSTRIES
Our research extends beyond aerospace to transform worker safety across all industries through integrated AI and IoT solutions. Comprehensive studies demonstrate significant improvements in worker health and safety when intelligent monitoring systems are deployed across various occupational environments.
MANUFACTURING & ASSEMBLY
AI-powered ergonomic assessment and real-time posture monitoring reduce musculoskeletal disorders and optimize production workflows [Nature, 2025].
CONSTRUCTION & MINING
Smart PPE with integrated sensors and predictive analytics for hazard detection, preventing falls and equipment-related accidents through real-time monitoring [Frontiers, 2024].
HEALTHCARE WORKERS
IoT-based fatigue detection and stress monitoring systems to prevent burnout and reduce medical errors, especially critical for shift workers and emergency personnel.
CHEMICAL & INDUSTRIAL
Advanced environmental monitoring for toxic exposure detection and air quality management, enabling immediate response to hazardous conditions and regulatory compliance.
SPECIALIZED APPLICATION: AEROSPACE MEDICINE
Aerospace represents the most extreme application of our occupational health research, where the technologies and methodologies developed for terrestrial industries find their ultimate test in the unforgiving environments of aviation and space exploration. Here, AI-driven human performance augmentation becomes mission-critical for survival. [NASA Technical Report, 2024] [The Innovation Medical, 2025]
EXTREME ENVIRONMENT APPLICATIONS
- Real-time physiological monitoring with AI-powered anomaly detection, adapted from industrial health monitoring systems but enhanced for space mission requirements [Number Analytics, 2025]
- Augmented reality interfaces for hands-free medical procedures in zero gravity, building on ergonomic assessment technologies from manufacturing environments [Universe Today, 2024]
- AI-assisted decision support for medical emergencies when Earth communication delays make consultation impossible, extending predictive analytics from terrestrial occupational health [ESA, 2024]
- Predictive analytics for space adaptation syndrome, leveraging machine learning models developed for fatigue detection in shift workers and ergonomic risk assessment [NASA, 2024]
CROSS-INDUSTRY INNOVATION
The extreme requirements of aerospace medicine drive innovations that benefit all industries. Technologies developed for space missions often find applications in manufacturing, healthcare, construction, and other high-risk occupations, creating a feedback loop of continuous improvement in worker safety across all sectors. [Space Technology Research, 2024]
RESEARCH TEAM
AsterPhysiology is developed and maintained by Juan Felipe Malpica and Diego Malpica, a father-son research team dedicated to revolutionizing occupational health and safety across all industries through artificial intelligence and IoT technology. Their shared passion for protecting workers everywhere - from manufacturing floors to space stations - drives innovative solutions that bridge the gap between cutting-edge AI technology and practical applications that save lives and prevent injuries in every work environment.