Process modelling, simulation and technoeconomic optimisation for continuous pharmaceutical manufacturing of (S)-warfarin

Diab, Samir; Gerogiorgis, Dimitrios I.

doi:10.1016/b978-0-444-64235-6.50286-2

Cited by 7 publications

(8 citation statements)

References 14 publications

(13 reference statements)

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“…Implementation of combined experimental and modelling approaches towards integrated LLE design in the literature for pharmaceutical purifications and separations demonstrate the utility of theoretical methods in establishing optimal design and operating parameters (Drageset and Bjørsvik, 2016;Monbaliu et al, 2016;Weeranoppanant et al, 2017). Mathematical optimisation can be used to identify cost optimal process designs for pharmaceutical manufacturing campaigns (Gross and Roosen, 1998;Patrascu and Barton, 2018); plantwide modelling and optimisation with a focus on optimal continuous separation process design towards total cost minimisation have been implemented by our group for numerous APIs (Jolliffe and Gerogiorgis, 2017a,b;Diab and Gerogiorgis, 2018b). Elucidating cost-optimal designs for atropine CPM will further aid process development for this societally-important API.…”

Section: Figurementioning

confidence: 99%

Process modelling, design and technoeconomic Liquid–Liquid Extraction (LLE) optimisation for comparative evaluation of batch vs. continuous pharmaceutical manufacturing of atropine

Diab

Mytis

Boudouvis

et al. 2019

Computers & Chemical Engineering

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Continuous Pharmaceutical Manufacturing (CPM) can revolutionise industrial efficiency via potential operational and economic benefits over currently dominant batch methods. Process modelling and optimisation are valuable towards rapid design space evaluation and elucidation of optimal process design configurations, without expensive and time-consuming experimental campaigns. This paper pursues total cost minimisation via nonlinear optimisation of different separation design options for atropine, a product of great societal importance. The study considers a demonstrated continuous flow synthesis, presents reaction kinetic parameter estimation towards reactor design, and illustrates a comparative analysis of the subsequent batch vs. continuous Liquid-Liquid Extraction (LLE) for product purification, using published partition coefficient data and UNIFAC-modelled ternary liquidliquid equilibria. Original optimisation results show that toluene is the best continuous LLE solvent, attaining the lowest total costs at both plant capacities considered and the greatest total cost savings with respect to batch LLE design for varying solvent recovery, at acceptable material efficiencies.

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Section: Figurementioning

confidence: 99%

Process modelling, design and technoeconomic Liquid–Liquid Extraction (LLE) optimisation for comparative evaluation of batch vs. continuous pharmaceutical manufacturing of atropine

Diab

Mytis

Boudouvis

et al. 2019

Computers & Chemical Engineering

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“…Several candidate separation solvents are compared for continuous LLE: ethyl acetate (EtOAc), isopropyl acetate (iPrOAc) and isobutyl acetate (iBuOAc). The CPM flowsheet for warfarin is shown in Figure 14 [68]. The continuous synthesis of (S)-warfarin was demonstrated by Porta et al (2015), featuring the nucleophilic addition of 4-hydroxy-coumarin to benzalacetone in the presence of TFA and a chiral amine catalyst in 1,4-dioxane [67].…”

Section: Warfarinmentioning

confidence: 99%

Section: Warfarinmentioning

confidence: 99%

Design Space Identification and Visualization for Continuous Pharmaceutical Manufacturing

Diab¹,

Gerogiorgis²

2020

Pharmaceutics

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Progress in continuous flow chemistry over the past two decades has facilitated significant developments in the flow synthesis of a wide variety of Active Pharmaceutical Ingredients (APIs), the foundation of Continuous Pharmaceutical Manufacturing (CPM), which has gained interest for its potential to reduce material usage, energy and costs and the ability to access novel processing windows that would be otherwise hazardous if operated via traditional batch techniques. Design space investigation of manufacturing processes is a useful task in elucidating attainable regions of process performance and product quality attributes that can allow insight into process design and optimization prior to costly experimental campaigns and pilot plant studies. This study discusses recent demonstrations from the literature on design space investigation and visualization for continuous API production and highlights attainable regions of recoveries, material efficiencies, flowsheet complexity and cost components for upstream (reaction + separation) via modeling, simulation and nonlinear optimization, providing insight into optimal CPM operation.

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“…Warfarin (anticoagulant): one reaction followed by continuous LLE with EtOAc, isopropyl acetate (iPrOAc) or isobutyl acetate (iBuOAc) (Diab and Gerogiorgis, 2018).…”

Section: Upstream Plantwide Design Case Studiesmentioning

confidence: 99%

“…For ibuprofen, the different separation options (LLE solvent = {nHex, PhMe}) give similar results and thus the LLE solvent with the lower environmental/EHS impact (i.e., PhMe) is preferable (Jolliffe and Gerogiorgis, 2016). Similarly, for warfarin and atropine, each considered LLE solvent performs similarly, however, each also have similar EHS characteristics; solvent selection should thus be informed by subsequent crystallisation process design (Diab and Gerogiorgis, 2018;. For artemisinin and diphenhydramine, plantwide technoeconomic performance varies more drastically with separation solvent choice; for artemisinin, EtOH as antisolvent allows for lower costs and is more environmentally friendly that EtOAc (Jolliffe and Gerogiorgis, 2016), and for diphenhydramine, nHep has both poorer EHS characteristics than either CyHex or MeCyHex as well as incurring higher costs (Diab and Gerogiorgis, 2017).…”

Section: Separation Process Design Option Selectionmentioning

confidence: 99%

Design Space Investigation for Development of Continuous Flow Syntheses of Active Pharmaceutical Ingredients

Diab

Gerogiorgis

2020

Computer Aided Chemical Engineering

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Continuous flow chemistry and synthesis have received significant attention over the past two decades for their potential for enhancing yields, selectivities, productivities, smaller operation and implementation of otherwise difficult/dangerous reactions. Recent demonstrations applied to a variety of different reaction types have highlighted the potential for continuous manufacturing technologies for fine and speciality chemical production, including many critical Active Pharmaceutical Ingredients (APIs) but also many biopharmaceuticals and therapeutics. This study discusses recent demonstrations from the literature on design space elucidation for continuous API production and further highlights attainable regions of recoveries, material efficiencies, flowsheet complexity and cost components for upstream (reaction + separation) via modelling, simulation and nonlinear optimisation studies, providing insight into optimal regions of operation.

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Process modelling, simulation and technoeconomic optimisation for continuous pharmaceutical manufacturing of (S)-warfarin

Cited by 7 publications

References 14 publications

Process modelling, design and technoeconomic Liquid–Liquid Extraction (LLE) optimisation for comparative evaluation of batch vs. continuous pharmaceutical manufacturing of atropine

Process modelling, design and technoeconomic Liquid–Liquid Extraction (LLE) optimisation for comparative evaluation of batch vs. continuous pharmaceutical manufacturing of atropine

Design Space Identification and Visualization for Continuous Pharmaceutical Manufacturing

Design Space Investigation for Development of Continuous Flow Syntheses of Active Pharmaceutical Ingredients

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