Shining a Light on the Advances, Challenges and Realisation of Utilising Photoredox Catalysis in Pharmaceutical Development

Callard‐Langdon, Emily E.; Steven, Alan; Kahan, Rachel J.

doi:10.1002/cctc.202300537

Cited by 7 publications

(5 citation statements)

References 95 publications

(85 reference statements)

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“…The literature of the last 100 years discusses the issues with photochemistry and how to overcome them, highlighting merits of both batch and flow reactors. ,− With the advent of the publication of “A Practical Flow Reactor for Continuous Organic Photochemistry” by Booker-Milburn and Berry in 2005 coupled with widely available nearly monochromatic light sources in the 310–800 nm range, i.e., light emitting diodes (LEDs), − this has transformed photochemistry from a seldom-used bond-forming strategy into an innovative technology . Recently, Bonfield et al (2020), Cohen et al (2023), and Callard-Langdon et al (2023) discussed scaling photochemistry in the pharmaceutical industry. With significant advances in scaling up photochemical reactions, we expect that more pharmaceutical companies will bring more types of reactions into their process development groups in the future.…”

Section: Resultsmentioning

confidence: 99%

“…Cross coupling reactions (20%, three examples) and halogenation (27%, four examples) still account for approximately 50% of transformations. However, a greater proportion of halogenation reactions ,,, have been scaled compared to cross couplings. − Next are trifluoromethylations, cycloadditions, , and isomerization (14% each, two examples each), and finally rearrangements and HAT reactions (7% each, one example each).…”

Section: Resultsmentioning

confidence: 99%

“…However, a greater proportion of halogenation reactions 15,26,74,75 have been scaled compared to cross couplings. 76−78 Next are trifluoromethylations, 79 cycloadditions, 80,81 and isomerization 73 (14% each, two examples each), and finally rearrangements and HAT reactions 80 (7% each, one example each).…”

Section: Lack Of Knowledge Of How To Scale Photochemistrymentioning

confidence: 99%

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Photochemistry in Pharmaceutical Development: A Survey of Strategies and Approaches to Industry-wide Implementation

Moschetta,

Cook,

Edwards

et al. 2024

Org. Process Res. Dev.

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We present and analyze the results of a pharmaceutical industry-wide survey of the strategies and approaches that companies have for implementing photochemical reactions in discovery chemistry, process development, and commercial manufacturing. The survey questions encompass the types of photochemical reactions that pharmaceutical companies pursue and why, the types of reactors (batch and flow) used, how they are characterized for photochemistry, scale-up of photochemical reactions, and how companies prioritize resources for developing photochemical reactions, among other topics. The survey focuses on many of these topics from the perspectives of discovery chemists and process scientists to highlight similarities and differences between their approaches on the specific photochemical transformations and materials of construction used in photochemical reactors. The survey results clearly demonstrate that photochemistry is a viable synthetic strategy for producing active pharmaceutical ingredients (APIs), from discovery all the way to commercialization. While photochemistry is more prevalent for discovery and early stage process development, the survey results indicate that more companies are leveraging photochemistry in successful scale-ups in later stages of process development, often using flow chemistry, and have significant knowledge resulting from these experiences. Nevertheless, there still are gaps to adopting photochemical reactions across stages of development and companies have very limited experience discussing photochemistry with regulatory agencies. Overall, the survey results demonstrate that photochemistry offers considerable benefits for synthesizing APIs and developing API processes, such as greenness and sustainability, shortening synthetic routes, and potential for improved product quality.

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Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

Section: Lack Of Knowledge Of How To Scale Photochemistrymentioning

confidence: 99%

See 1 more Smart Citation

Photochemistry in Pharmaceutical Development: A Survey of Strategies and Approaches to Industry-wide Implementation

Moschetta,

Cook,

Edwards

et al. 2024

Org. Process Res. Dev.

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“…In 2005, a landmark publication from Booker-Milburn and Berry (GSK) et al described a photochemical plug flow reactor (PFR) using readily available fluorinated ethylene propylene (FEP) tubing and mercury broad-spectrum lamps and subsequently sparked a renaissance in photochemistry . Coupled with the advent of cheaper monochromatic light sources, i.e., light emitting diodes (LEDs), there has been an explosion in new chemical transformations reported in the literature, from both academia and the pharmaceutical industry. − As these new transformations are implemented into the construction of active pharmaceutical ingredients (APIs), a perennial question arises: how do you scale photochemical transformations? Continuous flow chemistry has received much attention for scaling photochemistry due to the increased surface area to volume ratio which satisfies issues around the penetration of light (Beer–Lambert law) and the intensity of light (Bunsen–Roscoe law). , As intimated above, there are added complexities to reactor design for photochemistry, and both light penetration and the use of heterogeneous catalysis remain unresolved issues when designing reactors. In recent years, different types of reactors have been described in the literature as a solution to performing photochemistry on scale. − These reactors tend to follow a PFR design (Figure a), although the design of immersive modular photoreactors with static mixing has recently been reported to increase mass transfer in the system .…”

