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Nanostar Sieving for Exact Polymer Synthesis

Nanostar Sieving: Revolutionizing Polymer Synthesis with Precision

Created byAIChE
BeginnerUpdated Feb 16, 2025
Nanostar Sieving for Exact Polymer Synthesis

What You'll Learn

check_circleUnderstand Polymer Synthesis Challenges: Identify the challenges involved in creating exact polymers with precisely defined monomer sequences
check_circleAnalyze Current Industrial Approaches: Compare and contrast controlled polymerization and iterative synthesis for polymer production
check_circleExplore Nanostar Sieving Technology: Explain the principles and advantages of using Nanostar Sieving to synthesize exact polymer structures
check_circleEvaluate Membrane Applications: Investigate the use of organic solvent-stable membranes to separate polymer chains from molecular debris in solution
check_circleApply Precision PEGylation: Understand the process for producing high-purity polyethylene glycols (PEGs) for medical applications like antibody-drug conjugates (ADCs)
check_circleAssess Scale-Up Potential: Discuss the potential for scaling Nanostar Sieving technology to industrial levels for peptide and oligonucleotide synthesis

About This Course

Creating exact polymers with precisely defined monomer sequences is a technology challenge especially important in drug manufacture, where purity and consistency are prized. State-of-the-art industrial solutions are based on two approaches, controlled polymerization (mainly for synthetic polymers), and iterative synthesis (for biopolymers, including peptides, oligonucleotides). When the exact sequence of monomers is crucial, as it is for the burgeoning number of oligonucleotide therapies, iterative synthesis dominates commercial manufacture. There is at present no general approach for exact synthetic polymers such as polyethylene glycols, used for PEGylation and in antibody drug conjugate (ADC) linkers.

Iterative protecting group approaches use coupling/deprotecting cycles in which monomers are added one-at-a-time. Separation of unreacted monomers from the growing polymer at each cycle is the crucial, and hardest, step. Solid phase synthesis has been applied to biopolymers including oligonucleotides and is the dominant technology at present. The attachment of the growing oligo to the solid phase solves the problem of effective separation of molecular debris during the coupling cycle. However, it is difficult to monitor the reaction progress, mass transfer resistances inside the resin make achieving complete reactions difficult, and when it’s time to increase capacity, numbering out of synthesizers or scale up of packed beds is required.

This presentation will describe how highly stable membranes can be applied to solve the separation challenge inherent in iterative synthesis. Polymers are assembled in solution with real-time monitoring to ensure couplings proceed to completion, on a multi-armed star-shaped macromolecule to maximize efficiency during the molecular sieving process. The key to the nanostar sieving process is the separation of the growing polymer star from chain extension building blocks and debris, using a highly selective organic solvent stable membrane. At the completion of the synthesis, the polymers are cleaved from the nanostar complex and recovered.

The synthesis of uniform molecular weight polyethylene glycols (PEGs), which are single mass / unimolecular (EG112 (5kDa) with more than 96% molecular purity) will be described. These can be used for accurate PEGylation of medicines. Sequence-defined versions of PEGS with side-arms at precisely defined locations that can undergo site-selective modification after polymerization can offer utility as linkers and multifunctional carrier molecules, and will also be described.

Nanostar Sieving can also be applied for liquid phase peptide and oligo synthesis. A soluble nanostar is formed with three growing oligos attached. This is readily separated from molecular debris after each coupling using a nanofiltration membrane. The coupling cycles are carried out entirely in the liquid phase. The synthesis of (i) a 2'-methyl RNA phosphorothioate 20 mer sequence using this approach at the 1-2 mmol scale will be discussed, as well as the potential for scale up to metric ton per annum scale. Nanostar Sieving will also be directly compared to Solid Phase Synthesis via the formation of a short 8 amino-acid peptide.

Your Instructors

AIChE
AIChE

The Global Home of Chemical Engineers

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At every stage of your career, AIChE Academy is the definitive resource engineers use to sharpen their professional skills. We offer up-to-date courses and webinars in chemical engineering, process and hydrogen safety, bioengineering, sustainability, professional development, and many more.

Andrew Livingston
Andrew Livingston

Leader in Membrane Technology, Molecular Separations, and Precision Polymer Manufacturing

Andrew Livingston studied Chemical Engineering and then worked at an NZ food processing company followed by a PhD at Cambridge UK, and in 1990 joined the Department of Chemical Engineering at Imperial College, serving as Head of Department 2008-2016. From June 2017-May 2019 he was the interim academic lead, the interim Director, of the Rosalind Franklin Institute based at Harwell, UK, and from 1 November 2019 he has been the Vice Principal, Research and Innovation at Queen Mary, University of London. He leads a research group with interests in membranes for molecular separations in liquids and the development of chemical processes using these membranes. The specialist platform pioneered by the Livingston Group has been membranes which are stable in organic liquids and so which can be applied in organic solvent systems. These have led to new chemical manufacturing processes, including Nanostar Sieving, used to make a range of exact biological (Peptides, Oligonucleotides) and synthetic (PEGS) apolymers. Awards include the Junior Moulton Medal, Cremer and Warner Medal, and Underwood Medal of IChemE, and Silver Medal of Royal Academy of Engineering. AGL was elected a Fellow of the Royal Academy of Engineering in 2006. In 1996, AGL founded Membrane Extraction Technology, a start-up which developed solvent stable Organic Solvent Nanofiltration (OSN) membranes was acquired by Evonik Industries of Essen, Germany. In 2018 AGL founded Exactmer, a new start-up dedicated to the production of exact polymer molecules including oligonucleotides, peptides and synthetic polymers such as PEG, using Nanostar Sieving technology.

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