Browse Technologies

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Vanderbilt researchers have developed a breast implant device that minimizes potential contaminants during surgery by requiring no contact between the surgeon and the implant during insertion.

Vanderbilt researcher, Lisa Lancaster, MD, has developed a novel device to monitor the flow as well as adjust actively the levels of oxygen that pass to a patient suffering from Idiopathic Pulmonary Fibrosis or other causes of hypoxic lung disease. Standing out of the pack, this device ensures that patients exerting themselves are given enough oxygen while actively reducing the dosage, to prevent further damage, when the same patient is resting.

A research team at Vanderbilt University Mass Spectrometry Research Center has developed the Molecular Image Fusion software system, that by fusing spatial correspondence between histology and imaging mass spectrometry (IMS) measurements and cross-modality modeling, can predict ion distributions in tissue at spatial resolutions that exceed their acquisition resolution. The prediction resolution can even exceed the highest spatial resolution at which IMS can be physically measured. This software has been successfully tested on different IMS datasets and can be extended to other imaging modalities like MRI, PET, CT, profilometry, ion mobility spectroscopy, and different forms of microscopy.

The standard for kidney stone detection is through the use of computed tomography (CT). However, CT is expensive and delivers harmful ionizing radiation into the body. Ultrasound would be the ideal way to detect kidney stones except that it performs poorly in detecting and accurately sizing stones. Vanderbilt researchers inventors have developed a technique that is able to separate hard, mineralized material (i.e kidney stones) from soft tissue in a way that is both cheaper and safer than CT and performs better than conventional ultrasound imaging.