A method for mapping field inhomogeneity for forming a magnetic resonance image is provided. A magnetic resonance excitation is applied. A plurality of k-space echoes signals is acquired.
A method for creating a magnetic resonance image of an object with at least a first species and a second species, wherein the first species has a first T.sub.2 time and the second species has a second T.sub.2 time longer than the first T.sub.2 time is provided.
A method of performing magnetic resonance imaging is provided. Sampling requirements are used to define a three dimensional cone trajectory differential equation. The equation is solved to obtain a starting point.
A method for enhancing resolution and contrast in an MRI image is provided. A transient signal acquisition is applied to acquire a plurality of samples of data, comprising reducing transient signal oscillations and acquiring a plurality of MRI samples of data.
The Light Field Microscopy (“LFM”) is a patented system that enables rapid acquisition of images to be virtually analyzed at any time in the future from different viewpoints or focus adjustments.
This patented, automated data analytics tool sorts and analyzes large data sets by identifying and creating clusters of data. The algorithm intakes data and then groups them into clusters, groupings, or populations of data.
Researchers from Prof. Annelise Barron's laboratory have developed a novel method for purifying large, biologically produced protein polymers for DNA sequencing and genotyping.
Stanford researchers have further developed a new technique for magnetic resonance imaging (MRI). The technique called hyperpolarized carbon-13 MRI dramatically increases the sensitivity for molecular processes.
Engineers in Prof. Butrus Khuri-Yakub's laboratory have developed a patented, simple, cost efficient, CMUT (capacitive micromachined ultrasonic transducers) fabrication process with incomparable precision and performance.