Section: Introductionmentioning

confidence: 99%

“…7−11 As these new transformations are implemented into the construction of active pharmaceutical ingredients (APIs), a perennial question arises: how do you scale photochemical transformations? 12 Continuous flow chemistry has received much attention for scaling photochemistry due to the increased surface area to volume ratio which satisfies issues around the penetration of light (Beer−Lambert law) and the intensity of light (Bunsen−Roscoe law). 13,14 As intimated above, there are added complexities to reactor design for photochemistry, and both light penetration and the use of heterogeneous catalysis remain unresolved issues when design-ing reactors.…”

Section: ■ Introductionmentioning

confidence: 99%

Development of a Horizontal Dynamically Mixed Flow Reactor for Laboratory Scale-Up of Photochemical Wohl–Ziegler Bromination

Pratley,

Shaalan,

Boulton

et al. 2023

Org. Process Res. Dev.

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Flow reactors with enhanced mixing are of interest to the pharmaceutical industry for a range of photochemical applications. Taylor−Couette (vortex, dynamically mixed) reactors have been reported to have intensified mixing and have been used with heterogeneous systems. Our photochemical workflow has previously been demonstrated for the development of a photochemical Wohl−Ziegler process and scale-up in flow using a plug flow reactor (PFR). In this work, a 20 mL dynamically mixed Autichem, Ltd. prototype photochemical DART reactor (Taylor−Couette reactor) was paired with four custom Kessil PR160L 400 nm lamps. The reactor was evaluated as a 500 g scale-up option for the bromination of ethyl 4-methylbenzoate. Herein we describe our workflow moving from a Pacer International Photochemistry LED Illuminator (HTS system) to the photochemical DART reactor in the scale-up of the synthesis of ethyl 4-(bromomethyl)benzoate via a radical bromination process.

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Vitamin B₁₂ in Photocatalysis – An Underexplored Frontier in Cooperative Catalysis

Moser,

Funk,

West

2024

ChemCatChem

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Vitamin B12 (VB12) is a flexible and sustainable catalyst both in nature and the reaction flask, facilitating varied organic transformations of high value to both enzymatic processes and synthetic chemists. Key to this value is the breadth of reactivity it possesses, capable of both ionic, 2 electron chemistry, and radical, 1 electron chemistry. In particular, the ability to generate carbon‐centered radical intermediates via photolysis of organocobalt intermediates formed from alkyl electrophiles opens the door to powerful new radical transformations challenging to achieve using classical photoredox or ligand‐to‐metal charge transfer (LMCT) catalysis. While this unique photocatalytic reactivity of VB12 has been increasingly leveraged in monocatalytic schemes, recent reports have demonstrated VB12 is able to function as a powerful photocatalyst in cooperative schemes, driving diverse reactivity including remote elimination of alkyl halides, regioselective epoxide arylation, and regioselective epoxide reduction. This concept briefly overviews the enabling properties of VB12 as a photocatalyst and recent applications in cooperative catalysis, providing a framework for the continued development of new cooperative catalyst systems using this powerful photoactive complex.

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Shining a Light on the Advances, Challenges and Realisation of Utilising Photoredox Catalysis in Pharmaceutical Development

Cited by 7 publications

References 95 publications

Photochemistry in Pharmaceutical Development: A Survey of Strategies and Approaches to Industry-wide Implementation

Photochemistry in Pharmaceutical Development: A Survey of Strategies and Approaches to Industry-wide Implementation

Development of a Horizontal Dynamically Mixed Flow Reactor for Laboratory Scale-Up of Photochemical Wohl–Ziegler Bromination

Vitamin B₁₂ in Photocatalysis – An Underexplored Frontier in Cooperative Catalysis

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Shining a Light on the Advances, Challenges and Realisation of Utilising Photoredox Catalysis in Pharmaceutical Development

Cited by 7 publications

References 95 publications

Photochemistry in Pharmaceutical Development: A Survey of Strategies and Approaches to Industry-wide Implementation

Photochemistry in Pharmaceutical Development: A Survey of Strategies and Approaches to Industry-wide Implementation

Development of a Horizontal Dynamically Mixed Flow Reactor for Laboratory Scale-Up of Photochemical Wohl–Ziegler Bromination

Vitamin B12 in Photocatalysis – An Underexplored Frontier in Cooperative Catalysis

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Product

Resources

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Vitamin B₁₂ in Photocatalysis – An Underexplored Frontier in Cooperative Catalysis