Researchers in the Collaborative Haptics and Robotics in Medicine Lab at Stanford University have developed a monolithically 3D printed haptic device that provides skin pressure, linear and rotational shear, and vibration feedback.
Ultrasound technology is a safe, high-resolution, and cost-efficient tool for imaging. Other modalities, such as MRI or CT, may require the use of anesthesia. This makes it difficult to image pediatric patients and patients sensitive to anesthesia.
This highly instrumented laryngoscope measures intubation mechanics such as force and torque to quantitatively track how a laryngoscope is being inserted.
Stanford inventors have developed a method for collagen compression along with a polymer mesh as a mechanical support to produce collagen-based composite grafts.
Stanford inventors have engineered a method for breath-based cancer detection, which can provide rapid and non-invasive early cancer detection and surveillance.
Researchers at Stanford University, UCSB and MIT have invented a novel video compression pipeline, called Txt2Vid, which substantially reduces data transmission rates by compressing webcam videos ("talking-head videos") to a text transcript.
Inventors at Stanford University have developed a colorimetric device to visualize microstructural features in tissue biopsies towards clinical diagnostics.
Stanford inventors have developed a method of using CRISPR/Cas9 or similar gene editing technologies to genetically edit an individual's own myeloid cells for specific gene targets, which are critical to wound repair, and applying these edited cells in a hydrogel to promote ra
Researchers in Prof. David Myung's laboratory have developed a bio-compatible, crosslinking gel that can be used for in situ repair of damaged cornea or as a three-dimensional scaffold for keratocyte-keratinocyte tissue culture.
Stanford University researchers have developed a system that achieves atmospheric water harvesting with high specific productivity, defined as the rate of water collected per mass of absorbent material.
Using their newly developed acetyl-click screening platform, researchers at Stanford have identified riboflavin analogs as small molecule inhibitors of Histone Acetyltransferase 1 (HAT1) with anti-cancer activity.