DNA origami has become a transformative tool in nanotechnology, providing a robust and programmable method for fabricating highly ordered nanostructures with unparalleled accuracy. This article offers a thorough examination of the present state of DNA origami, first with an introduction to its origins and importance, and subsequently addressing the essential principles that dictate its design and folding processes. Multiple manufacturing methodologies and optimization tactics are examined, emphasizing innovations that improve structural complexity, stability, and functionalization. The study explores the many uses of DNA origami in biomedicine, sensing, drug delivery, and nanorobotics, highlighting its significant potential. Notwithstanding its potential, the analysis highlights significant problems like elevated manufacturing costs, restricted structural stability under physiological settings, scaling concerns, and integration difficulties with other nanomaterials. The future possibilities of DNA origami are examined, highlighting continuous advancements and multidisciplinary collaborations focused on addressing existing limits and converting this technology into useful, real-world applications.
Saleem et al. (Mon,) studied this question.