Abstract
A system and method are presented for a time-bounded, non-genetic regeneration framework in which synthetic, diatom-shaped functional organelles are continuously produced, deployed, and exhausted within a confined system. The approach relies on geometry-driven kinematic assembly, droplet and gel physics, and swarm-level population homeostasis rather than cellular replication or organism growth. A critical design invariant enforces the release of exactly two functional organelles per release event, ensuring bounded output, predictable dynamics, and safety. The disclosure provides laboratory-recognizable implementation pathways suitable for materials science, soft-matter physics, and bioengineering groups and is released for public use to establish prior art.
Publication Date
2026-01-05
Creative Commons License
This work is licensed under a Creative Commons Attribution 4.0 License.
Recommended Citation
Mallapragada, Suma; Sankepally, Vaishnavi; Manoharan, Anishkumar; Fazl, Muhamed; Dhawal, Cherukuri; Abhijit Patki, Shreya; and Datta Sai, Kethavarapu Uma Eswar, "Xenobot-Inspired Diatom Analogues for Synthetic Kinematic Renewal of Regenerative Nanobot Payloads", Technical Disclosure Commons, (January 05, 2026)
https://www.tdcommons.org/dpubs_series/9128