flexible devices for detecting small temperature variations, pressure changes, bending, and moistness fluctuations. [21,22] Besides, more recent reports on hydrogel [23,24] show good performance on the material response-based wearable devices. However, such sensing systems have parasitic repercussions, low performance, nonintrinsic electrical security, and electromagnetic interference, which hamper the working efficiency and restrict their wide applications as wearable gadgets. [25] But, optical segments incorporated on adaptable substrates were not explored more. These systems offer exceptional benefits like distant checking capacity, high affectability, nonelectromagnetic disturbances, real-time monitoring, and intrinsic electrical security apart from features like reconfigurability and scalability. One such optical segment is optical microfibers that possess strong evanescent fields [26][27][28][29] and are sensitive to microforce or relocation. [30,31] Furthermore, when light propagates through the optical microfiber, it excites the higher-order modes that interfere with the fundamental modes of single-mode fiber to form an interference pattern whose period can be tailored depending upon the requirement and the interference pattern shifts when subjected to external perturbations.On the other hand, polydimethylsiloxane (PDMS) is an excellent material to embed optical microfiber due to its biocompatibility and robust mechanical stability [32,33] apart from providing mechanical stability to the microfiber, which otherwise is fragile and difficult to use. PDMS-incorporated optical microfiber also exhibits low loss, high-temperature steadiness with high flexibility. Such an encapsulation also solves the demerits of conventional thermometers such as glass breaking, mercury poisoning, long-term affectability, and biocompatibility. These devices can also be directly affixed to the human body to detect small bending of different body joints like the neck, knee, elbow, and arms to name few where most conventional goniometers-based system cannot be utilized like the comfort and ease provided by flexible PDMS-assisted systems. Recent reports on knot resonator, [34] straight, and bend micronanofiber [35] are very delicate due to their miniature diameter, less sensitive, difficult to mount on skin as light enters from one side and comes out from other, nontailorable performance, and uses the change in incident light intensity for monitoring, which make its widely susceptible to light source fluctuations. Hence, it remains a challenge to develop a robust and stable system, which can be skin mountable, reconfigurable with
