Inventors and Patents From the City of Baton Rouge

Baton Rouge is home to several successful entrepreneurs, including those who have created revolutionary products. Recently, the city has witnessed the approval of seven patents. These include an PFKFB3 inhibitor, cancer homing peptides, nanoparticles, and syngas. Despite the success of Baton Rouge businesses, there are still many challenges associated with filing for patents.

PFKFB3 inhibitors

Recent studies have found that PFKFB3 inhibitors are effective against cancer cells. This inhibitor is related to glycolysis and autophagy, and is involved in regulating these processes. It may also be effective when used with autophagy inhibitors, but further research is necessary to confirm these results. In the meantime, however, there are several promising options for clinical use. Read on to learn more about the potential of PFKFB3 inhibitors.

PFKFB3 inhibitors are an important part of the treatment for solid tumors. PFK15 exhibits better pharmacokinetic properties than 3-PO, with a marked reduction in clearance and increased Cmax. Furthermore, this inhibitor suppresses tumor cell growth in Lewis lung cancer. It also inhibits caspase 3 cleavage. These results suggest that PFKFB3 inhibitors may have potential as therapeutic agents against P53-mutant tumor cells.

Another benefit of PFKFB3 inhibitors is the fact that they inhibit the production of ROS in tumor cells. This means that they can improve tumor cells’ responses to targeted cancer treatments and may even increase the chances of progression-free survival. This drug is also expected to decrease the risk of drug resistance. However, these treatments are not suitable for everyone, so further studies are needed to determine if it is a suitable treatment option.

PFKFB3 inhibitors are available over the counter or through a physician’s prescription. They target a particular enzyme that regulates the production of NADPH, a critical component of glycolysis. As a result, the inhibitors target this enzyme, inhibiting tumor growth and triggering cell apoptosis. These inhibitors are also effective in suppressing the growth of gastric cancer cells.

Cancer homing peptides

In March, nine patents were granted in the city, with the longest time between filing and grant being 1,890 days. One such patent was filed by Araicom Research, LLC on Dec. 27, 2016, and was approved on March 1, 2017. Although patents are necessary for inventions, they do not necessarily guarantee success. According to Dennis Crouch, co-director of the Center for Intellectual Property and Entrepreneurship, having a patent does not mean that an invention will be successful.


Inventors in Baton Rouge are proving that they can be a major force in the world of science. Their inventions are making lives better and creating jobs. As a result, the City of Baton Rouge is now a major hub for technology innovation. The state is home to more than a million people, and Baton Rouge is a hub for technology development. The city is also home to a large number of universities.


New technology for producing hydrogen and carbon dioxide from natural gas has led to the development of the syngas process. This new fuel type has a high H2/CO ratio, making it ideal for use in power plants and other energy applications. The process can be designed to maximize syngas production per mole of fossil fuel feedstock and to meet H2:CO ratio requirements for downstream processing. In some cases, a new combination of conditions results in a CO2 negative scheme, where the molar amount of CO2 entering the reactor is greater than the molar amount of CO2 leaving it.

This method uses a co-current moving bed reactor. This allows for higher syngas conversion rates, while reducing operating temperatures and allowing for more flexibility in the use of steam. The system produces hydrogen and carbon dioxide in a controlled atmosphere, with only a small amount of water and carbon monoxide remaining. In addition, it is suitable for use in Fischer-Tropsch synthesis and the production of liquid fuels.

A process for producing syngas requires an efficient process to separate halogens from methane. Alkali metals in syngas must be removed before it can be sent to gas turbines because they can cause deposition and corrosion issues. This system also requires a process that removes oxygen and carbon dioxide from natural gas. The process is very simple and does not require complex equipment, but it is effective and affordable.

The City of Baton Rouge is a hub for the development of biofuels, and many companies have been successful with the process. With the help of the innovative community of scientists and engineers, there are several companies in the region that have patented their innovations. One of these companies, Proton Power, has created a system that uses cellulose to generate syngas using a co-current flow of steam, hydrogen, and carbon. It produces a high yield of hydrogen and eliminates the need for drying the biomass before use.

Polymer that mimics the healing process of human skin

Researchers have developed a polymer that replicates the healing process of human skin to help heal wounds. The new material is made of several layers, much like the human skin. It also mimics the natural circulation in the body, making it a promising material for wound healing. This polymer may also extend the life of products. Here are some examples of applications of the material. These include artificial teeth, clothing, and medical devices.

Several types of materials can mimic the physical properties of human skin. These materials include hard solids, liquids, and polymers. By replicating these properties, researchers can better transfer knowledge to medical applications. These materials can also be customized to mimic specific physical properties of the skin. This will help in designing better materials and medical devices. But these new materials aren’t ready for the market just yet.

Although there is a demand for skin tissue grafts, the availability of a synthetic biopolymer is an attractive option. Researchers at Queensland University of Technology and Singapore’s Agency for Science, Technology, and Research are developing this material. This biomaterial will mimic the healing process of human skin and will improve wound healing and reduce the incidence of scarring. The application of this new material isn’t far away.

The structure of the synthetic elastomer is complex and difficult to fabricate. Until now, most works focused on the mechanical properties of the skin. But the researchers have also developed composites with nanofibers to mimic these mechanical properties. Nanofibers have increased the toughness of these composites without sacrificing their stretchability. But the problem is that the nanofibers do not interact with the matrix, which could result in instability during cyclic deformation.