Browse Technologies

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Adaptive PCR: A PCR control system to overcome challenging conditions

A PCR control system to overcome challenging conditions. By directly monitoring the hybridization of fluorescently labelled L-DNA mimics of the template DNA strands and primers, it is possible to improve the efficiency of PCR in challenging conditions. This approach eliminates some of the sample preparation and trial and error that would otherwise be required for difficult sample types such as urine or other samples that contain high levels of salts.  In addition, this approach enables on-demand PCR in most any environment.


Licensing Contact

Karen Rufus

615.322.4295
Research Reagent

Non-Invasive Skin Cancer Detection using Raman Spectroscopy-OCT System (Portfolio)

Vanderbilt University researchers have designed a system for non-invasive discrimination between normal and cancerous skin lesions. The system combines the depth-resolving capabilities of OCT technique with Raman Spectroscopy's specificity of molecular chemistry. By linking both imagining techniques into a single detector arm, the complexity, cost, and size of previously reported RS-OCT instruments have been significantly improved. The combined instrument is capable of acquiring data sets that allow for more thorough assessment of a sample than existing optical techniques.


Licensing Contact

Ashok Choudhury

615.322.2503

Systems and Methods for Optical Stimulation of Neural Tissues (Portfolio)

Vanderbilt researchers have developed a novel technique for contactless simulation of the central nervous system.  This involves the use of infrared neural stimulation (INS) to evoke the observable action potentials from neurons of the central nervous system.  While infrared neural stimulation of the peripheral nervous system was accomplished almost a decade ago, this is the first technique for infrared stimulation of the central nervous system. This technology has been protected by a portfolio of issued patents.


Licensing Contact

Ashok Choudhury

615.322.2503

Point of Care Rheological Assay for Sickle Cell Disease

Vanderbilt researchers have created a novel technology for the diagnosis and monitoring of disease states using the rheological properties of a blood sample with a lateral flow membrane.


Licensing Contact

Ashok Choudhury

615.322.2503

Organ-on-a-Chip System

Vanderbilt researchers have developed a group of microfluidic organ-on-chip devices that include perfusion controllers, microclinical analyzers, microformulators, and integrated microfluidic measurement chips. Together, these devices can measure and control multiple organ-on-chip systems in order to model the multi-organ physiology of humans.


Licensing Contact

Ashok Choudhury

615.322.2503
Microfluidics

Trackerless Image-Guidance Using a Surgical Microscope

Researchers at Vanderbilt have developed a new image-guided, trackerless surgical microscope system to be used in soft tissue surgeries. The current method is to use a surgical microscope along with an image-guided system. This new design eliminates the need for a separate image-guidance system; the entire guidance environment can be realized within the microscope environment.


Licensing Contact

Philip Swaney

615.322.1067

Inventors

Michael Miga

I-Wire: A Biotension Measurement Device for Tissue Engineering and Pharmacology

Vanderbilt researchers have developed an integrated system ("I-Wire") for the growth of miniature, engineered 3D cardiac or other muscle or connective tissues and their active and passive mechanical characterization. The system utilizes an inverted microscope to measure the strain when the tissue constructs are laterally displaced using a calibrated flexible cantilevered probe.


Licensing Contact

Ashok Choudhury

615.322.2503

PosiSeat(TM): Assured Seating of Threaded Surgical Components

Vanderbilt presents an intraoperative device for taking the guesswork out of whether or not a threaded component is securely affixed to bone. This device is an anchor driver that automatically releases upon proper seating of the anchor on the bone of interest.


Licensing Contact

Taylor Jordan

615.936.7505

Portfolio of Image-Guidance and Organ Localization Technologies from the Lab of Professor Michael Miga

The focus of Dr. Miga's laboratory is on the development of new paradigms in detection, diagnosis, characterization, and treatment of disease through the integration of computational models into research and clinical practice.


Licensing Contact

Philip Swaney

615.322.1067

Image Guidance System for Breast Cancer Surgery

Vanderbilt researchers have developed an image guidance system that aims to reduce the revision rate for breast conserving surgeries through the use of intraoperative tumor location. The platform integrates MRI imaging, optical tracking, tracked ultrasound, and patient specific biomechanical models to provide a superior tumor localization end result.


Licensing Contact

Philip Swaney

615.322.1067