In a groundbreaking development set to transform the future of flexible electronics, researchers Nakamura and Iwase have unveiled a novel kirigami-inspired structure that promises unprecedented stretchability and durability. Published in npj Flexible Electronics, their 2025 study presents a meticulously engineered stretch-based kirigami design featuring strategically placed folding lines, unlocking new possibilities for wearable devices, soft robotics, and biomedical applications. This innovative approach addresses longstanding challenges in the field of stretchable electronics by combining the ancient Japanese art of paper cutting with cutting-edge materials science, thus enabling circuits to expand, contract, and bend without compromising functionality.
The concept of kirigami—an extension of origami involving both folding and cutting—has fascinated scientists for years due to its potential to introduce mechanical flexibility into rigid materials. Nakamura and Iwase’s research advances this concept by incorporating precision-engineered fold lines within a stretchable substrate, creating a dynamic structure capable of complex deformations. Their design effectively redistributes mechanical strain, allowing electronic components to endure stretching forces that traditional flat designs cannot withstand.
At the heart of this innovation lies a sophisticated interplay between geometry and materials science. The authors detail how the folding lines act as predetermined mechanical hinges, facilitating controlled deformation that mitigates stress concentrations typically responsible for circuit failure. By tailoring fold patterns, the structure can accommodate multidirectional stretching while maintaining the integrity of conductive pathways embedded within the substrate. This design flexibility is pivotal for the evolving landscape of wearable technologies, where devices must conform seamlessly to the human body’s contours and movements.
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Nakamura and Iwase employ advanced computational models to optimize fold placement and orientation, ensuring maximal stretchability without sacrificing electronic performance. Their simulations reveal that certain kirigami patterns can achieve stretch ratios exceeding 100%, a benchmark previously unattainable in stretchable electronics. These results were experimentally validated through fabrication of prototype devices comprising conductive inks printed onto elastomeric films patterned with their kirigami design. The prototypes demonstrated remarkable resilience under repeated mechanical loading, maintaining stable electrical conductivity over thousands of deformation cycles.
One of the most compelling aspects of this research is its potential applicability to next-generation biomedical devices. Stretchable electronics that can conform and adapt to dynamic biological environments are critical for continuous health monitoring and advanced prosthetics. The kirigami structure’s ability to accommodate complex, multidirectional body motions without signal degradation opens pathways for the integration of sensors directly onto skin or even organs, enabling real-time data acquisition with minimal discomfort or interference.
The study also emphasizes the versatility of the kirigami approach for integrating diverse electronic components. Nakamura and Iwase discuss how their fold-based system can incorporate various functional elements such as transistors, sensors, and energy harvesters without compromising mechanical adaptability. This hybridization is crucial for realizing fully integrated flexible electronic systems capable of sophisticated computations and interactive functionalities, moving beyond simple stretchable conductors to smart, multifunctional devices.
From a materials perspective, the researchers highlight the importance of selecting elastomeric substrates with appropriate mechanical properties to complement the kirigami design. The synergy between substrate elasticity, fold geometry, and conductive material properties determines the overall durability and performance of the device. In particular, they focus on the balance between stiffness and flexibility—a key parameter governing the device’s ability to endure repetitive deformation over extended periods.
Beyond technical performance, the kirigami folding concept also offers advantages in manufacturability and scalability. The authors describe an accessible fabrication protocol involving standard printing and laser-cutting techniques compatible with existing manufacturing infrastructure. This compatibility suggests potential for large-scale production of stretchable electronics at reduced cost, accelerating their adoption in consumer and medical markets alike.
An intriguing implication of the work lies in the tunability of mechanical and electrical properties via fold pattern modifications. By altering key design parameters such as fold angle, spacing, and orientation, the researchers can finely control how a device responds to mechanical stress. This level of design precision empowers engineers to customize flexible electronics for specific use cases, whether requiring high stretchability, directional bending, or variable stiffness.
The implications of integrating kirigami structures into electronic devices extend to energy management as well. Nakamura and Iwase touch on the prospect of embedding energy harvesting mechanisms within the folds, harnessing deformation-induced strain to generate electrical power. Such self-powered systems hold promise for extending the operational lifespan of wearable electronics, reducing reliance on external batteries and enhancing device autonomy.
Furthermore, this research marks a significant departure from conventional approaches focused solely on new materials development. By leveraging structural innovation, the kirigami strategy sidesteps some intrinsic limitations of existing conductive polymers and elastomers, which often suffer from trade-offs between conductivity and stretchability. Instead, geometric engineering provides a complementary pathway to achieve mechanical resilience without compromising electronic functionality.
The team’s experimental investigations delve into fatigue behavior and failure modes of their kirigami devices, revealing insights vital for real-world application viability. Their findings indicate that fold lines act not only as stress relief zones but also as mechanical anchors, guiding crack propagation and preventing catastrophic device failure. Understanding these mechanisms lays the foundation for designing next-generation electronics with enhanced longevity in dynamic environments.
Looking ahead, Nakamura and Iwase envision multiple avenues for expanding this kirigami-based paradigm. Potential research directions include integrating sensing and actuation modules within fold networks, exploring novel biocompatible substrates for medical implants, and developing adaptive circuits that can actively reconfigure their topology based on user movement or environmental stimuli. This multidisciplinary approach bridges applied physics, materials science, and electrical engineering, promising rich innovation opportunities.
The transformative potential of this research extends beyond wearable devices. Stretchable electronics capable of complex deformation control could revolutionize soft robotics by enabling more sophisticated, lifelike motion. They may also impact consumer electronics, smart textiles, and even aerospace engineering where flexible yet durable circuits are in high demand.
In summary, the kirigami-inspired folding line design presented by Nakamura and Iwase represents a paradigm shift in the development of stretchable electronics. Their careful balance of geometric strategy, materials compatibility, and manufacturing feasibility lays a robust foundation for versatile, durable, and high-performance flexible devices. As flexible electronics continue to gain prominence across industries, approaches such as this one will be crucial to overcoming longstanding mechanical and functional challenges, ultimately propelling the field toward a more connected and adaptable technological future.
Subject of Research: Stretch-based kirigami structures designed with folding lines for enhanced stretchability and durability in flexible electronics.
Article Title: Stretch-based kirigami structure with folding lines for stretchable electronics.
Article References: Nakamura, N., Iwase, E. Stretch-based kirigami structure with folding lines for stretchable electronics. npj Flex Electron 9, 51 (2025). https://doi.org/10.1038/s41528-025-00409-4
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Tags: ancient art in modern technologybiomedical electronics advancementscutting-edge materials sciencedynamic structures in electronicsflexible electronic deviceskirigami-inspired structuresmechanical flexibility in materialsprecision-engineered fold linessoft robotics applicationsstress concentration mitigationstretchable electronicswearable technology innovations