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New production tools for current and future pharmaceuticals

Explore cutting-edge organic reagents developed by Assistant Professor Gregory B. Dudley at Florida State University. Learn how these tools revolutionize pharmaceutical production with aims to bring new products to market and establish new industry standards. Discover the impact on drug synthesis efficiency and explore the potential market value. Benefit from specialized reagents like PMBO-L and benzyl-OPT designed for complex chemical reactions. Join the future of pharmaceutical research with Dudley Lab's groundbreaking technology.

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New production tools for current and future pharmaceuticals

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  1. New production tools for current and future pharmaceuticals Organic Reagents Gregory B. Dudley Assistant Professor Florida State University Aim 1: Bring a new product from the Dudley lab to the market Aim 2: Create a new market for a Dudley lab product line FSURF meeting February 14, 2008

  2. What is an Organic Reagent? • A reagent is a “fine chemical” designed to achieve a specific chemical reaction • produced from petroleum commodity chemicals • market value of reagents exceeds $6 billion/year • Who buys organic reagents? • pharmaceutical industry ($600 billion/year in sales) • chemical research companies (Dow, DuPont, GE, etc.) • academic organic chemistry labs (ca. 1000 nationwide) • private research institutes (e.g., Scripps, Sloan–Kettering) • The Dudley lab reagents are tools for making drugs • benzyl reagent (on the market, Aim 1) • PMB reagent (market identified, Aim 1) • PSB reagents (new innovation, Aim 2)

  3. Production tools for chemical synthesis: Specialized organic reagents • Problem: The increasing complexity of commercially relevant target molecules is outpacing the development of new organic synthesis technology • Result: Synthetic routes become longer, more elaborate, and more expensive • Solution: Develop specialized organic reagents

  4. • similar or greater activity as compared to imidate • stable to storage • suitable for outsourcing • unsuitable for prolonged storage • prepared at Novartis (not outsourced) “all discodermolide… has been supplied by total synthesis” Specialized organic reagents in major commercial ventures: discodermolide (By this process, 100 kg/year of discodermolide would require more than 100,000 kg/year of PMB reagent) Process synthesis of discodermolide (Novartis):Org. Proc. Res. Dev.2004, 8, 92–130

  5. Aim 1: Bring PMBO–L from the Dudley Lab to the market • Why: • Meet growing market demand for specialized organic reagents • Eliminate barriers to the use of Dudley lab technology: get this tool into the hands of the drug makers • How: • Demonstrate advantages of Dudley reagents over current technology • Benzyl–OPT (on market now) • PMBO–L (under development) • Develop manufacturing processes for preparing the PMBO–L reagent • Analyze costs / identify alternatives “The PMBO-lepidine protecting procedure worked great for us. Other conditions weren’t feasible for our substrate” – Prof Steve Castle, BYU

  6. Aim 2: Create new markets for Dudley PSB technology • Why: • Unique market means no competition • Carbohydrate synthesis • Drug delivery polymers • Carbosilane materials • How: • Show the para-siletanylbenzyl (PSB) group doing things that nothing else can • Cleave using hydrogen peroxide (published) • Provide polymer support on demand • Collaborate on new carbosilane materials • Design a suitable PSB transfer reagent • Develop a PSB manufacturing process “if [a PSB reagent] were commercially available my research group would be ordering it” – anonymous peer review comment

  7. laulimalide discodermolide eleutherobin Leading Taxol-like drug candidates • Microtubule-stabilizing agents • Active against Taxol-resistant tumors • In clinical / preclinical development • Each and every one prepared through synthesis using PMB technology

  8. Acknowledgments • Contributing scientists • postdoctoral researchers • Hubert Lam, Kevin Poon, and Philip Albiniak • graduate students • Ernest Nwoye and Sami Fahd Tlais • undergraduate students • Jim Sunderhaus, Sarah House, and Cece O’Leary • Sigma–Aldrich Chemical Company • Nate Wallock • Florida State University GAP Committee • Jack Sams, Larry Lynch, Gus Ray, Eric McNair

  9. New production tools for current and future pharmaceuticals Organic Reagents Gregory B. Dudley Assistant Professor Florida State University Aim 1: Bring a new product from the Dudley lab to the market Aim 2: Create a new market for a Dudley lab product line FSURF meeting February 14, 2008

  10. GAP funding: activities to be completed within first year • Pave the way for new PMB reagent • Dudley benzyl and PMB technology surpass the capabilities of current methods • strong sales of current Dudley reagent (benzyl–OPT) will create a greater opening market for a PMB reagent • Market PMBO-L and/or PMBO-Q • lepidine-based PMBO-L is marketable but expensive • quinoline-based PMBO-Q would be more affordable • PMB and benzyl reagents impact major pharmaceutical discovery and manufacturing • Develop Dudley lab PSB reagents • create and control a new market

  11. Aim 1a: Use benzyl–OPT to pave the way for PMB reagent • Why: • Benzyl–OPT is the “parent” or “prototype” • skilled practitioners will infer reactivity of PMBO-L based on benzyl–OPT studies • new applications will increase sales of benzyl–OPT • Brought to market on the strength of one synthetic application: • alcohol  alkyl benzyl ether (published) • “benzyl bromide and… benzyl 2,2,2-trichloro[acet]imidate failed. The best results were reached with 2-benzyloxy-1-methylpyridinium triflate” – Langlois et. al. • How: • Demonstrate advantages over current technology • phenol  aryl benzyl ether • carboxylic acid  benzyl ester (published) • thiol  alkyl benzyl sulfide • amine  benzyl amine • Demonstrate unparalleled, high impact reactivity • ketone  benzyl enol ether • self-quenching Friedel–Crafts reactions (published) • self-controlled Ritter reactions

  12. Current manufacturing process for benzyl–OPT • Crude relative cost analysis of current routes • Sigma–Aldrich list prices • Bulk prices probably much lower in all cases Even at 25-times the price of the established product… “we have been very pleased with the year-to-date sales performance of this new product” – Dr. Nate Wallock, Sigma–Aldrich

  13. Aim 1b: Develop synthetic route for the manufacturing of PMBO-L • Crude relative cost analysis of current routes • Sigma–Aldrich list prices • Bulk prices probably much lower in all cases

  14. Aim 1b: Develop synthetic route for the manufacturing of PMBO-Q (new reagent?) • Prepare and examine alternative quinoline-based reagent • translate lepidine success into quinoline system • Compare quinoline- and lepidine- based reagents • chlorolepidine (original choice) cheaper than chloroquinoline • quinoline / oxidant combination would be ideal

  15. Aim 2: Create new markets for Dudley PSB technology • Problem: Standard approach to OPT reagents incompatible with siletane • Progress: Modified approach successful, but requires expensive siletane • Solution: Combine siletane synthesis with PSB assembly into a one-step manufacturing process “if [a PSB reagent] were commercially available my research group would be ordering it” – anonymous peer review comment

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