Elastomer-based whispering gallery mode microlasers with low Young's modulus for biosensing applications

Abstract: Sensing biological forces with microscopic lasers is an emerging technique that offers significant advantages over conventional fluorescent probes and imaging-based techniques. However, the limited availability of suitable deformable or elastic microlaser materials is restricting the scale of forces that can be detected which strongly narrows their overall applicability. Here, we describe the synthesis of spherical whispering gallery mode microbead lasers from a commercially available elastomer material in a microfluidic system with high viscosity. Upon doping with organic dye molecules, the microbeads show excellent lasing characteristics with low lasing thresholds. Measurements of the mechanical properties reveal that the lasing characteristics are directly proportional to the applied external force. The measured Young's modulus confirms that the newly synthesized microlasers are very soft and can detect higher forces than previously applied deformable microlasers made from oil droplets. Furthermore, we show that elastomer microlasers are non-toxic and stable in aqueous environments, making them ideally suited for sensing forces inside tissues and small animals.