Company Filing History:
3 out of 207 
2 out of 3,446 
Years Active: 1985-2006
Title: David J Newman: Innovator in Water-Soluble Drug Development
Introduction
David J Newman is a notable inventor based in Wayne, PA (US), recognized for his contributions to the field of pharmaceuticals, particularly in the development of water-soluble drugs. With a total of five patents to his name, Newman has made significant strides in enhancing the solubility of traditionally water-insoluble drugs, which can lead to improved therapeutic outcomes.
Latest Patents
Newman's latest patents focus on water-soluble drugs and methods for their production. One of his key inventions relates to a water-soluble analogue of geldanamycin. This invention outlines a method for producing water-soluble analogues of water-insoluble drugs through derivatization and conjugation with a polar moiety via a thiol ether bond with a heterobifunctional linking molecule. Another patent emphasizes the provision of water-soluble drugs, particularly water-soluble analogues of geldanamycin, and the methods to render these drugs soluble in water through derivatization with a bifunctional linking molecule and subsequent conjugation to a polar moiety through a thio ether. Additionally, this invention provides a method for treating cancer in mammals.
Career Highlights
Throughout his career, David J Newman has worked with prominent organizations such as SmithKline Beecham Corporation and the National Institutes of Health, which is a component of the US Department of Health & Human Services. His work in these institutions has allowed him to contribute to significant advancements in drug development and research.
Collaborations
Newman has collaborated with esteemed colleagues, including Betty A Bowie and Marcia C Shearer, which has further enriched his research and innovation efforts.
Conclusion
David J Newman stands out as an influential inventor in the pharmaceutical industry, particularly in the realm of water-soluble drugs. His innovative approaches and collaborations have the potential to significantly impact cancer treatment and drug solubility.