Lars Gössl, Kai Dahms, Gabriele Menges-Flanagan, Michael Maskos
{"title":"有机锌试剂:各种浓度和反应类型下的高效可扩展连续转化","authors":"Lars Gössl, Kai Dahms, Gabriele Menges-Flanagan, Michael Maskos","doi":"10.1021/acs.oprd.4c00292","DOIUrl":null,"url":null,"abstract":"Organometallic reagents play a crucial role in today’s synthetic chemistry. They are used in the production of active pharmaceutical ingredients (APIs), fragrances, and agrochemicals, among other things, as they are instrumental and invaluable to form new carbon–carbon bonds. In addition to the widely used organolithium and organomagnesium compounds, better known as Grignard reagents, organozinc compounds are predestined coupling partners in C–C bond formation. Even though organozinc compounds are among the oldest organometallic compounds, they have long been superseded by the more reactive Grignard reagents (RMgX) and lithium organyls (RLi). The low reactivity of organozinc compounds in combination with a high sensitivity to oxygen and moisture lead to difficult handling and problematic storage. Their usefulness for C–C bond formation was therefore underestimated for a long time but has experienced a renaissance in recent decades. In a previous publication, the scalable continuous synthesis of organozinc compounds in different concentrations and solvents was demonstrated. The organozinc compounds were produced in both laboratory and pilot scale with good to very good yields and the formation of highly concentrated organozinc compounds was also confirmed. To build on this work, the continuous conversion of organozinc compounds is described below. Two different reaction types were investigated: the noncatalyzed Saytzeff reaction and the palladium-catalyzed Negishi cross-coupling reaction. The former was carried out in both a two-step and a one-pot approach. The reactive allylzinc bromide was chosen as the organometallic reagent, which was reacted with various aldehydes and ketones to yield secondary or tertiary homoallyl alcohols. In the Saytzeff reaction, residence times of 2.0 min were sufficient to achieve complete conversion of the carbonyl compound and isolated yields of 66–98%. The conversion of the carbonyl compound was monitored using an online process IR spectrometer with flow cell. In the case of the Negishi coupling, a fixed-bed reactor filled with Pd catalyst was used. The syntheses investigated were focused on the reaction of benzylzinc bromide with various functionalized organic halides. The Negishi coupling provided complete to near complete conversion of the electrophilic substrate with isolated yields of 72–92% at residence times of 23–32 s. Both the Saytzeff and Negishi reactions were extended to include the conversion of highly concentrated 2.0 M organozinc compounds. The former delivered yields of 83% and 92%, the latter 72% and 79%. The Saytzeff conversion was additionally transferred to pilot scale to demonstrate the ease of scalability. The synthesis of two selected compounds was successfully transferred to pilot scale, where a liquid throughput of 13 L/h was achieved. The main objective of this work was to establish various catalyzed and noncatalyzed conversions of organozinc reagents, particularly at high organozinc reagent concentrations to enable fast and safe process intensification, optimization and scalability to industrially relevant throughputs.","PeriodicalId":55,"journal":{"name":"Organic Process Research & Development","volume":"58 1","pages":""},"PeriodicalIF":3.1000,"publicationDate":"2024-10-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"Organozinc Reagents: Highly Efficient Scalable Continuous Conversion in Various Concentrations and Reaction Types\",\"authors\":\"Lars Gössl, Kai Dahms, Gabriele Menges-Flanagan, Michael Maskos\",\"doi\":\"10.1021/acs.oprd.4c00292\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"Organometallic reagents play a crucial role in today’s synthetic chemistry. They are used in the production of active pharmaceutical ingredients (APIs), fragrances, and agrochemicals, among other things, as they are instrumental and invaluable to form new carbon–carbon bonds. In addition to the widely used organolithium and organomagnesium compounds, better known as Grignard reagents, organozinc compounds are predestined coupling partners in C–C bond formation. Even though organozinc compounds are among the oldest organometallic compounds, they have long been superseded by the more reactive Grignard reagents (RMgX) and lithium organyls (RLi). The low reactivity of organozinc compounds in combination with a high sensitivity to oxygen and moisture lead to difficult handling and problematic storage. Their usefulness for C–C bond formation was therefore underestimated for a long time but has experienced a renaissance in recent decades. In a previous publication, the scalable continuous synthesis of organozinc compounds in different concentrations and solvents was demonstrated. The organozinc compounds were produced in both laboratory and pilot scale with good to very good yields and the formation of highly concentrated organozinc compounds was also confirmed. To build on this work, the continuous conversion of organozinc compounds is described below. Two different reaction types were investigated: the noncatalyzed Saytzeff reaction and the palladium-catalyzed Negishi cross-coupling reaction. The former was carried out in both a two-step and a one-pot approach. The reactive allylzinc bromide was chosen as the organometallic reagent, which was reacted with various aldehydes and ketones to yield secondary or tertiary homoallyl alcohols. In the Saytzeff reaction, residence times of 2.0 min were sufficient to achieve complete conversion of the carbonyl compound and isolated yields of 66–98%. The conversion