Stanford researchers have developed a next-generation computational algorithm for diagnostic of pulmonary hypertension (PH) that provides an estimate of the tricuspid regurgitation (TR) velocity (Vmax) with increased accuracy and confidence.
Stanford scientists have invented an implicit an Neural Representation learning methodology with Prior embedding (NeRP) to reconstruct a computational medical image from sparsely sampled measurements using only a prior image of the subject.
Stanford researchers developed a programmable tuning circuit for dynamic, all-electronic tuning of the resonance frequency, sensitivity, and bandwidth of ultrasound transducers.
Using advances in flexible electronics, researchers at Stanford have developed a stretchable strain sensor for monitoring solid tumor size progression on or near the skin in real time.
Stanford inventors have developed a near infrared (NIR) tumor imaging platform that couples a novel rare earth cancer targeting agent and a handheld NIR-IIb fluorescence imager to enable tumor resection down to the few-cell level.
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.
Inventors at Stanford University have developed a colorimetric device to visualize microstructural features in tissue biopsies towards clinical diagnostics.
Stanford researchers have designed and prototyped an inexpensive, compact and easy-to-use smartphone lens mount for the capture of high quality photographs and videos of the eye's front and back structures.
Differential Phase Contrast (DPC) X-ray imaging measures both absorption and index of refraction of materials being imaged. This technique has several advantages compared to traditional absorption-only X-ray imaging.
Researchers at Stanford have developed a probe, NIRDye812, which improves contrast between healthy and diseased tissues for fluorescence-guided cancer surgery applications.
Stanford researchers at the Ferrara Lab have developed a volumetric ultrasound imaging that uses a motion controller to realize 3D imaging. This invention introduces a new transducer architecture with significantly improved image resolution.
Stanford doctors have developed a retractor that easily and accurately measures orbital compartment pressure without requiring precise orientation to the central cornea.