Visualizing Respiratory Droplet Dispersion: Gain insights into how respiratory droplets disperse during conversations, assessing the effectiveness of different ventilation strategies, and understanding the impact of environmental conditions on aerosol behavior.
Physics and Biology Integration: Our simulations blend physics, biology, and computational modeling, incorporating factors such as Lagrangian Particle Tracking, Brownian motion, virus survival, and host respiratory physiology to provide a holistic understanding of respiratory aerosols.
Assessing Efficacy of Respiratory Aids: Virtually evaluate the efficacy of various respiratory aids, including masks, respirators, and advanced ventilation systems.
Cutting-edge Computational Fluid Dynamics (CFD): Employing CFD techniques, we simulate airflow patterns, particle filtration efficiency, and aerosol containment, optimizing respiratory device designs for maximum effectiveness.
Evaluating Device Performance: Assess the performance of N95 masks, ventilators, and other respiratory devices in diverse scenarios, considering factors such as airflow resistance and filtration capacity.
Supporting Device Development: Collaborate with experts in biomedical engineering to innovate next-generation respiratory technologies, leveraging our simulations to refine designs and enhance efficacy.
Industry-standard Software Packages: Utilize industry-standard software packages to ensure accuracy and adaptability to specific design requirements.
Validation against Empirical Data: Validate simulations against empirical data, guaranteeing reliability and providing a robust foundation for decision-making and innovation.