of the carbonyl compound was monitored using an online process IR spectrometer with flow cell. In the case of the Negishi coupling, a fixed-bed reactor filled with Pd catalyst was used. The syntheses investigated were focused on the reaction of benzylzinc bromide with various functionalized organic halides. The Negishi coupling provided complete to near complete conversion of the electrophilic substrate with isolated yields of 72–92% at residence times of 23–32 s. Both the Saytzeff and Negishi reactions were extended to include the conversion of highly concentrated 2.0 M organozinc compounds. The former delivered yields of 83% and 92%, the latter 72% and 79%. The Saytzeff conversion was additionally transferred to pilot scale to demonstrate the ease of scalability. The synthesis of two selected compounds was successfully transferred to pilot scale, where a liquid throughput of 13 L/h was achieved. 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Organozinc Reagents: Highly Efficient Scalable Continuous Conversion in Various Concentrations and Reaction Types
Organometallic reagents play a crucial role in today’s synthetic chemistry. They are used in the production of active pharmaceutical ingredients (APIs), fragrances, and agrochemicals, among other things, as they are instrumental and invaluable to form new carbon–carbon bonds. In addition to the widely used organolithium and organomagnesium compounds, better known as Grignard reagents, organozinc compounds are predestined coupling partners in C–C bond formation. Even though organozinc compounds are among the oldest organometallic compounds, they have long been superseded by the more reactive Grignard reagents (RMgX) and lithium organyls (RLi). The low reactivity of organozinc compounds in combination with a high sensitivity to oxygen and moisture lead to difficult handling and problematic storage. Their usefulness for C–C bond formation was therefore underestimated for a long time but has experienced a renaissance in recent decades. In a previous publication, the scalable continuous synthesis of organozinc compounds in different concentrations and solvents was demonstrated. The organozinc compounds were produced in both laboratory and pilot scale with good to very good yields and the formation of highly concentrated organozinc compounds was also confirmed. To build on this work, the continuous conversion of organozinc compounds is described below. Two different reaction types were investigated: the noncatalyzed Saytzeff reaction and the palladium-catalyzed Negishi cross-coupling reaction. The former was carried out in both a two-step and a one-pot approach. The reactive allylzinc bromide was chosen as the organometallic reagent, which was reacted with various aldehydes and ketones to yield secondary or tertiary homoallyl alcohols. In the Saytzeff reaction, residence times of 2.0 min were sufficient to achieve complete conversion of the carbonyl compound and isolated yields of 66–98%. The conversion of the carbonyl compound was monitored using an online process IR spectrometer with flow cell. In the case of the Negishi coupling, a fixed-bed reactor filled with Pd catalyst was used. The syntheses investigated were focused on the reaction of benzylzinc bromide with various functionalized organic halides. The Negishi coupling provided complete to near complete conversion of the electrophilic substrate with isolated yields of 72–92% at residence times of 23–32 s. Both the Saytzeff and Negishi reactions were extended to include the conversion of highly concentrated 2.0 M organozinc compounds. The former delivered yields of 83% and 92%, the latter 72% and 79%. The Saytzeff conversion was additionally transferred to pilot scale to demonstrate the ease of scalability. The synthesis of two selected compounds was successfully transferred to pilot scale, where a liquid throughput of 13 L/h was achieved. The main objective of this work was to establish various catalyzed and noncatalyzed conversions of organozinc reagents, particularly at high organozinc reagent concentrations to enable fast and safe process intensification, optimization and scalability to industrially relevant throughputs.
期刊介绍:
The journal Organic Process Research & Development serves as a communication tool between industrial chemists and chemists working in universities and research institutes. As such, it reports original work from the broad field of industrial process chemistry but also presents academic results that are relevant, or potentially relevant, to industrial applications. Process chemistry is the science that enables the safe, environmentally benign and ultimately economical manufacturing of organic compounds that are required in larger amounts to help address the needs of society. Consequently, the Journal encompasses every aspect of organic chemistry, including all aspects of catalysis, synthetic methodology development and synthetic strategy exploration, but also includes aspects from analytical and solid-state chemistry and chemical engineering, such as work-up tools,process safety, or flow-chemistry. The goal of development and optimization of chemical reactions and processes is their transfer to a larger scale; original work describing such studies and the actual implementation on scale is highly relevant to the journal. However, studies on new developments from either industry, research institutes or academia that have not yet been demonstrated on scale, but where an industrial utility can be expected and where the study has addressed important prerequisites for a scale-up and has given confidence into the reliability and practicality of the chemistry, also serve the mission of OPR&D as a communication tool between the different contributors to the field.