Assessment of the 50 % and 95 % effective paratracheal forces for occluding the esophagus in anesthetized patients.

This study aimed to evaluate the 50% and 95% effective paratracheal forces for occluding the esophagus in anesthetized patients. In 46 anesthetized patients, the upper esophagus was examined using ultrasonography, and the lower paratracheal area over the esophagus just above the clavicle was marked. Manual paratracheal force was applied over that area using a novel pressure sensing device set-up.

Honeycomb-like MoS Nanotube Array-Based Wearable Sensors for Noninvasive Detection of Human Skin Moisture.

Technological advances in wearable electronics have driven the necessity of a highly sensitive humidity sensor that can precisely detect physiological signals from the human body in real time. Herein, we introduce the anodic aluminum oxide (AAO)-assisted MoS honeycomb structure as a resistive humidity sensor with superior sensing performance. The unique honeycomb-like structure consists of MoS nanotubes, which can amplify the sensing performance because of their open pores and wider surface absorption sites.

Highly Sensitive and Flexible Strain-Pressure Sensors with Cracked Paddy-Shaped MoS/Graphene Foam/Ecoflex Hybrid Nanostructures.

Three-dimensional graphene porous networks (GPNs) have received considerable attention as a nanomaterial for wearable touch sensor applications because of their outstanding electrical conductivity and mechanical stability. Herein, we demonstrate a strain-pressure sensor with high sensitivity and durability by combining molybdenum disulfide (MoS) and Ecoflex with a GPN. The planar sheets of MoS bonded to the GPN were conformally arranged with a cracked paddy shape, and the MoS nanoflakes were formed on the planar sheet.

High Durability and Waterproofing rGO/SWCNT-Fabric-Based Multifunctional Sensors for Human-Motion Detection.

Wearable strain-pressure sensors for detecting electrical signals generated by human activities are being widely investigated because of their diverse potential applications, from observing human motion to health monitoring. In this study, we fabricated reduced graphene oxide (rGO)/single-wall carbon nanotube (SWCNT) hybrid fabric-based strain-pressure sensors using a simple solution process. The structural and chemical properties of the rGO/SWCNT fabrics were characterized using scanning electron microscopy (SEM), Raman, and X-ray photoelectron spectroscopy (XPS).