Design of a Liquid‐Driven Laser Scanner with Low Voltage Based on Liquid‐Infused Membrane

Laser energy is commonly used in tissue ablation, wound suturing, and other precise manipulations during surgery. However, currently available laser scanners require further improvements in terms of miniaturization, driving voltage, and stability to steer the laser beam accurately within a constrained environment. Herein, the development of a liquid‐driven laser scanner installed on the end effector of a continuum endoscope to perform fast and reliable laser steering is proposed. The developed laser scanner is 7 mm in diameter and 7 mm in length, and it is actuated with a voltage lower than 15 V due to the liquid‐infused membrane. The miniature size and low driving voltage of the proposed laser scanner facilitate safe laser‐assisted surgery in confined spaces. A theoretical model is established to predict laser spot position quantitatively, and laser steering ability is also tested experimentally. The fiber‐delivered laser beam can be steered for 21.2° (±10.6°) with a standard deviation of 0.3° in 1000 cycles, demonstrating excellent stability. A laser steering speed of up to 27.3 mm s−1 and a reflection loss of less than 3.1% are achieved. This study develops a liquid‐driven laser scanner installed on the end effector of a continuum endoscope for laser steering. The optofluidic scanner is fabricated with the liquid‐infused membrane, reducing the driving voltage from 500 to 15 V. Over 1000 cycles of laser steering are achieved compared with tens of cycles in existing electrowetting devices, demonstrating excellent stability.