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All issues Volume 21 (2026) Math. Model. Nat. Phenom., 21 (2026) 6 References
Issue
Math. Model. Nat. Phenom.
Volume 21, 2026
Special Issue to honour Vitaly's work
Article Number 6
Number of page(s) 14
DOI https://doi.org/10.1051/mmnp/2025024
Published online 17 March 2026
  1. R. Fernandes and D.H. Gracias, Self-folding polymeric containers for encapsulation and delivery of drugs. Adv. Drug Deliv. Rev. 64 (2012) 1579–1589. [Google Scholar]
  2. M. Pisal, P. Barbade and S. Dudhal, Nanocapsule. Int. J. Pharm. Sci. Rev. Res. 60 (2020) 53–62. [Google Scholar]
  3. N. Kalra, V. Dhanya, V. Saini and G. Jeyabalan, Virosomes: as a drug delivery carrier. Am. J. Adv. Drug Deliv. 1 (2013) 29–35. [Google Scholar]
  4. F.K. Aldawood, A comprehensive review of 4D printing: state of the arts, opportunities, and challenges. Actuators 12 (2023) 101. [Google Scholar]
  5. S. Vatanparast, A. Boschetto, L. Boani and P. Gaudenzi, New trends in 4D printing: a critical review. Appl. Sci. 13 (2023) 7744. [Google Scholar]
  6. J.R. Jungck, S. Brittain, D. Plante and J. Flynn, Self-assembly, self-folding, and origami: comparative design principles. Biomimetics 8 (2023) Article 12. [Google Scholar]
  7. J.A. Geraets, E.C. Dykeman, P.G. Stockley, N.A. Ranson and R. Twarock, Genome organization in an RNA virus revealed via graph-theoretical analysis of tomographic data. PLoS Computat. Biol. 11 (2015) e100414. [Google Scholar]
  8. J. O'Rourke, How to Fold It: The Mathematics of Linkages, Origami, and Polyhedra. Cambridge University Press, New York (2011). [Google Scholar]
  9. P.M. Dodd, P.F. Damasceno and S.C. Glotzer, Universal folding pathways of polyhedron nets. Proc. Natl. Acad. Sci. U.S.A. 115 (2018) E6690-E6696. [Google Scholar]
  10. Protein Data Bank origami model of a Zika virus, https://cdn.rcsb.org/pdb101/learn/resources/zika/zika-paper-model.pdf. [Google Scholar]
  11. R. Kaplan, J. Klobušický, S. Pandey, D.H. Gracias and G. Menon, Building polyhedra by self-assembly: theory and experiment. Artif. Life 20 (2014) 409–439. [Google Scholar]
  12. D. George, M.J. Madou and E.A. Peraza-Hernandez, Programmable self-foldable films for origami-based manufacturing. Smart Mater. Struct. 30 (2021) 025012. [Google Scholar]
  13. A.A.A. Aljabali, S.S. Hassan, R.M. Pabari, S.H. Shahcheraghi, V. Mishra, N.B. Charbe, D.K. Chellappan, H. Dureja, G. Gupta, A.G. Almutary, A.M. Alnuqaydan, S.K. Verma, P.K. Panda, Y.K. Mishra, A. Serrano-Aroca, K. Dua, V.N. Uversky, E.M. Redwan, B. Bahar, A. Bhatia, P. Negi, R. Goyal, P. McCarron, H.A. Bakshi and M.M. Tambuwala, The viral capsid as novel nanomaterials for drug delivery. Future Sci. OA 7 (2021) FSO744. [Google Scholar]
  14. M. Bin Umair, F.N. Akusa, H. Kashif, Bu, F. Seerat-E-Fama, M. Azhar, I. Munir, M. Ahmed, W. Khalil, H. Sharyar, S. Rafique, M. Shahid and S. Afzal, Viruses as tools in gene therapy, vaccine development, and cancer treatment. Arch. Virol. 167 (2022) 1387–1404. [Google Scholar]
  15. E.A. Peraza-Hernandez, D.J. Hartl, D.C. Lagoudas, Unfolding polyhedra method for the design of origami structures with creased folds, in, Active Origami: Modeling, Design, and Applications, edited by E.A. Peraza-Hernandez, D.J. Hartl, D.C. Lagoudas. Springer (2019) 111–155. [Google Scholar]
  16. A. Azam, T.G. Leong, A.M. Zarafshar and D.H. Gracias, Compactness determines the success of cube and octahedron self-assembly. PLoS One 4 (2009) e4451. [Google Scholar]
  17. B. An, S. Miyashita, A. Ong, M.T. Tolley, M.L. Demaine, E.D. Demaine, R.J. Wood and D. Rus, An end-to-end approach to self-folding origami structures. IEEE Trans. Robot. 34 (2018) 1409–1424. [Google Scholar]
  18. E.A. Peraza-Hernandez, D.J. Hartl, R.J. Malak Jr and D.C. Lagoudas, Origami-inspired active structures: a synthesis and review. Smart Mater. Struct. 23 (2014) 094001. [Google Scholar]
  19. M.T. Tolley, S.M. Felton, S. Miyashita, D. Aukes, D. Rus and R.J. Wood, Self-folding origami: shape memory composites activated by uniform heating. Smart Mater. Struct. 23 (2014) 094006. [Google Scholar]
  20. M. Stern, M.B. Pinson and A. Murugan, The complexity of folding self-folding origami. Phys. Rev. X 7 (2017) 041070. [Google Scholar]
  21. S. Pandey, M. Ewing, A. Kunas, N. Nguyen, D.H. Gracias and G. Menon, Algorithmic design of self-folding polyhedra. Proc. Natl. Acad. Sci. U.S.A. 108 (2011) 19885–19890. [Google Scholar]
  22. A. Ghassaei, Origami Simulator. https://experiments.withgoogle.com/origami-simulator (2017). [Google Scholar]
  23. S. Brittain, F. Lovell and J.R. Jungck, PolyhedraNetsDisplay. Github. https://github.com/brittainst/PolyhedraNetsDisplay (2022). [Google Scholar]
  24. E. Peraza-Hernandez, D. Hartl and R. Malak, Simulation-based design of a self-folding smart material system, in International Design Engineering Technical Conferences and Computers and Information in Engineering Conference 55942: V0BT07A 045. American Society of Mechanical Engineers (2013). [Google Scholar]
  25. K. Yadav, D. Singh, M.R. Singh, N. Singh Chauhan, S. Minz and M. Pradhan, Nanobiomaterials as novel modules in the delivery of artemisinin and its derivatives for effective management of malaria, in Natural Products in Vector-Borne Disease Management. Academic Press (2023) 447–466. [Google Scholar]

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