Stanford researchers have developed a method that allows X-ray and CT imaging to achieve the same signal with two to three orders of magnitude less X-ray dosage.
Researchers at Stanford University have developed an affinity capture technique for top-down protein analysis that directly couples biolayer interferometry (BLI) with high resolution mass spectrometry (HR-MS).
Vibrational spectroscopy, including infrared and Raman optical spectroscopy, is an instrumental technique for fingerprinting molecular structures and the chemical compositions of different materials.
Measurement of dissolved CO2 has critical applications in healthcare monitoring and consumer goods quality control, yet is difficult to measure directly.
Researchers at Stanford have modified the spatial construction of two-wave interferometers to enable high-precision acoustic sensors and accelerometers produced at scale.
Stanford researchers have developed a device that combines one-photon and two-photon microscopy using fast temporal multiplexing enabling 3D alignment between in vivo and ex vivo data for neuroscience and spatial biology applications.
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.
Researchers in the Molecular Imaging Instrumentation Laboratory at Stanford University have developed a PET (positron emission tomography) detector and front end readout assembly that can operate in a high field MRI (magnetic resonance imaging) system.
Researchers at Stanford have designed a new nanophotonic detector to reduce cost, size and power consumption compared to existing thermal infrared (IR) cameras.