Company Filing History:
Years Active: 2016
Title: Martyna Ciezkowska: Innovator in Microbial Biotechnology
Introduction
Martyna Ciezkowska is a prominent inventor based in Minsk Mazowiecki, Poland. She has made significant contributions to the field of microbial biotechnology, particularly in the areas of cellulose hydrolysis and arsenic contamination remediation. With two patents to her name, her work is paving the way for innovative solutions in environmental sustainability.
Latest Patents
Ciezkowska's latest patents include a consortium and preparation of microorganisms for catalyzing cellulose hydrolysis. This invention focuses on a consortium of microorganisms capable of hydrolyzing cellulose, particularly from lignocellulosic biomass. The patent details various mixtures of bacterial strains, including KP7, KP20, KP8, and others, which are deposited in the Polish Collection of Microorganisms.
Another significant patent involves the development of novel bacterial strains capable of chemolithotrophic arsenite oxidation. This invention provides new strains, KKP 2039p and KKP 2040p, along with the plasmid pSinA and its functional derivatives. The method for producing these bacterial strains is also outlined, along with their application in bioaugmentation for arsenic-contaminated environments, particularly for the removal of arsenic from water sources.
Career Highlights
Martyna Ciezkowska is affiliated with the University of Warsaw, where she conducts her research and development activities. Her academic background and research focus have positioned her as a key figure in the field of microbial biotechnology.
Collaborations
Ciezkowska collaborates with notable colleagues, including Lukasz Drewniak and Aleksandra Sklodowska. Their combined expertise enhances the research output and innovation potential within their projects.
Conclusion
Martyna Ciezkowska is an influential inventor whose work in microbial biotechnology is contributing to advancements in environmental sustainability. Her patents reflect her commitment to addressing critical challenges in cellulose hydrolysis and arsenic contamination.