Browse Technologies

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Surface Active Ionic Liquid with Activity in Aqueous and Non-aqueous Media

Surface active ionic liquids (SAILs) exhibit extraordinary properties both as solvents and superior surfactants. However, existing SAILs have limitations that prevent their full potential from being realized. To address this, researchers at Vanderbilt have synthesized a promising chiral SAIL that can be used as a detergent or stabilizing agent at all kinds of interfaces and is made from an inexpensive and biodegradable starting material.


Licensing Contact

Masood Machingal

615.343.3548

Inexpensive Disposable Hydro-Jet Capsule Robot for Gastric Cancer Screening in Low-Income Countries

Gastric cancer is the second leading cause of cancer death worldwide. While screening programs have had a tremendous impact on reducing mortality, the majority of cases occur in low and middle-income countries (LMIC). Typically, screening for gastric and esophageal cancer is performed using a flexible endoscope; however, endoscopy resources for these settings are traditionally limited. With the development of an inexpensive, disposable system by Vanderbilt researchers, gastroscopy and colonoscopy can be facilitated in areas hampered by a lack of access to the appropriate means.


Licensing Contact

Masood Machingal

615.343.3548

Targeted light-based therapy for acne

Vanderbilt researchers have developed a photodynamic therapy (PDT) for effectively and specifically treating acne, the most common skin condition.


Licensing Contact

Cameron Sargent

615.322.5907
Therapeutics
Small Molecule

A Method to Obtain Uniform Radio Frequency Fields in the Body for High Field MRI

Researchers at Vanderbilt have created a new approach to produce uniform radio frequency (RF) fields in the body during high field magnetic resonance imaging (MRI). Existing high field MRI machines create non-uniform RF fields that lead to non-uniform sensitivity in the generated images, also referred to as "hot" and "cold" spots. These local variations interfere with the tissue contrast of the images that radiologists depend upon to make accurate diagnoses. By generating uniform RF fields in the body, this technology provides the benefits of high field MRI without the non-uniform RF fields.


Licensing Contact

Chris Harris

615.343.4433
Medical Imaging

Cell-Permeable Socs Proteins That Inhibit Cytokine-Induced Signaling

Scientists at Vanderbilt have developed a unique polypeptide using cell-penetrating SOCS polypeptides or SOCS sequences designed to inhibits cytokine signaling and thus prevent or treat inflammation or an inflammatory related disease such as diabetes. This strategy has been validated in NOD mice models for either induced or naturally occurring diabetes and have been efficacious.


Licensing Contact

Mike Villalobos

615.322.6751
Therapeutics

Protein that protects probiotics from desiccation, leading to improved gut colonization

Probiotic supplements undergo significant water loss before consumption, killing many of their bacteria and rendering them less effective. Vanderbilt researchers have discovered a protein that protects against damage caused by desiccation and shown that this molecular shield can be added to probiotics to help them survive and colonize the gut. This platform technology can be broadly incorporated into new or existing supplements to make them more efficacious and even improve costs and distribution.


Licensing Contact

Karen Rufus

615.322.4295

Inventors

Eric Skaar, Erin Green
Therapeutics

Early Detection of Implant Loosening

Vanderbilt University researchers have developed a new technique for identifying implantloosening. The technique utilizes the analysis of synovial fluid as an early indicator of potential loosening of orthopedic implants.


Licensing Contact

Ashok Choudhury

615.322.2503

Nanoporous Atomically Thin Breathable Personal Protective Membranes

Vanderbilt researchers have developed an atomically thin membrane with extremely high selectivity and permeability for use in personal protective equipment.


Licensing Contact

Philip Swaney

615.322.1067

Nanoporous Atomically Thin Graphene Membranes for Desalination & Nanofiltration

Vanderbilt researchers have developed an atomically thin membrane with extremely high selectivity and permeability for use in desalination and nanofiltration applications.


Licensing Contact

Philip Swaney

615.322.1067

A Novel Organs-On-Chip Platform

Vanderbilt researchers have created a new multi-organs-on-chip platform that comprises Perfusion Control systems, MicroFormulators, and MicroClinical Analyzers connected via fluidic networks. The real-time combination of multiple different solutions to create customized perfusion media and the analysis of the effluents from each well are both controlled by the intelligent use of a computer-operated system of pumps and valves. This permits, for the first time, a compact, low-cost system for creating a time-dependent drug dosage profile in a tissue system inside each well.


Licensing Contact

Ashok Choudhury

615.322.2503